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PMC004xxxxxx/PMC4396961.txt
LICENSE: This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. 101313252 34584 J Vis Exp J Vis Exp Journal of visualized experiments : JoVE 1940-087X 25549203 4396961 10.3791/52432 NIHMS831093 Article Macrophage Cholesterol Depletion and Its Effect on the Phagocytosis of Cryptococcus neoformans Bryan Arielle M. 1* Farnoud Amir M. *1 Mor Visesato 1 Del Poeta Maurizio 1 1 Department of Molecular Genetics and Microbiology, Stony Brook University Correspondence to: Maurizio Del Poeta at maurizio.delpoeta@stonybrook.edu * These authors contributed equally 21 11 2016 19 12 2014 19 12 2014 28 11 2016 94 10.3791/52432This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. Cryptococcosis is a life-threatening infection caused by pathogenic fungi of the genus Cryptococcus. Infection occurs upon inhalation of spores, which are able to replicate in the deep lung. Phagocytosis of Cryptococcus by macrophages is one of the ways that the disease is able to spread into the central nervous system to cause lethal meningoencephalitis. Therefore, study of the association between Cryptococcus and macrophages is important to understanding the progression of the infection. The present study describes a step-by-step protocol to study macrophage infectivity by C. neoformansin vitro. Using this protocol, the role of host sterols on host-pathogen interactions is studied. Different concentrations of methyl--cyclodextrin (MCD) were used to deplete cholesterol from murine reticulum sarcoma macrophage-like cell line J774A.1. Cholesterol depletion was confirmed and quantified using both a commercially available cholesterol quantification kit and thin layer chromatography. Cholesterol depleted cells were activated using Lipopolysacharide (LPS) and Interferon gamma (IFNγ) and infected with antibody-opsonized Cryptococcus neoformans wild-type H99 cells at an effector-to-target ratio of 1:1. Infected cells were monitored after 2 hr of incubation with C. neoformans and their phagocytic index was calculated. Cholesterol depletion resulted in a significant reduction in the phagocytic index. The presented protocols offer a convenient method to mimic the initiation of the infection process in a laboratory environment and study the role of host lipid composition on infectivity. Immunology Issue 94 Infection phagocytosis Cryptococcus cholesterol cyclodextrin macrophages Introduction Phagocytosis is a process by which extracellular entities are internalized by host cells. It is a key weapon in the immune system’s arsenal to defend against pathogens, but the process may often be subverted by pathogens to allow for internalization and spreading throughout the body1. Phagocytosis is mediated by several signaling events that result in attachment and engulfment via rearrangements of the host cell’s cytoskeleton. ‘Professional’ phagocytes are able to recognize and bind to opsonins on the surface of the invading pathogen to signal for attachment and the formation of lamellipodia, which engulf the pathogen and form a phagosome2. Among the so-called ‘professional’ phagocytes are macrophages. Macrophages are highly specialized cells that carry out protective functions that include seeking out and eliminating disease causing agents, repairing damaged tissues, and mediating inflammation, most of these through the process of phagocytosis1,2. Cryptococcus neoformans is a species of pathogenic yeast that causes a serious disease known as Cryptococcosis. Cryptococcus spores are inhaled by the host and result in a pulmonary infection that is usually asymptomatic. It is thought that exposure is extremely prevalent; a sample of 61 children from the Pediatric Infectious Diseases Clinic at the Bronx-Lebanon Hospital Center found that all those surveyed had antibodies to the cryptococcal polysaccharide glucuronoxylomannan and other studies have shown prevalence in both human immunodeficiency virus (HIV) uninfected and infected adults3,4. Alveolar macrophages are the first line of response to the pulmonary infection and in most cases successfully clear the pathogen. However, in immunocompromised individuals (e.g., HIV and AIDS patients) the yeast is able to survive within the macrophages. In these cases, the macrophages can serve as a niche for the replication of the pathogen and may facilitate its dissemination to the central nervous system (CNS) where the disease becomes fatal5–8. It is thought that macrophages may even deliver the yeast directly into the meninges, helping the yeast to cross the blood brain barrier via the “Trojan horse” model3,9–11. Thus, it is important to understand the process of phagocytosis and the factors that affect it, especially in cryptococcal infections. Previous work in other pathogen systems point to cholesterol and lipid rafts formed by cholesterol as having an important role to play in phagocytosis12–15. Cholesterol is the most abundant lipid species in mammalian cells and comprises 25 – 50% of the mammalian cell membrane16. It has been found to play a role in modulating the biophysical properties of membranes by changing their rigidity17. Cholesterol and sphingolipids together form lipid microdomains within the membrane known as lipid rafts. Lipid rafts have been found to be involved in the formation of caveolae, as well as providing an isolated domain for certain types of signaling16–18. Due to their small size, it is difficult to study lipid rafts in vivo. One useful way to study the role of lipid rafts is to alter their constituents. Methyl-β-cyclodextrin (MβCD) is a compound that has been found to deplete cholesterol from mammalian membranes and is commonly used to study the role of lipid rafts18. In this protocol, we present a method to deplete cholesterol from host cell membranes and quantify the effect of the depletion on the ability of the host cells to phagocytose C. neoformans in vitro. This procedure makes use of cell culture techniques on an immortalized macrophage like cell line (J774A.1) as a model for infection. Cholesterol depletion was accomplished by exposure to MβCD, which has a hydrophobic core specific to the size of sterols and is able to act as a sink for cholesterol to draw it out of the membrane19. Cholesterol depletion was measured quantitatively using a commercially available kit and qualitatively using a modified Bligh-Dyer lipid extraction followed by thin layer chromatography (TLC)20. Phagocytosis was measured by infecting the cell line with a culture of opsonized yeast mixed with a cocktail of interferon-γ and lipopolysaccharide for activating the macrophages. Cryptococcus was opsonized using a glucuronoxylomannan (GXM) antibody21–23. Staining and microscopy experiments allowed for visualization of the cells and calculation of the phagocytic index to assess the degree of phagocytosis. Taken together, this protocol describes a basic method that integrates the alteration of lipid composition with a physiological process. Protocol 1. Cholesterol Depletion of J774A.1 Cells with MβCD In a sterile biosafety cabinet, seed 105 J774A.1 macrophage-like cells per well on a 96-well cell culture plate in 200 μl of Dulbecco’s Modified Eagle Medium (DMEM) supplemented with 10% fetal bovine serum (FBS) and 1% penicillin/streptomycin (P/S). Incubate at 37 °C and 5% CO2 O/N. Remove media from the cell monolayer and wash the cells twice with 1x phosphate buffered saline (PBS) that has been filtered or autoclaved. Add 200 μl of MβCD solution at the desired concentration (10 mM or 30 mM in PBS) or 1x PBS as a control and incubate for 30 min at 37 °C with shaking. Remove supernatant and reserve at RT for quantitative analysis with commercially available kit immediately following the procedure. Wash the cells two to three times with 1x PBS or serum free DMEM and continue with infection or lyse cells by pipetting two to three times with deionized H2O for analysis with thin layer chromatography or with a kit. NOTE: Following cholesterol depletion a commercially available cholesterol quantification kit can be used. See materials section for details. Follow manufacturer’s instructions as written. 2. Observation of Cholesterol Content by Thin Layer Chromatography (TLC) Wash a TLC tank twice with acetone and once with a solution of petroleum ether:diethyl ether:acetic acid (65:30:1 by volume). Saturate the tank with the petroleum ether:diethyl ether:acetic acid (65:30:1 by volume) solution and leave O/N. NOTE: Organic solvents should always be used under a fume hood to prevent inhalation of vapor. Gloves and lab coat should be worn at all times. Acetic acid is a strong acid and should be used with caution. In a sterile biosafety cabinet, seed 106 J774A.1 macrophage-like cells per well on a 6-well cell culture plate in a volume of 5 ml of warm DMEM supplemented with 10% FBS and 1% P/S. Incubate at 37 °C, 5% CO2 O/N. Deplete macrophages of cholesterol by following steps 1.2 – 1.4, substituting 1 ml for 200 μl where applicable to account for the larger well size. Add 500 μl of Trypsin-EDTA to each well, incubate for 3 min at 37 °C, and gently scrape cells with a cell scraper. Transfer into a microfuge tube and add an additional 500 μl of warm DMEM supplemented with 10% FBS and 1% P/S. Spin the cells for 5 min at 300 × g and remove the supernatant. Add an additional 500 μl of warm DMEM supplemented with 10% FBS and 1% P/S to the cell pellet and resuspend carefully by pipetting up and down. Remove 10 μl of cells and count cells on a hemocytometer. Normalize the cell concentrations from each sample and add an equal number of cells to glass tubes. NOTE: At this step, one may choose to combine cells from the same treatment groups to obtain a more concentrated final lipid extract. Centrifuge cells at 300 × g for 5 min at RT and remove media. Add 2 ml of methanol and vortex. Then, add 1 ml of chloroform and vortex. Check the phase status to make sure the solution in monophasic. NOTE: Tubes can be stored at 4 °C O/N. Centrifuge at 1,700 × g for 10 min at RT and transfer the supernatant to a new tube Add an additional 1 ml of chloroform followed by 1 ml of dH2O. Vortex twice for 30 sec. Centrifuge at 1,700 × g for 5 min at RT. Weigh a glass tube on a sensitive balance and use a glass Pasteur pipette to transfer the lower phase into the glass tube of known weight. Dry down lipids in a centrifugal evaporator until dry (approximately 2 hr). Weigh tube with dried lipids and calculate the dry lipid weight. NOTE: Dry lipids can be stored in −20 °C until ready to perform TLC. Dilute dried lipids in enough chloroform to normalize the concentration of lipid (usually 20 – 50 μl) and load 20 μl of the diluted lipid on a silica TLC plate. Load 20 μg of cholesterol diluted in 20 μl of chloroform as a standard. Add dried TLC plate to the saturated TLC tank and allow solvent to migrate up to 1 cm before plate edge. Remove TLC plate from tank and allow it to dry about 5 min. Visualize lipids by placing in an iodine vapor tank to check migration. Remove and allow spots to fade for about 10 – 15 min under the hood. NOTE: Iodine is an inhalation hazard. Always use under a fume hood. Prepare a solution for neutral lipid staining by combining 60 ml of methanol with 60 ml of deionized H2O, 4 ml of sulfuric acid, and 630 mg of manganese chloride. Carefully and slowly dip the TLC plate into the neutral lipid staining solution in a tray and remove without sloughing off the silica layer. NOTE: The neutral lipid staining solution can be reused several times and so it can be retrieved from the tray and placed back in a bottle for later use. Allow plate to dry under the hood at RT until all bubbles has disappeared. Heat the TLC plate on a heat block set to 160 °C and char to the desired color. NOTE: A densitometry program such as Vision Works LS can be used to quantify the charred bands to compare lipid samples. 3. Infection of Macrophages with C. neoformans (H99) In a sterile biosafety cabinet, seed 105 macrophage-like cells per well on a 96-well cell culture plate in 200 μl of DMEM supplemented with 10% FBS and 1% P/S. Incubate at 37 °C, 5% CO2, 5% CO2 O/N. NOTE: Infection can also be done in glass bottomed confocal dishes for easier imaging; all amounts remain the same. Grow a culture of C. neoformans (H99) by inoculating 10 ml of YNB with one colony obtained from a struck plate and incubating it O/N at 30 °C with shaking. Wash and count C. neoformans (H99) cells. Centrifuge C. neoformans O/N culture at 1,700 × g for 10 min at 4 °C. Remove media and discard. Wash cells with 5 ml of 1x PBS. Centrifuge at 1,700 × g for 10 min at 4 °C. Remove PBS and wash with 5 ml of filtered 1x PBS. Centrifuge at 1,700 × g for 10 min at 4 °C. Repeat this step 2 more times. Remove PBS and resuspend in 5 ml of 1x PBS. Make a serial dilution in PBS to obtain a 1:500 dilution of the washed culture. Add 100 μl of the original sample to 900 μl of 1x PBS to obtain a 1:10 dilution. Add 100 μl of 1:10 diluted sample to 900 μl of 1x PBS to obtain a 1:100 dilution. Add 200 μl of the 1:100 diluted sample to 800 μl of 1x PBS to obtain a 1:500 dilution Take 10 μl of 1:500 dilution and count on hemocytometer to calculate the number of cells. Prepare working solution for activating macrophages and opsonizing C. neoformans. Dilute LPS and IFNγ 100x from stock solutions by adding 10 μl to 990 μl. NOTE: LPS and IFNγ are used to enhance phagocytic uptake but are not required for phagocytosis. If there is an interest in fungicidal activity of macrophages, perform activation O/N at 37 °C with shaking prior to infection. Per sample combine 7.5 μl of diluted LPS, 1.25 μl of diluted IFNγ, 1.25 μl of GXM antibody and the volume of the C. neoformans culture that gives 1.25 × 105 cells. Bring volume up to 250 μl multiplied by number of samples with DMEM supplemented with 10% FBS and 1% P/S. Vortex and incubate solution for 20 min at 37 °C with shaking. NOTE: Cholesterol depletion (steps 1.2 – 1.4) can be done concurrently with the opsonization step. Be sure to treat macrophages prior to combining the working solution, as the opsonized cells should optimally be used no longer than 20 min following the step 3.4.3 incubation. Infect Macrophages Wash macrophages twice with serum free DMEM and add 200 μl of opsonized C. neoformans working solution to each well. Incubate for 2 hr at 37 °C. Fix and Stain Cells Remove media and wash cells 2 times with DMEM. Air dry the cell monolayer for 10 min and add 200 μl of ice cold methanol to fix the cells. Incubate for 15 min at RT and remove any remaining methanol. Add 200 μl of 10x Giemsa and incubate for 5 min at RT. Wash 2 – 3 times with deionized water and dry O/N with cap off. NOTE: Imaging can be done the next day or up to a week following staining. Visualize and Count Using a microscope, count 300 cells per data point (if there are 2 of the same treatment count 150 per well) and note the number of infected macrophages and number of engulfed Cryptococcus cells. NOTE: To ensure even sampling per data point use 2 plates per condition, choose 3 non-overlapping areas per plate and count 50 cells per area. Calculate phagocytic index by multiplying the percentage of infected macrophages by the mean number of C. neoformans per macrophage. Normalize phagocytic index by expressing values as a percentage of the 1x PBS treated control. After several trials calculate the mean value and the standard deviation of the mean to determine trends in phagocytic index. Use student t-test to determine significance. Take micrographs of cells at 1,000X or 400X magnification. 4. Trypan Blue Assay In a sterile biosafety cabinet, seed 106 macrophage-like cells per well on a 6-well cell culture plate in a volume of 5 ml of Dulbecco’s minimal essential medium (DMEM) supplemented with 10% fetal bovine serum and 1% penicillin/streptomycin. Incubate at 37 °C, 5% CO2 O/N. Deplete macrophages of cholesterol by following steps 1.2 – 1.4 substituting 2 ml for 200 μl where applicable to account for the larger well size. NOTE: Be sure to include a control treated with 1x PBS as well as a control that is scraped prior to any treatment. Add 500 μl of 1x PBS to each well and gently scrape cells with a cell scraper. Transfer into a microfuge tube and suspend the cells by gently pipetting up and down. Remove 10 μl of cells and stain with 1 μl of 4% Trypan blue. Count cells on a hemocytometer and calculate viability using the following equation: % viability = [1 − (Blue cells/total cells)] × 100. Normalize values to the control that was untreated. After several trials calculate the mean value and the standard deviation to determine trends in viability. Use student t-test to determine significance. Representative Results Cholesterol Depletion Analysis of the supernatant reserved in step 1.3 of the protocol by following the manufacturer’s instructions in the Amplex Red Cholesterol Assay kit yields an elevated concentration of cholesterol in MβCD treated sample as compared to the 1x PBS control. Depending on cell type and MβCD concentration used cholesterol depletion may vary. For J774 treated with 10 mM MβCD, a depletion of approximately 50% was observed. Depletion can be calculated using values obtained from the supernatant and cell lysate collected in step 1.4 (Figure 1). Cell lysate analyzed using TLC shows a marked decrease in staining of cholesterol in cells treated with increasing concentration of MβCD (Figure 2A). Densitometry analysis of the TLC shows a similar trend to the quantitative assay (Figure 2B). The Bligh-Dyer method gives a crude extract of total lipids and it is essential to allow for adequate separation of lipids in order to identify the correct band utilizing the cholesterol standard. Infection After following the infection procedure, cells remain adhered and intact. Cell morphology remains unchanged between treatment groups. A control group that has not been exposed to C. neoformans serves as a checkpoint (Figure 3). It is possible to obtain suboptimal results and may manifest as lysis of cells and other abnormal morphologies. The most likely cause is contamination of the cell line or reagents used in the procedure. Micrographs of optimally infected cells clearly show C. neoformans engulfed within the mammalian cells. Differences in number of phagocytized yeast may be noted by observation between treatment groups (Figure 4). After calculating phagocytic index from 300 macrophage cells per treatment group a reduction in phagocytic index is found in cholesterol depleted cells (Figure 5). The reduction in the phagocytic index does not appear to be dependent on potential differences in macrophage activation, although they may occur. Performing the infection in the absence of macrophage activators, but after treatment with MCD results in a similar reduction of phagocytic index (data not shown). Trypan Blue Trypan Blue staining is used to assess the viability of cells after cholesterol depletion. No change in viability is observed between PBS treated and 10mM MCD treated cells. Viability appears to drop off slightly after treatment with 30 mM MCD, which may be expected due to the approximately 75% depletion in cholesterol (an essential lipid) observed in the densitometry analysis (Figure 6 and Figure 2B). Discussion In working with this protocol it is important to obtain accurate cell counts when plating mammalian cells and opsonizing C. neoformans cells. This minimizes variation between trials and ensures an accurate 1:1 target to effector ratio throughout the study. It is also critical to coordinate the timing of the cholesterol depletion and infection to prevent the opsonized yeast cells or treated macrophage cells from resting at RT in between the procedures. Long waiting periods could lead to loss of antibody opsonization or the replenishing of depleted cholesterol before infection can begin. If experiments are done with precision the data analysis allows for conclusions to be discerned about the role of cholesterol in phagocytosis. The limitations of the technique prevent any conclusions as to the specific mechanism by which cholesterol depletion lowers the phagocytic index of macrophage like cells, and it is unclear whether the effect is directly due to cholesterol or due to a secondary mechanism. Further work along this vein investigates other constituents of lipid rafts such as sphingolipids or proteins known to function in phagocytosis such as the Fcγ receptor and the complement receptor 3 2. Modifying this technique to use either antibody opsonization or complement alone could help distinguish a role for cholesterol in one or both of these known pathways. It is also important to remember that MβCD extracts cholesterol based on its hydrophobicity and size, thus sterols of a similar size may also be depleted and will migrate at a similar rate as cholesterol on a TLC. It is also important to note that cholesterol depletion can partially affect macrophage activation, this is unlikely to be responsible for the difference observed in uptake as performing the infection in the absence of IFN- and LPS shows the same reduction in the uptake of C. neoformans (data not shown), but it is of interest when modifying this technique to study the anti-fungal activities of macrophages and the role of activation. This method also does not allow us to discern whether cholesterol depletion has any therapeutic implications in fungal infection. Further work in vivo with cholesterol-lowering drugs and epidemiological studies of patients using cholesterol-lowering drugs could further elucidate a role for cholesterol depletion in the treatment of the disease and may offer a more selective way to inhibit cholesterol accumulation. This procedure could easily be used to study uptake of other pathogens or solid particles (i.e., glass beads) being phagocytized and allow for the study of basic biology of phagocytosis. Modifications could allow for the study of other aspects of phagocytosis by treating the macrophage cells with enzymes to selectively degrade other membrane components or various drugs and inhibitors which may be of interest. It should also be noted that flow cytometry may present a more accurate and quantitative way to characterize phagocytosis and could be used to replace the direct microscopic count24. Altogether, this is a fairly simple technique that can be used as a starting point for more in depth studies that answer questions about how lipids may play an important part in infection and immune response. This work was supported by NIH grants AI56168, AI71142, AI87541 and AI100631 to MDP. Maurizio Del Poeta is Burroughs Wellcome Investigator in Infectious Diseases. Figure 1 Cholesterol content of supernatant after treatment Quantification of cholesterol in the supernatant collected from treated cells shows enrichment in MCD when compared to 1x PBS. Cholesterol depletion is 50 ± 5% calculated from total cholesterol in 1x PBS (supernatant + cell lysate). Error bars show standard deviation (n = 5). Figure 2 TLC of cholesterol in cell lysate and densitometry Image of developed TLC plate visualized with MnCl2 charring. A marked decrease in cholesterol is seen after MβCD treatment (A). Densitometry analysis of bands as compared to the PBS treated control (shown as 100%) confirms trend found in Cholesterol quantification assay (B). Please click here to view a larger version of this figure. Figure 3 Uninfected control micrographs of treated J774 macrophages Images of uninfected J774 cells taken at 200X magnification. Scale bar is 50 μm. 1x PBS (A), 10 mM MβCD (B), and 30 mM MβCD (C) treated cells show no change. Please click here to view a larger version of this figure. Figure 4 Infection of J774 macrophages with C. neoformans. Images of infected J774 cells taken at 400X (top row A.1 – C.1) and 1,000X (bottom row A.2 – C.2) magnification are shown. Internalized C. neoformans cells appear as blue-violet spheres with a lighter ring surrounding them. Cells treated with 1x PBS (A), 10 mM MβCD (B), and 30 mM MβCD (C) show differences in C. neoformans uptake. Please click here to view a larger version of this figure. Figure 5 Phagocytic index Phagocytic index is shown with respect to the control group that was treated with PBS (Marked at 100 for comparison). Phagocytic index was reduced by 25% by 10 mM MβCD treatment and by almost 55% by 30 mM treatment. Error bars show standard deviation of the mean (n = 4). Figure 6 Cell viability Variations in cell viability by trypan blue assay show little variation when comparing all three treatment groups. There is a slight drop off in viability in the 30 mM MβCD treatment group, which can be expected from depletion of such a major component of the membrane. Error bars show standard deviation (n = 4). Video Link The video component of this article can be found at http://www.jove.com/video/52432/ Disclosures The authors have nothing to disclose. 1 Sarantis H Grinstein S Subversion of phagocytosis for pathogen survival Cell Host & Microbe 12 4 419 31 10.1016/J.Chom.2012.09.001 2012 23084912 2 Rougerie P Miskolci V Cox D Generation Of Membrane Structures During Phagocytosis And Chemotaxis Of Macrophages: Role And Regulation Of The Actin Cytoskeleton Immunological Reviews 256 1 222 39 10.1111/Imr.12118 2013 24117824 3 Liu T Perlin DS Xue C Molecular Mechanisms Of Cryptococcal Meningitis Virulence 3 173 181 10.4161/Viru.18685 2012 22460646 4 Abadi J Pirofski L A Antibodies Reactive With The Cryptococcal Capsular Polysaccharide Glucuronoxylomannan Are Present In Sera From Children With And Without Human Immunodeficiency Virus Infection The Journal Of Infectious Diseases 180 3 915 9 10.1086/314953 1999 10438394 5 Kechichian TB Shea J Del Poeta M Depletion Of Alveolar Macrophages Decreases The Dissemination Of A Glucosylceramide-Deficient Mutant Of Cryptococcus Neoformans In Immunodeficient Mice Infection And Immunity 75 10 4792 8 10.1128/IAI.00587-07 2007 17664261 6 Casadevall A Cryptococci At The Brain Gate: Break And Enter Or Use A Trojan Horse? The Journal Of Clinical Investigation 120 5 1389 92 10.1172/JCI42949 2010 20424319 7 Chrétien F Pathogenesis Of Cerebral Cryptococcus Neoformans Infection After Fungemia The Journal Of Infectious Diseases 186 4 522 30 10.1086/341564 2002 12195380 8 Luberto C Martiñez-Marino B Identification Of App1 As A Regulator Of Phagocytosis And Virulence Of Cryptococcus Neoformans The Journal Of Clinical Investigation 112 7 1080 94 10.1172/JCI18309 2003 14523045 9 Mcquiston TJ Williamson PR Paradoxical Roles Of Alveolar Macrophages In The Host Response To Cryptococcus Neoformans Journal Of Infection And Chemotherapy: Official Journal Of The Japan Society Of Chemotherapy 18 1 1 9 10.1007/S10156-011-0306-2 2012 22045161 10 García-Rodas R Zaragoza O Catch Me If You Can: Phagocytosis And Killing Avoidance By Cryptococcus Neoformans. FEMS Immunology And Medical Microbiology 64 2 147 61 10.1111/J.1574-695X.2011.00871.X 2012 22029633 11 Coelho C Bocca AL Casadevall A The Intracellular Life Of Cryptococcus Neoformans Annual Review Of Pathology 9 219 38 10.1146/Annurev-Pathol-012513-104653 2014 12 Rao M Peachman KK Alving CR Rothwell SW Depletion Of Cellular Cholesterol Interferes With Intracellular Trafficking Of Liposome-Encapsulated Ovalbumin Immunology And Cell Biology 81 415 423 10.1046/J.1440-1711.2003.01192.X 2003 14636238 13 Sein KK Aikawa M The Prime Role Of Plasma Membrane Cholesterol In The Pathogenesis Of Immune Evasion And Clinical Manifestations Of Falciparum Malaria Medical Hypotheses 51 2 105 110 10.1016/S0306-9877(98)90102-5 1998 9881815 14 Pucadyil TJ Tewary P Madhubala R Chattopadhyay A Cholesterol Is Required For Leishmania Donovani Infection: Implications In Leishmaniasis Molecular And Biochemical Parasitology 133 145 152 10.1016/J.Molbiopara.2003.10.002 2004 14698427 15 Tagliari L Membrane Microdomain Components Of Histoplasma Capsulatum Yeast Forms, And Their Role In Alveolar Macrophage Infectivity Biochimica Et Biophysica Acta 1818 3 458 66 10.1016/J.Bbamem.2011.12.008 2012 22197503 16 Crane JM Tamm LK Role Of Cholesterol In The Formation And Nature Of Lipid Rafts In Planar And Spherical Model Membranes Biophysical Journal 86 5 2965 79 10.1016/S0006-3495(04)74347-7 2004 15111412 17 Brown DA London E Functions Of Lipid Rafts In Biological Membranes Annual Review Of Cell And Developmental Biology 14 111 36 10.1146/Annurev.Cellbio.14.1.111 1998 18 Simons K Toomre D Lipid Rafts And Signal Transduction Nature Reviews Molecular Cell Biology 1 1 31 9 10.1038/35036052 2000 11413487 19 Ilangumaran S Hoessli DC Effects Of Cholesterol Depletion By Cyclodextrin On The Sphingolipid Microdomains Of The Plasma Membrane The Biochemical Journal 335 Pt 2 433 40 1998 9761744 20 Bligh EG Dyer WJ A Rapid Method Of Total Lipid Extraction And Purification Canadian Journal Of Biochemistry And Physiology 37 8 911 917 10.1139/O59-099 1959 13671378 21 Mukherjee S Lee S Casadevall A Antibodies To Cryptococcus Neoformans Glucuronoxylomannan Enhance Antifungal Activity Of Murine Macrophages Infect Immun 63 2 573 579 1995 7822024 22 Deshaw M Pirofski LA Antibodies To The Cryptococcus Neoformans Capsular Glucuronoxylomannan Are Ubiquitous In Serum From HIV+ And HIV− Individuals Clinical And Experimental Immunology 99 3 425 32 1995 7882565 23 Tripathi K Mor V Bairwa NK Del Poeta M Mohanty BK Hydroxyurea Treatment Inhibits Proliferation Of Cryptococcus Neoformans In Mice Frontiers In Microbiology 3 5 187 10.3389/Fmicb.2012.00187 2012 22783238 24 Chaka W Quantitative Analysis Of Phagocytosis And Killing Of Cryptococcus Neoformans By Human Peripheral Blood Mononuclear Cells By Flow Cytometry Clin Diagn Lab Immunol 2 6 753 759 1995 8574842
PMC004xxxxxx/PMC4969178.txt
LICENSE: This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. 101242342 32406 Contemp Clin Trials Contemp Clin Trials Contemporary clinical trials 1551-7144 1559-2030 27282117 4969178 10.1016/j.cct.2016.06.002 NIHMS794281 Article Interim Methadone and Patient Navigation in Jail: Rationale and Design of a Randomized Clinical Trial Schwartz Robert P. M.D. 1* Kelly Sharon M. Ph.D. 1 Mitchell Shannon G. Ph.D. 1 Dunlap Laura Ph.D. 2 Zarkin Gary A. Ph.D. 2 Sharma Anjalee M.S.W. 1 O’Grady Kevin E. Ph.D. 3 Jaffe Jerome H. M.D. 14 1* Friends Research Institute, Baltimore, MD USA 2 RTI International, Research Triangle Park, NC USA 3 Department of Psychology, University of Maryland, College Park, College Park, MD USA 4 Department of Psychiatry, University of Maryland School of Medicine, Baltimore, MD USA * Please address correspondence to Robert P. Schwartz, M.D., Friends Research Institute, Inc., 1040 Park Avenue, Suite 103, Baltimore, MD 21201 USA; Voice: 410-837-3977 x276; Fax: 410-752-4218; rschwartz@friendsresearch.org 14 6 2016 07 6 2016 7 2016 01 7 2017 49 2128 This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. Background Methadone maintenance is an effective treatment for opioid dependence but is rarely initiated in US jails. Patient navigation is a promising approach to improve continuity of care but has not been tested in bridging the gap between jail- and community-based drug treatment programs. Methods This is an open-label randomized clinical trial among 300 adult opioid dependent newly-arrested detainees that will compare three treatment conditions: methadone maintenance without routine counseling (termed Interim Methadone; IM) initiated in jail v. IM and patient navigation v. enhanced treatment-as-usual. The two primary outcomes will be: (1) the rate of entry into treatment for opioid use disorder within 30 days from release and (2) frequency of opioid positive urine tests over the 12-month follow-up period. An economic analysis will examine the costs, cost-effectiveness, and cost-benefit ratio of the study interventions. Results We describe the background and rationale for the study, its aims, hypotheses, and study design. Conclusions Given the large number of opioid dependent detainees in the US and elsewhere, initiating IM at the time of incarceration could be a significant public health and clinical approach to reducing relapse, recidivism, HIV-risk behavior, and criminal behavior. An economic analysis will be conducted to assist policy makers in determining the utility of adopting this approach. methadone treatment interim methadone patient navigation criminal justice jail Introduction and background Opioid use disorder is a serious problem among the millions of annual arrestees throughout much of the developed world [1, 2]. In the US, individuals with heroin and/or other opioid misuse are overrepresented in jails compared to the general population with 8% of the US sentenced jail population reporting such misuse [3]. Although methadone maintenance treatment (MMT) in the community is an effective treatment for opioid use disorder [4, 5], such treatment is rarely initiated in US jails [6]. Given the increased risk of relapse, re-arrest, and overdose death after brief periods of imposed abstinence [7–9], there is considerable public health and economic interest in demonstrating cost-effective approaches to engage arrestees in effective treatment. Jails house arrestees awaiting trial and those serving sentences up to one year. There are about 3,163 jails in the US [10]. While some US jails provide methadone to pregnant women [11] and a few (e.g., in Albuquerque, NM, Baltimore, MD, New Haven, CT, and New York, NY) continue MMT for patients receiving treatment in the community at the time of arrest [12], the jail at Rikers Island in New York City is one of the only US jails that has reported initiating MMT for those of its inmates who request it [13]. Barriers to providing MMT in jails include security concerns related to methadone storage, stigma, unfamiliarity or philosophical opposition to opioid maintenance, lack of sufficient medical staff, and logistical and cost issues [14, 15]. An additional barrier is the cost of counseling needed under Federal and State methadone regulations. This barrier could be overcome by providing methadone without routine counseling. Such care is delivered throughout many European and Australian communities [16, 17]. In the US, methadone treatment without routine counseling (termed Interim Methadone [IM]) has been shown to be as effective as methadone with routine counseling in suppressing illicit opioid use [18–20]. These findings provide support for offering methadone without routine counseling to out-of-treatment arrestees who are opioid-dependent at the time of incarceration. Reports from the Rikers Island MMT indicate that many inmates started on MMT do not enter treatment upon release [21]. This led to the suggestion of providing help to patients, such as obtaining tokens for public transportation, ID cards, Medicaid, and negotiating the treatment entry process [6]. Patient navigation (PN), is a form of strengths-based case management that has been shown to be beneficial in increasing cancer screening and follow-up rates, improving entry and adherence to HIV treatment, and increasing the likelihood of drug treatment entry [22–26]. It is reasonable to assume that patient navigation might be useful to assist inmates in maintaining continuity of care in MMT upon release from incarceration. Because patient navigation was originally developed to assist women to receive medical services [27] and women seeking to enter substance abuse treatment face particular barriers including social stigma, childcare concerns [28], gender might be a moderating factor in response to navigation. The present study will compare the effectiveness and cost-effectiveness of three conditions: methadone maintenance without routine counseling (termed Interim Methadone; IM) initiated in jail v. IM and patient navigation v. enhanced treatment-as-usual for newly-arrested adults in the Baltimore City Detention Center. This study is part of the National Institute on Drug Abuse-funded SOMATICS cooperative study that is examining approaches to delivering FDA-approved pharmacotherapies to recently arrested adults with opioid dependence. The other two studies, which are examining extended-release naltrexone (XR-NTX), are led by University of California Los Angeles and New York University and are described elsewhere in this journal. 2. Research Design and Study Population 2.1 Study Design This study is a parallel three-group randomized effectiveness trial that examines: (1) interim methadone maintenance (IM) initiated in jail v. (2) IM and patient navigation (PN) v. (3) enhanced treatment-as-usual (ETAU) that includes a brief methadone detoxification. The participants will be 300 opioid-dependent newly-arrested detainees receiving treatment for opioid withdrawal in the Baltimore City Detention Center. 2.2 Research questions and hypotheses The primary research aims are to determine the relative effectiveness and IM+PN v. IM alone v. ETAU delivered to a newly-arrested adult population with an opioid use disorder in regard to: (1) increasing the likelihood of post-release treatment entry and retention in community-based methadone treatment; (2) reducing the likelihood of post-release opioid and cocaine use; and, (3) reducing HIV-risk and criminal behavior, arrest, and days of incarceration. We hypothesize that IM+PN and IM Alone Conditions will have superior outcomes compared to ETAU, and IM+PN will have superior outcomes to IM alone. Secondary research aims are to determine the relationship between gender and effectiveness and to examine the cost, cost effectiveness, and cost-benefit of the three study Conditions from a societal perspective. 2.3 Study site The study is being conducted by Friends Research Institute in Baltimore. The recruitment and during-detention methadone treatment site is in the Baltimore City Pretrial and Detention Services, a division of Maryland’s Department of Public Safety and Correctional Services (DPSCS). DPSCS operates a methadone treatment program that provides methadone detoxification and maintains methadone treatment for arrestees who were enrolled in a methadone program at the time of arrest. Prior to the present study, this program did not initiate methadone maintenance treatment for arrestees with an opioid use disorder with the exception of pregnant women. The site does not provide buprenorphine or extended-release naltrexone to arrestees. The four community Opioid Treatment Programs agreed to receive new patients who were released from the Detention Center on methadone because these programs did not have waiting lists. 2.4 Inclusion/Exclusion Criteria To be included in the study, detainees must: (1) meet DSM-5 criteria for opioid use disorder; (2) be detained for at least 48 hours (because those detainees who are released quickly are most often released within 48 hours and hence would not have time to receive services provided through the study); (3) be receiving opioid withdrawal treatment at the men’s and women’s Pre-trial Facilities; (4) be able and willing to provide informed consent in English; (5) be detained for a charge that, if found guilty, will likely result in a sentence of less than 1 year; (6) plan to reside in Baltimore (city or county) upon release; and (7) be 18 years of age or older. Individuals are excluded if they: (1) are enrolled in opioid agonist treatment (methadone or buprenorphine treatment) in the community at the time of arrest; (2) have a medical or psychiatric condition that would make participation unsafe in the judgment of the medical staff or the PI; (3) are pregnant; (4) are allergic to methadone; or (5) require treatment for moderate or severe alcohol or sedative hypnotic withdrawal. 2.5 Recruitment The Medical Staff of the Detention Center refers newly-detained adults who are receiving opioid detoxification to speak with the Friends Research Institute’s Research Assistant (RA) about the study. Nursing coordinates the RA’s visit for informed consent and baseline assessment and the pre-screening medical eligibility visit with the methadone program physician. 2.6 Informed Consent During the research visit, the RA describes the study, reviews the informed consent form and reviews the risks and benefits of participation. The RA underlines the points that participation is completely voluntary and will not impact their criminal justice status. Individuals who decline participation are informed about alternative options including completing the detoxification that they are receiving and attending drug abuse treatment in the community. The RA administers a consent quiz on which individuals must receive a perfect score within three attempts to be deemed eligible. 2.7 Screening, Randomization, and Follow-up Procedures After the individual provides written informed consent, the RA administers the baseline instruments described below. The RA completes the eligibility checklist and obtains the prescreen eligibility checklist and physical exam from the physician. The PI reviews the eligibility checklists and source documents (RA eligibility checklists, consent quiz, informed consent, physician pre-screen eligibility checklist and physical exam and pregnancy test results [which are collected for all women upon detention]) and then enrolls eligible individuals. Following enrollment, the RA meets with the participant to provide standardized information about drug abuse, HIV prevention, overdose prevention, and information on how to contact Baltimore’s substance abuse treatment helpline for an intake and referral to treatment in the community. The RA opens the next randomization envelope and informs the participant of his/her assigned study Condition. Participants are assigned to Conditions using a random permutation procedure, such that, within gender, for each block of 3, 6, or 9 participants, one-third will be assigned at random to the IM+PN Condition, one-third to the IM alone Condition, and one-third to the ETAU Condition. Random block sizes are used to thwart any attempt by the RA or others to deduce the random assignment procedure. The Project Manager provides the RA with sealed opaque envelopes based on this random permutation procedure. Participants do not receive compensation for the baseline interview during incarceration in order not to have the appearance of monetary coercion for study enrollment, but they will receive $30 for each of the four follow-up interviews regardless of whether they are in the community or re-incarcerated. 2.8 Data Management RAs complete baseline study assessments on paper teleform (including only the participant’s study ID number and no other identifiers) and upload PDFs of the teleforms to the UCLA Data Management Center (DMC). Paper forms are necessary because the RAs do not have internet access in the Detention Center. Data from follow-up visits are entered by the RA using UCLA DMC’s web-based data entry system. 3.0 Approvals and Data and Safety Monitoring 3.1 Approvals The Friends Research Institute (FRI) Institutional Review Board (IRB) approved the study. The US Office of Human Research Protections approved the study protocol and agreed with the IRB that it met the conditions for ethical conduct of research among prisoners under 45 CFR 46.306(a)(2)(iv). The study was registered at ClinicalTrials.gov (NCT 02334215). A federal Certificate of Confidentiality was obtained to protect the confidentiality of the participants’ data. 3.2 Data and Safety Monitoring The study is being monitored by a Data and Safety Monitoring Board (DSMB) at UCLA. The FRI IRB, the UCLA DSMB, and NIDA (the study sponsor) monitor recruitment, retention, and study safety. All Serious Adverse Events are reported to the IRB, DSMB, and NIDA medical monitor regardless of their possible relationship to study procedures. 4.0 Interventions 4.1 Enhanced Treatment-as-Usual (ETAU) Individuals assigned to ETAU receive opioid withdrawal treatment with a methadone detoxification over about one week. In addition, Research Assistants (RAs) provided these participants with standardized information used in all three SOMATICS studies on the harms associated with drug abuse, referral information to substance abuse treatment in the community, and HIV and overdose prevention information. 4.2 Interim Methadone Maintenance Alone (IM Alone) Individuals assigned to IM Alone receive an individualized gradual dose induction and administered methadone under direct observation through the Pretrial and Detention Service’s Methadone Treatment Program. They do not receive routine counseling but are able to receive mental health treatment at their request (as would any other inmate). They remain on methadone during their sojourn in the Detention Center until their release, unless they request to discontinue treatment or are transferred to another facility (e.g., due to sentencing or for serious rule infractions such as attempted diversion of methadone). In these cases, whenever possible, the participant undergoes a gradual dose reduction under medical supervision. The RA asks the participant at enrollment which of four participating methadone maintenance treatment (MMT) programs he/she would like to attend in the community. The Pre-trial and Detention Services Methadone Program nursing staff will arrange for transfer to the community programs upon release. Participants are told by the RAs to report to their MMT program on the day following release (or within three days, at the most) to ensure admission and continuity of care. The nursing staff arranges “courtesy dosing” at one of the four cooperating community-based MMT programs (as would occur on a trip to another state) until the participant can be seen by the receiving MMT program for intake and admission. 4.3 Interim Methadone plus Patient Navigation (IM+PN) In addition to interim methadone described above, participants assigned to the IM+PN Condition are seen by the study’s Patient Navigator once while detained for an assessment of community reentry needs (focused on barriers to MMT entry). The navigator is available to the participant approximately weekly for up to three months post-release. During this time, following a patient navigation manual developed for the project based on the work of Sorensen and colleagues [6], the navigator seeks to meet the participant at the MMT program to increase the likelihood of a smooth admission process and reaches out to those participants who do not attend their first visit or who subsequently drop out of treatment in the community following release. Using strengths-based case management and motivational techniques, the navigator helps the participant obtain needed services such as an ID card, reduced fare bus passes, health insurance, and medical or psychiatric appointments. The navigator has a small amount of funds available (an average of approximately $40 per participant) to assist the participant in obtaining ID cards, bus passes, and other related items. 5.0 Assessments Assessments are conducted by trained RAs. The RAs are blind to study Condition at baseline but it will not be possible to blind RAs at follow-up visits conducted at 1, 3, 6, and 12 months post-release because follow-up interviews for those in treatment are conducted at the MMT. All participants will be sought for follow-up interviews regardless of whether they remained in treatment. Addiction Severity Index (ASI) - Lite is a 30–45 minute self-report interview covering seven domains over the participant’s past 30 days, including days of heroin and cocaine use, and days committing illegal activities [29]. The ASI will be administered at baseline and all follow-up points. Urine Drug Screening Urine samples will be collected by project staff at 1, 3, 6, and 12 months post-release and tested by an approved rapid drug screen test card for opiates, oxycodone, methadone, buprenorphine, cocaine, marijuana, amphetamine, and benzodiazepines. Methadone or buprenorphine positive tests will not be treated as “illicit” drugs for the purposes of analysis if the participants are enrolled in a treatment program. Modified Composite International Diagnostic Interview, version 2 (CIDI-2) for Substance Use Disorders The modified CIDI-2 [30] will be used to determine whether individuals met the DSM-5 criteria for opioid and cocaine use disorders or remission in the 12 months prior to baseline and during the one-month period prior to the 3, 6, and 12 month study assessments. The CIDI-2 was recommended by an expert panel of the NIDA Clinical Trials Network (CTN) for gauging DSM-IV remission in clinical studies [31]. It has been shown to have excellent reliability in diagnosing individuals with drug dependence [32]. Arrests and Incarcerations In addition to self-reports, the official arrest and incarceration records will be obtained for 1 year prior and 1 year post-study enrollment from the Maryland Department of Public Safety and Correctional Services. Risk Assessment Battery (RAB) is a 45-item questionnaire covering substance use and sexual HIV-risk behaviors that has been extensively used with drug-dependent populations [33]. It will be administered at baseline, 6 and 12 month follow-up. The scale’s drug- and sex-risk scores will be used as secondary outcome measures. World Health Organization Quality of Life (WHOQOL-BREF) is a brief 32-item instrument developed by the World Health Organization that has been used in a wide variety of populations internationally [34–36] and has been found to have strong psychometric properties [37, 38]. The WHOQOL-BREF produces scores in four QoL domains: physical, psychological, social, and environmental. The WHOQOL-BREF also contains a single item, which is not incorporated into any of the four scale scores, asking participants to rate their overall QoL on a 5-point Likert-type scale from very poor to very good. It will be administered at baseline, 1, 3, 6 and 12 month follow-up. Methadone Dose Higher methadone maintenance doses in jail have been shown to be associated with higher rates of treatment entry following release from incarceration [39] and improved retention rates in community-based treatment [5]. As such, methadone dose will be recorded at release from the Detention Center and at each follow-up to permit an examination of the relationship between methadone dose and outcomes by treatment Condition. Methadone Treatment Exposure Questionnaire This brief 7 item questionnaire was devised for the present study and inquires whether and when the participant entered methadone treatment following release as well as the number of days of methadone treatment in the community. It will be administered at baseline, 1, 3, 6 and 12 month follow-up. We will validate the self-report with available Opioid Treatment Program records. Economic Form 90 survey was originally designed to collect alcohol use and economic outcome data for alcohol treatment studies [40, 41]. It will be modified to collect data on patients’ residential drug treatment, outpatient, emergency room, and inpatient hospital utilization; and criminal behavior, including number of arrests, severity of offense, and nights incarcerated. Also collected will be labor market information, including employment status, current wage, average hours worked per week, and amount of money received from government sources (e.g., Social Security) and off-the-books earnings. It will be administered at baseline, 3, 6 and 12 month follow-up. Overdose Adverse Event Form A brief questionnaire devised for this study will be administered at 1,3, 6 and 12 month follow-up to determine the number and type of non-fatal overdoses that occur. Substance Abuse Services Cost Analysis Program (SASCAP) Provider costs for each of the study conditions will be estimated using an activity-based costing approach which will allow cost estimation at the service level for study participants. To collect activity-level resource use and cost data, we will modify the SASCAP [42] to collect resource use and cost data for identified activities that are performed within each study condition. Activities will comprise clinically relevant treatment activities (including related support activities), and we will exclude research-related activities from the cost estimation. The SASCAP consists of a provider questionnaire administered once during the intervention phase to collect activity-level resource use and cost data for provider staff and non-labor resources such as contracted services, building space, supplies and materials, and other miscellaneous resources (e.g., utilities). It has been used to reliably estimate the costs of specific treatment activities and the total cost per patient [43–46]. 5.1 Primary Outcomes The study has two primary outcomes: (1) the rate of entry into treatment for opioid use disorder within 30 days from release from incarceration measured by self-report on the methadone treatment exposure questionnaire and (2) frequency of opioid positive urine test results over the 12-month follow-up period, determined from study administered urine screening at each of the four follow-up points. 5.2 Secondary Outcomes The study has a number of secondary outcomes measured as change over time across the four follow-up interviews. These include the presence of opioid use and cocaine use disorder, the drug- and sex-risk scores on the RAB, the specific domain and overall scores on the WHOQOL-BREF [35], the number of days in treatment for opioid use disorder, self-reported illicit opioid and cocaine use and criminal behavior, the number of arrests and incarcerations, and health care utilization. The cost of substance use services, health care utilization, and incarceration will be calculated over the 12 month post-release follow-up period. 5.3 Hypotheses There are several study hypotheses. Hypothesis 1A is that the IM+PN and IM Alone Conditions will have higher rates of treatment entry and greater retention, and concomitant lower rates of illicit opioid and cocaine use and of meeting DSM-5 criteria for opioid and cocaine use disorders, HIV-risk behavior, criminal behavior, arrests, and days of incarcerations than the ETAU Condition. We are not aware of any randomized trial comparing methadone treatment entry rates for jail-based methadone maintenance, with or without PN, compared to treatment as usual. The rationale for this hypothesis stems from a longitudinal non-random assignment study from the Rikers Island MMT Program that has shown better treatment entry rates post-release for inmates started on MMT rather than provided with detoxification in jail [6]. Hypothesis 1B is that the IM+PN condition will have superior outcomes compared to the other study conditions. This hypothesis is supported by research showing that PN is associated with higher rates of treatment entry than no PN in non-jail and non-prison samples of opioid-addicted adults [22]. Hypothesis 2A is that women in the IM+PN condition will have superior outcomes to men in the IM+PN condition, while hypothesis 2B is that women in the IM alone and ETAU will have poorer outcomes than men in those two conditions. These hypotheses stem from the few studies of reentry from jail for men and women treated with methadone that have shown that women are less likely to enter and remain in treatment [6]. In contrast, the PN literature shows that women respond well to this intervention [47, 48]. Therefore, we hypothesize that women will respond better than men to IM+PN. 6.0 Statistical Analysis 6.1 Explanatory Variables There will be a single treatment variable with three conditions: Intervention Condition [IM+PN v. IM Alone v. ETAU); a single moderator variable: Participant Gender, and three predictor variables – participant age, prior methadone maintenance treatment (yes v. no), and self-reported cocaine use at baseline. The predictor variables were chosen because of their association with outcomes in prior research in community based methadone treatment [49–53]. Finally, the “repeated factor” for all outcome variables measured repeatedly (see Table 1) will be assessment Time point, allowing for evaluation of both differential course and impact of the interventions. 6.2 Planned Contrasts It is possible to construct two orthogonal, single degree of freedom planned contrasts that directly test Hypothesis 1A and 1B, respectively. Contrast 1A will compare the two IM treatment conditions (IM+PN and IM Alone, pooled) to the ETAU condition, directly addressing the question of the differential effectiveness of some form of IM treatment in comparison to ETAU. Contrast 1B will compare the IM+PN condition to the IM alone condition, directly addressing the question of the relative effectiveness of adding PN to IM treatment. Similarly, it is possible to construct two orthogonal, single df planned contrasts that directly test Hypothesis 2A and 2B, respectively. Contrast 2A will compare males and females in the IM+PN condition, directly addressing the question of the differential effectiveness of IM+PN treatment for males and females. Contrast 2B will compare males and females in the IM Alone and ETAU conditions, pooled, directly addressing the question of the differential effectiveness of non-PN treatments for males and females. Given that both the course and impact of treatment are important to evaluate, planned contrasts can be examined both as each interacts with the “repeated factor” of Time (when there is a repeated factor), and as a “simple effect” at a given time point, in the event either Planned Contrast X Time interaction subeffect proves to be significant. 6.3 Economic Evaluation Using the collected cost data, we will derive total costs and costs per participant, and costs for specific services for each intervention. The total provider cost for each of the interventions will be the sum across each activity of: (1) staff labor costs (e.g., time spent performing intervention activities); (2) costs of building space; (3) costs of any equipment; (4) costs of medication; (5) costs of any supplies or materials; and (6) costs of any other miscellaneous resources used in the intervention. Taking the mean across participants for a given intervention will yield the mean cost per participant of that intervention. Following our cost estimation, we will conduct a cost-effectiveness analysis of the interventions from the provider perspective. We will combine the estimated provider costs of delivering the interventions with selected intervention effects. Our cost-effectiveness method will follow the approach described in the literature (e.g.,[44, 54]). Starting with the intervention with the smallest cost (or effectiveness), cost-effectiveness ratios will be computed for each intervention relative to the next most expensive option after eliminating intervention options that are dominated by other interventions [54]. An intervention may be either strictly dominated (higher cost and lower effectiveness than another option) or weakly dominated (higher cost-effectiveness ratio than a more effective option). Separate cost-effectiveness analyses will be performed for each selected outcome. Primary outcomes for the cost-effectiveness analysis include: (1) percentage of participants without opioid use disorder diagnosis at 12-month follow-up (based on the DSM-5 Opioid Use Disorder Diagnosis; and (2) number of days of opioid use in the past 30 days assessed at the 12-month follow-up. Secondary outcomes that we will also examine include: (1) number of days incarcerated; and (2) percentage of participants not engaging in HIV-related risky behavior (as measured by the RAB [33]). Finally, we will conduct a cost-benefit analysis to estimate the economic benefits associated with reductions in criminal activity and criminal justice system costs, improved employment, and reduced health care use (e.g., ER visits, hospitalizations). The difference between the monetized economic benefits and intervention costs represents the net economic benefits of the interventions (or cost savings). 6.4 Sample Size, Power, and Effect Size Power was estimated according to a procedure for general linear models outlined by Stroup [55, 56] as well as by the set correlation method [57, 58], assuming the primary outcome measures follow a normal distribution. Assuming a Type I error rate of .01 and a sample size of 300, the general linear model power estimates (1 – β, where β is the Type II error rate) associated with the hypotheses exceeded .81 in all cases, assuming “small” (.2 of a standard deviation [57]) differences associated with each such effect, even assuming an unstructured covariance matrix for those outcomes measured repeatedly. For the set correlation approach, assuming a Type I error rate of .01 and a sample size of 270 due to attrition in order to remain conservative, an effect size f2=.045 for a Planned Contrast effect for an outcome measured only once, and effect sizes f2=.045, .059, and .064 with a Planned Contrast X Time subeffect for outcomes measured two, four, or five times, respectively, for the hypotheses would yield a power of .9 for that subeffect, where f2 is defined as the ratio of the variance of the means relative to the variance of the observations [57]. These effect sizes, f2, all fall in the “small-to-medium” range, with f2=.02 considered a “small” effect and f2=.15 a “medium” effect [57]. In other words, and imprecisely, under the assumption that the effect in the population was ≥ .045 for a Planned Contrast or ≥ .045, .059, or .064 for the Treatment Condition X Time subeffects, for outcomes measured two, four, or five times, respectively, there is an 90% chance of concluding that effect is significant if α is set to .01 and 270 participants are assessed at 12-month follow-up. 8.0 Discussion Despite the large number of adults with opioid use disorder (OUD) arrested in the US every year, pharmacotherapy for OUD is rarely provided in the over 3,000 US detention centers. After almost 50 years of experience with methadone, only one US jail (in New York City) has reported initiating opioid agonist treatment pharmacotherapy for arrestees with OUD. As mentioned briefly in the introduction, there are numerous barriers to initiating pharmacotherapy for OUD in jail settings. Methadone treatment, unlike buprenorphine or extended release naltrexone, requires special federal and state program licenses. A critical mass of patients is desired to make operating a methadone program in a correctional institution practical, thus making it less likely to open such programs in smaller jails or those with small numbers of opioid dependent inmates. There are also philosophic barriers to providing opioid agonist medications to inmates. Additionally, budgetary considerations are barriers to providing any of these treatments. Corrections budgets may not reap most of the potential benefit of a post-release reduction in criminal behavior and health care costs. The lack of strong cost-benefit economic data of these programs makes it somewhat difficult to convince some policymakers of the utility of these programs. Developing a research database for these treatments with prisoners has been difficult, although not impossible, because of the legacy of concerns regarding human subject protection in vulnerable populations and that it requires approval from the federal Office of Human Research Protection. Despite all of these challenges, the number of correctional institutions providing opioid agonist treatment is increasing throughout the world. To date, prisons in most countries of the European Union, Australia, Canada, China, Iran, Indonesia, Moldova, and Kyrgyzstan have such programs [59]. The rationale for these programs has been the principle of making treatment in the community available to incarcerated individuals, the goal of reducing the spread of HIV infection, and the hopes of reducing recidivism. The present study, by examining the use of methadone without counseling, will provide a potentially practical solution for detention centers that may not have the funds to provide counseling but that already have existing medical infrastructure to administer methadone. Unlike the other FDA-approved medications for treating opioid dependence, methadone itself costs pennies per day. Thus, these cost-considerations might provide some support for the use of interim methadone treatment in jails. Because the low range of reported rates of entry into community-based MMT programs by inmates initiated on methadone at the Rikers Island program (ranging from 14% to 50%) leaves considerable room for improvement, we have chosen to compare IM alone to IM+PN. We expect that patient navigation, by reducing barriers to continued treatment in the community and re-engaging those who drop out over the first 3 months of MMT, will result in the IM+PN condition having higher rates of treatment entry, longer retention in treatment, and thereby have superior treatment outcomes. In designing the present trial, we considered alternative designs. First, we considered using buprenorphine or extended-release naltrexone. Both of these medications have some advantages because they can be used with less regulatory and storage security burdens than methadone. However, they both are considerably more expensive to purchase than methadone. Buprenorphine appears to be much easier to divert during treatment than methadone because it must be administered sublingually, and if diversion is to be minimized, the patient must be observed for 5–10 minutes until the dose is absorbed (in tablet or film form). A study using buprenorphine in a Maryland prison with sentenced prisoners expected to be released within several months found that more than 10% of participants attempted to divert the medication and hence were discontinued from receiving the medication [60]. This rate of attempted buprenorphine diversion was similar to that found by Magura and colleagues in a study at Rikers Island comparing methadone to buprenorphine treatment for sentenced jail inmates [21]. Although extended-release naltrexone has the advantage of being a non-controlled substance, it is relatively expensive and not yet widely available in the community. Nevertheless, there are certainly advantages and disadvantages of these three medications and conceptually it would be advantageous to patients to have all three as available in jails as they are in the community. We decided to include an enhanced treatment-as-usual (ETAU) arm as a comparison because virtually all jails in the US (including in Baltimore) use detoxification with non-opioid medications (or less often with methadone) as their “treatment as usual.” ETAU also includes substance use, overdose, and HIV-prevention information, and a referral to community treatment services, thus exceeding the normal provision of service to this population. These latter elements of ETAU are shared by the other two SOMATICS studies. The economic analysis may be of benefit to policy makers and correctional and public health officials. We anticipate that IM alone will have greater treatment costs than ETAU and that IM+PN will have greater costs than IM alone. However, the greater costs for the two experimental conditions may yield superior outcomes and thereby prove more cost-effective than ETAU. Similarly, cost offset in terms of reduced hospital and criminal justice costs associated with superior outcomes for the two experimental conditions may yield greater net benefits for these conditions compared with ETAU. There are a number of limitations to the study design. First, because the efficacy of methadone treatment was not in question, the use of a placebo was deemed inappropriate, and therefore the Patient Navigation intervention is being compared to an enhanced version of treatment as usual. Second, the study is being conducted in a "real world" jail in an urban community with both a substantial number of arrests and a relatively high prevalence of illicit opioid use. Therefore, findings may not generalize to other jail systems in other localities where the number of arrestees or the prevalence of illicit opioid use or the availability of maintenance treatment in the community could make the utilization of methadone maintenance impractical. For the same reason, the economic analysis may not generalize to other localities. However, in jail facilities where there is a lower prevalence of illicit opioid use among arrestees there may be sufficient time to supervise the use of buprenorphine. Initiating buprenorphine maintenance for opioid dependent arrestees might result in fewer deaths and continued treatment following discharge. We would like to thank the medical team at Wexford Health: Kelly Blizzard, RN, Tabethia Pardoe, RN, Kara Hope, RN and Drs. Woreta, Goodwin, Tessias, Getachew and Luka and the Maryland Department of Public Safety and Correctional Services including Drs. Sharon Baucom and Adaora Odunze; and the Daybreak, Glenwood Life, Man Alive, and REACH Opioid Treatment Programs, for their assistance in making this study possible. This study is being funded by the National Institute on Drug Abuse grant number 2U01DA013636 (PI: Schwartz). ClinicalTrials.gov: NCT02334215 Table 1 Data Collection Schedule and Measures Measures Baseline 1-month 3-month 6-month 12-month Treatment Entry (Methadone Treatment Exposure Form) ♦ Days in Treatment (self-report from EF-90) ♦ ♦ ♦ Illicit Opioid and Cocaine Use (ASI and urine drug testing) ♦ ♦ ♦ ♦ ♦ DSM-5 Criteria of opioid and cocaine use disorder (modified CIDI-2 SAM) ♦ ♦ ♦ ♦ Criminal Behavior (Addiction Severity Index) ♦ ♦ ♦ ♦ ♦ Arrests and Incarcerations: (Self report) ♦ ♦ ♦ ♦ HIV Risk Behavior (Risk Assessment Battery) ♦ ♦ ♦ Overdose Adverse Event Form ♦ ♦ ♦ ♦ Methadone Treatment Exposure Questionnaire ♦ ♦ ♦ ♦ Quality of Life (WHOQOL-BREF) ♦ ♦ ♦ ♦ ♦ Economic Form 90 (Health care utilization) ♦ ♦ ♦ ♦ Substance Abuse Services Cost Analysis Program (SASCAP) † Arrest and incarceration (Criminal Justice Records) ♦ ♦ Note: ASI = Addiction Severity Index; CIDI-2 SAM = Modified Composite International Diagnostic Interview 2 Substance Abuse Module; WHOQOL-BREF = World Health Organization Quality of Life-Brief Form * Participants transitioning directly to other community Methadone Maintenance Programs or buprenorphine treatment will be considered still in treatment. † Consistent with prior research, the SASCAP will be administered once during the treatment phase. Table 2 Consent Quiz INSTRUCTIONS: Please circle T for True or F for False. T or F 1. This study is comparing three ways to treat opiate addiction in the Detention Center. T or F 2. If I am in the study, I can choose which study group I am in. T or F 3. Methadone has no side effects. T or F 4. If I get the methadone detox group I may have a greater chance of overdosing if I relapse     to heroin use. T or F 5. I can drop out of the study once I start. T or F 6. The study does not provide drug abuse counseling services while I am in the Detention     Center. T or F 7. The patient navigator will help every participant in the study. T or F 8. Because I am in the Detention Center, I have to be in the study. T or F 9. Possible side effects of methadone include drowsiness. T or F 10. There are risks to being in the study. This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. 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PMC005xxxxxx/PMC5068189.txt
LICENSE: This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. 101489144 35623 Circ Cardiovasc Genet Circ Cardiovasc Genet Circulation. Cardiovascular genetics 1942-325X 1942-3268 27625337 5068189 10.1161/CIRCGENETICS.116.001431 EMS69925 Article Combination of Whole Genome Sequencing, Linkage and Functional Studies Implicates a Missense Mutation in Titin as a Cause of Autosomal Dominant Cardiomyopathy with Features of Left Ventricular Non-Compaction Hastings Robert MBChB DPhil MRCP 1 de Villiers Carin PhD 1 Hooper Charlotte PhD 1 Ormondroyd Liz PhD, MSc 1 Pagnamenta Alistair PhD 23 Lise Stefano PhD 3 Salatino Silvia PhD 3 Knight Samantha JL PhD, CBiol, MSB, FRCPath 23 Taylor Jenny C. PhD 23 Thomson Kate L. BSc, FRCPath 14 Arnold Linda MSc 1 Chatziefthimiou Spyros D. PhD 5 Konarev Petr V. PhD 56 Wilmanns Matthias PhD 5 Ehler Elisabeth PhD 7 Ghisleni Andrea MSc 7 Gautel Mathias MD, PhD 7 Blair Edward BMSc, MBChB 4 Watkins Hugh MD, PhD, FRCP 1 Gehmlich Katja PhD 1 1 Division of Cardiovascular Medicine in the Radcliffe Department of Medicine, University of Oxford; BHF Centre of Research Excellence 2 NIHR Biomedical Research Centre Oxford, University of Oxford, Oxford, United Kingdom 3 Wellcome Trust Centre for Human Genetics, University of Oxford, Oxford, United Kingdom 4 Department of Clinical Genetics, Churchill Hospital, Oxford University NHS Trust, Oxford, United Kingdom 5 European Molecular Biology Laboratory, Hamburg, Germany 6 Laboratory of Reflectometry and Small-Angle Scattering, A.V.Shubnikov Institute of Crystallography, Russian Academy of Sciences, Moscow, Russian Federation 7 Randall Division of Cell and Molecular Biophysics and Cardiovascular Division, King’s College London BHF Centre of Research Excellence, London, United Kingdom Correspondence: Katja Gehmlich, Division of Cardiovascular Medicine, Radcliffe Department of Medicine, University of Oxford, Level 6, West Wing John Radcliffe Hospital, Headley Way, Oxford OX3 9DU, United Kingdom, Tel: ++44 1865 234902, Fax: ++44 1865 234681, katja.gehmlich@cardiov.ox.ac.uk 3 10 2016 13 9 2016 10 2016 20 10 2016 9 5 426435 This file is available to download for the purposes of text mining, consistent with the principles of UK copyright law. Background High throughput next generation sequencing techniques have made whole genome sequencing accessible in clinical practice, however, the abundance of variation in the human genomes makes the identification of a disease-causing mutation on a background of benign rare variants challenging. Methods and Results Here we combine whole genome sequencing with linkage analysis in a three-generation family affected by cardiomyopathy with features of autosomal dominant left-ventricular non-compaction cardiomyopathy. A missense mutation in the giant protein titin is the only plausible disease-causing variant that segregates with disease amongst the eight surviving affected individuals, with interrogation of the entire genome excluding other potential causes. This A178D missense mutation, affecting a conserved residue in the second immunoglobulin-like domain of titin, was introduced in a bacterially expressed recombinant protein fragment and biophysically characterised in comparison to its wild-type counterpart. Multiple experiments, including size exclusion chromatography, small angle X-ray scattering and circular dichroism spectroscopy suggest partial unfolding and domain destabilisation in the presence of the mutation. Moreover, binding experiments in mammalian cells show that the mutation markedly impairs binding to the titin ligand telethonin. Conclusions Here we present genetic and functional evidence implicating the novel A178D missense mutation in titin as the cause of a highly penetrant familial cardiomyopathy with features of left-ventricular non-compaction. This expands the spectrum of titin’s roles in cardiomyopathies. It furthermore highlights that rare titin missense variants, currently often ignored or left un-interpreted, should be considered to be relevant for cardiomyopathies and can be identified by the approach presented here. genetics basic science research left ventricular noncompaction cardiomyopathy whole genome sequencing titin telethonin missense mutation Introduction Cardiomyopathies (CM) are a diverse group of diseases affecting the heart muscle 1; many of them are inherited and transmitted in autosomal dominant patterns. The first cardiomyopathy genes were identified by genome-wide linkage analysis in large families 2. In practice, however, the small size of most families, or even the availability of members of larger families, often limits the power of linkage analysis. Recently, high throughput next generation sequencing (NGS) techniques have become widely accessible, making whole genome sequencing (WGS) cost- and time-effective. However, the abundance of variation in the human genome 3 makes it difficult to distinguish rare benign variants from rare disease-causing mutations in an isolated individual, even with growing knowledge of variants in population cohorts (e.g. >60,000 sequenced exomes in the ExAC database, http://exac.broadinstitute.org/). NGS poses, therefore, a significant clinical challenge: the capability to assess variants as pathogenic lags significantly behind variant identification, especially for non-synonymous point mutations 4, 5. Algorithmic predictors are currently unable to accurately assess their exact impact on protein-protein interactions or even on protein folding. Experimental validation of genetic variants is therefore an increasingly indispensable component of NGS discoveries. In the current study, we combine WGS with linkage analysis in a medium-sized family affected by cardiomyopathy with features of left-ventricular non-compaction cardiomyopathy (LVNC). By performing WGS in two family members, filtering against variants seen in normal population cohorts and using linkage information derived from single nucleotide polymorphism (SNP) arrays of 13 family members, we could identify a missense variant in the titin gene (TTN) as the most plausible cause of disease in the family. Functional data, generated from biophysical and protein binding experiments on this titin missense variant provide further support of a causative role in cardiomyopathy through domain misfolding and destabilisation, resulting in impaired binding to the ligand telethonin (also known as t-cap). Methods Clinical Evaluation The study was approved by the Oxfordshire Research Ethics Committee B (REC Ref 09/H0605/3) and all subjects gave informed consent. A three-generational family with history of cardiomyopathy was recruited. Clinical assessment and genetic studies were performed in available family members, who had clinical examination, ECG, echocardiography (with contrast agent where appropriate) and cardiac MRI if possible. Diagnosis of cardiomyopathy was based on established criteria. The diagnosis of LVNC was based on published criteria from echocardiographic and/or cardiac MR imaging 6, 7: the compaction ratio (CR), i.e. the ratio of the thickness of non-compacted to compacted myocardium >2.3 measured on MRI in diastole, or >2.0 on echocardiography in systole was used to diagnose LVNC. Genetic Studies SNP array genotyping was performed using the Illumina HumanCytoSNP-12v1 BeadChip (Illumina, San Diego, CA), containing nearly 300,000 genetic markers, according to the manufacturer’s protocols. A refined subset of roughly 24,000 SNPs in approximate linkage equilibrium was generated using the software PLINK v1.07 8 and the HapMap genotype file available from the PLINK website (http://pngu.mgh.harvard.edu/purcell/plink/). Linkage analysis of the SNP subset was performed using MERLIN v1.1.2 9, specifying an autosomal dominant disease model. Genomic intervals with LOD scores > 0, compatible with segregation of variants in these regions, were selected for downstream analyses. WGS was performed on genomic DNA extracted from peripheral blood as part of the WGS500 project as described previously 10. Sequence reads from the affected individuals were mapped to the human reference genome (hs37d5 version of build 37) using STAMPY 11. Duplicate reads were removed with PICARD (http://broadinstitute.github.io/picard/). The software Platypus (version 0.8.1, default parameters) 12 was used jointly on the two .bam files in order to call SNPs and short (< 50 bp) indels across both samples. All the 5,946,161 identified variants were annotated with an in-house pipeline based on the Variant Effect Predictor (VEP) Ensembl framework (version 77) 13. A number of additional databases were used to integrate the information provided by VEP (Table S1). Known associations with diseases were screened using HGMD (http://www.hgmd.cf.ac.uk/ac/index.php) and ClinVar 14. Variants were filtered by in-house Python scripts based on criteria outlined in Table S1 (steps 1-10), followed by manual inspection (steps 11-13). The variants remaining after step 10 are documented in Results and in Tables S2, S3. Confirmatory Sanger sequencing was performed with the primers listed in Table S4. Both SNP and WGS data were interrogated also for clinically relevant copy number variants (CNVs) using Nexus Copy Number 7.5.2 Discovery Edition (BioDiscovery, Hawthorne, CA; see Supplementary methods). Functional characterisation of the titin missense variant The mutation was introduced into human titin Z1Z2 constructs (amino acids 1-196, accession no. ACN81321.1) for bacterial and mammalian expression using Quikchange II XL (Agilent) with primers given in Table S4. Bacterial expression and purification was performed as previously described 15. Size exclusion chromatography - Tridetector analysis (light scattering, refractive index, and UV absorbance), small angle X-ray scattering (SAXS) experiments, circular dichroism spectroscopy, and thermolysin digests were essentially performed as described 15–18 and experimental details are given in Suppl. Material. NRC cultures were established and transfected 16 using hemagglutinin(HA)-tagged expression constructs and counter-stained for titin T12 epitope 19 or telethonin (mouse monoclonal antibody, Santa Cruz) 48 hrs post transfection and analysed by confocal microscopy. GST pulldown assays were performed as described 20 using mammalian expression constructs for telethonin amino acids 1-90 and 1-167 fused to GST, and titin Z1Z2 fused to GFP (pEGFP-N1, Clontech) in transfected COS-1 cells. Förster Resonance Energy Transfer (FRET) experiments from transfected COS-1 cells and the assessment of reduced protein stability in NRC and COS-1 cells are described in the Suppl. Material. Results The proband was a 20yr old male (II-3 in Figure 1A) who died suddenly in hospital in 1970 having presented with rapidly decompensating congestive heart failure; at post mortem his heart (680 g) had evidence of dilatation and both macroscopic and microscopic hypertrophy but no myocyte disarray. His brother (II-4) was later found to have an enlarged heart with wall thickness at the upper limit of normal and marked hypertrabeculation. The proband’s sister (II-2) presented with a non ST-elevation myocardial infarct due to coronary embolus at the age of 61. LVNC with mild LV dilatation and apical hypertrophy was diagnosed at this time (Figure 1B, C). Cascade screening identified the same condition in further family members with consistent clinical features of adult onset cardiomyopathy with features of LVNC. Five affected family members had sufficient non-compaction to meet the diagnostic criteria for LVNC while three others with early or mild disease had lesser extent of hypertrabeculation but clear evidence of cardiomyopathy with LV dilatation and/or systolic dysfunction (Figures 1A, S1, Table 1). Aside from the proband who had advanced congestive failure, there were no arrhythmic features in any affected family member, nor were there any extra-cardiac (e.g. neuromuscular) manifestations. Identification of TTN mutation A178D segregating with disease Affected first cousins III-1 and III-4 were selected for WGS. Sequencing was performed by Illumina Cambridge as 100bp paired-end reads to a mean coverage of 56.9x and 52.0x respectively, such that 99 % of the genome was covered at 20x or more in both samples, identifying 5,946,161 variants shared by the two individuals. In addition, SNP arrays were performed on all individuals of the family (except II-3 and III-2, Figure 1A). Neither the SNP array nor WGS data revealed likely causative CNVs. Genomic regions identical by descent were identified through linkage analysis (see Methods, Figure S2) and out of the 100,789 candidate variants within the three linkage regions (on chromosomes 2, 9 and 16), potentially pathogenic ones were selected based on an autosomal dominant model, caused by a rare heterozygous mutation. Variants were filtered accordingly by in-house Python scripts and the remaining six variants were manually inspected (Table S2). Four of them were excluded: one is assumed to be an artefact due to an incorrect transcript being present in Ensembl and another variant did not segregate with disease in the family; two splice variants were predicted to be silent (at positions -5 and -3 of a 3' splice junction, respectively, for details see Table S3). Only two final candidate variants were considered conceivably linked to the phenotype: missense changes in PDP2 and TTN, respectively (Table S2). PDP2 codes for pyruvate dehyrogenase phosphatase catalytic subunit 2 and has low expression levels in the heart. Although the change E316K is predicted to be damaging by Polyphen and SIFT algorithms (Table S2), a heterozygous loss-of-function in this enzyme would not be expected to produce a phenotype, and indeed heterozygous loss-of-function mutations in PDP1 are clinically silent 21. The variant is not plausible as a cause of a penetrant dominant disorder because it is found six times in 121,412 alleles in the ExAC database. Six instances would equal at least 10 % of all expected LVNC cases in ExAC, assuming a maximal prevalence of 1:1,000 for the disease 22. This appears an implausibly high percentage for a novel, unpublished disease-causing variant. In support, in the two largest clinical cardiomyopathy cohorts published to date, the most common reported pathogenic variant (MYBPC3, p.Arg502Trp) detected in 104 out of 6179 HCM cases (1.7%, 95CI 1.4-2.0%), was only observed 3 times in ExAC (3/120,674) with all other pathogenic variants for HCM or DCM being present 0 or 1 times only 23. The second variant is found in TTN, the gene which codes for titin, an abundant skeletal muscle and heart specific protein with crucial functions 24, 25 (and reviewed in 26). Mutations in titin have been associated with CM and skeletal myopathy (reviewed in 27). The identified missense variant c.533C>A in TTN, which codes for a p.A178D change at the amino-acid level, is absent in ExAC. Sanger sequencing confirmed the co-segregation of the heterozygous mutation with disease in all affected individuals of the family (Figures 1, S3A, LOD score 2.1). Thus comprehensive whole genome analysis reveals this as the most plausible causative mutation in the family. Functional studies Prediction of deleterious effects of the mutation Each single molecule of the giant protein titin spans half a sarcomere from the Z-disk to the M-band 28. The first two Immunoglobulin-like (Ig) domains (Z1Z2) of titin are located in the Z-disk and form a super-stable complex with telethonin 29. The A178 position is evolutionarily very well conserved back to zebrafish and lamprey. Additionally, A178 is located in a highly conserved structural section (Figure S3B), the β-strand F of the second Ig-domain of Z1Z2, neighbouring the β-strand G of titin Z2 which forms a strong and extended interaction with the β-strands of telethonin (30, Figure 2A). The A178D mutation is predicted to directly affect the β-strands B and C as well as the loop connecting the β-strands B and C due to steric hindrance of D178 with V127 and P133 respectively (Figure 2B). Thus, the insertion of a charged residue in this position is likely to have significant impact on the secondary structure of this domain and could potentially cause misfolding of the protein. Altered protein characteristics of purified titin Z1Z2 A178D recombinant fragment To assess how the A178D mutation affects the folding and stability of the protein, recombinant titin Z1Z2 WT and A178D were expressed in E. coli and purified under native conditions. Of note, the yield of the soluble protein fraction was consistently lower for A178D compared to WT preparations, despite equal total expression levels (data not shown). Circular dichroism (CD) spectroscopy demonstrated a typical β-sheet signature for WT Z1Z2 (Figure 3A). In contrast, the spectrum for Z1Z2 A178D differs significantly: Although the characteristic negative band at 216 nm is still present, but slightly shifted, there was no significant positive band at around 200 nm. The absence of this band, associated with β-sheet conformation, and the presence of a negative peak at around 198 nm, characteristic of random coil structures, indicate that the Z1Z2 A178D mutant is partially unfolded. In support, thermal denaturation experiments for Z1Z2 A178D showed high fluorescence signal already at low temperatures, suggesting solvent exposed hydrophobic residues due to partial unfolding. No melting temperature can be deducted for titin Z1Z2 A178D, in contrast to the WT protein, which has a melting temperature of 62 ºC, typical for Ig domains (Figure S4). SAXS experiments confirmed the presence of unfolded parts/flexible domains in Z1Z2 A178D, as shown by the Kratky plot (Figure S5A), whereas Z1Z2 WT displays a typical profile for folded structures. The domain destabilisation as a consequence of partial unfolding is evidenced by the formation of higher oligomers (approx. 20-mers) for the Z1Z2 A178D mutant in vitro: Size exclusion chromatography and Tridetector analysis revealed that in contrast to the monomeric Z1Z2 WT, the A178D mutant eluted in two peaks, corresponding predominantly to higher molecular aggregates and to a lesser extent to dimeric protein (Figure 3B, Table 2). SAXS measurements also confirmed that Z1Z2 WT is monomeric, whereas Z1Z2 A178D is found in a higher oligomeric state (Figure S5B, Table 2). In conclusion, the mutation A178D leads to partial misfolding of bacterially expressed Z1Z2 protein fragment. Reduced stability of titin Z1Z2 A178D as a consequence of the partial misfolding When performing denaturing gel electrophoresis, a degradation product was observed exclusively for Z1Z2 A178D preparations (arrowhead in Figure 4A) and upon thermolysin treatment, only Z1Z2 A178D showed rapid degradation, while Z1Z2 WT was resistant to the protease treatment (Figure 4B). In addition, Z1Z2 A178D showed reduced stability when expressed in neonatal rat cardiomyocytes and COS-1 cells (Figures 4C, S6), suggesting that the mutation destabilises Z1Z2 also in a physiological, cellular environment. However, formation of large aggregates was not observed in transfected cells expressing Z1Z2 A178D (Figures 4D, S7). Impaired binding to telethonin Localisation of transfected Z1Z2 was not altered in the presence of the A178D mutation (Figure 4D). To assess the consequences of the mutation on binding telethonin, semi-quantitative GST-pulldown assays were performed with titin Z1Z2 and telethonin co-expressed in mammalian cells. Z1Z2 A178D showed impaired binding to two telethonin constructs (Figure 5A, B). The interaction between titin and telethonin was further quantified in FRET experiments, where close proximity of proteins in a complex allows energy transfer from Cyan Florescent Protein (CFP) to Yellow Fluorescent Protein (YFP) between two fusion protein constructs 31. By introducing the A178D mutation into a Z1Zr3-CFP construct, FRET efficiency to telethonin-YFP was almost abolished (Figure 5C, D), validating and quantifying the observation that A178D impairs binding to telethonin in the cellular context. Taken together, our functional data suggest that the A178D mutant may affect protein folding, stability and impairs binding to telethonin, thus supporting its pathogenic potential. Discussion In this study, we present a three-generation family with multiple individuals affected by cardiomyopathy with features of LVNC, systolic impairment and an autosomal dominant inheritance pattern. Of note, the affected family members show a consistent phenotype with prominent hypertrabeculation as the main abnormality in the majority; this is relatively unusual as it is more typical to see LVNC in individual members of families with other forms of cardiomyopathy. We employed a combination of WGS in two affected individuals and linkage analysis in 13 family members; this approach identified only two rare candidate variants across the whole genome that segregated with the autosomal dominant cardiomyopathy. Since one of the identified genes (PDP2) is barely expressed in the heart, and the variant appears in implausible high numbers in the ExAC database, it is extremely unlikely to be disease-causative. In contrast, titin, the gene affected by the other missense variant (TTN p.A178D), has crucial functions in the heart and is a known disease gene for cardiomyopathies (see below). Despite the fact that the family is too small for traditional genome-wide linkage analysis to identify the genetic cause of the disease (the LOD score of 2.1, i.e. odds ratio 1:125, is well below the threshold of 3.0, i.e. odds ratio 1:1000), interrogation of the entire genome adds substantial weight to a likely causative role of the titin missense mutation for disease: no other plausible mutations, including larger genomic re-organisations (CNVs), were detected in any other genes in the linkage regions and the remainder of the genome is excluded by negative LOD scores. Titin has been implicated in cardiac and skeletal muscle disease, occasionally involving a combination of both. Mutations in this gene have been described in various forms of CM, such as Dilated CM, Arrhythmogenic Right Ventricular CM, Hypertrophic CM and Restrictive CM (reviewed in 27). Truncating variants in titin (TTNtv) are the most frequent genetic finding in idiopathic Dilated CM, being present in 15-25 % of the cases 32 and are also frequent in Peripartum CM (15 %) 33. However, penetrance appears to be low, as TTNtv are also found in approx. 1 % of normal populations and hence the large majority of carriers do not manifest with disease 34. More recent work 35 showed that Dilated CM causing TTNtv are enriched in the sarcomeric A-band region, whereas TTNtv found in control cohorts tend to spare the A-band region and are in exons with low usage in cardiac transcripts. An internal promotor in titin rescuing TTNtv N-terminally of the A-band region may explain this phenomenon 36. Titin missense mutations have been identified in Dilated and Hypertrophic CM cohorts 4, 37, 38. A causative role for TTN p. W976R in Dilated CM is well supported by co-segregation within a large family and functional data 39, 40. However, generally, titin missense mutations are challenging to interpret, as rare benign variants are common in normal population cohorts. In the ExAC database, more than a third of the individuals carry a rare missense variant in titin (21,939 missense variants with <0.01 % allelic frequency in 58,687 exomes), and although a proportion of these may represent recessive pathogenic alleles 27, only a very small fraction will be disease-causing with dominant inheritance. Hence, clinical practitioners require co-segregation information to assign causality as bioinformatic prediction tools can only give probabilistic data 4, 37. As we document here, interrogation of the entire genome combined with linkage analysis can help to narrow down lists of potential causative variants, even in small families. Our finding of TTN p.A178D in a family with features of LVNC expands the spectrum of titinopathies: to our knowledge, this is the first report of a titin missense mutation implicated in cardiomyopathy with predominant features of LVNC and one of the first titin missense mutations supported by robust genome-wide genetics and detailed functional data. The latter suggests a likely pathogenic role of titin A178D by a) evidence of protein degradation, partial unfolding and domain destabilisation in vitro, b) protein destabilisation in two cellular systems and c) altered binding properties to the ligand telethonin. Although extrapolations from such in vitro experiments on isolated domains to the full length giant protein are not without uncertainty, such parameters will be useful complements in the future studies of other TTN missense variants. It is currently unclear how this particular mutation leads to this distinct phenotype, and more insight into the biology of Z-disk titin is needed to understand the underlying disease pathways. This will be addressed with the help of model organisms 36, 41 or patient-derived induced pluripotent stem cell derived cardiomyocytes 40, focussing on the titin-telethonin complex 29 and its downstream signalling targets 42 in future work. Supplementary Material Supplemental Material Acknowledgments” We thank Stephan Lange (UCSD) for a titin Z1Z2 expression constructs. SAXS data were collected at the beamline P12, operated by EMBL, Hamburg unit, at the PETRA III storage ring (DESY, Hamburg, Germany). We gratefully thank Dmitry Svergun and his group for help with the SAXS data, the SPC facility at EMBL Hamburg for technical support and Annabel Parret for her help with the Tridetector Analysis. Sources of Funding: KG is supported by British Heart Foundation Grants (FS/12/40/29712, PG/15/113/31944). KG, RH and HW acknowledge support from the BHF Centre of Research Excellence, Oxford (grant codes HSRNWBY, HSRNWB11 and RE/13/1/30181). KLT is the recipient of a National Institute for Health Research (NIHR) doctoral fellowship (NIHR-HCS-D13-04-006). This publication includes independent research supported also by the NIHR Biomedical Research Centre, Oxford. The work was supported also by funding from the Wellcome Trust Core Award Grant Number 090532/Z/09/Z. The views expressed are those of the authors and not necessarily those of the Department of Health or Wellcome Trust. MG and AG were supported by the EU MUZIC network, the MRC and the Leducq Foundation. MG holds the BHF Chair of Molecular Cardiology. Clinical Perspective High throughput next generation sequencing techniques have made whole genome sequencing accessible and are increasingly applied in clinical practice. However, the abundance of variation in the human genomes makes the identification of a disease-causing mutation on a background of benign rare variants challenging. To illustrate, more than one third of individuals in normal population cohorts carry a rare missense variant in the giant protein titin (coded by the gene TTN), but only a very small fraction of these will be disease-causing with dominant inheritance. Hence titin missense variants are currently often ignored or left un-interpreted when found in cardiomyopathy patients. Here we combine whole genome sequencing with linkage analysis in a three-generation family affected by cardiomyopathy with features of autosomal dominant left-ventricular non-compaction cardiomyopathy. A missense mutation in titin (TTN p. A178D) is the only plausible disease-causing variant that segregates with disease amongst affected individuals of the family, with interrogation of the entire genome excluding other potential causes. Functional studies on this missense mutation demonstrate domain misfolding and destabilisation, resulting in paired binding to the ligand telethonin/t-cap,and hence supporting its highly likely causative role. Our report expands the spectrum of titin’s roles in cardiomyopathies and furthermore highlights that rare titin missense variants should be considered to be relevant for cardiomyopathies and can be identified by combining whole genome sequencing with linkage analysis in medium-sized cardiomyopathy families. Figure 1 A – Pedigree of the family, males depicted as squares, females as circles, slanted symbols deceased individuals. Clinically affected individuals are marked in grey, unaffected are shown in white, “?” means unclassified clinical status. The presence of the TTN p.A178D mutation is indicated (“+”present, “-“absent, ND not determined.) Individuals selected for WGS are marked with thicker symbols (III-1 and III-4). B – Echocardiogram images showing the characteristic 'spongy' appearance of non-compaction in individual II-2 with and without contrast. C – Echocardiogram image from individual II-4 showing significant dilatation, but maintaining a thickened myocardium and preserved ejection fraction. Figure 2 A – Position of the TTN p. A178D on a structural model (pdb: 1YA5) of the titin Z1Z2 domains (purple) in complex with telethonin (pink). B – Close-up of the site of mutation. The red discs show van der Waals overlaps or steric clashing that A178D is predicted to cause with valine127 and proline133. The figures of the crystal structure were generated by pymol (http://www.pymol.org). Figure 3 A – CD spectroscopy of purified titin Z1Z2 fragments (WT solid line and A178D dashed line). B – Size exclusion chromatography for titin Z1Z2 fragments (WT solid line and A178D dashed line). Z1Z2 WT elutes as monomeric protein ($), whereas peaks corresponding to dimer (*) and higher molecular aggregates (#) are observed for Z1Z2 A178D. Figure 4 Destabilisation of the titin Z1Z2 fragment in the presence of the A178D mutation: A – Denaturing gel-electrophoresis of purified titin Z1Z2 fragments (WT and A178D) expressed in E. coli. The WT fragment is detected as a single band of 23 kD (arrow). Only for Z1Z2 A178D a degradation product (arrowhead) is observed. The position of marker proteins and their size (in kD) is indicated. B – Titin Z1Z2 protein fragments (WT – left, A178D – right) were incubated with protease thermolysin for the length indicated. Control: titin Z1Z2 protein sample without thermolysin. A stable degradation fragment of approx. 15 kD is observed for the mutant titin Z1Z2. The position of marker proteins and their size (in kD) is indicated. C – Decreased stability of titin Z1Z2 A178D in NRC: NRC were infected in duplicates with adenoviral particles for HA-tagged titin Z1Z2 (WT or A178D, MOI 5). Infection with parental empty vector (GFP) and non-infected cells (NI) served as controls. Steady-state titin fragment protein amount was assayed by Western blotting for the HA-tag. Probing for hrGFP served as infection control and probing for endogenous GAPDH served as loading control. Despite equal infection rates (for confirmatory control experiments see Figure S6A), less titin A178D protein fragment was detected, indicating reduced stability in NRC. D – Localisation of titin Z1Z2 in NRC: Cells were transfected with constructs coding for HA-tagged titin Z1Z2 WT (top, first row) or titin Z1Z2 A178D (bottom, first row) mutant protein fragment and counterstained for endogenous titin with T12 antibody (middle row, Z-disk proximal epitope, but not recognising the transfected titin Z1Z2 protein fragment). Merged images are shown in the third row, HA shown in red, endogenous titin in green. Scale bar represents 10 microns. Figure 5 Functional implications of the titin Z1Z2 A178D mutation. A – Semi-quantitative GST-pulldown assays using telethonin fragments fused to GST (left aa 1-90, right full length) and titin Z1Z2 fragments (WT and A178D as indicated) as GFP fusions expressed in COS-1 cells. Bound titin-GFP fragments are detected by Western blotting (top row), input lysate controls are shown in the second row. Pulled down GST-telethonin fragments are shown in row three, as well as lysate controls (bottom row). B – Quantification of GST-pulldown experiments from panel A visualises reduced binding of titin Z1Z2 to telethonin in the presence of the A178D mutation, values are expressed as bound protein relative to lysate, with the first WT experiment set to 100 % (n = 2 per group, values expressed as mean with standard deviation for error bars; one representative experiment of three independent ones is shown). Due to the semi-quantitative nature of the experiments, no statistical test was performed. C – FRET experiments using COS-1 cells co-transfected with telethonin (aa 1-90) fused to YFP (first row) and titin Z1Zr3 fused to CFP (second row). Images pre- and post-bleach are shown, FRET ratios are shown in the third row. Inserts show magnification of indicated area. Scale bar represents 10 microns. D – Quantification of FRET efficiency for titin Z1Zr3 WT/A178D and telethonin pairs. The A178D mutation reduces the FRET efficiency from approx. 0.15 to 0.01 indicating a dramatic loss of binding ability (WT n=20 and A178D n=26 cells; * p < 0.0001 unpaired Student’s t-test). Table 1 Summary of clinical findings. Symbol Sex Age* Clinical status† Genetic status Trabeculation compaction ratio (CR)‡ IVS D PW D LVED D LVES D EF ECG Comments I-1 M 87 affected TTN A178D 2.5 (echo) 24 13 40 35 42 left axis deviation, anteroseptal Q wave Marked ASH with low EF, CVA, hypertension; meets diagnostic criteria for LVNC (echo). I-2 F 72 unaffected WT 1.8 (echo) 12 11 48 30 76 AF, paced LVNC excluded (echo), structurally normal heart at age 70, moderate concentric LVH by age 85 II-2 F 61 affected TTN A178D 2.0 (echo) 9 10 53 36 47 left axis deviation Mildly thickened apical segments, cardiac embolus at 61y; meets diagnostic criteria for LVNC (echo). II-3 M 20 assumed affected no DNA Rapidly progressive HF with sudden death at 20y (1970); hypertrophy and dilatation at post mortem. II-4 M 37 affected TTN A178D <2 (MRI) 12 12 64 44 57 normal Dilated LV, late Gd on MRI, hypertension. II-6 M 42 unaffected WT 11 9 50 30 78 normal III-1 M 27 affected TTN A178D 2.5 (echo) 12 11 64 42 63 QRS 120 msec Mild regional systolic dysfunction; meets diagnostic criteria for LVNC (echo). III-2 M 21 unclassified no DNA 0.8 (echo) 13 13 54 37 68 normal Mild concentric LVH III-3 M 32 affected TTN A178D 2.8 (MRI) 11 13 52 35 68 normal Hypertension; meets diagnostic criteria for LVNC (MRI) III-4 F 23 affected TTN A178D 2.6 (MRI) 8 9 46 32 58 normal Meets diagnostic criteria for LVNC (MRI) III-5 M 25 affected TTN A178D 2.0-2.5 (MRI) 10 10 46 27 51 inferior T-wave inversion Hypokinesia apical LV incl. septum; borderline for diagnostic criteria for LVNC (MRI) III-6 M 23 affected TTN A178D 1.5 (MRI) 8 9 53 34 48 Q wave & T-wave inversion in lead III Mild DCM, faint late Gd, borderline dilated LV with mildly impaired function, inferior hypokinesia III-7 M 21 unclassified WT 1.6 (MRI) 9 7 55 38 59 normal Documented myocarditis at 21y (MRI) Cardiac dimensions (IVSD – Interventricular Septal Thickness at Diastole, PWD –Posterior Wall Thickness at Diastole, LVEDD – Left Ventricular End Diastolic Diameter, LVESD – Left Ventricular End Systolic Diameter) are given in mm Abbreviations: EF – Ejection Fraction (in %). ASH – Asymmetric Septal Hypertrophy, CVA – Cerebrovascular Accident, LVH – Left Ventricular Hypertrophy, Gd – Gadolinium, HF – Heart Failure, AF – Atrial Fibrillation, DCM – Dilated CM. Blank cells indicate no data available. * Age of diagnosis or first clinical assessment, however parameters of most recent cardiac assessment are given (with exception of I-2 where data at first assessment aged 70 are given and II-7, where the last assessment before myocarditis is shown). † Clinical status ‘affected’ means affected by cardiomyopathy. Whether individuals meet diagnostic criteria for LVNC is shown in the Comments column (in brackets shown whether MRI or echo criteria have been used). ‡ For the definition of trabeculation compaction ratio (CR) see Methods section, in brackets the mode of imaging is indicated. Representative MRI images are shown in Figure S1. Table 2 Biophysical characterisation of recombinant Z1Z2 WT and A178D protein fragments Titin Z1Z2 WT Titin Z1Z2 A178D Calculated molecular weight (kDa) 22.7 22.8 Size exclusion chromatography Retention time (mL) 15.7 9.9 (1st peak) 14.4 (2nd peak) Static Light Scattering Molecular weight (kDa) 21 ± 2 452 ± 45 (1st peak) 45 ± 4 (2nd peak) Small Angle X-ray Scattering Vp excluded volume of the hydrated particle (nm3) 40 ± 5 305 ± 20 Rg radius of gyration (nm) 3.10 ± 0.05 6.8 ± 0.1 Dmax maximum particle size (nm) 10.5 ± 0.5 25.0 ± 1.0 Normalized Kratky plot folded partly unfolded/ flexible domains Disclosures: None. 1 Watkins H Ashrafian H Redwood C Inherited cardiomyopathies N Engl J Med 2011 364 1643 1656 21524215 2 Jarcho JA McKenna W Pare JA Solomon SD Holcombe RF Dickie S Mapping a gene for familial hypertrophic cardiomyopathy to chromosome 14q1 N Engl J Med 1989 321 1372 1378 2811944 3 1000 Genomes Project Consortium Abecasis GR Auton A Brooks LD DePristo MA Durbin RM An integrated map of genetic variation from 1,092 human genomes Nature 2012 491 56 65 23128226 4 Haas J Frese KS Peil B Kloos W Keller A Nietsch R Atlas of the clinical genetics of human dilated cardiomyopathy Eur Heart J 2015 36 1123 1135a 25163546 5 Watkins H Assigning a causal role to genetic variants in hypertrophic cardiomyopathy Circ Cardiovasc Genet 2013 6 2 4 23424253 6 Jenni R Oechslin E Schneider J Attenhofer Jost C Kaufmann PA Echocardiographic and pathoanatomical characteristics of isolated left ventricular non-compaction: a step towards classification as a distinct cardiomyopathy Heart 2001 86 666 671 11711464 7 Petersen SE Selvanayagam JB Wiesmann F Robson MD Francis JM Anderson RH Left ventricular non-compaction: insights from cardiovascular magnetic resonance imaging J Am Coll Cardiol 2005 46 101 105 15992642 8 Purcell S Neale B Todd-Brown K Thomas L Ferreira MA Bender D PLINK: a tool set for whole-genome association and population-based linkage analyses Am J Hum Genet 2007 81 559 575 17701901 9 Abecasis GR Cherny SS Cookson WO Cardon LR Merlin--rapid analysis of dense genetic maps using sparse gene flow trees Nat Genet 2002 30 97 101 11731797 10 Taylor JC Martin HC Lise S Broxholme J Cazier JB Rimmer A Factors influencing success of clinical genome sequencing across a broad spectrum of disorders Nat Genet 2015 47 717 726 25985138 11 Lunter G Goodson M Stampy: a statistical algorithm for sensitive and fast mapping of Illumina sequence reads Genome Res 2011 21 936 939 20980556 12 Rimmer A Phan H Mathieson I Iqbal Z Twigg SR Consortium WGS Integrating mapping-, assembly- and haplotype-based approaches for calling variants in clinical sequencing applications Nat Genet 2014 46 912 918 25017105 13 McLaren W Pritchard B Rios D Chen Y Flicek P Cunningham F Deriving the consequences of genomic variants with the Ensembl API and SNP Effect Predictor Bioinformatics 2010 26 2069 2070 20562413 14 Landrum MJ Lee JM Riley GR Jang W Rubinstein WS Church DM ClinVar: public archive of relationships among sequence variation and human phenotype Nucleic Acids Res 2014 42 D980 985 24234437 15 Zou P Gautel M Geerlof A Wilmanns M Koch MH Svergun DI Solution scattering suggests cross-linking function of telethonin in the complex with titin J Biol Chem 2003 278 2636 2644 12446666 16 Geier C Gehmlich K Ehler E Hassfeld S Perrot A Hayess K Beyond the sarcomere: CSRP3 mutations cause hypertrophic cardiomyopathy Hum Mol Genet 2008 17 2753 2765 18505755 17 Reinhard L Mayerhofer H Geerlof A Mueller-Dieckmann J Weiss MS Optimization of protein buffer cocktails using Thermofluor Acta Crystallogr Sect F Struct Biol Cryst Commun 2013 69 209 214 18 Shaya D Kreir M Robbins RA Wong S Hammon J Bruggemann A Voltage-gated sodium channel (NaV) protein dissection creates a set of functional pore-only proteins Proc Natl Acad Sci U S A 2011 108 12313 12318 21746903 19 Furst DO Osborn M Nave R Weber K The organization of titin filaments in the half-sarcomere revealed by monoclonal antibodies in immunoelectron microscopy: a map of ten nonrepetitive epitopes starting at the Z line extends close to the M line J Cell Biol 1988 106 1563 1572 2453516 20 Gehmlich K Asimaki A Cahill TJ Ehler E Syrris P Zachara E Novel missense mutations in exon 15 of desmoglein-2: role of the intracellular cadherin segment in arrhythmogenic right ventricular cardiomyopathy? Heart Rhythm 2010 7 1446 1453 20708101 21 Cameron JM Maj M Levandovskiy V Barnett CP Blaser S Mackay N Pyruvate dehydrogenase phosphatase 1 (PDP1) null mutation produces a lethal infantile phenotype Hum Genet 2009 125 319 326 19184109 22 Carrilho-Ferreira P Almeida AG Pinto FJ Non-compaction cardiomyopathy: prevalence, prognosis, pathoetiology, genetics, and risk of cardioembolism Curr Heart Fail Rep 2014 11 393 403 25239435 23 Walsh R Thomson KL Ware JS Funke BH Woodley J McGuire KJ Reassessment Of Mendelian Gene Pathogenicity Using 7,855 Cardiomyopathy Cases And 60,706 Reference Samples Genet Med 2016 8 17 10.1038/gim.2016.90 [Epub ahead of print] 24 Labeit S Kolmerer B Linke WA The giant protein titin. Emerging roles in physiology and pathophysiology Circ Res 1997 80 290 294 9012751 25 Wang K McClure J Tu A Titin: major myofibrillar components of striated muscle Proc Natl Acad Sci U S A 1979 76 3698 3702 291034 26 Gerull B The Rapidly Evolving Role of Titin in Cardiac Physiology and Cardiomyopathy Can J Cardiol 2015 31 1351 1359 26518445 27 Chauveau C Rowell J Ferreiro A A rising titan: TTN review and mutation update Hum Mutat 2014 35 1046 1059 24980681 28 Hidalgo C Granzier H Tuning the molecular giant titin through phosphorylation: role in health and disease Trends Cardiovasc Med 2013 23 165 171 23295080 29 Bertz M Wilmanns M Rief M The titin-telethonin complex is a directed, superstable molecular bond in the muscle Z-disk Proc Natl Acad Sci U S A 2009 106 13307 133310 19622741 30 Zou P Pinotsis N Lange S Song YH Popov A Mavridis I Palindromic assembly of the giant muscle protein titin in the sarcomeric Z-disk Nature 2006 439 229 233 16407954 31 Truong K Ikura M The use of FRET imaging microscopy to detect protein-protein interactions and protein conformational changes in vivo Curr Opin Struct Biol 2001 11 573 578 11785758 32 Herman DS Lam L Taylor MR Wang L Teekakirikul P Christodoulou D Truncations of titin causing dilated cardiomyopathy N Engl J Med 2012 366 619 628 22335739 33 Ware JS Li J Mazaika E Yasso CM DeSouza T Cappola TP Shared Genetic Predisposition in Peripartum and Dilated Cardiomyopathies N Engl J Med 2016 374 233 241 26735901 34 Watkins H Tackling the achilles' heel of genetic testing Sci Transl Med 2015 7 270fs1 35 Roberts AM Ware JS Herman DS Schafer S Baksi J Bick AG Integrated allelic, transcriptional, and phenomic dissection of the cardiac effects of titin truncations in health and disease Sci Transl Med 2015 7 270ra6 36 Zou J Tran D Baalbaki M Tang LF Poon A Pelonero A An internal promoter underlies the difference in disease severity between N- and C-terminal truncation mutations of Titin in zebrafish Elife 2015 4 e09406 26473617 37 Begay RL Graw S Sinagra G Merlo M Slavov D Gowan K Role of Titin Missense Variants in Dilated Cardiomyopathy J Am Heart Assoc 2015 4 pii: e002645 38 Lopes LR Zekavati A Syrris P Hubank M Giambartolomei C Dalageorgou C Genetic complexity in hypertrophic cardiomyopathy revealed by high-throughput sequencing J Med Genet 2013 50 228 239 23396983 39 Gerull B Gramlich M Atherton J McNabb M Trombitas K Sasse-Klaassen S Mutations of TTN, encoding the giant muscle filament titin, cause familial dilated cardiomyopathy Nat Genet 2002 30 201 204 11788824 40 Hinson JT Chopra A Nafissi N Polacheck WJ Benson CC Swist S HEART DISEASE. Titin mutations in iPS cells define sarcomere insufficiency as a cause of dilated cardiomyopathy Science 2015 349 982 986 26315439 41 Gramlich M Pane LS Zhou Q Chen Z Murgia M Schotterl S Antisense-mediated exon skipping: a therapeutic strategy for titin-based dilated cardiomyopathy EMBO Mol Med 2015 7 562 576 25759365 42 Knoll R Linke WA Zou P Miocic S Kostin S Buyandelger B Telethonin deficiency is associated with maladaptation to biomechanical stress in the mammalian heart Circ Res 2011 109 758 769 21799151
PMC005xxxxxx/PMC5111163.txt
LICENSE: This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. 8907828 20554 J Psychopharmacol J. Psychopharmacol. (Oxford) Journal of psychopharmacology (Oxford, England) 0269-8811 1461-7285 24327452 5111163 10.1177/0269881113515061 NIHMS828453 Article Psychiatric profiles of mothers who take Ecstasy/MDMA during pregnancy: Reduced depression 1 year after giving birth and quitting Ecstasy Turner John JD 1 Parrott Andrew C 2 Goodwin Julia 1 Moore Derek G 1 Fulton Sarah 3 Min Meeyoung O 3 Singer Lynn T 3 1 University of East London, London, UK 2 Swansea University, Swansea, UK 3 Case Western Reserve University, Cleveland, USA Corresponding author: John JD Turner, School of Psychology, University of East London, London E15 4LZ, UK. j.j.d.turner@uel.ac.uk 9 11 2016 10 12 2013 1 2014 16 11 2016 28 1 5561 This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. Background The recreational drug MDMA (3,4-methylenedioxymethamphetamine) or ‘Ecstasy’ is associated with heightened psychiatric distress and feelings of depression. The Drugs and Infancy Study (DAISY) monitored the psychiatric symptom profiles of mothers who used Ecstasy/MDMA while pregnant, and followed them over the first year post-partum. Methods We compared 28 young women whom took MDMA during their pregnancy with a polydrug control group of 68 women who took other psychoactive drugs while pregnant. The Brief Symptom Inventory (BSI) was completed for several periods: The first trimester of pregnancy; and 1, 4 and 12 months after childbirth. Recreational drug use was monitored at each time point. Results During the first trimester of pregnancy, MDMA-using mothers reported higher depression scores than the polydrug controls. At 1 year after childbirth, their BSI depression scores were significantly lower, now closer to the control group values. At the same time point, their self-reported use of MDMA became nearly zero, in contrast to their continued use of Cannabis/marijuana, nicotine and alcohol. We found significant symptom reductions in those with BSI obsessive-compulsive and interpersonal sensitivity, following Ecstasy/MDMA cessation. Conclusions The findings from this unique prospective study of young recreational drug-using mothers are consistent with previous reports of improved psychiatric health after quitting MDMA. Cessation depression drug addiction Ecstasy MDMA middle class mother post-partum pregnancy quitting recreational drugs Introduction ‘Ecstasy’ or 3,4-methylenedioxymethamphetamine (MDMA) is used as an illicit drug by subgroups of adolescents and young adults. Its recreational use is mainly associated with dance clubs, all-night ‘raves’ and house parties (Parrott et al., 2008; Winstock et al., 2001). Population surveys in the US reveal usage levels as high as 9.5% in college students (Johnston et al., 2005; Singer et al., 2004). In the American National Survey on drug use and health, Ecstasy/MDMA is found to be used more by young women than men (Wu et al., 2010). Neuroimaging studies of abstinent MDMA users reveal significantly lower levels of the serotonin transporter (SERT) (Erritizoe et al., 2011; Kish et al., 2010), and are widely interpreted as suggesting serotonergic neurotoxicity (Benningfield and Cowan, 2013; Parrott, 2013a; Puerta et al., 2009; Ricaurte et al., 2000). Recreational use of MDMA is also associated with various neuropsychobiological problems, including memory deficits (Montgomery et al., 2010; Rogers et al., 2009; Zakzanis and Campbell, 2006), impairments in higher cognitive processing (Fox et al, 2002; Parrott, 2012, 2013b; Reay et al., 2006), sleep apnea (McCann et al., 2009), raised cortisol levels (Parrott, 2009; Parrott et al., 2012), psychosocial impairment (Topp et al., 1999) and various psychiatric problems (Briere et al., 2012; MacInnes et al., 2000; Milani et al., 2004; Morgan et al., 2002; Schifano et al., 1998; Singer et al., 2004; Verheyden et al., 2003). Laboratory animal studies show adverse effects of MDMA upon the developing foetus (Adori et al., 2010; Skelton et al., 2008), raising concerns about potentially damaging effects when taken by female recreational users during pregnancy. To date, there has been no controlled empirical data addressing this question, although there is some evidence of adverse birth consequences (McElhatton et al., 1999; Singer et al., 2012b). To investigate the potential effects of foetal MDMA exposure on development, the US National Institute on Drug Abuse (NIDA) funded the Drugs and Infancy Study (DAISY). This prospective study monitored a group of mothers whom took recreational Ecstasy/MDMA while pregnant, and a control group of pregnant females, the other ‘polydrug’ users. The two groups were followed over time, in order to monitor the physical development and psychobiological well-being of their children. Over the first year of life, the children of MDMA-using mothers displayed significantly poorer gross psychomotor skills than control group children (Singer et al., 2012a, 2012b). The DAISY study also assessed maternal well-being, using the Brief Symptom Inventory, a self-reporting measure of psychiatric health for non-clinical populations, derived from the earlier Symptom Check List-90 (Derogatis and Nelisaratos, 1983). This psychiatric measure was included, because previous research shows higher symptom profiles in abstinent Ecstasy/MDMA users. Soar et al. (2001) reviews the medical case study literature, which indicated an increased risk of several psychiatric disorders, including depression and psychosis, in MDMA users. Schifano et al. (1998) noted that regular Ecstasy/MDMA users are at increased risk of developing various psychiatric problems, the most frequent being depression. MacInnes et al. (2000) found significantly raised Beck Depression Inventory (BDI) scores in a non-clinical sample of abstinent regular Ecstasy/MDMA users. Singer et al. (2004) found that abstinent Ecstasy users reported significantly higher BSI scores for anxiety, depression and obsessive-compulsive disorder than non-user controls. Milani et al. (2004) reported significant gender effects, with female Ecstasy/MDMA users reporting higher levels of BSI anxiety, depression and somatization scores. Verheyden et al. (2003) investigated the reasons for quitting Ecstasy/MDMA: They found that most users in their large survey reported improved mental health after drug cessation. In the current DAISY, the BSI allowed us to prospectively monitor the psychiatric health of our pregnant mothers and to investigate how any changes in drug usage were associated with their report of psychological distress on the BSI. Based on previous findings, it might be predicted that elevated psychiatric symptoms would be evident in mothers who are continuing MDMA users, whilst those who discontinue use may show improvements; however, given its uniqueness, and the additional biopsychosocial changes associated with pregnancy and motherhood, the aims of the study were largely exploratory. Methods Experimental design The data in the current report were collected as part of the maternal assessment component of DAISY, a prospective study primarily exploring the effects of recreational drug use, notably MDMA/Ecstasy, on infant social and cognitive development (Moore et al., 2010; Singer et al., 2012a, 2012b). In a mixed design, mothers who used MDMA/Ecstasy during pregnancy (MDMA/Ecstasy users) were compared with those who used other drugs, but not MDMA/Ecstasy (Polydrug user controls), across measures of drug use and symptoms of mental distress, at four distinct time periods: the first trimester of pregnancy and at 1, 4 and 12 months post-partum. Participants We prospectively recruited 96 pregnant women from the UK through midwife referrals, leaflets describing the study at prenatal clinics and advertisements in commercial pregnancy magazines. We sought pregnant women whom were using recreational drugs during pregnancy, listing ecstasy, tobacco, Cannabis, alcohol and cocaine as examples. The majority of participants were therefore recreational ‘polydrug’ users. Exclusionary factors included: positive HIV status, moderate or severe intellectual disability, chronic medical disorder or psychiatric diagnosis. In total, there were 28 mothers in the MDMA-exposed group, who used MDMA (and other substances) during pregnancy, and 68 non-MDMA controls (some of whom used substances during pregnancy, but not MDMA). The majority of the sample were white, married or with a partner, and educated to a UK degree level. Their mean ages at the birth of their infants were 30.3 (SD 6.4) years of age in the MDMA-exposed group and 28.4 (SD 6.2) in the controls. The groups did not differ on basic demographic profiles. Participants were informed of data confidentiality and they gave written informed consent. The study protocol was approved by ethics committees from the University of East London, UK; Case Western Reserve University, US; and the National Health Service, UK. For a fuller description of the participant sample and screening procedures, see Singer et al. (2012a). Drug usage All women were individually interviewed about their substance use by fully trained female research assistants. The interview was an adaptation of the Maternal Post-Partum Interview, which was developed for earlier studies of maternal cocaine exposure (Singer et al., 2002). Interview questions covered substances commonly used in the UK and were based on the University of East London Recreational Drug Usage Questionnaire (Parrott et al., 2001). The list of drugs included tobacco/cigarettes, alcohol, Cannabis, Ecstasy/MDMA, amphetamine, cocaine, LSD, benzodiazepines, hallucinogenic mushrooms, ketamine and opiates. It may be noted that mephedrone (m-cathinone or ‘m-cat’) was not on this list, since the DAISY study was undertaken before ‘m-cat’ was used as a recreational drug (Schifano et al., 2011). Mean usage for each drug per week was calculated by multiplying the frequency of use with the amount taken per occasion. The MDMA user group comprised women who reported taking MDMA during pregnancy or in the month prior to pregnancy. Those who reported MDMA use prior to this time were categorized as non-users, because the study was designed to assess foetal drug exposure. Assessment battery The study included a comprehensive battery of assessment measures, covering various aspects of child behaviour and physical health indices, maternal activities and psychological well-being (Singer et al., 2012a,2012b). This report describes the findings from the Brief Symptom Inventory (BSI) (Derogatis and Nelisaratos, 1983). This questionnaire comprises 53 self-rating questions across nine psychiatric subscales, for: depression, anxiety, phobic anxiety, hostility, somatic complaints, obsessive-compulsive behavior, interpersonal sensitivity, paranoid ideation and psychosis/schizophrenia. The summary measure, the General Severity Index (GSI), provided a general index for overall psychiatric distress. The assessments covered four occasions: first trimester of pregnancy, 1 month post-partum, 4 months postpartum and 12 months post-partum. Statistical analyses Data that were positively skewed were transformed using natural logarithm, prior to analysis; however, the means and SDs are reported for the untransformed scores. Bivariate correlations were employed to calculate the inter-relationships between variables. Multicollinearity was assessed using tolerance and variance inflation factor. We implemented repeated measures Analysis of Variance (ANOVA), using a mixed model approach, by SAS Proc Mixed with maximum estimation method, to compare the substance use for both groups, MDMA-users during pregnancy (n = 28) and non-users of MDMA during pregnancy (n = 68), at the four different assessment times (during pregnancy, 4 weeks after birth, 12 weeks and 52 weeks). As noted earlier, both groups contained polydrug users of various substances, both legal (tobacco and/or alcohol), and illegal (Cannabis, amphetamine and/or cocaine) (Moore et al., 2010). Because the dependent variables were repeated measures and correlated within subjects, we used an unstructured covariance matrix to account for these correlated responses. We included interaction terms between drug groups and time, to test for homogeneity of MDMA effects over time. For all BSI outcome measures, we employed repeated measures Analysis of Covariance (ANCOVA). The covariates included other substance usage that differed by MDMA status at p < 0.10, and were correlated with the given outcome at p < 0.10 on at least two time points: They were then entered into the longitudinal model. Different sets of covariates were adjusted on each psychological outcome, and included demographic variables and use of all other drugs. Results The socioeconomic and educational profiles of mothers enrolled in the study are described more fully elsewhere (Singer et al., 2012a). In brief, the cohort was primarily white, married or in a stable relationship, and represented a wide range of socioeconomic backgrounds that included many from middle and higher psychosocial groupings. The MDMA-using mothers and polydrug control mothers were well matched on most variables (Singer et al., 2012a). Table 1 describes the group mean weekly rates of usage for the five main types of drug used: alcohol, nicotine/cigarettes, Cannabis/marijuana, cocaine and Ecstasy/MDMA. Other psychoactive drugs were taken by a few individuals, and those data are described more fully elsewhere (Moore et al., 2010). A mixed ANOVA was conducted with group as the between-conditions factor and time as the within-conditions factor. The between-groups ANOVA revealed that the two groups did not differ in overall use of alcohol, cigarettes, Cannabis nor cocaine; although the cocaine group effect was statistically borderline (Table 1, where the group effect for Ecstasy was not calculated, because it was used to define these two groups). The ANOVA for the time factor was significant for all five drugs (all p = 0.01 or smaller), with lower rates of usage during the weeks after giving birth. The ANOVA grouped by time interactions were significant for alcohol and cigarettes (F[3,88] = 4.06; p < 0.005 and F[3,88] = 3.61; p < 0.02 respectively), with the MDMA mothers using slightly more than the controls during the first trimester of pregnancy, but slightly less than controls across all the other time periods (Table 1). The group × time interaction was not significant for Cannabis, though Ecstasy/MDMA-using mothers appeared to be taking slightly more Cannabis than controls, across all time points (Table 1). The group × time interaction was significant for cocaine (F[3,88] = 3.48; p < 0.05), with the most usage during the first session by Ecstasy users (Table 1). The Ecstasy-using mothers reported taking an average of 0.84 Ecstasy tablets/week during the first trimester of pregnancy. In terms of previous lifetime usage (Singer et al., 2012a), they reported first using Ecstasy at a mean age of 20.2 years (range 14 – 29 years), had taken it on an average of 171 times/lifetime (range 6 – 936 times), and typically ingested an average of 3 tablets per occasion (range 1 – 8 tablets), with an average maximum usage per occasion of 7.4 Ecstasy tablets (range 2 – 20 tablets). Turning to their usage around the time of pregnancy, the mean total amount of MDMA used during pregnancy and in the month prior was 25 tablets (range 0.45 – 180 tablets). Within the polydrug control group, several women had used ecstasy/MDMA previously, but were currently non-users (Singer et al., 2012a). The Brief Symptom Inventory findings are summarized in Table 2. The main focus of interest here is the difference in psychiatric well-being between the first and last sessions. Over that time period, the control group mothers showed a significant decline in BSI symptoms for somatization (p < 0.001) and anxiety (p < 0.05). Over the same period, the Ecstasy/MDMA subgroup mothers showed significant declines in BSI symptoms for (Table 2): somatization (p < 0.001), depression (p < 0.05), interpersonal sensitivity (p < 0.05) and obsessive-compulsive disorder (p < 0.05). Discussion The young mothers in the DAISY study provided a unique cohort in several respects. Although recreational polydrug users, they were predominantly middle class with middle socioeconomic status, and in stable interpersonal relationships; hence, unlike many studies of illicit drug users, they were not socially disadvantaged. The study covered an extended time period of nearly 2 years, and is to our knowledge the first study of pregnant Ecstasy/MDMA users. The cohort of almost 100 mothers was comparatively large, especially for a prospective study with repeated assessments. One of the main aims of the DAISY study was to investigate the effects of recreational Ecstasy/MDMA usage during pregnancy on subsequent child development. The main findings were that the children of Ecstasy/MDMA using mothers displayed significant psychomotor problems in comparison to control group children, as described elsewhere (Singer et al., 2012a, 2012b). The study design allowed us to monitor changes in maternal reports of psychological well-being over time, in particular any alterations in their psychiatric status from the first to the last assessment. In this respect, both groups of mothers showed significantly higher somatization scores during the first trimester of pregnancy, when compared to 12 months post-partum (Table 2). The control group mothers also showed a significant reduction in BSI symptoms of anxiety, while the MDMA subgroup showed a very similar trend (Table 2). The first trimester of pregnancy is a period of pronounced somatic body changes, and so intuitively explains the higher somatization scores in both groups of women. Thus, the reduced BSI somatization scores 1 year post-partum may reflect a return to physical normality in both groups of women. The first trimester of pregnancy is also a period of general anxiety, with natural concerns and worries over becoming pregnant. This may help to explain the comparatively higher BSI anxiety scores during the first trimester, and the reduced scores at the final session (Table 2). The Ecstasy/MDMA-using mothers showed a different pattern of change, compared to the controls, on three BSI subscales, for: depression, obsessive compulsive disorder and interpersonal sensitivity (Table 2). The Ecstasy subgroup mothers reported feeling more depressed than control mothers at the first time point, with a statistically borderline between-group difference (p = 0.058, two-tail). At 1 year post-partum, the depression scores for the MDMA group had reduced significantly (p < 0.05), to become almost identical to the control group (Figure 1). The BSI depression scores for the control group mothers remained broadly unchanged over this period. The MDMA group also showed significant BSI reductions for interpersonal sensitivity and obsessive-compulsive disorder (Table 2). In order to examine the potential reasons for these changes, the changing patterns of drug usage over time should be noted. The Ecstasy/MDMA-group mothers had reduced their usage of Ecstasy to near-zero after giving birth (Table 1); hence, 1 year post-partum they had become former MDMA users. Their BSI improvement may reflect this cessation of Ecstasy/MDMA use. There is extensive empirical literature demonstrating higher rates of psychiatric distress in current Ecstasy/MDMA users and psychiatric gains following drug cessation. Schifano et al. (1998) gave structured psychiatric interviews to young Ecstasy/MDMA users at an addiction centre in Italy, reporting that around one-half the sample reported symptoms of psychiatric distress, especially depression, but also psychotic disorder, impulse control disorder, bulimia and panic disorder. MacInnes et al. (2000) compared young Ecstasy/MDMA users and polydrug controls, with participants screened to exclude anyone with a prior psychiatric history. On the BDI, Ecstasy users displayed significantly higher depression scores than the non-MDMA-user controls. In a survey of over 700 young people from the UK and Italy, the SCL-90 symptom profiles of the Ecstasy polydrug users were significantly higher than the non-MDMA-user controls (Parrott et al., 2001). In a US study of abstinent MDMA users compared to non-user controls who visited raves (Singer et al., 2004), the Ecstasy/MDMA users reported significantly higher BSI depression, anxiety and obsessive-compulsive disorder than the controls. Brière et al. (2012) prospectively found that taking up recreational Ecstasy/MDMA in Canadian schoolchildren led to increased depression 1 year later. There are also indications that psychiatric health can improve after quitting. Morgan et al. (2002) report that current Ecstasy/MDMA users have elevated scores on many SCL-90 subscales, whereas former Ecstasy users have scores intermediate between the current Ecstasy users and the non-user controls. Verheyden et al. (2003) interviewed former users about their reasons for quitting Ecstasy/MDMA. Over one-half reported that ‘mental health problems due to MDMA’ were the main reason for quitting drug use: That using Ecstasy led to feelings of anxiety and depression, and that they feared for their mental health in the longer-term. Over 70% of those participants report ‘improved mental health’ after quitting. An important potential confounder for Ecstasy/MDMA research is the use of other recreational drugs, because many Ecstasy users take a range of psychoactive drugs (Parrott et al., 2001; Parrott et al., 2007; Sala and Braida, 2004; Scholey et al., 2004). In the DAISY study, we collected systematic drug usage data at all four time points. As noted above, the use of Ecstasy/MDMA was largely restricted to the first trimester of pregnancy. In contrast, the use of alcohol, tobacco and Cannabis continued throughout the study. There is some indication of a decline in all drug use in the Ecstasy/MDMA group, with significant group/time interactions for alcohol and cigarettes, especially. As such, it could be argued that the depression effect in the Ecstasy/MDMA users was in part due to changes in alcohol and/or cigarette use, as both have been linked to higher depression scores (Munafo and Araya, 2010; Raimo and Schuckit, 1998); however, usage rates at baseline were broadly similar to 1 year post-partum, in both groups (Table 1). Hence, the changes in psychiatric status noted here (Table 2) cannot easily be attributed to alcohol, tobacco, nor Cannabis usage; however, the usage pattern for cocaine was very similar to Ecstasy/MDMA, with almost total cessation after the first trimester (Table 1). Thus, the selective reductions in particular psychiatric symptoms may reflect the cessation of Ecstasy/MDMA and/or cocaine usage. There are several ways in which central nervous system (CNS) stimulant drugs like MDMA can enhance psychiatric distress. In acute terms, MDMA is a powerful mood intensifier, but it can boost positive and negative-feeling states; thus, increased levels of happiness and euphoria are often accompanied by emotional tension. This intensification of both positive and negative moods is reported in studies of recreational users and in placebo-controlled laboratory studies (Kirkpatrick et al., 2012; Parrott et al., 2011). It is also noted in the psychotherapeutic situation: Two clients undergoing ‘MDMA-assisted psychotherapy’ experienced a resurgence of previous psychiatric problems following acute MDMA administration, with one client needing psychotherapy for a year afterwards, to resolve the MDMA-induced problems (Greer and Tolbert, 1986; Parrott, 2007). In sub-acute terms, MDMA use is typically followed by a period of neurochemical recovery, when low moods and feelings of depression predominate; indeed, the ‘mid-week blues’ can often last for several days and may reach clinical levels in some individuals (Curran and Travill, 1997). Because the positive mood intensification under MDMA is brief (several hours), and the post-MDMA period of mood recovery is more prolonged (several days), the average weekly mood of Ecstasy users will often be lower than in non-users (Parrott and Lasky, 1998). Such effects are supported in the animal literature by the acute and subacute impact of MDMA on 5-HT, notably, delays in recovery of this transmitter in brain regions regulating emotion (Colado et al., 1999); and similar pattern reductions in other functional serotonergic factors, such as SERT and tryptophan hydroxylase (Adori et al., 2011). In addition, in chronic terms, abstinent Ecstasy/MDMA users report higher levels of stress and lower levels of happiness than non-user controls (Scholey et al., 2011). When used repeatedly, sympathomimetic drugs such as amphetamine, cocaine and MDMA can adversely affect the hypothalamic pituitary adrenal (HPA) axis and impair homeostatic control via the stress hormone cortisol (Seyle, 1955). Indeed, acute MDMA use can increase cortisol levels by 800% in young dance club attendees (Parrott et al., 2008). While sub-chronically, recent Ecstasy/MDMA users display a 400% increase of cortisol in 3-month hair samples (Parrott et al., 2012); hence, recreational MDMA is both an acute and chronic stressor for the HPA axis (Parrott, 2009). There is also evidence that premorbid factors may heighten the likelihood of clinical problems in disadvantaged individuals; this interactive ‘diathesis-stress’ model for recreational Ecstasy/MDMA is described more fully elsewhere (Parrott, 2006). The possible causative factors (including neurotoxicity, recovery and/or HPA axis changes) for the effects observed here in the current data, and in much of the literature, still need considerable further empirical investigation. There are several limitations to the DAISY study. We relied on self-reported drug use and cannot therefore be certain that ‘Ecstasy’ comprised ‘MDMA’; however, data collection occurred during 2003 – 2006, which corresponded with a period of high MDMA purity in the UK. This was apparent in another study we undertook during 2006, which shows very high concordance between self-rated Ecstasy and MDMA use as detected in saliva samples (Parrott et al., 2008). The second weakness was the absence of a non-user control group, because many studies have found that polydrug users are more impaired than non-users (Morgan et al., 2002; Parrot et al., 2001). Thirdly, although the DAISY study was designed as a prospective study, this was only partially achieved (Moore et al., 2010); hence, missing data point’s retrospective ratings were sometimes required (Singer et al., 2012a). Finally, the overall BSI difference scores were not large (Table 2); however, we were not expecting strong drug effects, because our participants were psychiatrically normal and their use of most drugs was similar at the first and last time points. Furthermore, although the group mean reduction of 0.2 on the BSI depression subscale may have been comparatively slight, it would still be beneficial for the individual user. It would also reduce the likelihood of individuals with prior vulnerability factors from developing more severe psychiatric problems (Parrott, 2006). In summary, recreational stimulant drugs such as MDMA, cocaine and amphetamine, are well-known to be associated with enhanced psychiatric distress. The DAISY study found that women who took Ecstasy/MDMA during their first trimester of pregnancy reported slightly higher psychiatric symptom profiles than a control group of polydrug-using mothers. One year after giving birth, their psychiatric symptom profiles improved to values near the control group (Table 2 and Figure 1). The main explanatory factor proposed for this gain in psychiatric well-being was the cessation of Ecstasy/MDMA usage, coupled with the parallel reduction in cocaine use. Hence, this study confirmed that a reduction in stimulant drug usage can have beneficial effects on well-being. Finally, we should also note that the DAISY study investigated the effects of MDMA use during pregnancy on the child’s subsequent development. It reveals that the children of MDMA-using mothers have various impairments in gross psychomotor skill (Singer et al., 2012a,2012b); hence, an important message for young females and their partners is to stop taking MDMA before pregnancy. This will protect the developing child and enhance maternal well-being. Acknowledgements We would like to thank all the mothers who gave of their time and patience. Many thanks also to Fleur Braddick, Emma Axelsson, Stephanie Lynch, Helena Ribeiro, Caroline Frostick, Alice Toplis and Helen Fox, for undertaking the data collection and scoring. Funding This work (DAISY study) was funded by the National Institute on Drug Abuse in America (grant number DA-14910-05). Figure 1 Brief Symptom Inventory ratings of depression during the first trimester and at 12 months post-partum, in women reporting MDMA/Ecstasy use during pregnancy, and in control women taking other recreational drugs during pregnancy. *p < 0.05; Error bars indicate ±1 SE. MDMA: ‘Ecstasy’ or 3,4-methylenedioxymethamphetamine. Table 1 Ecstasy/MDMA, alcohol, cigarettes, marijuana/Cannabis and cocaine usage patterns for 28 mothers whom took Ecstasy/MDMA during pregnancy and a control group of 68 polydrug users during pregnancy. Drug values represent mean weekly rates of usage, during first trimester of pregnancy and three times up to 1 year post-partum. Drug type Maternal group First trimester of pregnancy 1 month post-partum 4 months post- partum 12 months post-partum ANOVA Group Time (G×T) Ecstasy (tablets) Polydrug controls 0.00 +/− 0.00 0.00 +/− 0.00 0.02 +/− 0.16 0.01 +/− 0.02 No between- group analysis < .0001 - Ecstasy users 0.82 +/− 1.57 0.01 +/− 0.03 0.03 +/− 0.13 0.06 +/− 0.09 Alcohol (units) Polydrug controls 6.94 +/− 16.90 3.11 +/− 10.66 6.48 +/−10.89 13.75 +/−24.02 n.s .0001 .02 Ecstasy users 12.07 +/− 16.62 1.33 +/− 1.80 5.30 +/− 5.70 6.01 +/− 5.99 Cigarette (numbers) Polydrug controls 28.15 +/−48.10 23.45 +/− 50.13 27.27 +/− 40.02 32.88 +/−48.14 n.s .0001 .003 Ecstasy users 44.78 +/− 49.50 17.88 +/−30.79 17.59 +/− 22.23 28.68 +/−34.37 Cannabis (joints) Polydrug controls 7.44 +/− 19.24 3.36 +/− 7.87 3.12 +/−7.51 5.26 +/−12.95 n.s .0001 n.s. Ecstasy users 10.28 +/− 20.81 6.86 +/− 17.36 6.20 +/− 16.12 7.35 +/−15.46 Cocaine (grams) Polydrug controls 0.02 +/−0.18 0.001 +/− 0.01 0.01 +/− 0.07 0.02 +/− 0.14 .057 .013 .03 Ecstasy users 0.23 +/− 0.85 0.01 +/− 0.04 0.02 +/− 0.06 0.02 +/− 0.05 MDMA: ‘Ecstasy’ or 3,4-methylenedioxymethamphetamine. Note: Units refer to UK units of alcohol (1 unit = 10ml or 7.9 grams of alcohol); n.s.= non-significant. Table 2 Psychiatric symptoms on the Brief Symptom Inventory during and after pregnancy for 28 mothers whom took Ecstasy/MDMA during pregnancy and for a non-user control group of 68 mothers whom took other drugs during pregnancy (polydrug controls). Group Time 1: Early-mid Pregnancy Time 2: Postpartum 1 month Time 3: Postpartum 4 months Time 4: Postpartum 12 months Paired comparison, Time 1 vs. 4 General symptoms Polydrug controls 0.61 0.51 0.54 0.50 - Ecstasy users 0.79 0.71 0.81 0.56 - Depression Polydrug controls 0.50 0.45 0.57 0.50 - Ecstasy users 0.87 0.74 0.80 0.51 p < 0.05 Anxiety Polydrug controls 0.55 0.46 0.48 0.34 p < 0.05 Ecstasy users 0.74 0.68 0.69 0.56 - Hostility Polydrug controls 0.71 0.65 0.66 0.59 - Ecstasy users 0.74 0.80 1.24 0.55 - Psychoticism Polydrug controls 0.31 0.25 0.36 0.30 - Ecstasy users 0.52 0.51 0.62 0.42 - Somatization Polydrug controls 0.58 0.36 0.27 0.32 p < 0.001 Ecstasy users 0.78 0.50 0.51 0.39 p < 0.01 Paranoid ideation Polydrug controls 0.61 0.48 0.64 0.66 - Ecstasy users 0.75 0.70 066 0.73 - Obsessive-compulsive Polydrug controls 1.08 1.10 0.98 0.89 - Ecstasy users 1.20 1.23 1.31 0.82 p < 0.05 Interpersonal sensitivity Polydrug controls 0.74 0.64 0.64 0.73 - Ecstasy users 0.92 0.85 0.96 0.57 p < 0.05 Phobic anxiety Polydrug controls 0.27 0.20 0.30 0.20 - Ecstasy users 0.47 0.39 0.52 0.37 - MDMA: ‘Ecstasy’ or 3,4-methylenedioxymethamphetamine. Conflict of interest The authors declare no conflict of interest. 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LICENSE: This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. 101234237 32207 J Biomed Mater Res A J Biomed Mater Res A Journal of biomedical materials research. Part A 1549-3296 1552-4965 26841263 5111169 10.1002/jbm.a.35675 NIHMS757124 Article Persistence, Distribution, and Impact of Distinctly Segmented Microparticles on Cochlear Health following In Vivo Infusion3* Ross Astin M. 12 Rahmani Sahar 15 Prieskorn Diane M. 2 Dishman Acacia F 35 Miller Josef M. 2 Lahann Joerg 145 Altschuler Richard A. 2* 1 Department of Biomedical Engineering, University of Michigan, Ann Arbor 48109, USA 2 Kresge Hearing Research Institute, University of Michigan, Ann Arbor 48109, USA 3 Department of Biophysics, University of Michigan, Ann Arbor 48109, USA 4 Department of Chemical Engineering, University of Michigan, Ann Arbor 48109, USA 5 Biointerfaces Institute, University of Michigan, Ann Arbor 48109, USA * Corresponding author: astinr@umich.edu (Astin Ross) 11 2 2016 02 3 2016 6 2016 01 6 2017 104 6 15101522 This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. Delivery of pharmaceuticals to the cochleae of patients with auditory dysfunction could potentially have many benefits from enhancing auditory nerve survival to protecting remaining sensory cells and their neuronal connections. Treatment would require platforms to enable drug delivery directly to the cochlea and increase the potential efficacy of intervention. Cochlear implant recipients are a specific patient subset that could benefit from local drug delivery as more candidates have residual hearing; and since residual hearing directly contributes to post-implantation hearing outcomes, it requires protection from implant insertion-induced trauma. This study assessed the feasibility of utilizing microparticles for drug delivery into cochlear fluids, testing persistence, distribution, biocompatibility, and drug release characteristics. To allow for delivery of multiple therapeutics, particles were composed of two distinct compartments; one containing polylactide-co-glycolide (PLGA), and one composed of acetal-modified dextran and PLGA. Following in vivo infusion, image analysis revealed microparticle persistence in the cochlea for at least 7 days post-infusion, primarily in the first and second turns. The majority of subjects maintained or had only slight elevation in auditory brainstem response thresholds at 7 days post-infusion compared to pre-infusion baselines. There was only minor to limited loss of cochlear hair cells and negligible immune response based on CD45+ immunolabling. When Piribedil-loaded microparticles were infused, Piribedil was detectable within the cochlear fluids at 7 days post-infusion. These results indicate that segmented microparticles are relatively inert, can persist, release their contents, and be functionally and biologically compatible with cochlear function and therefore are promising vehicles for cochlear drug delivery. segmented microparticle electrohydrodynamic co-jetting cochlear drug delivery biocompatibility 1. Introduction There is increasing need for local drug delivery to the cochleae of patients with various cochlear pathologies, including cochlear implants. Local drug delivery could be used to increase survival and function of remaining auditory neurons following trauma such as implantation1,2. With the increasing number of implantees with remaining sensory cells and hearing, there is also growing interest in drug treatment for preservation and protection of remaining hair cells and their synaptic connections with the auditory nerve3. There are many potential strategies for providing local drug delivery to the cochlea (Table 1) including hydrogels, microfluidics, osmotic pumps, gene therapy/viral vectors, and micro/nanoparticles. Although multiple local delivery strategies are under development, systemic drug delivery, either orally or intravenously4, has historically been the primary mode of pharmaceutical delivery to the cochlea because it is relatively safe and non-invasive. However, because of the existence of the blood-labyrinth barrier, one of the principal limitations of systemic delivery is that therapeutic levels of the drug may never reach the cochlea. Further, systemic delivery is more likely to lead to unwanted side effects, as there is increased opportunity for the drug to act on other organ systems. Local delivery directly into the cochlea is therefore becoming a preferred strategy for the delivery of pharmaceuticals to the inner ear3,5. One option is intratympanic or transtympanic delivery that involves the placement of pharmaceuticals into the middle ear and relies on diffusion across the round window membrane (RWM) for agents to reach the inner ear. Such delivery is relatively non-invasive and exploits the permeability of the RWM. A drug can be injected through the tympanic membrane directly into the middle ear or more commonly, it is placed in a release medium (i.e. biodegradable hydrogel) on or near the RWM6. A disadvantage for use of intratympanic delivery is that it can lead to uncertainty as to the amount of drug that reaches the cochlea due to drug losses through the Eustachian tube in the middle ear, the size and charge of delivered particles, and variations in the thickness and composition of the RWM itself4. Another local option is intracochlear delivery directly into the cochlear fluids via surgical intervention. Unfortunately, the half-life of drugs directly injected into the cochlea is relatively short (minutes or hours) which limits the utility of this approach. Further, when a drug is injected, it is likely to accumulate at the site of injection rather than being distributed along the cochlear spiral. An additional intracochlear delivery method utilizes microfluidics, including osmotic pumps, reciprocating microfluidic systems, and incorporation of microfluidic channels within the cochlear implant4. Disadvantages of this method are that the pumps/channels must be refilled and their fill ports are susceptible to biofilm formation. A more recent strategy for intracochlear delivery is the use of viral vectors, or gene therapy to deliver molecular therapeutics to the cochlea wherein most recent studies have focused on the use of adenovirus (Ad) and adeno-associated viruses (AAV) as cochlear delivery vehicles7. Though promising, this approach is not without its concerns. Specifically, the use of a virus poses significant toxicity concerns related to immunogenicity and some of the vectors can be difficult to generate2. Further, because of lack of cell targeting vectors are randomly dispersed within the cochlea; thereby limiting the number of genes that can be efficiently delivered to auditory neurons. Effective delivery to the intended target is critical in order to have the desired therapeutic impact. Intracochlear drug delivery via a micro- or nanocarrier overcomes many of the limitations encountered with the aforementioned drug delivery techniques. In particular when placed in the cochlea, a micro-/nano-carrier enables a sustained release of drug over time (days or weeks) and could provide greater distribution and accumulation of the drug along the cochlear spiral therefore providing enhanced therapeutic benefit. As a result, polymeric micro- and nanoparticles have gained prominence as drug delivery vehicles. Several particle types have been utilized to facilitate therapeutic delivery to the inner ear including hydroxyapatite, silica, and polymeric nanoparticles8. Because of their wide-ranging and tunable properties, polymeric micro/nanoparticles are garnering increased interest for cochlear drug delivery. Specifically, polymeric materials such as poly-l-lysine (PLL), polylactic-co-glycolic acid (PLGA), and poly(L- caprolactone) (PCL) have been investigated as potential drug carriers to attenuate pathological conditions of the inner ear6,9. The characteristics of PLGA particles are particularly promising as they can be designed to meet many of the desired criteria for a drug delivery vehicle. These criteria include biocompatibility (PLGA is an FDA approved material and its degradation products are naturally eliminated from the body), controlled drug release (polymer degradation rates of weeks to months can be tuned to meet therapeutic needs by changing the ratio of lactic to glycolic acid), tailored size and shape enhance persistence and distribution of particles in the cochlea (resulting from control of fabrication process parameters), and potential for targeted delivery (via particle surface functionalization using the free chemical groups on the polymer surface). Moreover, polymer particles fabricated with electrohydrodynamic co-jetting (EHD) can be compartmentalized allowing loading of multiple pharmaceuticals into a single particle. Loading of multiple therapeutic agents is important to facilitate the delivery of drugs capable of attenuating the acute impact (swelling, etc.) of trauma and providing the sustained release of agents needed to potentially protect remaining hearing. Further, discrete compartments also enable pharmaceuticals with distinct pharmacokinetic profiles to be delivered from the same platform. This flexibility expands the combination of agents that can be simultaneously screened to identify the best drug combinations to ameliorate hearing loss following cochlear trauma; thereby ultimately improving the utility of the intervention. Our study tested intracochlear release of the dopamine agonist Piribedil from segmented microparticles. This glutamate inhibitor/anti-excitotoxic agent was chosen for three reasons: previous efficacy in protection from noise, current clinical use and potential for re-purposing, and inherent fluorescence10. The use of EHD also allows for fine control of particle shape and size, characteristics that have previously been demonstrated to impact drug delivery, macrophage uptake, and cell uptake of particles11. Cell binding is size and shape limited because test articles must be sufficiently small compared to a target cell. The size of target cells in the inner ear range from 8–20 µm in length, therefore a candidate microparticle with a diameter of approximately 8 µm was selected to encourage cell binding and limit particle phagocytosis by macrophages. Use of material that forms acidic, albeit natural byproducts, in the pH sensitive fluid environment of the cochlea, was controlled by modulation of particle characteristics such as size and porosity12. By selecting a particle size of approximately 8 µm for assessment of cochlear drug delivery, we are well below the size range of concern with respect to acid accumulation within particles13. Further, use of acetal dextran enables the fabrication of a porous particle, thereby inhibiting the development of an acidic particle interior because of increased exchange between the particle and the incubation medium in which it is contained. As porosity is increased, the ability to form extremely acidic microenvironments decreases because degradation products escape more readily from the interior and surrounding medium. In this study, we demonstrate the ability of dual carrier polymeric microparticles to persist and release their contents in a biocompatible manner within the cochlea. 2. Materials & Methods 2.1 Particle Materials Dextran, chloroform, dimethyl sulfoxide (DMSO), dimethylformamide (DMF), pyridinium p-toluenesulfonate, 2-methoxypropane triethylamine, acetic acid, sodium acetate, phosphate buffered saline (PBS), poly[(m-phenylenevinylene)-alt-(2,5-dihexyloxy-p-phenylenevinylene)] (MEHPV) as the blue marker for confocal imaging, and tween 20 were used as purchased from Sigma Aldrich, USA. Polylactide-co-glycolide (PLGA) with a molecular weight of 44 kDa and a ratio of 50:50 lactide to glycolide was purchased from Lactel Corporation. Piribedil was purchased from Ontario Chemicals. 2.2 Particle Fabrication Particles were made from polylactide-co-glycolide and dextran acetal (PLGA/dex). Dextran acetal was chemically modified from dextran according to previously published work by Bachnelder, et al14. A light-emitting polymer, poly[(m-phenylenevinylene)-alt-(2,5-dihexyloxy-p-phenylenevinylene (MEHPV), was also incorporated into the PLGA and PLGA/dex compartments to facilitate particle visualization via confocal microscopy. PLGA (MW: 44 kDa) with a lactic to glycolic acid ratio of 50:50 was used and PLGA/dex compartments contained 1:3 PLGA and 2:3 Dextran Acetal. All segmented particles were created via electrohydrodynamic co-jetting15, a process that involves a side-by-side capillary needle system containing polymer solutions and the application of an electric field to the system. The interface between the solutions is stabilized by the field enabling the formation of an electrified polymer jet of particles with multiple distinct compartments. Additional details on processing of the particles used in this study for cochlear delivery can be found in Supplemental information and Rahmani, et al16,17. The jetted microparticles were imaged via confocal laser scanning microscopy (CLSM) using an Olympus confocal microscope at the Microscopy and Imaging Laboratory facilities at the University of Michigan. Prior to an experiment, a known mass of particles was suspended in artificial perilymph (AP; 118 mM NaCl, 30 mM KCl, 2.0 mM MgSO4, 1.2 mM CaCl2, 5.0 mM HEPES; pH = 7.35–7.40, osmolality = 285–294 mOsm) or artificial perilymph with guinea pig serum albumin (GPSA) to create a 15 mg/mL infusion solution. 2.3 In vivo infusion Surgeries were conducted in a sterile environment and utilized aseptic technique. For in vivo infusions, Hartley guinea pigs (Charles River Laboratory, Wilmington, MA) were anesthetized and a post auricular approach was used to provide access to the middle ear. The temporal bone was drilled to visualize the cochlea and a fine pick was used to create a small hole in the basal turn of the cochlea near the round window. A microcannula with a silastic ball was inserted 0.5 mm into the basal turn of the scala tympani and cyanoacrylate was used to seal the cannula in place as outlined previously19. The microcannula was made from polyethylene 10 tubing and polyimide (I.D. = 0.12 mm, O.D. =0.16 mm). The silastic ball was made from Sylgard. A syringe infusion pump was used to deliver either a particle solution or a vehicle solution consisting of artificial perilymph and guinea pig serum albumin into the scala tympani of the guinea pigs at a flow rate of 1 µl/minute over 5 minutes. Infusions were always performed on the left ear and the right ear was used as needed for a contralateral control. NIH guidelines for the care and use of laboratory animals have been observed. 2.4 Harvesting, cryoprotection, and decalcification of cochlear specimens Guinea pigs were anesthetized and euthanized by injection of sodium pentobarbital. In all cases, secondary euthanasia was performed by transecting the aorta and ventricle. Animals were then decapitated and the temporal bones that encase the cochleae were detached. Excess bullar bone was removed to facilitate visualization of each cochlea and then the middle ear bones were also detached. Specimens were fixed in 4% paraformaldehyde (PFA) for 1–2 hours. Following fixation, cochleae were decalcified in a solution that was two-thirds formic acid and one-third 7% sucrose overnight. Prior to freezing, specimens were placed in foil molds and immersed in a 30% sucrose solution. Freezing was performed by placing the bottom of the container in contact with liquid nitrogen cooled 2-methyl-butane. Specimens were wrapped in parafilm and stored at −80°C until sectioning. 2.5 Cryostat Sectioning Samples were cut into 14 µm sections. For stereological samples, the cochleae were sectioned up to a depth of approximately 4000 µm. Every 6th section was collected. A random number generator was used to select a number between 1 and 6. The number generated identified the first slide for analysis in each cochlea. Thereafter, every 6th slide was evaluated such that the slides with numerical markings of 1, 7, 13, etc. were exhaustively assessed. A total of 61 slides were generated for each animal and 10 slides from each animal were assessed to ascertain particle number and distribution. For immunohistochemistry, up to 4 midmodiolar sections were taken from the MP infused cochlea of each animal. These sections were stained with CD45, a leukocyte antigen, to denote immune cell activity, and propidium iodide (PI) to indicate the presence of general cell structures such as nuclei. Cryosections of guinea pig liver were also made for use as positive and negative (in the absence of primary antibody) controls. The number of respective CD45+ and PI+ cells in cochlear cross sections were counted and the ratio CD45+ cells to total cells (CD45+ and PI+) was calculated to determine the percentage of CD45+ present within treated and untreated cochleae. 2.6 Infused particle number and persistence A sample of the particle solution was counted before the infusions using a hemacytometer. Persistence and distribution assessments were conducted using cryosections from cochleae that had particle infusions 7 days prior to harvest of the cochlea (n=3). Sections from various depths of the cochlea were sampled for particle number. The guinea pig cochlea consists of four turns with two perilymphatic compartments, the scala tympani and scala vestibule. During assessment, the location and distribution of particles within intact cochlea and cochlear cross-sections was determined. 2.7 Stereological Analysis Stereological analysis was used to determine particle distribution in animals infused with unloaded PLGA/dex particles (n=3) and to estimate the number of particles entering the cochlea at the time of infusion. In particular, the optical dissector method was used to systematically create image slices that contained particles in tissue at multiple planes within the cochlea. This technique is an unbiased method whereby an object is counted the first time it appears in an image18. A confocal microscope with a 405 nm laser was used to acquire z-stack image series of particles within cochlear cross-sections. The z-step size was 3.6 µm. Every 6th slide from each sample was evaluated using an unbiased counting grid composed of green inclusion lines and red exclusion lines. The grid was superimposed on top of specimen images and a particle was counted if it was inside of one of the squares in the counting grid or in contact with a green inclusion line. The total particle number within an infused cochlear sample could be estimated by multiplying the number of particles counted within the assessed samples by a factor of 6. 2.8 Auditory Brainstem Response (ABR) Animals were anesthetized with xylazine (10 mg/kg intramuscularly) and ketamine (40 mg/kg intramuscularly). Needle electrodes (active, reference, and ground) were inserted subcutaneously at the vertex and below each pinna and used to record the neurologic response. Up to 1024 responses were averaged for each stimulus level, with the stimulus consisting of a 15-msec tone burst, provided at 10/sec. Pure tones were delivered via a transducer coupled to the external auditory canal at 4, 8, and 20 kHz. Initial sound levels were set at 80 dB for pre- and post- infusion tests. Threshold determination was made by non-blinded evaluators based on the visual detection of maximum peak–peak amplitude of the resulting waveforms. ABRs were performed prior to infusion to enable exclusion of animals with abnormal hearing, and to enable detection, if present, of threshold shifts post-infusion. 2.9 Hair cell counts To prepare specimens for hair cell analysis, ears were harvested in the same manner as those used for cryosection preparation with a few notable differences. Following removal of the middle ear bones, the apex was visualized under stereoscopic magnification and slightly perforated with a 28G needle to create a small hole. Then the round window was opened and approximately 300 µL of 4% PFA was infused directly into the cochlea via the hole in the apex. Specimens were postfixed by immersion in 4% PFA overnight. The following day, cochleae were rinsed and the otic capsule, lateral wall, and tectorial membrane were carefully removed. Phalloidin was used to stain the modiolous and the attached organ of Corti. Following rinsing to remove excess stain, the organ of Corti was dissected from the modiolous and each turn was mounted onto a microscope slide and coverslipped. Phalloidin staining of the organ of Corti enabled visualization and counting of both inner and outer hair cells (as indicated by the presence of nuclei and/or stereocillia). The blinded counts were performed as described previously21. Counts were then plotted using a cytocochleogram program developed in house20, and depicted as percentage hair cell loss at a particular distance from the apex as compared to a database of normal guinea pigs (those not exposed to any external stimuli or agents that could induce hearing loss). Tracking distance along the cochlear spiral also facilitated the correlation of areas of loss with known frequency maps of the guinea pig cochlea. This provided insight on areas that may be functionally affected by the treatment. 2.10 Immunohistochemistry Specimens were prepared similarly to those used for cytocochleograms, except post fixation was performed for 2 hours rather than 12. Then the same protocol was followed as outlined in 2.4. Midmodiolar sections, 12 in total, were selected from 3 of the animals used for the collection of Piribedil exposed perilymph in vivo. These sections were assessed with CD45, a leukocyte antigen, to determine the extent to which particle infusion induced a local immune response. Sections from contralateral control ears and the liver from one of the guinea pigs (in the absence of primary antibody incubation) served as negative controls. In the presence of CD45 primary antibody, cryosections of the liver were used as positive controls. The specimens were pre-treated for 15 minutes with 0.3% Triton X-100 in PBS, followed by PBS rinsing (3×5 minutes). Each section was blocked for 1 hour with 5% goat serum, permeabilized for 30 minutes with 0.3% Triton in 5% goat serum, and incubated with a primary antibody for CD45 (mouse anti-guinea pig), and PBS (1:50). The diluted primary solution was incubated with plates overnight at 4°C in a sealed chamber. 2.11 Statistical analysis An analysis of variance (ANOVA) was performed on the hair cell counts of MP infused cochleae to determine whether significant quantitative differences existed between sensory cell viability in treated and untreated ears. Using SPSS software, a two factor model, with factor 1 = ear and factor 2 = turn was employed to assess whether any observed differences in hair cell loss were significantly different between treated and untreated ears and between turns. Further bonferroni post-hoc correction was used to account for the multiple comparisons made. The p value for significance was .05. 2.12 In vivo Piribedil release Liquid chromatography-mass spectrometry (LC-MS) analysis was performed to determine the Piribedil concentration in cochlear fluid samples. Use of LC allows separation of the drug from a biologically relevant background matrix (native or artificial perilymph) and mass spectrometry enables detection at very low concentrations. The extraction solvent contained 997.5 µL acetonitrile + 2.5 µL Acar mix. Six standards (0–3000 nM), were prepared by spiking native or artificial perilymph with 3 µM stock Piribedil solutions that had been diluted with the extraction solvent. Experimental samples obtained from animals exposed to Piribedil-loaded microparticles were mixed with extraction solvent and vortexed, followed by 5-minute incubation at 4°C. Two vortex/cooling cycles were completed prior to centrifugation of the samples at 15,000 rpm and 4°C for 5 minutes. Sample supernatants were transferred to autosampler vials and subjected to LC-MS analysis utilizing an Agilent 1200 RRLC coupled to an Agilent 6410 Triple Quad LC/MS. Analyte peaks were resolved with the use of a Waters Xbridge C18 (50 mm × 2.1 mm, particle size 2.5 µm) column. The liquid chromatographic conditions were as follows: mobile phases: A = 5mM ammonium acetate, adjusted to pH 9.9 with ammonium hydroxide; B = acetonitrile; flow rate: 0.25 mL/min; and injection volume: 2 µL. The gradient began at 25%B and followed a linear regime from 25% to 75%B over 5 minutes before increasing to and holding at 100% for 3 minutes. Then it was returned to 50%B and re-equilibrated for 4 minutes, thereby resulting in a total run time of 12 minutes/injection. The mass spectrometry source conditions were: gas temp: 325°C, gas flow: 10 L/minute, nebulizing pressure: 40 psi, and capillary voltage: 4000 V. All mass spectrometry readings were collected in positive ion mode. Though the total volume of perilymph in the cochlea is 10 µL, the volume of perilymph in the scala tympani, the chamber into which the particle solution is infused, is only 4.7 µL5. The remaining fluid consists of fluid from the scala vestibule or cerebrospinal fluid therefore a simple correction factor is attained by dividing total perilymph volume by collected perilymph volume. 3. Results 3.1 Particle Fabrication The PLGA/dex particles were fabricated as described previously in Rahmani, et al16,17. Average particle diameter was 7.7 ± 0.12 µm and was determined from ImageJ analysis of scanning electron microscope (SEM) images of the microparticles. Further characterization of the segmented microparticles, such as zeta potential measurements, morphology, and size distribution can be found in Supplemental information and Rahmani, et al16, 17. 3.2 Infused particle number and persistence The number of particles released into the cochlea at the time of infusion was examined. On average, 350,000 particles were infused into each cochlea as counted by a hemacytometer. The persistence of the aforementioned infused particles within the cochlea was also examined. On day 7 following microparticle infusions, untargeted unloaded particles were distributed in the cochlea (Figure 1). The vast majority of particles were located in the first turn of the cochlea (94±17%), followed by the second turn (6±2%) and the third and fourth turns (0%). The third and fourth turns were combined during analysis due to the relatively few numbers of particles found in each turn alone. 3.3 Stereological Analysis In order to facilitate an estimation of the remaining particle number, it was necessary to use stereology, an analysis method that utilizes random, systematic sampling to count objects, in this case, fluorescent particles within cochlear cross-sections. Though methodological restraints prevented retroactive analysis of the samples discussed in section 3.2, particle persistence and distribution of one timepoint, 7 days, was used for stereological analysis. In the new group of animals (n=3), the distribution profile was similar to the previous samples and the average number of particles persisting after 7 days was 20,000±4000. No particles were found in the contralateral ear and a comparison of the number of persisting particles to the number of infused particles demonstrated that approximately 5.7% of untargeted particles were retained in the cochlea following infusion. 3.4 Auditory brainstem responses (ABRs) The hearing thresholds of the animals used in this study were assessed both pre- and post-infusion. ABRs were administered before the start of the experiment to promote the inclusion of only those animals with behaviorally normal hearing (particularly in the lower two-thirds of the cochlea; the upper third was beyond the frequency threshold that can be measured non-invasively). Baseline hearing assessment also provided a basis for comparison to ABR results following infusion to assess particle impact on hearing. Post-infusion testing was conducted at the same three frequencies, 4, 8, and 20 kHz as the pre-test. If the intensity level required for the subject to detect the stimulatory tone at any of the frequencies changed, then a threshold shift occurred. Hearing was considered to have worsened if the sound intensity needed for the subject to detect the stimulatory tone was more than 10 decibels higher than in the pre-test. This value was selected because it has been shown to be outside the bounds of normal experimental variation and therefore can be indicative of an actual functional change in hearing capacity22. A total of eight animals underwent ABR assessment, five that received microparticle infusions and three that were infused with a vehicle solution consisting of artificial perilymph and guinea pig serum albumin. As seen in Figure 2, following microparticle infusion, three out of five animals had hearing within the normal range as compared to their pre-infusion values that is indicated by the threshold shift. One of the MP infused animals, GP 1, demonstrated a threshold shift (>10 dB) at one frequency, 20 kHz. Another MP infused animal, GP 3, demonstrated threshold shifts at all frequencies. Following vehicle infusion, only one animal, GPV 2, demonstrated a large threshold shift at 4 kHz (Figure 2). Therefore, it was imperative to evaluate these results in conjunction with hair cell viability, a morphological indicator of cochlear health, to enable the most complete interpretation of experimental outcomes. 3.5 Cytocochleograms In addition to functional performance, cochlear cell/tissue appearance, particularly the presence or absence of hair cells and immune cells, was evaluated following microparticle and vehicle infusion. Cytocochleograms provided a visual representation of areas of missing hair cells and the location of these cells relative to the apex and base of the cochlea. All infused cochleae were assessed via cytocochleogram and contralateral cochleae were evaluated as needed. Based on previous studies, an area was considered normal if the outer hair cell (OHC) loss occurred intermittently and was 20% or less23. Further, there should be almost negligible loss of inner hair cells (IHCs) observed. It should be noted that in the Hartley strain of guinea pig used in these studies, it is not uncommon to have untreated animals that have large amounts of hair cell loss in the apical third of the cochlea that cannot be detected by ABR during prescreening [unpublished observation] because of the technical limitations of the testing equipment. The distance from the aforementioned area is sufficiently far however, from the lower sixth of the cochlea where the particles were infused to enable the determination of the impact of particle delivery on hair cells/hair cell viability. Upon assessment, two of the microparticle infused animals used for cytocochleograms (GP 1 and GP 4) were found to have the aforementioned apical hair cell loss. However, in all but one case, microparticle infused animals had hair cell losses in all rows of less than 20% in the areas adjacent to the site of infusion (Figure 3). Further, the cytocochleogram of GP 3 demonstrated minimal hair cell loss; therefore, functional deficits identified at the lower frequencies during ABR were likely the result of conductive hearing losses due to the presence of middle ear fluid that was detected during gross dissection. Therefore, microparticle infusion was well tolerated in four out of five animals with only one animal, GP 1, displaying functional and histological losses. For vehicle infused animals, two of three animals, GPV 1 and GPV 3, did not exceed the functional loss criteria as determined by ABR (Figure 2). Further, for GPV 2, the decrement seen at 20 kHz could be explained by the presence of scar tissue, particularly when evaluated in conjunction with the hair cell counts obtained for that animal. Upon histological evaluation by cytocochleogram, all of the vehicle infused animals had minimal to limited hair cell losses near the cochleostomy, including GPV 2, which had hair cell losses in all rows of less than 20% in the areas adjacent to the site of infusion (Figure 4). A moderate apical hair cell loss was also demonstrated in GPV 3, one of the vehicle infused animals (Figure 4). In addition, within MP infused animals, a 2-factor analysis of variance (ANOVA) on OHC loss determined that both ear and turn losses were significant with a p-value below the α=.05 level indicating that treated ears and locations in the higher turns demonstrated greater losses. Subsequent analyses compared the OHC loss of treated and untreated ears at each individual turn (Figure 5). OHC loss in turn 1, near the infusion site, was not significantly different between treated and untreated ears. In turn 2, the difference was statistically significant at .02, however, as average losses for both the non-treated and treated ears were well under 10%, the difference may not be as functionally meaningful. Interestingly, turns 3 and 4 were significantly different when treated (left ears) are compared to non-treated (right ears). It is likely however, that differences observed are related to factors other than the physical presence of the particles because distribution studies demonstrated that particles were primarily located in the first and second turns. 3.6 Immunohistochemistry White blood cells were present in both treated and non-treated ears. The cells were primarily located near vasculature and within the spiral ligament. This finding correlates well with other work reporting the presence of macrophages within the native cochlea24. Further, the number of white blood cells present in treated ears (7.21% ± 4.62) was comparable to that seen in the untreated ears (6.57% ± 3.38) indicating that at 7 days post-infusion, the immune response to the particles was negligible (Figure 6). 3.7 In vivo Piribedil release Piribedil-loaded microparticles contained 2 w/w% Piribedil and a 7-day post-infusion timepoint was selected to perform perilymph sampling to ascertain in vivo concentration of Piribedil release from the particles. The total volume of fluid collected ranged from approximately 6.9–10.2 µL and Piribedil was detected in all analyzed samples (Table 2). Although Piribedil was present in all samples, the apparent concentrations of the drug at 7 days post-infusion were below therapeutic level10. 4. Discussion Historically, much of the focus with regard to cochlear drug delivery has been via systemic administration or acute injection of free drug. Carriers, particularly microparticles made from biodegradable, tunable polymers have the potential to facilitate sustained local drug release to the cochlea. In this study, the polymeric microparticles used were observed to accumulate primarily within the first turn. This finding was not unexpected as this location was the site of infusion and existence of fluid flow in the cochlea is negligible. During infusion, the dispersion of particles to other turns relies primarily upon diffusion and the small flow induced by the micropump. The infused particles were found in comparable numbers and distributions 1 and 7 days post-infusion thereby indicating that particles capable of surviving acute clearance (washout via eustachian tube, immune response, etc.) were able to remain in the cochlea for an extended period. Further, no particles were detected in the contralateral ear, indicating that the delivery platform does not diffuse to the contralateral cochlea via cerebrospinal fluid, nor were they seen in the liver, as can occur with nanoparticles25, thereby eliminating concerns about inadvertent effects. Though the percentage of remaining particles was small (5.7% ± 1.1), the utility of delivery from particles following infusion would be dependent on the dose of drug needed to achieve therapeutic level and the extent to which the drug was able to be incorporated (weight %) into the particles. Further, the percentage observed could be a consequence of the sample processing required to generate the particle cross-sections used in the analysis. During incubation in the decalcifying solution and/or the cryoprotection solution, particles located in the fluid spaces could be displaced, meaning that only particles closely associated with the lining of the cochlear chambers would remain for analysis. Therefore, it is possible that non-adherent particles were simply “washed out” of the system before they could be assessed. Potential modifications to the surface of the microparticles to include ligands targeting cochlear structures or implant materials may also help to increase the number of attached particles. The majority of infused animals had comparable or only slightly elevated post-infusion hearing thresholds and minimal hair cell loss following infusion. Hair cells act as mechanotransducers and enable the conversion of fluid movement into electrical signals within the cochlea that can be then be interpreted by the brain. These cells are sensitive to damage from both chemical and physical means and their absence impairs auditory function. One of the microparticle infused animals with an apparent post-infusion threshold shift was GP 3. This animal had an observable threshold increase at all frequencies, however the greatest shifts occurred at 4 and 8 kHz; this physiology correlated well with its gross anatomy in that fluid was present in its middle ear and excess fluid makes it more difficult for sound to be transmitted, particularly at lower frequencies. Further, GP 3 had similar numbers of viable hair cells as non-shifted animals, therefore conductive losses rather than particle presence caused the detected functional deficits. The almost negligible loss of inner hair cells and normal losses of outer hair cells near the site of infusion indicate that locally delivery of segmented microparticles was well tolerated in four out of five microparticle infused animals. One animal, GP 1, however, did experience functional and histological detriment following MP infusion. Within the three vehicle animals that received an infusion of the vehicle solution consisting of artificial perilymph and guinea pig serum albumin, one had an apparent threshold shift. This animal, GPV 2, had a large (greater than 40 dB) threshold shift at 4kHz. Examination and analysis following harvesting of the cochlea GPV 2 revealed a normal cytocochleogram and the presence of scar tissue on the treated cochlea although the tympanic membrane and middle ear were clear. This finding indicates that the functional deficit observed is also likely the result of conductive losses. The two remaining vehicle infused animals tolerated the procedure well and did not have extensive amounts of hair cell loss near the site of infusion. Upon further examination of the ANOVA analysis, the determination that both ear and turn were significant factors in predicting hair cell loss was found to be primarily based on differences between OHC presence in turns 3 and 4 of treated ears. The statistically significant difference observed in treated versus untreated ears in turns 3 and 4 seems unusual because distribution studies determined that the majority of particles were in the first and second turns. Further, based on the site of infusion, any potential hair cell loss would be expected to occur at the base of the cochlea. It is possible that the differences seen are related to an increase in intracochlear pressure induced by surgery or the viscosity of the delivery solution formed from artificial perilymph and guinea pig serum albumin as this increased trauma was also present when a vehicle solution was used. To alleviate potential pressure changes caused by displacement of native perilymph during infusion, an outlet hole could be drilled to provide an alternative exit to the cochlear aqueduct, thereby enabling removal of excess fluid from the perilymphatic space26. Further, future work could include assessment of the functional and pathophysiological impact of the viscosity of the delivery solution and incorporate this knowledge into future iterations of the particle delivery protocol. In addition, surface modification could enable particle attachment to implants and eliminate need for a delivery solution. The apparent biocompatibility of PLGA/dextran microparticles with the cochlea was not unexpected due to the composition of the constituent materials. PLGA is a FDA approved biodegradable polymer and it, along with its degradation products, is relatively biologically inert14. In addition, Dextran is a natural polysaccharide that is also well tolerated in the body14. Further, the detection of Piribedil, a proof of principle medication in this study, demonstrated that drug release from the particles is measurable albeit currently sub-therapeutic within cochlear fluids at 7 days post-infusion; Piribedil has poor solubility that resulted in low percentage incorporation into the polymer matrix of the microparticle. An alternative non-competitive glutamate agonist with better solubility could be utilized in future work to address the efficacy of intervention, thereby increasing the likelihood that therapeutic level could be attained in vivo. 5. Conclusions This work has demonstrated the feasibility of delivering microparticles with multiple distinct compartments to the cochlea in vivo. Specifically it has characterized the in vivo persistence, distribution, and drug release from the chosen particle system. Particles persisted within the cochlea for at least seven days. Following particle infusion, there was only a slight impact on cochlear functionality in the majority of animals and a robust immune response was not induced. Cell survival and morphology were also well maintained in areas of the cochlea with high numbers of particles. This technology represents a tunable platform with potential for intracochlear drug delivery as targeted free particle suspensions or particles attached to an auditory implant. Future work should consider the impact of the viscosity of the particle delivery solution on cochlear functionality and assess efficacy of drug delivery from segmented particles in a trauma model. Supplementary Material Supp Fig 01a Supp Fig 01b Supp Info The authors acknowledge funding from the National Institute of Deafness and Communication Disorders (NIH-NIDCD 5R01 DC011294-01), the Multidisciplinary University Research Initiative of the Department of Defense and the Army Research Office (W911NF-10-1-0518), the DOD through an idea award (W81XWH-11-1-0111), and the Tissue Engineering and Regenerative Medicine Training Grant (DE00007057-36). We also thank Noel Wys and Catherine Martin for their technical assistance. Figure 1 Particle distribution of unloaded microparticles observed 7 days after in vivo infusion. A) Percentage distribution of particles within the first four turns of the guinea pig cochlea where turn 1 (B–A) is the closest to the cochleostomy/infusion site and turn 2 (B–B) is the next adjacent turn. Figure 2 Cochlear function 7 days post MP or vehicle infusion as represented by auditory brainstem responses. For all animals, threshold shift (difference between pre- and post-infusion thresholds) at 4, 8, and 20 kilohertz are shown. A threshold shift greater than 10 dB (*) is indicative of a change in an animal’s hearing. At the majority of frequencies across animals, no shift is observed, though at 20 kHz GP 1 and 3 both demonstrate shifts and GP 3 also demonstrates shifts at 4 and 8 kHz. Among vehicle infused animals, GPV 2 demonstrates a notable shift at 4 kHz. Based on anatomical observations, the threshold shifts observed at lower frequencies are likely the result of conductive losses rather than the physical presence of the microparticles. Threshold shifts for GP and GPV animals are denoted by patterned or solid columns, respectively. GP= microparticle infused animals. GPV= vehicle infused animals. Figure 3 Cochlear hair cell death as represented by cytocochleograms (graphical representation of hair cell loss) at day 7 post-infusion for microparticle infused guinea pigs (n=5) receiving 5µL of microparticles. The regions of auditory brainstem response (ABR) functional testing as well as the cochleostomy site have been indicated along the x-axis. In all animals, hair cell loss near the cochleostomy site in the infused ear is minimal. Cytocochleograms for all left/treated ears are shown and a representative cytocochleogram (GP 1) of a right/untreated ear is provided in the upper right panel of the figure. Figure 4 Cochlear hair cell death as represented by cytocochleograms (graphical representation of hair cell loss) at day 7 post-infusion for vehicle infused guinea pigs (n=3) receiving 5µL of vehicle solution. The regions of auditory brainstem response (ABR) functional testing as well as the cochleostomy site have been indicated along the x-axis. In all animals, hair cell loss near the cochleostomy site in the infused ear is limited. Cytocochleograms for all left/treated and right/untreated ears are shown. Figure 5 Cochlear outer hair cell loss comparison. Graphical depiction of the OHC loss as a function of ear (treated/left vs. non-treated/right) and turn at 7 days post microparticle infusion. A two-factor analysis of variance (ANOVA) with α=.05 found that turn (p=0.00) and ear (p=0.00) were both significant. The differences between ears were primarily driven by OHC losses in turns 3 and 4. Differences between ears in turn 2 were functionally negligible and did not exist in turn 1. OHC= outer hair cell. Black bars are standard deviation. Figure 6 CD45 presence in treated and untreated cochleae. Resident white blood cells may be in the normal cochlea and no differences are seen in the number of these cells present at 7 days following MP infusion. A) A representative cochlear cross-section wherein leukocytes are identified as nuclei (red) whose surface/cell membrane is positive for CD45 (green). B) Quantification of the percentage of CD45+ cells present within treated and untreated cochlear cross-sections. Black bars are standard deviation. Table 1 Potential Strategies for Local Cochlear Drug Delivery Contains a synopsis of various platforms investigated for local cochlear drug delivery and outlines the advantages, limitations, and distribution profile of each type of carrier/strategy. Potential Inner Ear Carriers Advantages Limitations Cochlear Distribution (turn) Hydrogel/Sponge Ease of insertion/non-invasive; biodegradable Extracochlear/Intratympanic application; drug incorporation by diffusion; relies on RWM permeability Basal Microfluidics/Mini-Osmotic Pumps Continuous delivery; real time modulation of infusion rate Must be refilled/size; biofilm formation; finite power supply Basal to apex Viral Vector Induce regeneration Induce immune response; toxicity Variable Biodegradable Micro/nanoparticles Biodegradable; size; multifunctional Invasive; release rate predetermined Variable Table 2 Intracochlear Concentration of Piribedil at 7 Days Post-infusion of Piribedil-loaded Microparticles Contains the volumes, apparent concentrations, and volume corrected concentrations from each sample. The corrected concentrations were obtained by multiplying the apparent concentration by a correction factor derived from dividing total perilymph volume by collected perilymph volume. Specimen Volume (µL) Apparent Concentration (nM) Volume Corrected Concentration (nM) GP 11 10.20 339.23 736.20 GP 13 9.00 106.04 207.57 GP 22 8.40 207.41 370.68 GP 25 7.22 205.73 316.04 GP 15 6.88 223.43 327.07 GP 26 7.10 192.01 290.06 Average 8.13 212.31 374.60 Standard Deviation 1.31 74.84 185.20 3* Conflict of Interest: No benefit of any kind will be received either directly or indirectly by the author(s). 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PMC005xxxxxx/PMC5111634.txt
LICENSE: This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. 7702118 4161 Immunol Rev Immunol. Rev. Immunological reviews 0105-2896 1600-065X 27782333 5111634 10.1111/imr.12499 NIHMS817361 Article The Immune System’s Role in Sepsis Progression, Resolution and Long-Term Outcome Delano Matthew J. 1 Ward Peter A. 2* 1 Department of Surgery, Division of Acute Care Surgery, University of Michigan 2 Department of Pathology, University of Michigan Medical School * Correspondence should be directed to: Peter A. Ward, M.D., Godfrey D. Stobbe Professor of Pathology, University of Michigan Medical School, Department of Pathology, 1301 Catherine Street, 7520 MSRB I, Ann Arbor, MI 48109-5602, Tel. 734-647-2921, Fax 734-764-4308, pward@umich.edu 22 9 2016 11 2016 01 11 2017 274 1 330353 This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. SUMMARY Sepsis occurs when an infection exceeds local tissue containment and induces a series of dysregulated physiologic responses that result in organ dysfunction. A subset of patients with sepsis progress to septic shock, defined by profound circulatory, cellular, and metabolic abnormalities, and associated with a greater mortality. Historically, sepsis-induced organ dysfunction and lethality were attributed to the complex interplay between the initial inflammatory and later anti-inflammatory responses. With advances in intensive care medicine and goal-directed interventions, early 30-day sepsis mortality has diminished, only to steadily escalate long after “recovery” from acute events. Since so many sepsis survivors succumb later to persistent, recurrent, nosocomial and secondary infections, many investigators have turned their attention to the long-term sepsis-induced alterations in cellular immune function. Sepsis clearly alters the innate and adaptive immune responses for sustained periods of time after clinical recovery, with immune suppression, chronic inflammation, and persistence of bacterial representing such alterations. Understanding that sepsis-associated immune cell defects correlate with long-term mortality, more investigations have centered on the potential for immune modulatory therapy to improve long term patient outcomes. These efforts are focused on more clearly defining and effectively reversing the persistent immune cell dysfunction associated with long-term sepsis mortality. inflammation sepsis immune suppression sepsis innate immune dysfunction adaptive immune dysfunction INTRODUCTION Until recently, sepsis was defined as the constellation of symptoms occurring when a bacterial, viral or fungal infection leads to a systemic inflammatory response syndrome (SIRS), including fever, leukocytosis or leukopenia, and decreased vascular resistance frequently leading to hypotension (septic shock), organ failure (severe sepsis) and death(1, 2) (Fig.1). However, vagueness in definitions and ineffective clinical strategies have led to discrepancies in the incidence of sepsis and the observed mortality(3). In response, the Third International Consensus Definitions for Sepsis and Septic Shock (Sepsis-3) were developed and address the limitations of previous definitions that were over focused on SIRS and inflammation(4). In addition, the Consensus also dispelled the longstanding notion that SIRS criteria possess adequate specificity and sensitivity to define and diagnose sepsis. Lastly, the report debunked the misleading model that sepsis always follows a linear continuum from the SIRS through severe sepsis and septic shock, and declared the term “severe sepsis” redundant and unnecessary. Instead, the Consensus report recommends that sepsis be defined as a life-threatening organ dysfunction caused by a dysregulated host response to an infection (Fig. 2). Organ dysfunction is now defined by an increase in the Sequential Organ Failure Assessment (SOFA) score of 2 points or more, which is associated with an in-hospital mortality greater than 10% (Fig. 3). Furthermore, septic shock is now defined as a subset of sepsis in which profound circulatory, cellular, and metabolic abnormalities are associated with a greater risk of mortality than with sepsis alone. Clinically, patients with septic shock can be identified by a vasopressor requirement to maintain a mean arterial pressure of 65 mmHg or greater and serum lactate level greater (>18mg/dL) in the absence of hypovolemia with inhospital mortality rates greater than 40% (Fig. 4). In order to identify patients with the highest probability of poor outcome associated with sepsis, a new bedside clinical score named the quickSOFA (qSOFA) was created which consist of at least 2 of the following clinical criteria including, respiratory rate of 22/min or greater, altered mentation, or systolic blood pressure of 100mmHg or less(4) (Fig. 5). Even though substantial advances in our clinical understanding, disease definition, and immune pathophysiology have improved overall sepsis survival, long-term sepsis mortality is abysmal, at 40–80%(5). Despite progress in antibiotic therapy, ventilator management, resuscitative strategies and blood glucose maintenance, sepsis remains the leading cause of death in the intensive care units (ICUs)(6). Even more alarming is the escalating cost of sepsis-associated medical care, which is estimated at $17 billion annually in the United States(7). Considering the rapidly expanding elderly population with large comorbidity burdens, physiologic frailty and immune senescence(8), sepsis mortality is expected to rise at an alarming rate over the next two decades(9). Despite over 100 therapeutic clinical trials in sepsis, no FDA-approved treatment options currently exist that improve sepsis survival(10). Although clinicians and investigators have opined in a sundry of editorials, reviews and commentaries incriminating a multitude of possible explanations such as, impaired cellular metabolism, tissue oxygenation, and myocardial dysfunction(11), the most accepted postulate describes a persistent and complex, immune/inflammatory interplay that is yet ill-defined(11, 12). Traditionally, sepsis investigations attempted to improve thirty day survival by dampening the inflammatory response by way of IL-1 and TNF blockade(13) with little success in reducing mortality. However, continued improvements in clinical treatment strategies over the past two decades(14) have resulted in more patients surviving life-threatening sepsis and organ dysfunction, only to manifest prolonged states of immune dysfunction, immune suppression(15), persistent inflammation and metabolic catabolism(16). These varying states of immune paralysis are characterized by impaired immune surveillance and the development of persistent, recurrent, secondary, and nosocomial infections which facilitate protracted events that often lead to death(17). Historically the sepsis death distribution has been biphasic, with an initial early peak at several days due to inadequate fluid resuscitation, resulting in cardiac and pulmonary failure, and a late peak at several weeks due to persistent organ injury or failure(18). Considering the recent recognition in mounting long-term sepsis mortality, a trimodal pattern is more indicative of the current death distribution(17–19). The early peaks in mortality exist, albeit of much less magnitude, and the third upswing occurs after 60–90 days and continues to soar over the ensuing three years(17, 19, 20) (Fig. 6A, B). These deaths are speculated to be the consequence of more sophisticated ICU care that keeps elderly and co-morbidly challenged(9) patients alive longer in spite of ongoing immune, physiologic, biochemical, and metabolic aberrations(21). Although the specific etiologies of long-term sepsis mortality are currently unclear, several reports suggest that advanced age, comorbidities, and persistent organ injury synergize to generate a damaging state of chronic and critically ill disease characterized by ongoing immune dysfunction, immune suppression, and catabolism and inflammation(15, 16, 22). Moreover, persistent inflammation combined with chronic immobility, catabolic drugs, and extended paralytic drugs all culminate to produce a state of immune dysregulation that facilitates infectious complications and terminates in chronic deterioration and death(23). Thus, investigators have been forced to refocus their efforts on the underlying innate and adaptive immune system derangements that facilitate the development of infectious complications, impair sepsis recovery and increase long-term mortality(24, 25). In this review we will outline the immune system’s role in sepsis progression, resolution and long term outcome and focus our attention on the clinical implications, and potential therapeutic interventions available to improve long-term survival. Immune Dysfunction in Sepsis Sepsis impacts the immune system by directly altering the life span, production and function of effector cells responsible for homeostasis(26, 27). The hematopoietic compartment constituently replenishes terminally differentiated innate and adaptive cells which are intrinsically responsible for immune surveillance against offending pathogens, and concomitantly prerequisite for successful tissue regeneration and wound healing. Over the last two decades a debate has persisted as to whether innate and adaptive immune dysfunction or inflammatory and anti-inflammatory processes are more detrimental to sepsis survival(28). Formerly, the inflammatory response was thought to drive early mortality in the first several days of sepsis, and the compensatory anti-inflammatory response was thought to induce organ failure, immune suppression and mortality weeks later (29). However new insights gathered using genomic analysis of septic patient tissue samples(15) and severely injured trauma patients, have identified an enduring and simultaneous inflammatory and anti-inflammatory state driven by dysfunctional innate and suppressed adaptive immunity that together culminate in persistent organ injury(30) and patient death(31, 32) (Fig. 7). Although shortcomings in each of these studies exist, when the collective results are compared with patient outcomes, it is clear that a paradigm shift is necessary to explain the long-term mortality surge after sepsis. It is evident that inflammatory and anti-inflammatory responses and innate and adaptive immune systems are each equally important, and likely present targets for future immune therapies to improve long-term sepsis outcomes(25–27, 33). The following discussion provides an overview of the sepsis-induced alterations in inflammation, innate and adaptive immune cell function, and the most promising immune response modifiers being considered for future human sepsis therapy. Hyperinflammation Once the host loses local-regional containment of an infection, the body is systemically exposed to microbes, microbial components and products of damaged tissue. This induces an inflammatory response and initiates sepsis-like responses through the recognition of pathogens and damaged tissue by way of pattern recognition receptors (PRRs) which are ubiquitous on immune cell surfaces. PRRs are expressed primarily on immune and phagocytic cells and on many types of somatic tissues. Microbial infections are recognized by pathogen-associated molecular patterns (PAMPs) that are expressed by both pathogenic and harmless microbes. PAMPs are recognized by PRRs such as Toll-like receptors (TLR), C-type and mannan binding lectin receptors, NOD-like receptors, and RIG-I-like receptors. Proteins and cellular products released by tissue damage are similarly recognized as damage-associated molecular patterns (DAMPs)(34). During sepsis, systemic activation of the innate immune system by PAMPs and DAMPs results in a severe and persistent inflammatory response characterized by an excessive release of inflammatory cytokines such as IL-1, TNF, and IL-17, collectively known as the “cytokine storm”(30). The exorbitant release of inflammatory cytokines occurs over a relatively short period of time (several days). In addition, intense complement activation and innate immune stimulation potentiate what should be a normal physiological response to infection, instead into an excessive inflammatory response resulting in tissue damage, cellular compromise, and molecular dysregulation that initiate organ dysfunction and even multi-organ failure(30). Although some patients recover from this inflammatory state, for unknown reasons elderly patients with heavy comorbidity burdens fail to resolve this initial condition and progress to a state of persistent ongoing inflammation, immune cell dysfunction, and catabolic metabolism, all of which degrades the immune system’s ability to clear infections and heal injured tissues(35). Recently, investigators have suggested that therapeutic interventions that curb hyperinflammation, shift catabolism toward anabolism, and bolster immune function maybe beneficial in combination, once the initial episode of sepsis has subsided(24, 36, 37). Although in other disease states such as severe burns(38), advanced cancers(24, 25, 39, 40), and autoimmune diseases(41), combination therapies that reduce inflammation, optimize metabolism, and decrease infections are common-place, there is as of yet no clear plan for the routine use of these or similar strategies to improve long-term outcome in sepsis(19). Until we embrace and adapt strategies for sepsis therapy that have been demonstrated to improve outcome in other inflammatory disease states, we may not be able to meaningfully improve sepsis survival. Immune Resolution Resolution of the hyperinflammatory cytokine cascade was thought to begin days after the initial sepsis episode had passed. However recently, it has been discovered that compensatory anti-inflammatory pathways are activated shortly after sepsis initiation(28). The hallmark cytokine is IL-10, which is produced by a variety of leukocytes, suppressing the production of IL-6 and interferon-γ (IFNγ), and stimulating the production of soluble TNF receptor and IL-1 receptor antagonist. These products neutralize proinflammatory TNFα and IL-1 signaling(42). At the subcellular level, autophagy provides a way to eliminate DAMPs and PAMPs by packaging pathogen components, damaged organelles and cellular proteins into vesicles targeted for lysosomal degradation, resulting in reduced inflammation and cellular activation(43). Resolution of inflammation after severe infection is not simply a passive process of curbing cytokine production and easing inflammatory pathways. Instead, dampening of inflammation involves an interdigitating, complex and coordinated array of cellular processes and recently recognized molecular signals. Soon after pathologic bacteria are eliminated from the host, damaged tissues, cells and leukocytes must be removed from the infection site. Under favorable circumstances the defunctionalized tissue cells and leukocytes undergo apoptosis, becoming engulfed by macrophages and removed from the inflamed field, triggering the production of anti-inflammatory IL-10 and transforming growth factor β. Furthermore, recently discovered bioactive lipids termed lipoxins, resolvins, protectins, and maresins have been shown to reduce ROS, endothelial permeability, and leukocyte recruitment, and further enhance macrophage phagocytosis(44, 45). In addition to anti-inflammatory cytokines, inflammation resolution is also governed by multiple subsets of regulatory immune cells such regulatory T cells (Tregs)(46, 47) and myeloid derived suppressor cells (MDSCs) that orchestrate inhibition over cytoxic effectors and curb inflammatory cytokine production(48). Historically, therapeutic interventions aimed at inhibiting the acute inflammatory response to infection and subsequent sepsis using glucocorticoids, nonsteroidal anti-inflammatory agents, and anti–TNFα antibodies have repeatedly failed to improve outcomes in patients with sepsis and septic shock(10). Conversely, strategies that stimulate endogenous mediators that actively resolve inflammation have not been thoroughly explored because the critical signaling factors that regulate these native processes have remained elusive. Serhan and colleagues, demonstrated that eicosapentaenoic acid (EPA) and docosahexaenoic acid (DHA) derived lipids, [coined pro-resolving mediators (SPMs), including resolvins, protectins, and maresins], increase early after states of infection, regulate inflammation resolution, and enhance bacterial clearance(44). Recently, Dalli and coauthors reported a novel cohort of host-protective lipids termed 13-series resolvins (RvTs)(49). These host-protective lipids are formed early during inflammation, promote bacterial phagocytosis, increase production of reactive oxygen species, and augment host recovery from systemic infection by accelerating the resolution of the acute inflammation(49). Furthermore, the systemic administration of atorvastatin can increase RvT biosynthesis through activation of COX-2 and accelerate infection resolution which can be reversed by COX-2 inhibition using celecoxib(49). Together these findings shed light on a new group of endogenous mediators that resolve host inflammation without interfering with phagocytosis and identify a new mechanism for the pleiotropic effects of statins that mitigate inflammation and promote endothelial function(50). Although statin therapy in sepsis has yielded little benefit in clinical trials(51), the discovery of a new class of bioactive lipids that resolve inflammation could provide a biomarker to identify subgroups with impaired RvT biosynthesis who may benefit from statin therapy. Immune Suppression Generally, therapeutic strategies to treat sepsis have focused on inhibiting the early hyperinflammatory phase. However, it is evident that a state of immune suppression exists concomitantly with persistent inflammation and enables the development of persistent, recurrent, secondary, and nosocomial infections which lead to poorer outcomes and increased long-term mortality(25). Sepsis-induced immune suppression impacts both cellular effectors of the innate and adaptive immune systems. Neutrophils, essential for bacterial eradication, display defects in chemotaxis and recruitment to sites of infection, in the setting of sepsis(52, 53). Furthermore, the production and release of essential effector molecules, such as reactive oxygen species (ROS) and cytokines, is significantly impaired(53–55), leading to bacterial persistence and the development of infectious complications. Even though myeloid cell production of pro-inflammatory cytokines is reduced, overall myeloid cell production and release of anti-inflammatory cytokines (e.g., IL-10) is elevated(54). Defects in antigen presenting cell (APC) function, including reduced HLA-DR expression, endotoxin tolerance and impaired cytokine production all reduce the capabilities of APCs to stimulate lymphocyte driven immune functions following sepsis(56–59). Apoptosis of lymphocytes and APCs (dendritic cells, T cells and B cells) is considered a hallmark of septic immune suppression(60, 61). In addition to diminished innate function, adaptive immunity is similarly impaired. Splenocytes harvested from deceased sepsis patients demonstrate reduced numbers of CD4+ and CD8+ lymphocytes that emanate from substantial apoptosis(15). Moreover, CD4+ cell loss is associated with a reduced ability to mount appropriate immune responses to viral infections including cytomegalovirus, Epstein-Barr virus, herpes simplex virus, and human herpes virus reactivate after septic insults(62). However, reduced lymphocyte numbers are not just reflective of the risk for viral reactivation following sepsis. Lymphopenia four days after the onset of sepsis is associated with the development of secondary infection and is predictive of long-term mortality at one year after sepsis(63). Overall these specific cellular alterations coalesce into a chronic state of immune suppression, characterized by persistent, recurrent, secondary, and nosocomial infectious complications(64) often resulting in hospital readmissions(65–67), and poor long-term survival(68). Over the last 5 years it has become abundantly clear that in the weeks and months following hospital discharge, sepsis survivors have increased readmission rates(69) due to infectious complications(70), requiring more antibiotics, ICU days, and hospital resources, when compared to patients not experiencing sepsis(71). With the ever increasing, comorbidly-challenged elderly population, demonstrating persistent inflammation, immune suppression and immune senescence, the number of sepsis survivors that develop subsequent infections is predicted to rise substantially in the next decades(68, 72). It is evident that sepsis induces a pathologic state of immune suppression that prompts the development of secondary infections while still in the ICU setting(73). Several reports over the past five years demonstrate that sepsis survivors experience dramatically higher rates of subsequent infections long after the initial episode of sepsis has resolved(65, 69, 70, 74–76). The increased hospital readmission rates due to infectious complications among sepsis survivors is a sign of ongoing immune suppression and dysregulation that if not corrected, diminishes life quality and durable survival. Molecular Alterations in Sepsis Current sepsis observations suggest that multiple organ failure occurs even in the context of preserved cell morphology and in the absence of significant cell injury. In addition, organ dysfunction is often reversible, even in organs that regenerate poorly (heart, lung, central nervous system, kidneys). Therefore, it is apparent that sepsis-induced organ dysfunction occurs primarily though cellular and molecular dysregulation, as opposed to gross tissue damage. By this principle, immune dysfunction in sepsis is also associated with molecular alterations that alter cellular phenotype and function. Below, we outline several important pathways of cellular dysfunction that impact immune function during and after episodes of sepsis. Complement Activation It has long been known in human and rodent sepsis models that a robust and consumptive depletion of complement occurs, resulting in a sharp drop in hemolytic plasma complement and in the appearance in plasma of complement activation products(77). There is also evidence that sepsis in humans causes shedding of the C5a receptor into plasma, likely due to release of microparticles from neutrophils(78). Similar events occur in rats and mice with experimental polymicrobial sepsis(79). In addition to complement activation, there is also a robust stimulation of both the fibrinolytic and clotting systems(80). There is also evidence for activation of several clotting factors, some of which have C3 and C5 convertase activities, generating C3a as well as activation of thrombin which has C5 convertase activity and generates C5a and the terminal membrane attack complex (MAC)(81). There is well established evidence that activation of the complement system is often linked to activation of both the clotting and the fibrinolytic systems. Development of neutralizing C5a antibodies in murine models dramatically attenuated the intensity of sepsis, including greatly improved 7-day survival, reduced levels of plasma cytokines, and decreased multiple organ failure(79, 80, 82). The steady progress achieved in understanding complement and how its production and deposition increase systemic inflammation, organ failure and mortality, have resulted in the development and randomized phase 2 trial of a C5a inhibitor, CaCP29 (EudraCT Number: 2013-001037-40) which has shown great promise despite a historically large field of other failed antibody inhibitors(83). Redox Imbalance Clinical and experimental evidence has been well published that demonstrates septic patients exhibit overwhelming oxidative stress(84–86) which results from uncontrolled production of ROS and reactive nitrogen species (RNS). This severe state of oxidative stress is produced by activated immune and epithelial cells that overexpress oxide synthases including inducible nitric oxide synthase (iNOS), or via mitochondrial production of ROS(86–88). ROS and RNS play crucial roles in sepsis progression by interfering with nitric oxide signaling cascades and oxidation/nitrosylation of proteins or nucleic acid substrates that results in harmful molecular function(87, 89). Although anti-oxidant therapies have shown benefit during animal models of experimental sepsis, the same advantage has not translated into successful human clinical trials(90). Ca2+ Homeostasis Hypocalcemia is common in sepsis and correlates with disease specific scores during critical illness(91–94). Altered intracellular calcium handling is hypothesized to be responsible for the observed systemic hypocalcemia(94). Although systemic Ca2+ levels are reduced during sepsis, there are increased Ca2+ cytosolic levels which may stem from increased uptake. The same intracellular calcium fluctuations are elevated in a variety of tissues and cell types during sepsis(95–97) although the specific mechanisms underlying altered Ca2+ handling remain unclear. Heightened intracellular calcium leads to elevated inflammatory responses, cellular dysfunction, and can even be cytotoxic. In addition, the accumulation of Ca2+ in organs during sepsis is also associated with significant organ dysfunction(98). PARP1 and PARP2 Activation Poly(ADP-Ribose) Polymerase 1 (PARP1) and PARP2 are enzymes that catalyze poly(ADP-robosyl)ation of proteins. Catalytic activity of these enzymes is stimulated by DNA strand breaks. PARP activity is viewed as a sensor of DNA damage. PARP1 activation and initiation of the inflammatory response occur simultaneously(99). PARP1 activity upregulates proinflammatory gene expression(100), which is attributed to PARP1-induced alterations in chromatin structure and in transcriptional regulation(99, 101). Because PARP1 also directly contributes to cell death in affected tissues(99) it is hypothesized that PARP1 also plays a role in sepsis associated immune cell death. PARP1 genetic deficiency is protective during murine models of experimental sepsis, and is associated with significantly lowered plasma cytokine levels and reduced tissue/organ dysfunction(102). Inhibitors of PARP1 have been studied in clinical trials as potential cancer therapeutics, but trials for sepsis have not been initiated. Therefore, it is not clear whether inhibitors of PARP1 will be beneficial during the treatment of human sepsis. Mitochondrial Dysfunction Mitochondria are critical for maintaining an adequate supply of ATP for cellular processes. In addition, damaged mitochondria can trigger cell death pathways through the release of mitochondrial cytochrome c(103). Mitochondria are affected in several ways during sepsis. The generation of excessive amounts of ROS and RNS can directly inhibit respiration and damage respiratory chain components in mitochondria(104–106). In addition, impaired tissue perfusion (due to fluid loss, both intrinsic and extrinsic, as well as reduced vascular tone) leads to tissue hypoxia. Loss of tissue oxygenation significantly impairs oxidative phosphorylation and may trigger cell death pathways(107). Mitochondrial dysfunction, or direct damage of mitochondria, can directly affect the generation of ATP. Not only will the drop in ATP negatively affect cellular processes, but severe lack of ATP can trigger cellular anergy, whereby the cell will not necessarily die, but instead acquire a hibernation-like state resulting in tissue dysfunction and organ failure(108). The importance of mitochondrial dysfunction during sepsis is highlighted by the observations that cellular ATP levels are correlated with survival in both human and animal sepsis models(106, 109). Cellular Defects The following discussion provides a summary of the sepsis-induced immune alterations in the majority of innate and adaptive cell types, along with the most promising candidates under consideration to be employed as immune response modifiers for future human sepsis therapy. Although we have attempted to focus this discussion on human sepsis, many of the current insights have been gleaned from animal sepsis model recapitulating aspects of human sepsis. The authors recognize the recent and ongoing debate about the efficacy of murine and other animal models to accurately reflect human disease processes(110). The authors’ opinion is that both human and animal models are necessary if continued scientific progress and improved patient outcome is to continue. Even though we clearly realize that animals do not immunologically, metabolically, or genomically equal the state of human responses, it is not sustainable to merely test all of the proposed hypotheses in human disease systems without the benefit of animal correlation to explore scientific avenues not otherwise ethically amenable to the human condition. Innate Immunity Endothelium Endothelial cells (ECs) form a single cell layer called the endothelium, which line all of the vasculature and lymphatic systems in the body and comprise a semi-permeable barrier between blood and lymph within vessels and the surrounding tissue. ECs are a heterogeneous population of cells that fulfill many physiological processes and participate in innate and adaptive immune responses. ECs function as danger signal sensors, therefore are one of the first cell types to detect invading microbes via endogenous metabolite-related danger signals in the bloodstream(111). LPS exposure activates ECs, causing the production of pro-inflammatory cytokines and chemokines, which amplify the immune response by recruiting immune cells(112). Therefore, ECs function as innate force multipliers, cell mobilizers, and immune regulators by modulating cellular function(113). In special circumstances, ECs can serve as antigen presenting cells expressing both MHC I and II molecules and present endothelial antigens to T cells. ECs also express TLR-2 and TLR-4 enabling them to respond to LPS in states of bacterial infection(112). During sepsis a significant amount of EC dysfunction is present and manifests as several pathological processes including capillary leak, altered vasomotor tone and microvascular thrombosis(114). A further consequence of damage to the endothelium is the release of pathological quantities of von Willebrand factor, which promotes platelet aggregation and adhesion to the subendothelial layer and the formation of pathologic thrombi. In sepsis there may be direct destruction of the endothelial barrier, and an increased number of circulating endothelial cells that have been observed in patients with septic shock. Angiopoietin-2 (Ang-2) mediates endothelial microvascular leak and is an independent predictor of death and organ dysfunction during sepsis(115). Since the early outcome of sepsis is mainly determined by the degree of organ failure, macro- and microvascular endothelial dysfunction has been proposed as an early biomarker of immune function and outcome. In patients with severe sepsis, in vivo measured endothelial dysfunction coincides with lower numbers and reduced function of circulating progenitor cells implicated in endothelial repair(116). The results suggest that cellular markers of endothelial repair might be valuable in the assessment and evolution of organ dysfunction and even outcome following episodes of sepsis. ECs also release microparticles which are protective against vasomotor hyporeactivity, which accounts for hypotension in patients with septic shock(117). Taken together, there is a large amount of data to suggest that ECs are key regulators of the physiologic and immunologic dysfunction during and after sepsis, and that EC modulation is possibly beneficial to improve long-term human sepsis survival. Neutrophils Neutrophils are the most prevalent and integral cell type of innate function, essential for microbial containment and eradication, and prerequisite for long-term sepsis survival(118). They comprise the majority of the cellularity in the bone marrow (BM) and are the very first responders to sites of microbial infections (119). One of the most pronounced innate immune alterations in sepsis is a delayed state of neutrophil apoptosis(120), leading to ongoing neutrophil dysfunction. This delayed state of neutrophil apoptosis is further compounded by the release of immature band-like neutrophils from the BM that demonstrate clear deficits in oxidative burst(121), cellular migration patterns(122, 123), complement activation ability and bacterial eradication(54), which all combine and contribute to persistent immune dysfunction and inflammation. These findings combined with TLR signaling deficits (124), chemokine-induced chemotaxis reductions (125), altered apoptosis signaling pathways, and neutrophil immune senescence(126), result in a sundry of functional deficiencies that endure long after sepsis symptoms have subsided. A host of mounting scientific evidence also suggests that neutrophils may function as APCs in a broad array of pathological infections and act as crosstalkers between innate and adaptive responses through activation of CD4+ and CD8+ effector cells(127, 128). More importantly, multiple human studies have implicated the complex array of persistent neutrophil dysfunction in the development of hospital acquired infections(129). Furthermore, patients with the most pronounced derangements in neutrophil function following sepsis are the most susceptible to develop intensive care unit complications such as ventilator-associated pneumonia and other nosocomial infections(130). The vast majority of patients who die from sepsis have ongoing infections(15), suggesting that defects in innate immunity in general and neutrophil-mediated bacterial clearance in particular, could serve as potential therapeutic targets to regulate neutrophil apoptosis, production, maturation and function. In addition to the ability to eliminate pathogens by phagocytosis, oxidative burst and/or degranulation, it has recently been shown that neutrophils can eradicate a wide range of microorganisms by forming neutrophil extracellular traps (NETs)(131). This novel mechanism entails the release of antimicrobial proteins anchored to a chromatin network of activated neutrophils. A rapidly expanding body of evidence demonstrates that NET release is integral in the pathogenesis of diseases such as sepsis, atherosclerosis, and autoimmunity(132, 133). DNA is the major structural component of NETs. In addition, granule and cytoplasmic proteins, including neutrophil elastase (NE), myeloperoxidase (MPO), cathepsin G, proteinase 3 (PR3), gelatinase, LL-37, lactoferrin, and calprotectin as well as histones H1, H2A, H2B, H3, and H4, are all embedded in the DNA backbone comprising the NET. The DNA fibers promote physical containment of the microbes, whereas the histones and granular proteins confer an antimicrobial function to the NETs. Neutrophil NET production requires platelet-neutrophil interactions and can be inhibited by platelet depletion or disruption of integrin-mediated platelet-neutrophil binding. Released into the vasculature to ensnare bacteria from the bloodstream, NETs prevent further bacterial dissemination(134). During sepsis, NET release increases bacterial trapping by 4-fold in liver sinusoids. Furthermore, the correlation between the presence of NETs in peripheral blood and organ dysfunction was evaluated in 31 septic patients. Elevated NET concentrations were observed in septic patients in contrast with the healthy controls, and increased NET levels were associated with sepsis severity and organ dysfunction(135). Collectively these insights provide a foundation from which to explore the potential of immune modulatory therapy to exploit the benefits of NET formation in states of bacterial infection while minimizing the hazards of worsening organ dysfunction. Monocytes and Macrophages The impact of an episode of sepsis on human monocyte subpopulations has long been the subject of intense investigation over past half century. For decades it has been apparent that reduced mononuclear cell HLA-DR expression clearly correlates with human sepsis mortality (136). Moreover, the reduced capacity of blood monocytes from septic patients to release pro-inflammatory cytokines after endotoxin (LPS) challenge has been described as “endotoxin tolerance”, which has been suggested to facilitate poor short and long-term sepsis outcomes(137, 138). Although a sundry of complex mononuclear cell signaling pathways are altered and contribute to the establishment of endotoxin tolerance, the major implication on monocytes, and to a lesser extent macrophages, is reduced antigen presentation related to diminished HLA-DR cell surface expression(139). In addition to the clear and persistent reductions in HLA-DR cell surface expression, monocytes from septic patients also demonstrate a reduced ability to secrete the pro-inflammatory cytokines TNF, IL-1, IL-6, and IL-12 after LPS challenge. The reduced monocyte capacity to secrete pro-inflammatory cytokines suggest that intracellular signaling has shifted toward the production of anti-inflammatory mediators which are associated with hospital acquired, ongoing, and secondary infections which ultimately increase sepsis-associated mortality. Currently many investigators agree that reduced monocyte HLA-DR expression is a surrogate marker of monocyte “anergy”, development of ongoing infections, and patient death(140–142). In addition to diminished pro-inflammatory cytokine secretion, several reports associate low monocyte HLA-DR expression with reduced antigen-specific lymphocyte proliferation(143, 144). These findings suggest that sepsis induced monocyte anergy and immune suppression separately contribute to the increased risk of complications and adverse outcomes in sepsis. Although the mechanisms accounting for monocyte LPS tolerance are not clear at this moment, sepsis-induced monocyte epigenetic reprogramming may play a pivotal role the establishment of LPS tolerance, myeloid anergy and the overall immune-suppressive monocyte phenotype(145). Analysis of human monocyte mRNA clearly shows increased levels of inhibitory cytokine genes and reduced levels of pro-inflammatory chemokine genes(146). Recent reports on human monocytes make a substantial and convincing argument for the important impact of epigenetic reprograming on the establishment of monocyte anergy, however the true functional impact of these epigenetic alterations on long-term outcomes in human sepsis is still unknown(147). Natural Killer Cells (NK) Historically NK cells were thought of as undeveloped assassins of host cells that either lacked self-identification or were infected by viruses. However, thankfully the field on innate immunity has moved forward and we now clearly know that NK cells act as regulators immune complex immune functions. NK cells are divided into various different subgroups based on CD16 and CD56 cell surface expression(148). Human sepsis evidence indicates that both CD56hi and CD56low NK cell subgroups are significantly altered during episodes of sepsis. These observed alterations have recently been associated in several reports with increased lethality in human sepsis (149–151). Additionally, NK cell cytotoxic function in human sepsis is greatly decreased(152). Similarly, to LPS tolerance in monocytes, NK cell ex vivo production of IFNγ in response to TLR agonists is also gravely diminished. This evidence indicates that NK cell tolerance may be responsible for the reactivation of latent viruses such as CMV, which is frequently encountered in intensive care unit populations and more importantly may serve as a future target for therapeutic intervention(153). Despite the lack of published data, it is apparent that NK cells are major effectors of the final outcome in sepsis through modulation of INF-γ production(154). Contradictory results in clinical studies may be explained by sampling time variability and apparent patient heterogeneity. It is evident that NK cell activation provides protection from pneumonia through excess production of INF-γ which inhibits bacterial growth and has a major impact on sepsis outcome(155). Dendritic Cells (DCs) DCs are traditionally characterized as either conventional DCs (cDCs) or plasmacytoid DCs (pDCs). cDCs are similar to monocytes and secrete IL-12, while pDCs the are similar to plasma cells and secrete large amounts of IFNα. cDCs and pDCs are of particular interest due to their enhanced apoptosis during sepsis(60) and in patients who developed nosocomial infections(156). Although DCs have varying immune functions compared with monocytes, like monocytes, DCs also exhibit reduced HLA-DR expression and produce increased amounts of immune suppressive IL-10(157). Furthermore, co-culture of DCs with T effectors induces T cell anergy and Treg proliferation, which both correlate with sepsis-induced immune dysfunction. A couple of recent investigations have demonstrated that prevention of sepsis-induced DC apoptosis or augmentation of DC function enhances sepsis long-term survival(158, 159). Several reports demonstrate that immune suppression can be ameliorated by DC treatment with growth factor FMS-like tyrosine kinase 3 ligand (FLT3L). FLT3L therapy models of burn-wound sepsis enhances DC cytokine secretion (IL-12, IL-15 and IFNγ), and augments CD4+ T cell, NK, and neutrophil function(160). Still further investigations indicate that the DC-associated gains in sepsis survival occur through TLR signaling pathways, increased MHC class II antigen and costimulatory molecules CD80 and CD86 expression (57). These observations have led researchers and clinicians together to surmise that improvements in DC number and function may be high yield targets for future therapeutic interventions in sepsis(158, 159). Myeloid-Derived Suppressor Cells (MDSCs) and Myelopoiesis MDSCs are a heterogeneous population of immature myeloid cells that expand dramatically in sepsis, impede immune responses, and signal through TLR-mediated pathways(127, 161). MDSCs associated with sepsis are phenotypically similar to the MDSCs described in states of advanced cancer(127, 162). Although MDSCs have been demonstrated to inhibit CD8+ cell function, the actual and functional impact of MDSCs in human sepsis is still uncertain. A summation of the current literature implies a beneficial role centered on replenishing innate cell function and immune surveillance through emergency granulopoiesis (123). Prior to MDSC expansion, we have identified a window of susceptibility to secondary infections and subsequent mortality associated with reduced BM cells, and reduced blood and tissue neutrophil numbers and function(121). We have also demonstrated that robust MDSC expansion through enhanced granulopoiesis imparts lasting immunity to secondary and nosocomial infections in sepsis(163). Due to the inherent difficulty in immune phenotyping immature myeloid cells between mice and humans very limited investigations and clinical studies have closely examined the roles of MDSCs in human sepsis(164). Nonetheless, there is mounting interest being paid to myelopoiesis, MDSC expansion, emergency granulopoiesis and hematopoietic stem cell production and function(121, 127, 163, 165, 166). Due to the importance of efficiently regenerating functioning neutrophils, monocytes and DCs, it is no surprise that MDSCs expand to meet the continual need for functional innate immune cells. Considering that five to seven days are required for the BM to adequately produce a functioning neutrophil, an expansive immature pool (~18 x 1011) of myeloid lineage precursors in the BM and secondary lymphoid organs(167) is required to maintain a functioning cohort of innate immune cells. In humans, approximately 16 x 1010 neutrophils are produced daily which can be rapidly increased 5- to 10-fold in response to foreign microbial invaders and pathologic stated of infection. Our prior work has clearly demonstrated that myeloid expansion involving hematopoietic stem cells (HSCs) occurs through c-KIT-, type-I IFN- (IFN-I), and CXCL10-dependent mechanisms that involve IFN-I-secreting B cells(165, 166). Moreover, impaired HSC proliferation, development and function in human BM transplant models is clearly associated with increased mortality to secondary, chronic and nosocomial infections(168). Humans with reduced granulopoiesis ability undoubtedly experience more frequent, severe and anomalous infections, demonstrating the essential requirement for effective neutrophil production. Recently, patients with sepsis have been shown to have MDSCs persistently increased, functionally immune suppressive, and associated with adverse outcomes including increased nosocomial infections, prolonged intensive care unit stays, and poor functional status at discharge(169). Conversely, overzealous MDSC proliferation may facilitate a physiologic syndrome of persistent inflammation, such as in adult respiratory distress syndrome (ARDS) or persistent inflammation immunosuppression, and catabolism syndrome (PICS), causing patients with sepsis to experience a poor outcome(16). Recent work by Terashima and coauthors demonstrated that acute inflammation causes the reduction of peripheral lymphocytes and common lymphoid progenitors (CLPs) in the bone marrow, which is also associated with a dramatic decrease in the osteoblast number. Moreover, osteoblast-specific IL-7 production during myelopoiesis was shown to be pivotal in the regulation of lymphopoiesis during systemic inflammation and may serve as a target for improved lymphocyte production(170). The specific contributions of lymphopoiesis, myelopoiesis and MDSCs to sepsis recovery versus persistent inflammation and catabolism remain poorly understood. However, new insights into these processes and their roles in sepsis resolution and recovery will hopefully present new targets for immune modulatory therapy to improve sepsis outcomes. Adaptive Immunity Lymphoid Apoptosis and Immune Suppression In the majority of septic patients, circulating lymphocytes and gastrointestinal epithelial cells undergo significant apoptosis, while apoptosis/necrosis in the heart, kidneys, and lungs is not apparent(171). Lymphocyte apoptosis has now been accepted as an important step in the pathogenesis of sepsis and contributes to septic immunosuppression(172). Lymphocyte apoptosis has been described in both septic patients and animal sepsis models(173, 174). Importantly, lymphocyte apoptosis has been shown to occur through both the intrinsic (Fas, FasL) and extrinsic (TNF) pathways(174). Although the defining factors for this phenomenon are still not clear, recent evidence suggest that the release of extracellular histones during sepsis may drive lymphocyte apoptosis(175, 176). Therapeutic blockade of lymphocyte apoptosis and/or restoring lymphocyte function have generated promising preclinical data that may lead to new treatments after episodes of sepsis in humans(171, 177, 178). Gamma delta T cells (γδ T cells) γδ T cells are a diminutive subset of T cells that possess a rather distinct T cell receptor (TCR) on their cell surface. The majority of T cells have a TCR composed of two α and β glycoprotein chains, while γδ T cells have a TCR that is made up of one γ chain and one δ chain. This uniquely distinct group of T cells exists mainly in and around the gut mucosa within a population of intraepithelial lymphocytes(179). Despite the fact that the antigens to which γδ T cells respond are still unknown, it is suspected that these cells recognize lipid antigens from pathogens present on mucosal surfaces within the intestine(180). What is clear is that upon activation, γδ T cells release IFNγ, IL-17 and other inflammatory chemokines. In humans with sepsis the number of circulating γδ T cells is significantly diminished, and these reductions correlate clearly with the highest rates of sepsis lethality (181). The observed reduction in γδ T cells in the gut mucosa may serve to potentiate typically non-invasive intestinal bacteria types to become more invasive and translocate into the host systemic circulation, causing pathological infections following episodes of sepsis(182). In patients with acute sepsis, circulating neutrophils display a similar APC-like phenotype and readily process soluble proteins for cross-presentation of antigenic peptides to CD8+ T cells, at a time when peripheral γδ T cells are highly activated(128). From their findings the authors conclude that unconventional T cells represent key controllers of neutrophil-driven innate and adaptive responses to a broad range of pathogens and may serves as targets for additional immune enhancement. In addition, others have also postulated that tremendous potential exist for the therapeutic potential of NKT cellular targeting and immune enhancement in sepsis(183). TH cell subpopulations T helper cells (Th cells) assist other cell types, including B cell differentiation, cytotoxic T cell activation, and monocyte stimulation with immunological processes. When confronted with peptide antigens by MHC class II molecules expressed on APCs, CD4+ cells are quickly activated, rapidly proliferate, and efficiently secrete cytokines that regulate adaptive and innate responses. Upon activation, CD4+ cells have the capability to differentiate into one of several T cell subsets including Th1, Th2, Th3, Th17, Th22, Th9, or T follicular helper (TFH), which facilitate various immune responses through differing cytokine generation and secretion (184). Although numerous reports relate the effects of sepsis on circulating and peripheral CD4+ T cell subsets(46), the following section will highlight only the most relevant investigations to convey the important themes and potential areas of therapeutic interest. Similar to the phenomenon observed in neutrophils and monocytes, one of the most deleterious T cell defects induced by sepsis is development of apoptosis that decimates CD4+ populations(15, 185). In humans that die from sepsis, there was a much greater magnitude of lymphocyte (specifically CD4+) apoptosis than in T cell from sepsis survivors(15). Of the CD4+ cells that manage to persist, multiple investigations demonstrate that both Th1- and Th2-associated cytokine production is reduced during and long after sepsis subsides (186). Marked reductions in the transcription factors T-bet and GATA3, which modulate the Th1 and Th2 response, respectively, support the notion that CD4+ subsets are suppressed during sepsis(187). There are a sundry of factors and influences that regulate CD4+ Th subpopulation differentiation, including histone methylation and chromatin remodeling, which together are postulated to suppress Th1 and Th2 CD4+ T cell functions(188). However, the sepsis-induced immune impact is not only relegated to Th1 and Th2 CD4+ T cells but also to Th17 subsets and the other Th subsets as well. Th17 cytokine production is reduced in sepsis and probably negatively impacts long-term mortality(189). Given the fundamental role of Th17 in eradication of pathologic fungal infections, reduced Th17 cytokine production in sepsis is probably responsible for the increased susceptibility to fungal infections frequently observed in critically ill populations(190). Circulating CD4+ and CD8+ cells from patients with Candidemia display an immune phenotype consistent with immune suppression, T cell exhaustion and downregulation of positive co-stimulatory molecules(191). Moreover, IL-7 treatment has been demonstrated to increase Th17 cell responsiveness and reduce mortality from secondary fungal infections, making IL-17 a potential therapeutic agent(177). These findings may help explain why patients with fungal sepsis have a high mortality despite appropriate antifungal therapy. Regulatory T cells (Tregs) Tregs are a master regulators of adaptive immunity that suppresses responses of other effector T cells subsets, helping to maintain self-tolerance and suppress autoimmune disease. In states of sepsis, critical illness and states of inflammation, Tregs potentiate deleterious effector T cell (Teff) suppression that prolongs recovery and may dispose to increased complications. Increased Treg ratios are present early after episodes of sepsis and remain elevated in those patients who died from sepsis while hospitalized, placing a high level of attention on Treg function. Other reports relate that Treg number increases are due to effector Th cell loss from apoptosis rather than an absolute increase in Treg numbers(47). This observation suggests to many that Tregs are resistant to sepsis-induced apoptosis, thereby preventing the recovering immune system from mounting excessive autoimmune responses during the heightened initial inflammatory phase. Moreover, heat shock proteins and histones that induce mononuclear cell epigenetic changes also play a role as inducers of Tregs in sepsis(192). Recent murine reports demonstrate that Tregs are detrimental to Teff proliferation and immune function(193). This effect is ameliorated by the administration of therapeutic siRNAs that inhibit Treg differentiation(47). In other investigations, glucocorticoid-induced TNF-receptor-related protein (GITR) inhibitory antibodies were used to block Treg function, resulting in improved immune function and microbial killing(194). Treg-associated immune dysfunction in sepsis has also been linked to more rapid cancer and solid tumor cell growth, which probably stems from a reduced overall cytotoxic T cell (CTL) and mononuclear cell immune surveillance functions (195). In conclusion a strong notion exist that Tregs are resistant to apoptosis in sepsis, augment ongoing Teff cell dysregulation, contribute to infection development and potentially serve as targets for immune modulation. B cells B cells are a very diverse immune cell population with varying functional and phenotypical attributes. Historically B cell function was understood to only encompass producing antibodies and plasma cells for long-term antibody responses (196). Conversely, a rapidly growing body of knowledge and collection of recent reports demonstrate that B cells play a much more pivotal role in sepsis immune biology than previously suspected. Clearly humans with septic shock have overall reductions in B cell numbers, however the most significant deficit in B cell number is in CD5+ B1a-type cells, which correlate and are predictive of survivors and non-survivors following episodes of sepsis (197). In mouse models of human sepsis, B cells are necessary to improve cytokine production, reduce bacterial load and improve survival through type I interferon signaling (198). A recent investigation identified an innate response activator (IRA) B cell population, which is phenotypically and functionally distinct from B1a cells and depends on PRRs, which produces granulocyte-macrophage-CSF (GM-CSF). Inhibition of IRA B cells impairs bacterial eradication, enhances a cytokine storm, and perpetuates the symptoms of septic shock. These recent clarifications position IRA B cells as immunological gatekeepers of bacterial infection elimination and simultaneously recognize IRA B cells as a new therapeutic target to improve survival in human sepsis (199). Lastly, IRA B cell generation of IL-3 has been revealed to greatly enhance sepsis associated inflammation, induce myeloid production of Ly-6Chi mononuclear cells and potentiate cytokine production, while elevated plasma IL-3 levels correlate with increased human sepsis mortality(200). B cells stimulated ex vivo in both aging and sepsis patients demonstrate significant reductions in supernatant IgM production(76). This finding is clinically relevant and interesting and may explain why elderly patients with decreased IgM production are more susceptible to gram-negative bacteria and fungal infection. Reduced immunocompetent B cells may be related to increased secondary infection after sepsis, especially in the elderly. All things considered, the recent and vast advancement in our understanding of B cell biology has provided a great insight into the B cell role in immune modulation, emergency myelopoiesis, and IL-3 production which is also new potential therapeutic focus in sepsis(201). Immune Modulatory Therapies in Sepsis G-CSF and GM-CSF Granulocyte-colony stimulating factor (G-CSF) is a glycoprotein that stimulates the production of stem cells, progenitors and granulocytes of all maturity ranges(202). G-CSF is very efficacious in reducing the incidence of sepsis in patients with low absolute neutrophil counts, such as those undergoing BM transplant, cancer chemotherapy or autoimmune radiation(203). Two randomized controlled human trials with recombinant G-CSF have been conducted in a goal directed effort to bolster neutrophil production, maturity and overall function. Clinicians and research investigators alike hypothesized G-CSF that administration would improve granulocyte function and microbial elimination in such circumstances. Although an increase in blood leukocyte counts was realized, there was no improvement in 28-day patient mortality(204, 205). Although the initial conclusions of these two clinical studies were disheartening, the fact remains as the premise of this report that most of the sepsis-induced mortality occurs in a protracted process beyond 90 days(17). This makes one wonder if a longer study therapy or observation time would have changes the investigation outcomes. However as of this time the impact of G-CSF on mortality beyond 28 days is unknown. Given the ongoing and continuous alterations observed in granulocyte production, myelopoiesis and neutrophil function especially in comorbidly-challenged patients such as those with diabetes and physiologic frailty, prolonged G-CSF administration may be efficacious for improved immune surveillance, infection eradication, tissue regeneration and sepsis survival in future clinical trials. GM-CSF is a another cytokine that enhances stem cells and progenitors to produce neutrophils, monocytes and macrophages(206). In the immune suppressive phase of sepsis, patients that were ventilator-dependent and treated with recombinant GM-CSF and had fewer ventilator and ICU days(207, 208). Furthermore, recombinant GM-CSF treatment in immune suppressed pediatric populations with severe sepsis restored TNF production in lymphocytes and significantly reduced hospital associated infections(209). Even further evidence for GM-CSF therapy is gleaned from a meta-analysis of over 12 clinical studies involving either G-CSF or GM-CSF that demonstrated that either therapy significantly reduced the rate of infectious complications (210). In lite of the fact that that 70–80% patients who succumb to sepsis harbor persistent, chronic, ongoing, or secondary infections(15), GM-CSF and/or G-CSF in combination with other immune modulatory agents may prove invaluable for enhancing infection eradication during and after sepsis and improved long-term survival after sepsis(204, 211). Interferon gamma (IFNγ) IFNγ is unique and the sole member of the type II interferon family. Adequate IFNγ production and signaling is critical for appropriate immune function against viral, bacterial and protozoal invaders. Moreover, IFNγ is a central inducer of macrophage activation, inducing stimulating class I MHC expression(139). When treated with recombinant IFNγ, patients with severe sepsis and decreased monocyte HLA-DR levels demonstrate reversal of sepsis induced monocyte dysfunction and overall improved sepsis survival(212). Although the majority of the interventional therapeutic trials with IFNγ were done in burn and mixed severely injured trauma cohorts, the largest of these reports clearly demonstrated a decrease in infection-related mortality among patients treated with IFNγ(213). Moreover, a new study of severely injured trauma patients revealed that 42 of 63 genes identified as being differentially expressed in patients with uncomplicated vs complicated outcomes, were specifically associated with interferon signaling. The investigators discovered that IFN-associated genes were suppressed in trauma patients with complicated outcomes(31, 32), implying that this set of genes may be useful for identifying patients at risk for complications after trauma. In addition these patients prone to develop complications may preferentially respond to therapies utilizing IL-7, IL-15, IFNγ, and GITR agonists. IFNγ is very promising if it is targeted to the patient populations that may benefit the greatest such as those who demonstrate or are at risk for immune suppression, decreased monocyte HLA-DR expression, adaptive immune dysfunction or chronic inflammation in prolonged hospital stays. In a recent report, recombinant IFNγ treatment was able to partially restore immune metabolic defects associated with immune paralysis in humans after sepsis further suggesting that IFNγ therapy after sepsis may benefit a multitude of cellular immune functions(214). Though IFNγ offers promise as a potential immune modulatory therapy given its ability to rejuvenate monocyte/macrophage function and adaptive immunity, IFNγ may be more efficacious if administered in a time-phased approach coupled with the likes of GM-CSF and G-CSF or even IL-7 and/or PD-1 inhibitors to bolster specific immune function, reduce secondary and nosocomial infections, and improve long-term survival as sepsis recovery evolves. Programmed Cell Death Protein-1 and Ligand (PD-1 and PD-L1) Steady progress in cancer biology has generated a new class of drugs that inhibit programmed cell death. Programmed Cell Death Protein-1 (PD-1) is a protein that under homeostasis generates an inhibitory signal that reduces CD8+ T cell proliferation and accumulation in secondary lymphoid organs such as lymph nodes. PD-1 is expressed on most T- and B-lymphocytes and myeloid cells. The ligand for PD-1, (PD-L1) is ubiquitously expressed on epithelial and endothelial cells, monocytes, macrophages, and DCs(215). Considering that PD-1 is upregulated on both CD4+ and CD8+ cells during viral infections and cancer states, it is often associated with the phenomenon of “T cell exhaustion”, which is thought to stem from prolonged periods of exposure to self-antigens (216). Both anti-PD-1 and anti-PD-L1 therapies have demonstrated promising results in human trials involving cancer and viral infection. Therefore, sepsis biologist have postulated that anti-PD-1 and anti-PD-L1 therapy could also have similar beneficial results with reducing sepsis-induced immune dysfunction that drives ongoing infectious complications (217). Patients with septic shock demonstrate increased levels of PD-1 and PD-L1 on their monocyte and T-lymphocyte cell types (218). Recent studies demonstrate granulocyte PD-L1 upregulation results in potentiation of lymphocyte apoptosis through contact inhibition, which correlates with outcome(219). Moreover, in clinically relevant animal models of experimental sepsis, inhibition of PD-1 and PD-L1 signaling pathways improved survival and reduced the number of fungal infections(220). Considering the beneficial impact on adaptive immunity and tumor eradication strategies, it makes sense that PD-1 and PD-1L could concomitantly serve as biomarkers of sepsis-initiated immune suppression as well as prospective therapeutic targets to reverse adaptive immune dysfunction and improve long-term survival. Recombinant Human IL-3, IL-7, IL-15 Considering the well documented and significant loss of lymphocytes in sepsis, IL-7 administration has been suggested as possible treatment strategy. IL-7 is a hematopoietic cytokine produced by BM stromal cells and is prerequisite for B and T cell production, maturation, homeostasis, and maintenance(221). IL-7 is an attractive therapy due to its ability to upregulate the anti-apoptotic protein BCL-2, which intern causes increased numbers of peripheral blood CD4+ and CD8+ cells. IL-7 also augments TCR diversity, which is lost in septic patients and is associated with increased development of nosocomial infections and hospital complications (177, 222). Low doses of recombinant human IL-7 preferentially activate Teffs from patients with sepsis(223). Although recent evidence exists that IL-7 can improve lymphocyte PD-1 expression, cytokine-driven peripheral T cell expansion and survival remain intact(224). However, when IL-7 was administered to patients with HIV, lymphocyte expression of PD-1 was decreased(225). Although IL-7 has the potential to work synergistically with other therapies targeting PD-1 or PD-L1 to improve aspects of T cell function lost in sepsis, the capability of PD-1 or PD-L1 to reduce hospital acquired infections or improve survival in human sepsis is currently unknown. Emerging evidence suggest that sepsis reduces bone osteoblast number, which induces lymphopenia through IL-7 downregulation, demonstrating a reciprocal interaction between the immune and bone systems and identifying bone cells as potential therapeutic targets in sepsis(170). Although clinical studies do support IL-7 therapy in HIV-infected patients receiving antiretroviral therapy, no human sepsis trials currently exist. Given the promise that IL-7 has demonstrated in other states inflammatory disease, sepsis clinical trials with IL-7 either alone or in combination with other immune modulators such as anti-PD-1 should be considered. Although still in preclinical scientific and experimental phases, it is worth mentioning IL-3 and IL-15 as potential sepsis therapies that have gained considerable attention. Considering the central role of IL-15 in the development and activation of effector and memory T, NK and NKT cells and neutrophils, it has become a hopeful therapeutic candidate for future sepsis trials (226). In murine models of experimental sepsis, IL-15 treatment diminished overall immune dysfunction and reduced mortality(227). The synergistic impact that IL-3 plays in stem cell and progenitor maturation and development along with IL-7 makes IL-3 an appealing therapy to augment the potential impact of IL-7therapy(200, 201). However, there is very little evidence relating to the impact of either IL-3 or IL-15 in states of human sepsis and further discourse is purely speculative. Vagal Nerve Modulation A growing body of evidence over the last two decades has revealed that systemic cytokine production and release is controlled by the 10th cranial nerve (vagus nerve). The scientific thrust of this discovery was done by the Tracey laboratory which elucidated the efferent arm of the inflammatory reflex(228, 229) As the cholinergic anti-inflammatory pathway(230). Accumulating experimental evidence establishes that vagus nerve activation operated via cholinergic anti-inflammatory signaling via [alpha]7 nicotinic acetylcholine receptors (7nAChR) expressed on nonneuronal cytokine-producing cells. Therefore, 7nAChR receptor agonists inhibit sepsis associated cytokine release and protect animals in experimental models of sepsis and in a variety of other experimental inflammatory models(231). Vagus nerve stimulation has an anti-inflammatory effect in sepsis and downregulates proinflammatory cytokine production in sepsis, decreasing the plasma protein levels of high mobility group box 1 (HMGB1) and improving survival in septic peritonitis models(232). Surgical vagotomy increases the plasma levels of pro-inflammatory cytokines, tissue damage and mortality in sepsis(233). Conversely, in rat models of sepsis, vagus nerve electrical stimulation attenuates and prevents hypotension(234), modulates coagulation, and fibrinolysis activation which all decrease organ dysfunction(235). Hence, the therapeutic potential of vagal efferent fiber modulation to treat disorders characterized by cytokine dysregulation is of great interest(236). However, until very recently, a paucity of real human data existed indicating that vagus nerve modulation was achievable let alone beneficial to outcomes in diseases of inflammation(237). Recently, clinical trial data demonstrates that stimulating the vagus nerve with a tiny implantable bioelectronic device significantly improves measures of disease activity in patients with rheumatoid arthritis, specifically reducing TNF production(238). Given the positive results of vagus nerve modulation in experimental models of sepsis, this latest report offers the real potential for systemic cytokine modulation over the long-term. In addition, the potential also exists for cellular modulation at the immune phenotype level as demonstrated by a recent report from Mucida and coauthors(239). Incorporating technologically advanced imaging and transcriptional profiling techniques, the authors demonstrate that lamina propria zone macrophages, residing close to fecal contents, are primarily proinflammatory, poised to mount robust inflammatory responses should the epithelial barrier be breeched. Conversely, muscularis macrophages, residing deeper in the gut wall, are primarily anti-inflammatory, expressing a tissue protective phenotype. Their search for the mechanism of this phenotypic switch revealed a breakthrough discovery that adrenergic neural signals regulate the tissue protective switch by norepinephrine signaling through β2 AR(239). This is the first direct evidence of a closed loop neural reflex that regulates gut immunity. Moreover, considering the newest insights into gut barrier function, host pathogen interaction, and microbiota contribution to gastrointestinal dysfunction in sepsis, the novel finding that neuronal reflexes control macrophage phenotypic regulation adds importantly to the growing list of neural reflexes implicated in modulating innate and adaptive cellular immune function(240). Metabolic Regulation of Immunity The immune system protects against foreign invaders, maintains optimal tissue homeostasis, and facilitates wound healing throughout the life of the organism. These diverse and integral functions require precise control of cellular, metabolic and bioenergetics pathways. While these initial observations were described at the turn of the century(241), more recent investigations have better defined the molecular basis for how extracellular signals control the uptake, anabolism and catabolism of nutrients in quiescent, activated, and inflammatory immune cells. These reports collectively reveal that oxidative metabolism, glycolysis, and glutaminolysis are preferentially utilized by immune cells and decide cell fate and effector functions(242–244). For more than a century, we have known that propagation of a successful innate effector response is dependent on glucose metabolism(245). In addition, we have also long understood that mitogen-driven proliferation of adaptive immune cells is predicated on the utilization of extracellular glutamine(246, 247). Under homeostatic conditions immune cells rely on oxidative phosphorylation and β-oxidation as energy sources for ATP production to maintain cellular equipoise(248). However, after stimulation, leukocytes shift their metabolism toward aerobic glycolysis in a process known as the Warburg effect(249). In this metabolic shift, cellular energy is predominantly manufactured by an increase in glycolysis followed by lactic acid fermentation (lactate production) in the cytosol, rather than a low rate of glycolysis followed by oxidation of pyruvate in mitochondria(250). Hypoxia-inducible factor–1a(HIF-1a) and the mammalian target of rapamycin (mTOR) are major drivers of this metabolic switch and hence cellular fate(251, 252) (Fig. 8). When innate immune cells are deficient in myeloid specific HIF1a, mice are not protected against S. aureus sepsis, indicating that this HIF1a pathway and glycolytic flux is integral for septic immune responses(253). However, the HIF-1a is not the only metabolic intermediate that drives immune responses in sepsis. Upon exposure to LPS macrophages demonstrate a shift from oxidative phosphorylation to glycolysis and succinate and induce IL-1β production(254, 255). The Glucose transporter 1 (Glut1) mediates an increase in glycolysis that facilitates a macrophage proinflammatory phenotype(256). In a recent report, human leukocytes rendered tolerant by exposure to LPS after isolation from patients with sepsis and immune paralysis demonstrated a generalized metabolic defect at the level of glycolysis and oxidative metabolism, which was restored after patient recovery(214). Compared with baseline, blood gene expression in patients who developed ICU-acquired infections post-sepsis revealed reduced expression of genes involved in gluconeogenesis and glycolysis(73). Furthermore, the genomic response of patients with sepsis was consistent with immune suppression at the onset of secondary infection in the ICU setting. Another report on sepsis patients, identified regulatory genetic variants involving key mediators of gene networks implicated in the hypoxic response and the switch to glycolysis that occurs in sepsis, including HIF1α and mTOR, and mediators of endotoxin tolerance, T-cell activation, and viral defense(257). A clearer understanding of the metabolic checkpoints that control immune cell function, transition, and maturation will provide new insights for modulating systemic inflammation, cellular immunity, and sepsis recovery. The realization that oncogenesis and immune responses have a common mechanism for metabolic switching after stimulation indicates a fundamental cellular processes that can serve as a potential therapeutic targets. Propranolol, Oxandrolone, Dronabinol The adrenergic system is a powerful modulator of the immune system(258). Hematopoietic and lymphopoietic tissues such as the spleen, thymus, lymph nodes, and bone marrow are all predominantly innervated by the sympathetic neurons. Except for CD4+ Th2 cells, the majority of lymphoid cells express beta-adrenergic receptors on their cell surface. Bone marrow production and differentiation of monocytes is influenced by the adrenergic system and immune cell apoptosis is at least partly mediated by catecholamines, via alpha-adrenergic and beta-adrenergic pathways(259, 260). The adrenergic system also modulates cell death, mitochondrial function, and inflammatory signaling(261). Although a great deal of focus has centered on the cardiovascular benefits of beta blockade in sepsis(262), the ubiquitous nature of the adrenergic system begs the question whether there are additional mechanisms whereby beta blockers may exert beneficial influences on immune process. It has been recognized for over fifty years that epinephrine enhances bacterial infections and reduces the absolute number of bacteria necessary for a lethal dose in both Clostridia species and pathogenic aerobic organisms(263). Catecholamines also enhance biofilm formation and stimulate bacterial growth in Staphylococcus epidermidis infections(264). Escherichia coli O157:H7, Salmonella enterica, and Yersinia enterocolitica proliferation are all greatly enhanced by dopamine and norepinephrine through the catechol moiety and its subsequent acquisition by the bacteria(265, 266). Although there is a clear connection between the adrenergic and immune systems, further investigation is still required to elucidate the fundamental mechanisms. For instance, beta blockade reduces proinflammatory cytokines in heart failure(267), critically ill trauma patients(268), and appears to have a beneficial effect on Th1 to Th2 helper T cell ratio(269). In a clinical trial including 55 severely injured patients at increased risk for heart disease, administration of metoprolol or esmolol decreased serum interleukin- (IL-) 6 levels(270). Christensen and coinvestigators conducted a retrospective study on 8087 ICU patients over 6 years. In this case-matched study of 3112 patients the 30-day mortality was 25.7% among beta blocker users and 31.4% among nonusers (OR 0.74 (95% CI: 0.63 to 0.87))(271). Herndon and colleagues have successfully shown that propranolol reduces heart rate by 20% in burned septic children, decreases systemic hypermetabolism and diminishes of muscle-protein catabolism over the ensuing 12 months(272). A retrospective study in trauma patients suggests that pretreatment with beta blockade is associated with a significant decrease in fatal outcome and healing time(273). Given the multiple studies demonstrating a benefit from beta blockade in general and propranolol in particular, the administration of propranolol in burn wounds greater than 20% is considered the standard of care. However, the propranolol induced benefit of reducing hypermetabolism and muscle-protein catabolism in the recovery and long term survival of sepsis patients requires further investigation to prove efficacy. Despite the fact that oxandrolone (testosterone derivative) has not been shown to impact immune function in patients with severe burns or sepsis per se, it has become a mainstay of therapy in severely burned populations to improve weight loss, protect muscle mass, and minimize long term cachectic metabolism(274). In addition, oxandrolone is also associated with improved donor site wound healing(275). In one prospective study, treatment with 10mg of oxandrolone every 12 hours decreased hospital length of stay(276). Lastly in a prospective, double blind, randomized single center trial, oxandrolone administered at a dose of 0.1mg/kg every 12 hours decreased hospital length of stay, preserved lean body mass, improved overall body composition, and enhanced liver protein synthesis(38). Taken together, there is ample evidence that oxandrolone therapy ameliorates the protein wasting, hypermetabolic state, and long term cachectic milieu facilitated by severe burn injury. Although direct evidence establishing oxandrolone as a modulator of immune cell function is lacking, insurmountable data exist indicating that protein wasting, cachexia, weight loss and hypermetabolism are all associated with poor immune function and abysmal outcome in severely injured trauma and critically ill sepsis cohorts(277). This observation has led some to garner optimism for the use of oxandrolone to counteract the well documented catabolism syndrome observed after sepsis(16). Dronabinol is the International Nonproprietary Name for the pure isomer of THC, (–)-trans-Δ9-tetrahydrocannabinol, which is the main isomer found in cannabis. It is used to treat anorexia in people with HIV/AIDS as well as for refractory nausea and vomiting in people undergoing chemotherapy(278). Antagonists at the cannabinoid receptors 1 or 2, (CB1 or CB2) prevents the delay of GI transit and thus may be powerful tools in the future treatment of septic ileus(279). Dexanabinol a synthetic cannabinoid devoid of psychotropic effects, improves neurological outcome in models of brain trauma, ischemia and meningitis. In addition, when given 2 to 3 min before LPS induced rat endotoxemia, completely abolishes the typical hypotensive response. Furthermore, the drug also markedly suppressed in vitro TNFα production and nitric oxide generation in murine peritoneal macrophages and rat alveolar macrophage cell line exposed to LPS. Dexanabinol may, therefore, have therapeutic implications in the treatment of TNFα-mediated pathologies such as sepsis(280). Biomarkers Over 180 biomarkers have been unsuccessfully evaluated for use in sepsis over the past 5 decades(281). Most of the biomarkers had been tested clinically, primarily as prognostic markers in sepsis; relatively few have been used for sepsis diagnosis and prognosis. None of the markers have demonstrated sufficient specificity or sensitivity for reasonable utility in clinical practice. In the past, procalcitonin and C-reactive protein have been most widely used but are limited in their ability to distinguish sepsis from other inflammatory conditions or to predict outcome. More recently, the use of serum lactate levels greater than 2 mmol/L (>18 mg/dL) in the absence of hypovolemia is now a biomarker used in the diagnosis of septic shock(4). The identification of precise biomarkers to detect and quantitate immune suppression in septic patients will be key to successful interdiction with immune modulatory therapies in sepsis. At the present time, reduced HLA–DR expression on monocytes is the most reliable biomarker to assess the immune status of critically ill patients. Reduced monocyte HLA-DR expression and failure of HLA–DR expression restoration are indicative of immune paralysis, the susceptibility to opportunistic infections and overall sepsis outcome(282). In addition the decreased expression of monocyte HLA-DR, the most robust biomarker of sepsis-induced immune suppression, is easily measured by flow cytometry analysis which is quick, easy and affordable(283). In a recent report, investigators were able to demonstrate that monocyte PD-L1 expression after 3–4 days of sepsis was associated with risk stratification and mortality. Moreover, monocyte PD-L1 expression was a promising independent prognostic marker for septic shock patients(284). As our knowledge of cellular phenotype and prognosis grows we will hopefully be able to capitalize on our newfound knowledge of immune suppression and intervene prior to adverse outcomes. Considering our discussion of cell specific immune dysregulation and targeted approaches to restore or enhance cellular function also implies that sensitive and specific tests exist for measuring cellular function and dysfunction that easily identify sepsis survivors who may potentially benefit from immune therapy. For instance, the ability to determine that neutrophil phagocytosis and oxidative burst capability is reduced, CD4+ cell immune exhaustion is present and that Th17 cell cytokine production is diminished are all valuable functional readouts that may serve as new markers of immune dysfunction that can specifically be augmented by targeted therapy. Lastly, genomic prediction modeling can be implemented to identify the inter-individual variation between transcriptomes of patients with sepsis and used to predict long-term outcome(257). As we more clearly begin to understand which aspects of immune dysfunction and suppression are the most crucial for successful outcome, we will be able to develop comprehensive panels of biomarkers comprised of immune phenotypes, cellular functions, genomic alterations, and signaling intermediates to more precisely guide specific immune therapy interventions. Immune Modulatory Intervention The sepsis landscape is littered with failed therapeutic interventions to block particular pathways or processes in humans(10). Although there are as many explanations as failures, continued attempts to augment immune processes at early time points with the expectation that sepsis mortality will be halved at 2 years are doomed to fail(26). However, if the sepsis-induced immune derangements are analyzed alongside other immune-mediated disease processes such as cancer, autoimmune disease, or HIV, where immune modulatory therapy has improved patient survival, it is obvious that single-agent therapy is ineffective. Rather, it is preferable to use multiple agents in combination that are introduced at the correct moment and synergistically altered over time, according to disease-specific progression, patient immune responses, and defined host/pathogen genomic interactions(285). Cancer chemotherapy strategies already utilize a personalized combination of therapies to induce, maintain and prolong cancer disease-free survival based on patient disease progression and tumor-specific genetic patterns. We propose a similar strategy be applied in sepsis therapy with a high probability of success if the interventions are tailored to specific host/pathogen genomic patterns and immune perturbations that occur in the elderly and in patients with co-morbidities as post-sepsis recovery evolves(22). Considering the ease of modern genomic determination and patient screening for specific genetic variations, therapies that enhance microbial eradication could be used to develop a personalized treatment plan. In addition, the widespread and routine use of flow cytometry technology for immune cell phenotyping in blood borne and other cancers types already provides a solid platform for immune cell profiling during cancer, sepsis and other inflammatory states. Although no FDA approved sepsis biomarkers exist at present, using a thoughtful approach to plan patient follow-up, evaluate nutritional status, determine immune cell function, and assess inflammation status, will serve as a foundation to gain the necessary insights to identify the appropriate times and immune therapies to provide to the patient. The collective willingness of sepsis investigators and patient care providers to replace their favorite molecules and interesting mechanistic pathways with a transparent and unified approach to streamline research and patient outcomes to learn meaningful lessons from prior negative intervention trials is paramount. The adoption of the adaptive trail design that has been successfully employed in other disease states should be employed to quickly adjust interventional sepsis trials based on interim analysis and quality reassessment instead of the classic and dogmatic trail design that is methodical and slow natured(286). Finally, the recognition that an episode of sepsis is associated with long-term debilitation, deterioration, and demise in very definable patient populations begs the question why we have such poor follow up and care after hospital discharge? Patients with cancer follow up with their oncologist and receive chemotherapy for years. Patients with HIV and hepatitis C routinely follow-up with their infectious disease specialist for ongoing disease evaluation and microbial therapy alterations over the long term to achieve remission. Until the greater body of inflammation investigators and sepsis clinicians alike coalesce to provide the same long term care and follow up, as done in other specialties in other disease states, the long-term sepsis mortality will continue to climb with time. Although the specific combinations of immune modulation therapy are numerous and all associated with select pros and cons, the following combinations are to serve as an example, to illustrate how long-term sepsis treatment strategies could be employed. These are by no means the only options or even the most correct for all or any patients, but hopefully will convey to the reader how a successful strategy to curb long-term mortality based on the observed immune defects could be employed. For example, GM-CSF treatment with IL-3 and may enhance monocyte and neutrophil production and function early after sepsis when the mature pool of these cells is depleted. Next, a combination of anti-PD-1 or anti-PD-L1 coupled with IFNγ may prove beneficial for lymphocyte activation and augmentation of innate immune surveillance to prevent secondary and nosocomial infections (Table 1). Lastly, a low-dose combination of oxandrolone, propranolol, and even dronabinol may ameliorate protein catabolism and persistent inflammation and promote anabolism, which has already been implemented in promoting recovery of severely burned patients (Table 2). Moreover, with improvements in biomarkers, cellular function determination and host/pathogen genomic prediction models, strategically engineered combinations of immune modulators could be employed in a goal-directed manner based on patient comorbidity profiles, immune function, and recovery course. For example, poorly maintained type 2 diabetic patients recovering from sepsis are predisposed to develop secondary and nosocomial infections associated with poor neutrophil and lymphocyte function. This group of patients may benefit from the concomitant administration of G-CSF, GM-CSF and anti-PD-1 or anti-PD-1L early in the sepsis recovery phase to prevent ongoing infection and subsequent mortality, followed by IFNγ therapy to facilitate an infection-free period and promote more durable recovery. Employing this strategy in sepsis would allow for tailored and monitored interventions that vary over time with specific patient populations, minimizing the human physiologic heterogeneity that has plagued prior sepsis clinical trials. Sepsis Trial Designs In clinical studies, the enrollment criteria are typically very broad, the agent is administered on the basis of a standard formula for only a short period (a few days). There is little information on how an agent changes the host response and host-pathogen interactions, and the primary end point is death from any cause. Such a research strategy is probably overly simplistic in that it does not select patients who are most likely to benefit, cannot adjust therapy on the basis of the evolving host response and clinical course, and does not capture potentially important effects except for effects on 28-day mortality. A more advantageous strategy would be to implement an adaptive clinical trial design that evaluates a sepsis treatment by observing clinical outcomes and side-effects on a routine schedule(287). This information would then be used to modify the study protocols in accord with those newly acquired observations. The “adaptation process” would continue throughout the trial as described in the trial protocol. Modifications may include drug dosage, sample size, patient selection criteria and drug cocktail administration. In some instances, trials have become an ongoing process that routinely adds and drops therapies and patient cohorts as more insight is gained(288). Most importantly, the aim of an adaptive trial is to more quickly identify therapies that have a beneficial effect and the patient populations that are appropriate for such treatment(289). CONCLUSIONS Sepsis induces a multitude of defects in immunity that cause protracted inflammation, immune suppression, susceptibility to infections and insurmountable death. Although there are new cell-based methodologies available to identify patients with post-sepsis immune dysregulation, it is still unclear which interventions and at what time points targeting cell-specific deficits will be most beneficial for sepsis survival. Considering the overlapping, inter-related and interdigitating complexity of immune cell derangements, as well as the protracted and convoluted road to mortality, we believe that single-agent immune modulatory intervention as attempted in past sepsis trials will fail. Conversely, the notion of more thorough and rigorous patient stratification and selection, coupled with strategic and thoughtful long-term monitoring of immune function, combined with goal-directed immune modulatory therapy will, over time, provide optimal clinical benefit to those surviving initial sepsis. MJD would like to acknowledge the Research and Education Foundation Scholarship that supported this work and was generously provided by the 2015 American Association for the Surgery of Trauma and the 2016 Shock Society Faculty Research Award for Early Career Faculty Investigators. Additional support was provided by National Institutes of Health grants, GM-29507 and GM-61656, and from the Godfrey D. Stobbe Endowment (PAW). Figure 1 Earlier Conceptual View and Definition of Systemic Inflammatory Response Syndrome (SIRS), Sepsis, Severe Sepsis, and Septic Shock (A.) The concept of an infection exceeding local regional control and inducing an inflammatory SIRS response has been the fundamental premise conceptualizing sepsis for over two decades. (B.) Until recently, sepsis was defined as the constellation of symptoms occurring when a bacterial, viral or fungal infection leads to a systemic inflammatory response syndrome, including fever, leukocytosis or leukopenia, and decreased vascular resistance frequently leading to hypotension (septic shock), organ failure (severe sepsis) and death. However, confounding the prior definition of sepsis is that other states of inflammation such as pancreatitis, trauma and burns can also produce a SIRS response making the definition overly nebulous and misapplied in many instances. (C.) In addition to the conceptual vagueness, the prior sepsis definition also implied that SIRS criteria possess adequate specificity and sensitivity to define and diagnose sepsis which is not always the case. Moreover, the prior sepsis model inferred that sepsis always follows a linear trajectory from SIRS through severe sepsis and septic shock, which is offend times does not occur. Adapted from Bone RC et al: Chest. 1992,101:1644–55. Figure 2 The Third International Consensus Definitions for Sepsis and Septic Shock The current definitions for sepsis and septic shock were developed to address the limitations of previous definitions that were over focused on SIRS and inflammation. In addition, the Sepsis-3 also dispelled the longstanding notion that SIRS criteria possess adequate specificity and sensitivity to define and diagnose sepsis. Lastly, the report debunked the misleading model that sepsis always follows a linear continuum from the SIRS through severe sepsis and septic shock, and declared the term “severe sepsis” redundant and unnecessary. Instead, the Consensus report recommends that sepsis be defined as a life-threatening organ dysfunction caused by a dysregulated host response to an infection. Figure 3 Organ Dysfunction in Sepsis and Associated Mortality The Sepsis-3 consensus report defined organ dysfunction by an increase in the Sequential Organ Failure Assessment (SOFA) score of 2 points or more, which is associated with an inhospital mortality greater than 10%. Figure 4 Definition of Septic Shock and Associated Mortality Septic shock is now defined as a subset of sepsis in which profound circulatory, cellular, and metabolic abnormalities are associated with a greater risk of mortality than with sepsis alone. Clinically, patients with septic shock can be identified by a vasopressor requirement to maintain a mean arterial pressure of 65 mmHg or greater and serum lactate level greater than 2 mmol/L (>18mg/dL) in the absence of hypovolemia with in-hospital mortality rates greater than 40%. Figure 5 Bedside Criteria Defined to Identify To identify patients with the highest probability of poor outcome associated with sepsis, a new bedside clinical score named the quickSOFA (qSOFA) was created which consist of at least 2 of the following clinical criteria including, respiratory rate of 22/min or greater, altered mentation (GCS 14), or systolic blood pressure of 100mmHg or less. Figure 6 Past and Present Mortality Distribution Sepsis (A.) Classically, the mortality distribution from sepsis occurred in a biphasic pattern, with an initial peak due to inadequate resuscitation resulting in cardiac and pulmonary failure and a second peak at several weeks from persistent organ dysfunction. Considering the recent trends in physiologic frailty, the growing elderly population, and mounting long-term mortality, a trimodal distribution is more indicative of the current sepsis-associated mortality. (B.) The two early peaks in mortality still do exist but with much less magnitude than in the past. The third and largest upswing occurs beginning at 2–3 months after sepsis and continues to steeply climb as time progresses. This delay in sepsis mortality is attributed to significant advances in ICU care that keeps the elderly and co-morbidly challenged patients alive longer despite ongoing immune, physiologic, metabolomics and biochemical aberrations. Figure 7 Inflammatory vs Anti-Inflammatory Responses An ongoing debate persist as to whether innate and adaptive immune dysfunction or inflammatory and anti-inflammatory processes are more detrimental to overall sepsis survival. In the past, the inflammatory response was thought to drive early mortality in the initial days of sepsis, and the compensatory anti-inflammatory response was thought to induce mortality weeks later through immune suppression and organ failure. However new insights gathered from septic patient tissue samples and severely injured trauma patients, have identified an enduring and simultaneous inflammatory and anti-inflammatory state of affairs driven by dysfunctional innate and suppressed adaptive immunity that together culminate in persistent organ injury, infectious complications requiring hospital readmission, and ultimately patient death. It is evident that the inflammatory and anti-inflammatory responses and innate and adaptive immune systems are each equally important, continually in a state of fluctuation, and ever at odds with one another, as sepsis recovery progresses. This perpetual state of immunologic yin and yang is thought to drive ongoing inflammation, facilitate organ injury, and enable infectious complications that all preclude durable sepsis survival. Figure 8 Alterations in Metabolic Function Determine Immune Phenotype Immune cells rely on oxidative phosphorylation and β-oxidation as energy sources for ATP production to maintain cellular equipoise at homeostasis. However, after stimulation, leukocytes shift their metabolism toward aerobic glycolysis in a process known as the Warburg effect. In this metabolic shift, cellular energy is predominantly manufactured by an increase in glycolysis followed by lactic acid fermentation (lactate production) in the cytosol, rather than a low rate of glycolysis followed by oxidation of pyruvate in mitochondria. Hypoxia-inducible factor–1a(HIF-1a) and the mammalian target of rapamycin (mTOR) are major drivers of this metabolic switch and hence determines cellular fate. These metabolic shifts have been incriminated in immune suppression and secondary infection progression in humans. A clearer understanding of the metabolic checkpoints that control immune cell function, transition, and maturation will provide new insights for modulating systemic inflammation, cellular immunity, and sepsis recovery. Table 1 Immune Modulator G-CSF GM-CSF IFNγ PD-1 and PD-L1 IL-3 IL-7 IL-15 Cellular Benefit Improve neutrophil and monocyte production and release Improve neutrophil and monocyte production and function Improve monocyte HLA-DR expression and function Biomarker to identify candidates for immune modulatory therapy Promote stem cell and progenitor development Increase T cell proliferation and recruitment Decrease NK, T cell, and NKT cell apoptosis Improve meylopoiesis and granulopoiesis Enhance monocyte and lymphocyte cytotoxicity Reduce infection and related complications Reverse T cell exhaustion Enhance lymphopoiesis in combination with IL-7 Decrease lymphocyte apoptosis Increase NK, T cell, and NKT cell proliferation and activation Augment T cell responses Improve immunity against fungal infections Promote lymphocyte proliferation Increase T cell IFNγ secretion Reduce nosocomial infection acquisition Augment neutrophil and monocyte cytotoxicity Improve T cell homing and pathogen clearance Reduce ventilator days Reduce opportunistic infections Increases T cell receptor diversity Table 2 Immune Modulator Propranolol Oxandrolone Dronabinol Benefit Reduce inflammatory cytokine production Improve wieght loss Improve gut transit, Increase appetite Diminish muscle protien catabolism Protect muscle mass, Reduce length of stay Reduce TNFα production Improve 30 day survival Minimize cachectic metabolism Reduce nitric oxide generation The authors declare there are no commercial or financial conflicts of interest related to the studies. 1 American College of Chest Physicians/Society of Critical Care Medicine Consensus Conference: definitions for sepsis and organ failure and guidelines for the use of innovative therapies in sepsis Crit Care Med 1992 20 864 874 1597042 2 Levy MM 2001 SCCM/ESICM/ACCP/ATS/SIS International Sepsis Definitions Conference Crit Care Med 2003 31 1250 1256 12682500 3 Kaukonen KM Bailey M Pilcher D Cooper DJ Bellomo R Systemic inflammatory response syndrome criteria in defining severe sepsis N Engl J Med 2015 372 1629 1638 25776936 4 Singer M The Third International Consensus Definitions for Sepsis and Septic Shock (Sepsis-3) JAMA 2016 315 801 810 26903338 5 Gaieski DF Edwards JM Kallan MJ Carr BG Benchmarking the incidence and mortality of severe sepsis in the United States Crit Care Med 2013 41 1167 1174 23442987 6 Mayr FB Yende S Angus DC Epidemiology of severe sepsis Virulence 2014 5 4 11 24335434 7 Coopersmith CM A comparison of critical care research funding and the financial burden of critical illness in the United States Crit Care Med 2012 40 1072 1079 22202712 8 Martin GS Mannino DM Moss M The effect of age on the development and outcome of adult sepsis Crit Care Med 2006 34 15 21 16374151 9 Kahn JM The epidemiology of chronic critical illness in the United States* Critical care medicine 2015 43 282 287 25377018 10 Marshall JC Why have clinical trials in sepsis failed? 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PMC005xxxxxx/PMC5111811.txt
LICENSE: This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. 101656080 43733 Cell Syst Cell Syst Cell systems 2405-4712 2405-4720 27720632 5111811 10.1016/j.cels.2016.09.003 NIHMS816984 Article Extended twilight among isogenic C. elegans causes a disproportionate scaling between lifespan and health Zhang William B. 12 Sinha Drew B. 123 Pittman William E. 123 Hvatum Erik 12 Stroustrup Nicholas 4 Pincus Zachary 12* 1 Department of Genetics, Washington University in St. Louis, St. Louis, MO 63110, USA 2 Department of Developmental Biology, Washington University in St. Louis, St. Louis, MO 63110, USA 3 Department of Biomedical Engineering, Washington University in St. Louis, St. Louis, MO 63130, USA 4 Department of Systems Biology, Harvard Medical School, Boston, MA 02115, USA * Corresponding Author and Lead Contact: 660 South Euclid Avenue, Department of Genetics, CB 8232, St. Louis, MO 63110-1031, zpincus@wustl.edu 23 9 2016 6 10 2016 26 10 2016 26 10 2017 3 4 333345.e4 This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. Summary Although many genetic factors and lifestyle interventions are known to affect the mean lifespan of animal populations, the physiological variation displayed by individuals across their lifespans remains largely uncharacterized. Here, we use a custom culture apparatus to continuously monitor five aspects of aging physiology across hundreds of isolated Caenorhabditis elegans individuals kept in a constant environment from hatching until death. Aggregating these measurements into an overall estimate of senescence, we find two chief differences between longer- and shorter-lived individuals. First, though long- and short-lived individuals are physiologically equivalent in early adulthood, longer-lived individuals experience a lower rate of physiological decline throughout life. Second, and counter-intuitively, long-lived individuals have a disproportionately extended “twilight” period of low physiological function. While longer-lived individuals experience more overall days of good health, their proportion of good to bad health, and thus their average quality of life, is systematically lower than that of shorter-lived individuals. We conclude that within a homogeneous population reared under constant conditions, the period of early-life good health is comparatively uniform and the most plastic period in the aging process is end-of-life senescence. eTOC Zhang et al. use a novel culture system to study inter-individual variation in aging in C. elegans. They uncover systematic, qualitative differences in the aging process of short- vs. long-lived individuals within a wild-type population. Introduction Pioneering work over the last quarter century has identified many molecular pathways involved in determining lifespan and illustrated that aging is a plastic process (Kenyon, 2010, 2005; Guarente and Kenyon, 2000). Many genes, small molecules, and environmental interventions have been found that alter a population’s mean lifespan. However, even in very homogeneous conditions, there is a large degree of variability in the lifespan of individuals around that population’s mean (Vaupel et al., 1998). Comparatively little is known, however, about the origins and consequences of inter-individual differences in the aging process. In general, the bulk of variability in lifespan is of not of genetic origin, and persists even in homogeneous environmental conditions. Studies estimate that only 15–25% of variation in human lifespan is attributable to genetic variation (Christensen et al., 2006; Gögele et al., 2011; Pettay et al., 2005; Herskind et al., 1996). Moreover, genetically identical populations of model organisms, reared in tightly controlled laboratory conditions have a similar degree of variability in lifespan as outbred humans (relative to the population mean) (Kirkwood et al., 2005; Vaupel et al., 1998). Even conditions and mutations that dramatically extend or shorten lifespan do not generally change the degree of inter-individual variation in longevity (Stroustrup et al., 2016). This raises a fundamental question: what distinguishes long-lived from short-lived individuals, when they are genetically identical and reared in the same cage, vial, or culture dish? Previous studies of single individuals have identified inter-individual differences in gene expression that are predictive of future lifespan in C. elegans, either early (Pincus et al., 2011; Golden et al., 2008) or late (Sánchez-Blanco and Kim, 2011; Golden et al., 2008) in adulthood. However, chronological lifespan merely measures the end of a complex process of aging and senescence. Pioneering studies of individual animals have therefore sought correlates of early and mid-life physiological health as well (Glenn et al., 2004; Chow et al., 2006; Golden et al., 2008; Eckley et al., 2013). However, due to technical limitations and the use of invasive measurements, many of these efforts were unable to follow an individual’s health longitudinally through time. Therefore, the relationship between the complex progression of aging and ultimate lifespan has been relatively unstudied. In this work, we focus on the physiological changes that characterize senescent decline in individual C. elegans (Klass, 1977; Hosono et al., 1980; Herndon et al., 2002; Huang et al., 2004). In particular, we determined how the physiological process of aging differs between long- and short-lived wild-type C. elegans. Do individuals with different lifespans senesce in a qualitatively different manner? Or does an identical aging process simply play out at a different rate for short- and long-lived individuals? In order to address these questions, we developed an experimental technique to isolate and image many individual C. elegans over each animal’s entire lifespan. This is not possible with existing automated vermiculture methods, which generally focus on enumeration of lifespans for screening purposes (Gill et al., 2003; Hertweck and Baumeister, 2005; Stroustrup et al., 2013), and are not designed for making detailed measurements of physiology. Here, using custom microscopy hardware and image-analysis software, we performed a battery of non-invasive physiological measurements of each individual, every three hours over their approximately two-week lifespans. This dataset of longitudinal measures of 734 animals, based on over 400,000 images obtained at subcellular resolution, allowed us to retrospectively understand how and when the aging process diverges between long- and short-lived individuals. Results Longitudinal Measurements of Physiology in Individual C. elegans In order to measure physiological changes throughout aging, we developed a specialized culture system to allow for observation of many freely moving, isolated individuals throughout their entire lives. This new system improves on our previous culture techniques (Pincus et al., 2011), allowing for denser culture (~100 animals per standard microscope slide) and fully automated image acquisition and processing. In brief, we produce a smooth hydrogel surface atop standard microscope slides by polymerizing polyethylene glycol (PEG) monomers in situ (see Methods and Resources). We then dispense a grid of ~2 mm diameter droplets of concentrated bacteria onto the gel, to provide a food source. After allowing each droplet to adsorb to the surface, we transfer one egg from the temperature-sensitive sterile strain spe-9(hc88) to each food pad. Finally, we pour a thin layer of polydimethylsiloxane (PDMS) over the gel. While polymerizing overnight at room temperature, the PDMS also cross-links with unreacted acrylate moieties in the PEG gel. This cross-linking proceeds everywhere except where the PEG is separated from the PDMS by the bacterial food pads. Thus while each individual C. elegans is free to move about the 2-dimensional surface of its food pad, it is constrained at all borders by strong covalent bonds within and between the PEG and PDMS polymers (Figure 1A). We placed slides constructed in this fashion on the stage of a computer-controlled microscope, housed in a temperature- and humidity-controlled enclosure. Every three hours, timepoint data for each individual was acquired autonomously, driven by custom microscope-control scripts (Figure 1B). We designed a comprehensive panel of phenotypic measurements encompassing five diverse aspects of aging physiology. For this, we drew from previously validated “biomarkers of aging” (Baker and Sprott, 1988; Pincus and Slack, 2010). These biomarkers measure aspects of physiology that differ prospectively between long- and short-lived individuals, and can thus be used to predict an individual’s future lifespan. First, we examined C. elegans neuromuscular function, as measured by locomotory ability. Second, we assessed age-associated tissue deterioration through quantitative measurements of textural order and disorder in brightfield images (Johnston et al., 2008; Pincus et al., 2011). Third, we measured age-related declines in homeostatic ability, as manifested in the accumulation of fluorescent non-hydrolyzable materials in intestinal endosomes (Klass, 1977; Clokey and Jacobson, 1986; Gerstbrein et al., 2005; Hermann et al., 2005; Pincus et al., 2016). Fourth, we evaluated nutritional history and somatic investment through cross-sectional body size (Pincus et al., 2011; Hulme et al., 2010). Fifth, we quantified reproductive output and investment through the number of oocytes laid (Huang et al., 2004; Pickett et al., 2013). These measurements were all performed via custom, fully automated image segmentation and analysis software (Figure 1C and D; see Methods and Resources). Taken together, this panel comprises a diverse set of individual measurements, allowing us to characterize longitudinal changes in distinct aspects of aging physiology. Distinct Physiology of Long- vs. Short-Lived Individuals In total, we observed 734 individuals from hatching to death, through the stages of larval development, reproductive maturity, and senescence. The population, maintained throughout life at 25°C, had a mean lifespan of 12.1 days with a stand ard deviation of 2.3 days from hatch, within the range of lifespans previously observed at this temperature (Byerly et al., 1976; Fabian and Johnson, 1994; Pincus et al., 2011). In order to rule out potential systematic biases in our data, we confirmed that overall lifespan distributions are consistent across experimental runs spanning roughly three months of time (Figure S1A), and are not influenced by the specific culture slide used within an experimental run, or by the spatial position of an individual’s food pad within the slide (Figure S1B–G). We find that virtually all variation in lifespan is due to differences in the period between reproductive maturity and death, rather than in the length of larval development (Figure S1H–J). Though larval development takes 2.1 days on average (17.3% of an average animal’s lifespan), the variability of time in development accounts for less than 0.1% of the variability in total lifespan. Therefore, we limited our analysis to the animals’ lifespans after reproductive maturity. The mean adult lifespan in our population is 10.0 days, ranging from 2.2–15.5 days. For illustration, we grouped the animals into seven cohorts by lifespan, with the first cohort containing individuals with adult lifespans of 2–4 days, the second containing individuals with adult lifespans of 4–6 days, and so forth (Figures 2A and B, S2), and plotted cohort averages of each of our physiological measurements over time (Figure 2C). For our measures of autofluorescence, body texture, and long-term movement, we observed a graded difference between shorter-lived and longer-lived cohorts (Figure 2D–F). At any given age, the shorter-lived cohorts had higher levels of autofluoresence, worse tissue maintenance, and were less mobile than their longer-lived peers. In contrast, for our measures of body size and reproductive output, we noticed a nonlinear trend among our lifespan cohorts (Figure 2G and H). For animals with adult lifespans from 2 to 8 days, larger body size and greater reproductive output were correlated with longer life, as in the existing literature (Huang et al., 2004; Hulme et al., 2010; Pincus et al., 2011). Among the longest-lived cohorts, however, this trend reverses itself: of individuals with lifespans between 10 and 16 days, longer-lived individuals tend to be smaller and produce fewer oocytes. We therefore examined this nonlinear relationship between longevity and certain aspects of physiology more closely. Overall, this effect is largely driven by a small subpopulation (13.7% of the total) of small, sickly-looking individuals that appear unhealthy throughout their lives but have very long lifespans (Figure S3A–G). We have also found evidence of this population in standard C. elegans culture conditions (Figure S3D). Overall, however, the existence of this sub-population suggests that there may be a component of functional health that can be de-coupled from lifespan. In particular, it appears that some longer-lived individuals may be qualitatively less healthy over the course of their lives compared to shorter-lived peers. Regardless, excluding this population does not substantially alter the results described below (Figure S4A–H). Differences in Aging Rate and Health at Death in Long- vs. Short-Lived Individuals To understand how aging differs in long- and short-lived individuals, we developed a physiological measure of overall senescence. Since the main hallmark of aging is increased mortality over time, more senescent (i.e. less healthy) individuals have shorter expected future lifespans. As each of the diverse physiological parameters we measured is a known biomarker of aging – that is, a predictor of future lifespan – we therefore aggregated these measures into a single, maximally informative estimate of future lifespan. We use this estimate, which we term prognosis, as a measure of an individual’s degree of senescence, or, equivalently, its state of health. To construct this prognosis, we first verified that in our dataset, each of our measures is a bona fide biomarker of aging and of mortality (Table S3). The trends over time of the raw measurements also indicate that the relationship between each parameter and future lifespan is generally nonlinear (Figure 2D–H). Therefore, we used support vector regression to define a nonlinear mapping from an individual’s measured physiological parameters at any given timepoint to an estimate of its future lifespan at that time. The overall r2 for this regression is 0.695 (10-fold cross-validated r2 = 0.669), suggesting that throughout life, these measures are able to explain the bulk of the total variability in future lifespan. While some of the measurements correlate with one another and thus redundantly measure certain aspects of physiology (Table S1), each contributes a measurable amount of independent, nonredundant information about future lifespan (Tables S2 and S3). This indicates the physiological parameters as a set, and thus our prognosis score, report on multiple distinct aspects of the aging process. We also verified that this prognosis score is neither driven by our choice of regression methodology, nor by any particular physiological measurement (these analyses are described in the STAR Methods section). We next use this prognosis of future lifespan to distinguish among several possibilities for how long- and short-lived individuals differ in physiological aging. First, it could be that short-lived individuals simply start their adulthoods in worse health (the “starting point hypothesis”; Figure 3A). Second, it is possible that senescence proceeds more rapidly in short-lived individuals (the “rate of aging hypothesis”; Figure 3B). Finally, it may be the case there is no difference in the trajectory of senescent decline between long- and short-lived individuals, and all individuals start out with similar prognoses and decline at the same rate. Here, shorter-lived animals will be those that die “prematurely”, in more healthy-appearing states, before the full process of senescence has played out (the “premature death hypothesis”; Figure 3C). In this latter case, all individuals would be, by our measurements, indistinguishable over the course of aging, and death would be stochastic and unpredictable. Short-lived individuals would differ from long-lived ones by simply happening to be the ones that died early. The trajectories of our health score look very similar to those predicted by the “rate of aging” and “premature death” hypotheses, even from a cursory visual inspection of Figure 3D. To test this more rigorously, we examined the relationships between lifespan and an individual’s prognosis at the first day of adulthood (i.e. its starting health), its rate of decline in prognosis (its rate of aging, or senescence), and its prognosis at the time of death (how “premature” its demise appears to have been, based on its health immediately prior to death). As shown in Figure 3E and F, there is no substantial relationship between starting health and lifespan, but a strong correlation between the rate of decline (as measured by simply subtracting an individual’s ending health from its starting health and dividing by its lifespan) and lifespan (Pearson r2 = 0.676; p < 10−180, F-test; Spearman ρ2 = 0.615; p < 10−153, F-test) and a modest one between prematurity of death and lifespan (Pearson r2 = 0.096; p < 10−30, F-test; Spearman ρ2 = 0.123; p < 10−16, F-test). (Quadratic fits were used to estimate r2 values due to the clear nonlinearity of these two relationships.) This latter trend indicates a modest but significant contribution either from stochastic death, or from differences in health not captured by our measurements. Overall, we conclude that long-lived individuals are not physiologically different from short-lived individuals at the start of reproductive maturity, but age more slowly throughout adulthood and experience the full scope of senescent decline. Uneven Rates of Aging Produce Lower Quality of Life in Longer-Lived Individuals Next, we asked whether long and short-lived individuals exhibit qualitatively different aging processes, in addition to having quantitatively different rates of aging. The black line in Figure 4A presents a “neutral rate of aging” for both long- and short-lived individuals: the level of health decreases uniformly throughout life. However, an individual might have a positive deviation (green line) from the neutral, straight-line decline, such that the individual appears to maintain a high level of function until a precipitous decline at the very end of its life – a phenomenon known as “morbidity compression” (Fries, 1980). Alternately, an individual may have a negative deviation (red line) from the neutral decline, and will thus senesce relatively early in its life, and persist in an extended “twilight” period of low physiological function for a larger fraction of its life. To visualize these qualitatively different classes of functional declines independently of their quantitative rate, we represent physiological change not as a function of chronological time, but as a function of the relative fraction of lifespan elapsed. If the process of aging is identical between long- and short-lived individuals except for differences in rate, then the trajectory of physiological decline of cohorts with different lifespans should fully overlap when rescaled to “relative time” (Figure 4C, left). Alternately, long-lived individuals may have systematically more positive deviations, and thus will remain healthy for a greater proportion of their lives (Figure 4C, center). This would lead long-lived animals to experience a higher average quality of life, as measured by the area under the health vs. relative-lifespan curve for long-lived vs. short-lived individuals. Finally, the opposite may be true: long-lived individuals may exhibit declines in health relatively earlier in life, leading to a greater proportion of life spent in poor health (Figure 4C, right). In this scenario, due to an extended period of poor physiological function, longer-lived individuals would have an overall lower average quality of life than shorter-lived individuals. Figure 4D shows that this latter hypothesis is most accurate, and that long-lived individuals experience a lower average quality of life compared to their short-lived counterparts. This is visible not only in the cohort averages of Figure 4D but in the clear negative relationship between each individual’s lifespan and the deviation from a neutral, straight-line decline from the population mean starting prognosis to the mean prognosis at death (Figure 4E; Pearson r2 = 0.207; p < 10−37, F-test; Spearman ρ2 = 0.183; p < 10−33, F-test). Longer-lived animals typically have negative deviations (i.e. they decline in health relatively early in life), while shorter-lived animals have more positive deviations and decline in health relatively late in life. To control for shorter-lived individuals dying in healthier states, we repeated the analysis with each animal’s health set to 1 at the onset of reproductive maturity and to 0 at the time of death (Figure 4F and G). Even when adjusted for each individual animal’s starting and ending health, the association between long lifespan and negative deviation remains (Pearson r2 = 0.123; p < 10−21, F-test; Spearman ρ2 = 0.106; p < 10−18, F-test). Taken together, these results demonstrate that longer-lived individuals have systematically worse qualitative physiological declines, despite the fact that longer-lived individuals typically have a better health prognosis on any chronological day of life (Figure 3D). The extended end-of-life period of low function in long-lived animals simply drags the overall average quality of life below that of short-lived animals. Longer-Lived Individuals Have Disproportionately Extended Gerospans The qualitatively worse senescent declines of long-lived individuals can be observed more starkly by partitioning each individual’s life into two segments: “healthspan”, the period of high physiological function, and “gerospan”, the period of low physiological function. Given a threshold prognosis score, we define healthspan as the period of time from the beginning of adulthood until an individual’s prognosis dips below that threshold for the first time. Gerospan is then the remainder of life thereafter (Figure 5A and B). In order to make a neutral comparison, we selected a threshold value that yields identical average healthspans and gerospans across the population: 5.0 days each. (Similar analysis with different thresholds yields essentially identical results to the below; see Figure S5A–P.) Figure 5A and C show that, as expected, longer-lived individuals enjoy longer healthspans in absolute chronological time. However, the differences in healthspans among long- and short-lived cohorts are small compared to the differences in gerospans. In contrast, we observe that despite this long chronological healthspan, longer-lived individuals nevertheless experience a systematically larger fraction of their total lives in senescent gerospan (Figure 5B and D). This is analogous to the results of our analysis of the full trajectories of senescence, above: long-lived individuals enjoy a better prognosis at any point in absolute chronological time, but experience declines in health relatively early in their lives. In order to validate this key result and ensure it is not an artifact of our culture system or analysis methods, we turned to data from the “Lifespan Machine”, which measures the movement individual C. elegans on standard culture plates in order to tally lifespans in an automated fashion (Stroustrup et al., 2013). The Lifespan Machine tracks individual animals once they are no longer able to move more than a few hundred microns in any direction; therefore this system inherently measures a “fast moving span” and a “slow moving” span for each individual. We manually validated these span annotations from an extant dataset with a similar genetic background and culture conditions, and computed the “slow moving span” (i.e. gerospan) as a fraction of total lifespan for each individual. As shown in Figure 5E, longer-lived individuals in these conditions experience a larger portion of life in senescent, slow-moving states. If we define the slow-moving and fast-moving spans similarly in our present dataset, we observe a very similar trend in (Figure 5F). This analysis provides an intuitive understanding of why longer-lived individuals spend more of their lives in gerospan. Figure 5G and H plot the relationship between total lifespan and healthspan or gerospan, respectively. Longer-lived individuals are both likelier to have longer healthspans and longer gerospans. However, while inter-individual differences in healthspan account for about 30% of the total variability in lifespan, differences in gerospan account for about 67% of variability in lifespan. As shown in Figure 5I, though we selected a threshold that yields equal mean healthspan and gerospan, there is simply more inter-individual variability in gerospan than healthspan. Indeed, this relationship holds for several choices of threshold (Figure S5Q and R) and our full deviation analysis, which is not subject to any arbitrary threshold. In sum, variability in lifespan is in large part driven by differences in individual gerospans, and much less so by differences in healthspans. Taken together, this indicates that gerospan may be inherently more flexible than healthspan. Discussion In this work, we examined the substantial variation in lifespan and aging physiology that exists even in isogenic individuals reared in identical environments. We developed a culture method that, to the best of our knowledge, allows for the first time high-resolution imaging of a large number of individual C. elegans throughout life. This enabled us to analyze many different aspects of each individual animal’s physiology in longitudinal fashion, from hatching until death. Motivated by similar efforts to define and characterize a “biological age” (Borkan and Norris, 1980; Baker and Sprott, 1988) or “frailty score” (Fried et al., 2001; Hubbard, 2015) in humans, we aggregated these measurements into a prognostic estimate of days of life remaining. Using this prognosis, we were able to determine how the progress of senescence differs between longer- and shorter-lived individuals. As one might expect for a genetically identical population reared in homogenous conditions, long-lived C. elegans do not begin adulthood with healthier physiology according to any of our measures. This is consistent with our previous work, which found that while physiological measurements made on the third and fourth day of adulthood can readily distinguish long- from short-lived individuals, physiological measures earlier in life cannot (Pincus et al., 2011). However, several fluorescent gene-expression reporters can be used to predict future lifespan even at the onset of adulthood: the level of the microRNA mir-71, which regulates insulin signaling (Pincus et al., 2011), and the expression, after a heat shock, of the heat-shock response protein hsp-16.2 (Rea et al., 2005). Thus, while long- and short-lived animals are not physiologically distinguishable at the start of adulthood, gene-regulatory and biochemical differences between individuals with different future fates are already established, and only later manifest themselves as phenotypic differences. Indeed, we find that the population does not remain physiologically identical for long. Systematic differences between the longest- and shortest-lived individuals are detectable less than one day after reproductive maturity. Overall, shorter-lived animals age more rapidly throughout adulthood. That is, short-lived individuals are generally in worse physiological health than their long-lived counterparts at any particular chronological age. In addition, short-lived individuals typically die before experiencing the most advanced stages of senescence. However, senescence typically occurs relatively late in life in shorter-lived individuals, which thus remain healthy-appearing for a large fraction of their lives. In contrast, longer-lived animals undergo the full range of senescent decline, from good to ill health. These declines typically begin relatively earlier in life, leading long-lived animals to die after an extended twilight period of low physiological function (Figure 6). Moreover, we identified a previously uncharacterized subpopulation of individuals that demonstrate these trends in the extreme. Small in size, with very poor oocyte production, and qualitatively and quantitatively ill appearing, these individuals are, however, extremely long-lived. While the mechanisms underlying this expansion in fractional gerospan in long-lived individuals are unclear, it is possible that they may result from diminished homeostatic capacity in older animals. One possibility is that phenotypically similar individuals entering gerospan may nevertheless have different degrees of homeostatic capacity (also known as “organ reserve” (Montgomery, 2000; Ghezzi and Ship, 2003) or “resilience” (McEwen, 2003; Stroustrup et al., 2016). Such latent, currently unobservable variability could allow some individuals to persist longer than others in highly senescent states. Alternately, a uniformly diminished homeostatic reserve across all individuals in gerospan might leave individuals susceptible to lethal stochastic insults (e.g. free-radical damage or protein translation errors) that would be survivable by a healthier individual. In this scenario, the variability in gerospan would be driven by the rate at which these insults occur. Therefore, determining the mechanistic underpinnings of these systematic trends in aging physiology is an important direction for future study. Our results highlight how the physiological determinants of lifespan and of health need not completely overlap. As shown in Figure 3, some individuals die in outward good health, while others spend unexpectedly long in a twilight of ill health before death. And though we observed distinct phenotypes of late-life senescence – gonadal hypertrophy, large collections of clear fluid, “wrinkling” of the cuticle due to shrinkage, and distended intestines packed with bacteria (Figure S3H–K) – we did not observe significant differences in lifespan among individuals with these different phenotypes (Figure S3L and M). Overall, individuals exhibiting ostensibly similar phenotypic health can have very different lifespans, while at the same time individuals with seemingly very different senescent pathologies can have very similar lifespans. These results provide additional context for recent work on physiologic determinants of lifespan in C. elegans (Stroustrup et al., 2016). Stroustrup and colleagues found that diverse interventions, including oxidative stress, changes in body temperature, and lifespan-extending mutations, do not change the overall shape of the population survival curve, but instead scale it uniformly in time. The data presented here show that the health declines of long- vs. short-lived individuals within a population do have qualitatively different shapes, however (Figure 4), and thus do not reflect a simple rescaling of time. Perhaps the decoupling of the health measures we observe from lifespan, and the similarity in lifespan of animals dying with different senescent pathologies, may be an important element in explaining how diverse interventions all produce similar effects on lifespan distributions. Our data also offer a new perspective on recent studies of functional declines in health in long-lived mutants. Bansal et al. measured the population average of several tests of stress resistance and physiological function in wild-type and long-lived mutant C. elegans, defining “healthspan” for any particular test as the period of time with greater than 50% of the maximal wild-type functional capacity (Bansal et al., 2015). These investigators found that while some long-lived mutants had longer healthspans in absolute time on certain functional tests, the relative fraction of life spent in good health was diminished in many long-lived mutant strains. (A notable exception is the insulin-signaling deficient mutant daf-2; see also (Hahm et al., 2015).) This overall result has been taken by some to suggest that these long-lived mutants are not good models for wild-type aging, and that the observed extension of relative time spent in poor life may have been a pleiotropic effect of the lifespan-extending genetic mutations. However, we show here that this is not necessarily the case. Our study, which incorporates comprehensive, lifelong measurements and an integrated definition of overall health (both suggested to be critical factors for such an analysis (Melov, 2016)), shows similar results in a genetically identical, wild-type population. Specifically, we observe a continuum in which the fraction of lifespan spent in good health systematically diminishes from short- to long-lived individuals. The results of Bansal et al. can thus be seen as placing many longevity mutants along this same continuum. As such, a relative expansion in gerospan may not be a “bug” specific to certain long-lived mutants, but rather a general property of the aging process itself. Together, these results demonstrate that extended lifespan, whether induced by stochastic events (in the case of inter-individual variability) or mutations (in the case of inter-strain differences), is often due to a disproportionate extension of a highly senescent “twilight period” of low physiological function. Put simply, it appears that an individual’s gerospan is inherently more plastic than its healthspan. Determining whether these results hold in more complex organisms is an important task. First, it is certainly true that in humans and other mammals, longer-lived individuals typically enjoy more total days of healthy life. Likewise, it is well established that individuals with higher physiological function and better physical fitness generally live longer. In particular, several remarkable studies in humans have shown that heritable factors that favor exceptional longevity also increase healthspan (Sebastiani et al., 2013; Ash et al., 2015). Further, longevity is more generally associated with a longer chronological span of healthy life, both within a relatively homogeneous Ashkenazi Jewish population (Ismail et al., 2016), and among the ethnically diverse general Chinese population (Gu et al., 2009). Our results in C. elegans are identical: longer-lived C. elegans enjoy longer absolute healthspans (Figure 4C), and better health at any point in time is correlated with extended future lifespan (Figure 4A). It is an open question, however, whether longer-lived individuals within mammalian populations spend a smaller fraction of their lives in good health, as we observe in C. elegans (Figure 4D). As above, several studies in humans have demonstrated in different contexts that extended lifespan is associated with extended chronological healthspan. Nevertheless, it remains a matter of some debate whether longer life brings with it a proportionate extension in healthspan (Rechel et al., 2013; Ash et al., 2015). As most of the current studies do not include data on ultimate lifespan, either due to cross-sectional study design or ongoing follow-up in a longitudinal study, these analyses cannot yet shed light on the proportion of life spent in good health in short- vs. long-lived individuals. Some recent work has been able to address this question by asking whether modern advances in medicine have been more successful in extending disability-free life (healthspan) or activity-limited life (gerospan). There is evidence that, especially for females, medical advances have prolonged longevity primarily by expanding the late-life period of morbidity, without much effect on the span of disability-free life (Freedman et al., 2016). Fundamentally, however, whether it is worthwhile to extend lifespan in this fashion is a value judgment that may vary between individuals, and is thus more in the realm of clinical decision analysis (Kassirer, 1976; Weinstein and Stason, 1977; Lee et al., 2009) than experimental biology. (The simple analysis in Figure S5S–U shows how the desirability of such extensions can depend on the threshold for acceptable quality of life.) It is, however, an experimental question whether there are conditions, interventions, or mutations that can extend fractional healthspan as easily as fractional gerospan. In mammals, exercise (Garcia-Valles et al., 2013) and caloric restriction (Mattison et al., 2012) may extend the ratio of healthspan to gerospan. In C. elegans, the data from Bansal et al. and Hahm et al. both show that the long-lived daf-2 mutant enjoys a proportionate extension of both healthspan and gerospan in relevant physiological assays. Thus the daf-2 mutant likely departs from the relationship between long life and extended fractional gerospan that we have characterized. Our longitudinal approach now allows for a more detailed understanding of how health integrates across physiological systems and evolves over time in different genetic backgrounds, filling a previously unmet experimental need (Melov, 2016). Future studies with these approaches promise to unravel the complex relationship between the plasticity of different phases of senescence and lifespan extension in general. Methods and Resources Contact for Reagent and Resource Sharing Zachary Pincus is the Lead Contact and may be contacted at 660 South Euclid Avenue; Department of Genetics, CB 8232; St. Louis, MO 63110-1031 and at zpincus@wustl.edu. Experimental Model and Subject Details Strains The C. elegans strain spe-9(hc88), a temperature-sensitive fertilization-defective mutant, was provided by the Caenorhabditis Genetics Center (CGC). The strain was maintained at 15°C and assays were conducted at a restrictive temperature of 25°C. spe-9(hc88) strains are widely used as an alternative to 5-fluoro-2′-deoxyuridine (FUDR) sterilization, and have been validated to have wild-type lifespans at the restrictive temperature of 25.5°C (Fabian and Johnson, 1994) and wild-type brood sizes at the permissive temperatures of 16°C and 20 °C (Singson et al., 1998). We used spe-9(hc88) to avoid the known confounding effects of FUDR (Anderson et al., 2016) and to eliminate issues due to the timing of administration (such as being administered at different phases of life for fast- and slow-developing individuals on the same slide). Method Details Single-Animal Vermiculture Standard 25 mm × 75 mm (1.2 mm thick) glass microscopy slides (obtained from VWR International, LLC; Radnor, PA, USA) were used as the base support for our culture device. Before use, the glass slides were bonded to custom-machined aluminum frames (outer dimensions 25 mm × 75 mm; inner dimensions 20 mm × 70 mm; thickness 2.36 mm) using 120 μL of polydimethylsiloxane (PDMS; Sylgard 184 Silicone Elastomer Kit obtained from Dow Corning Corporation; Midland, MI, USA). The PDMS was then cured in an oven at 100°C f or 3 hours. The device was then cleaned with distilled water and ethanol, sealed in aluminum foil, and dry heat sterilized at 160°C for 2 hours. Next, a modified version of standard nematode growth media (NGM) (Brenner, 1974) was made by mixing 97.5 mL of distilled water with 0.3 g of sodium chloride, 0.25 g of peptone, 0.1 mL of 1M magnesium sulfate, and 2.5 mL of 1M potassium phosphate buffer (pH 6.3, titrated with sodium hydroxide and hydrochloric acid). We omit the calcium chloride used in standard NGM, and modify the pH of the potassium phosphate buffer from 6.0 to 6.3 to allow for polymerization of the polyethylene glycol (PEG) gel. Instead of autoclaving, which can darken sugar-containing solutions, we filter-sterilized the modified NGM to maximize optical clarity. Then, 8 μL/mL of cholesterol stock (5 mg/mL in 95% ethanol) was added to the NGM, which was then used to separately dissolve an 8-armed PEG-thiol (Jenkem Technology; Beijing, P. R. China; Item Number: 8ARM(TP)-SH-10K) and PEG-diacrylate (Sigma-Aldrich; St. Louis, MO, USA; Catalog Number: 455008 Aldrich) at 140 mg/mL and 40 mg/mL, respectively. The NGM-PEG-thiol and NGM-PEG-diacrylate solutions were then mixed in a 1:1 ratio and vortexed vigorously. 1.7 mL of the mixture was then added to the center of the aluminum frame on the culture device. The device was tilted to break the surface tension of the PEG mixture and to achieve an even layer of fluid. The device was then placed in a standard 100 mm × 15 mm petri dish. A delicate task wipe was cut in half and added to the petri dish, and 700 μL of distilled water was pippetted onto each half wipe in order to maintain the humidity of the petri dish and prevent excessive evaporation of water from the PEG gel. Finally, an additional 25 mm × 75 mm glass slide was sterilized with ethanol, dried, and placed on top of the aluminum frame to further isolate the gel during polymerization. The petri dish containing the device is then left at room temperature for 90 minutes, during which the 8-armed PEG-thiol crosslinks to the PEG-diacrylate via Michael addition. Next, an array of 0.2 μL droplets of an OP50 E. coli (50% by mass) food source was deposited onto the gel. Single, individual pretzel-stage eggs were picked into each droplet using an eyelash pick. Approximately 100 eggs can be picked onto each slide in 20 rows of 5 eggs each. After the E. coli droplets were dried, 1.2 mL of PDMS was deposited over the PEG gel using a syringe. The PDMS polymerizes overnight at 25°C. During polymerizatio n, each individual is trapped on its food pad by hydrosilylation chemistry between unreacted moieties in the PDMS cure agent and unreacted acrylate groups in the PEG-diacrylate. This reaction results in a covalent bond between the PDMS and the PEG gel, formed at all locations where the gel is in direct contact with the PDMS (i.e. everywhere except the bacterial food pads). Immediately after deposition of the PDMS, the glass slide was placed on the stage of our computer-controlled microscope, and automated image acquisition was initiated. Image Acquisition All images were acquired at 5× magnification using custom-built hardware and software. The microscope itself was housed in a climate-controlled enclosure to provide consistent temperature and humidity for the animals studied. A thermoelectric cooler with continuous temperature monitoring (Torrey Pines Scientific, La Jolla, CA) was used to maintain the temperature of the enclosure at 25.0±0.1°C. Humidity was maintained at 85±10% relative humidity by including a tub of distilled water in the enclosure and using two aquarium air diffusion stones along with an air pump to aerate the water. Consistent air circulation was achieved with the use of several 80 mm DC fans attached to the thermoelectric cooler and the walls of the enclosure. Custom in-house control software was developed and used to move to and automatically focus (Firestone et al., 1991; Brenner et al., 1976) on each animal every three hours. At each time point, a series of six brightfield and one fluorescence image was acquired, taking approximately 17 seconds per animal. The fluorescence image and one bright-field image were taken first, taking less than 60 ms combined time to acquire. The fluorescence image taken with a 50 ms exposure using a TRITC filter (Semrock part DA/FI/TR-3X-A-000), with light from a Lumencor Spectra X. The center wavelengths of the excitation and emission bands were 556 nm and 613 nm, respectively. Next, a series of 5 bright-field images to assess short-term movement were taken over 4.5 seconds, with 0.5 seconds between the first and second images, 1.0 seconds between the second and third images, during which time the animals were stimulated with a 0.5 second pulse of cyan light (Edwards et al., 2008), 1.5 seconds between the third and fourth images, and 1.5 seconds between the fourth and fifth images. For the first 10 timepoints, the 0.5 second pulse of cyan light and the fluorescence image were omitted to avoid excessive stimulation of the animals during early larval development. The microscope was automatically re-calibrated at every three-hour timepoint for spatial and temporal variation in light-source intensity for both the bright-field lamp and the fluorescence light source. In addition, images were corrected for variation in sensitivity of the camera image sensor. Finally, bright-field exposure times and lamp intensities were adjusted at every time point to optimize the dynamic range of the acquired images. Overall, all images were corrected for background camera noise (dark current), spatial illumination inhomogeneity (flat field) and temporal variation in illumination. After correction, image intensity values were divided by the exposure time to render all images comparable. Image Segmentation The acquired image series were then manually annotated for time of hatching, reproductive maturity as indicated by first oocyte laid, and death as indicated by total cessation of coordinated movement. Eight developmentally defective animals that never reached reproductive maturity were censored from our analysis, while 734 were included in the final analysis. All animals were observed for an additional 30 hours post-mortem to confirm death. A suite of custom image analysis software was written to automatically identify the location of the animal in the over 400,000 bright-field images. First, the rough location of the animal was determined using background subtraction (Piccardi, 2004), which takes advantage of the fact that the animal moves around in the image, while other objects such as the bacterial lawn are stationary. The current image was combined with the previous nine images taken for the same individual by computing a pixel-wise median, which produces a model of the background. This background image was then subtracted from the current image, and thresholded for only pixels above the 97.5th percentile of brightness. The largest contiguous object in the thresholded image was then identified as the animal, and all internal holes in the object were filled. This location was then masked out of future background contexts to improve the robustness of the background model. Finally, the algorithm was run backwards in time to identify the position of the animal during the first nine time points. Next, the location of the individual was refined using the Canny edge detector (Canny, 1986). While the background subtraction segmentation is sensitive to changes in the bacterial lawn surrounding the animal due to illumination changes or physical churning by the animal’s movement, edge-detection defines sharper borders based on local spatial intensity gradients. The largest object in the field of view (excluding the edge of illumination from vignetting and the border of the bacterial lawn itself) was identified as the worm, and all internal holes in the object were filled. However, edge detection can occasionally locate the wrong object due to a large pattern of churned bacteria or the introduction of a piece of dust or air bubble into the field of view. Therefore, the background subtraction-derived location was used as a fallback for cases in which the location of the animal as defined by edge detection was more than 50 pixels from the location as identified by the more reliable background subtraction. Finally, a support vector classifier (SVC) (Cortes and Vapnik, 1995) with a radial basis function kernel (γ = 4.88 × 10−4, ν = 8.99 × 10−4) was trained on the intensities from 10,000 5 × 5 pixel patches from 1,617 manually drawn outlines of worms to distinguish between the animals and their surrounding bacteria. This classifier was then applied to patches centered on each individual pixel within the animal’s location as computed by the previous two methods. Using the SVC allowed us to improve our image segmentation significantly in cases in which the animal was in a curled posture and looped back on itself. While the simple hole-filling would naïvely identify patches of bacteria surround by the animal as part of the animal itself, the SVC is generally able to distinguish between the two. Overall, the automated segmentation agreed strongly with manual segmentation, with Pearson correlation coefficients between automated size and manual size of r2 = 0.81 and between automated position and manual position of r2 > 0.95 (Figure S1K–O). Physiological Panel Design Several “biomarkers of aging” (Baker and Sprott, 1988; Pincus and Slack, 2010) – properties that can predict an individual’s future lifespan better than age alone – have previously been identified in C. elegans. As each biomarker represents an aspect of physiology that differs between long- and short-lived individuals at some point in life, we selected a number of these markers to follow longitudinally across our population. First, we examined C. elegans neuromuscular function, as measured by locomotory ability. Previous work has shown that locomotion in age-matched animals diminishes over time, correlates with remaining lifespan (Hosono et al., 1980; Herndon et al., 2002; Huang et al., 2004; Hsu et al., 2009; Hulme et al., 2010; Pincus et al., 2011) and with the degree of sarcopenia (Herndon et al., 2002). Second, we assay the accumulation of non-hydrolyzable autofluorescent material in intestinal endosomes (Klass, 1977; Clokey and Jacobson, 1986; Gerstbrein et al., 2005; Hermann et al., 2005; Pincus et al., 2016). This is a marker for declining macromolecular homeostatic capacity over time, as individuals fail to clear the fluorescent material at a pace that balances its production. We chose to follow red-wavelength autofluorescence, which is most predictive of future lifespan (Pincus et al., 2016), instead of blue or green autofluorescence, which largely report only incipient death (Coburn et al., 2013; Pincus et al., 2016). Third, we also measure declining tissue organization through quantitative measurements of textural order and disorder in brightfield images, which has been shown to correlate with lifespan (Herndon et al., 2002; Johnston et al., 2008; Shamir et al., 2009; Pincus et al., 2011). Fourth, C. elegans reproductive output has also been identified as a biomarker of aging and has been shown to decrease with age (Pickett et al., 2013). While Huang et al. found no correlation between reproduction and lifespan was found in unmated, and hence sperm-limited, hermaphrodite C. elegans (Huang et al., 2004), we here examine the temperature-sensitive sterile strain spe-9, which lays unfertilized oocytes, and may thus not be sperm-limited in the same way. Finally, we and others have shown that overall body size, and rate growth and/or shrinkage correlate with future lifespan (Pincus et al., 2011; Hulme et al., 2010). Taken together, this panel comprises a diverse set of individual measurements, allowing us to characterize longitudinal changes in distinct aspects of aging physiology (Figure 1C–E). Image Measurements Autofluorescence measurements (in red wavelengths; excitation 556 nm, emission 613 nm (Pincus et al., 2016)) were made using pixel values within the defined animal location from automated image segmentation of the paired bright field image. Intensity values were extracted and summary statistics such as 80th percentile of intensity and integrated total body fluorescence were computed. Using a percentile score provides robustness against brightly autofluorescent clumps of debris or oocytes overlapping the individual (see Figures S6A for example illustrative images). Four measures of motion were made at each time point. Long-term movement over a three-hour time scale was assessed by measuring the displacement between the centroid of the animal’s current position and that of its previous position. Unstimulated movement and stimulated movement immediately before and after blue-light stimulus were assessed by measuring distances between centroids of animal positions from the sequence of five bright-field images (see Figures S6B for example illustrative images). An estimate of the number of oocytes laid was used as a proxy for reproductive investment. This measure was made by measuring the total area of objects detected within the bacterial lawn, excluding the animal itself and thresholding by size to remove small debris. This total area was then divided by the area of an average oocyte to obtain an estimate of the total number laid (see Figure S6C for example illustrative images). Cross-sectional size of the animal was measured by simply counting the number of pixels within the segmented animal region. The raw measured size was adjusted for a slight systematic bias towards overestimating the animal’s size by a linear regression between automatically measured size and size from 1,617 human-drawn outlines of the animal (see Figure S6D for example illustrative images). Finally, a quantitative measure of tissue degeneration similar to the score used in (Pincus et al., 2011) was made by analyzing pixel patches within animals’ outlines. First, representative texture patches (“textons”) for different stages of decrepitude were obtained by grouping images by the number of days remaining in the animal’s life at that point in time (bins of 0–3, 3–6, 6–9, etc. days left to live), sampling 200,000 17 × 17 pixel patches from images in each bin, and using k-means classification to obtain 60 representative patches for bin (300 total). Then, the texture pattern of an image was defined as the 300-element histogram containing the count of closest- matching 17 × 17 pixel patches for each texton, normalized by the total number of patches in that image. These histograms were then used to train a support vector regression procedure to produce a tissue degeneration score in terms of predicted days of remaining life (see Figure S6E for example illustrative images). Quantification and Statistical Analysis Smoothing Individual animals’ time traces for each measurement were smoothed using 3 iterations of the one-dimensional Savitzsky–Golay filter (Savitzky and Golay, 1964) with a 1-degree polynomial and a window length of 9. Smoothing parameters were optimized for signal-to-noise ratio by checking the physiological measurements’ cross-validated partial Pearson r2 with remaining lifespan, controlled for age. Pearson Correlations p-values for Pearson correlations were computed using an F-test for linear regression. The F-statistic was computed in the usual way as F = r2(df)/(1 − r2), where df = n − 2, n is the sample size, and r is the Pearson coefficient of correlation. The test was performed under the assumption of normality, so for computational efficiency an appropriately renormalized chi-squared distribution was used as an approximation for the exact Fisher–Snedecor distribution. Non-parametric Spearman Correlations To validate our results without the assumption of normality made in computing Pearson correlations and their associated p-values, we also performed non-parametric Spearman correlations on the ranks of the data for each statistical test. These were performed identically to the Pearson correlation p-values. Overfitting and Multiple Hypothesis Testing To guard against overfitting, we analyzed the cross-validated Pearson r2 for defining our prognosis measurement, finding that it was not substantially lower than the non-cross-validated version. All p-values are significant even after applying the conservative Bonferroni correction for the 6 hypothesis tests conducted. Alternate Health Regression Approaches To ensure that our results were not artifacts of our particular methodology for computing a prognosis and measuring health, we examined several alternate approaches, none of which altered our key findings. Table S4 demonstrates our key results are visible from each of the individual aspects of aging physiology we measured, without combining them to form the prognosis score. Figure S4I–P shows that these results also hold when using linear regression to create the prognosis, which also allows the relative contributions of each raw measurement used to be compared (Table S5). This indicates that no specific measurement, nor the regression methodology, drives the central findings of this study. Next, we used multivariate support vector regression to create alternates to our “prognosis” score. By regressing against age rather than remaining lifespan we created a “youthfulness” or “biological age” score (Borkan and Norris, 1980; Baker and Sprott, 1988). Similarly, regressing against predicted three-day survival created a “frailty” score (Fried et al., 2001; Hubbard, 2015) (Figure S4Y, inset). Both frailty and youthfulness scores produced similar findings to our approach above (Figure S4Q–X and Y–FF). Data and Software Availability All physiological data used in this study is included with this manuscript in Supplemental_Data.zip, which is related to Figures 1–6. The image acquisition software is freely available at https://github.com/zplab/rpc-scope, and the image processing and statistical analysis software is freely available at https://github.com/zplab/wormPhysiology. Additional Resources Additional galleries of randomly selected images are available on Mendeley Data at DOI: 10.17632/9xdthhmm75.1. Supplementary Material 1 2 We would like to thank Shin-ichiro Imai, Heidi Tissenbaum, Brian Kim, Amy Xu, and Seth Pincus for helpful discussions and thoughtful feedback. ZP began this work in the lab of Frank J. Slack, supported by NIH R01 AG033921. WZ, DS, WP, EH and ZP are supported by NIH R00 AG042487. WZ and ZP are supported by Longer Life Foundation grant 2015-008. WZ is additionally supported by NIH T32 GM07200. NS is supported by a Glenn Award from the Glenn Foundation for Medical Research. Some strains were provided by the CGC, which is funded by the NIH Office of Research Infrastructure Programs (P40 OD010440). Figure 1 Experimental workflow (A) A novel culture device allows for lifelong, longitudinal observation of a high-density array of isolated individual C. elegans. Individuals are free to move about on pads of bacterial food, but cannot depart the pads. (B) Images of each individual C. elegans are acquired every three hours throughout life, at 2.2-μm resolution. The spe-9(hc88) temperature-sensitive sterile strain is used to prevent reproduction. Unfertilized oocytes are visible as dark clumps on the bacterial food pad. (C) Custom software automatically annotates the region of the food pad and the position of the animal. (D) These annotations are used to make several physiological measurements (left to right): Movement between and within timepoints is scored as a measure of neuromuscular function. The brightfield image of the animal is used to automatically score tissue integrity. Red autofluorescence is used as a measure of macromolecular homeostasis. To characterize somatic maintenance, body size is measured as cross-sectional area. Last, the number of oocytes laid is counted as a measure of reproductive investment. (E) This battery of five longitudinal physiological measurements is aggregated together to produce an estimate of remaining lifespan at each timepoint. We use this “prognosis” as an operational definition of an individual’s overall degree of senescence. (F) Examples of prognosis scores. Left: a healthy, young adult with 10.3 estimated days of life remaining. Right: an unhealthy, late-life animal with 0.5 estimated days remaining. Figure 2 Variation in lifespan and physiology within a homogeneous population (A) The survival curve for all 734 individuals in our study population, as a function of age after reproductive maturity. (B) Histogram of the number of individuals in each of seven cohorts, grouped by lifespan into 2-day-wide bins. A kernel density estimate of the underlying distribution of ages at death is shown in black. (C) An illustration of how we calculate trends of a given measurement over time. At left, the distributions of values for some lifespan-predictive measurement are shown for a long- and short-lived cohort, at day three of adulthood. Dashed lines show the mean of each distribution. At right, the trend in these means over time is plotted for each cohort. (D) Trends of bulk movement between three-hour timepoints over time, for each lifespan cohort. Due to the limited size of the food pad, this measurement saturates around 160 μm/hour. (E) Trends in autofluorescence over time, measured as the 80th percentile of whole-body red-channel autofluorescence. (F) Trends in tissue integrity score over time. This score is produced via support vector regression that maps brightfield image texture into an estimate of remaining days of life. (G) Trends in cumulative oocytes laid. (H) Trends in body size. Figure 3 How does aging physiology differ between long- and short-lived individuals? (A) “Starting Point” hypothesis: long-lived individuals start their adulthood healthier than short-lived individuals. (B) “Rate of Aging” hypothesis: long-lived individuals age more slowly than do short-lived individuals. (C) “Premature Death” hypothesis: short- and long-lived individuals are indistinguishable over the course of their lives. In this case, differences in lifespan arise from stochastic, inherently unpredictable causes of death or from factors outside our prognostic criteria. (D) Trends in the decline of prognosis over time, for each of the seven lifespan cohorts in Figure 2. These qualitatively match the “rate of aging” and “premature death” hypotheses from panels b and c. (E) We observe little quantitative relationship between lifespan and starting health (measured by an individual’s prognosis score at reproductive maturity). (F) In contrast, there is a strong negative correlation between lifespan and the rate of decline of physiological health. (G) Last, there is a moderate negative correlation between health at death and lifespan, suggesting stochasticity in death or unmeasured differences in functional health. Figure 4 Systematic differences in the trajectories of physiological decline (A) The pattern of decline can differ even among individuals with identical lifespans, starting prognoses, and ending prognoses. Individuals may experience senescence evenly throughout life (black; “neutral decline”). Alternately, senescence can accelerate early (red; a “negative deviation”), which produces a relatively extended period of low function. Finally, senescence can be delayed (green; “positive deviation”), leading to a compressed period of low function. (B) We quantify an individual’s trajectory deviation as the area between the actual trajectory (green) and a linear decline (black). This value is positive for trajectories above neutral decline, and negative for those below. To compare individuals with different lifespans, we divide this total area by each individual’s lifespan to produce the “average deviation” throughout life. (C) How trajectories of senescent decline may differ between long- and short-lived individuals. Left: Senescence is identical between long- and short-lived individuals and is merely stretched in time, causing the trajectories to align when plotted in terms of the relative fraction of life elapsed. Middle: Longer-lived individuals might have more positive deviations from neutral declines. Right: Shorter-lived individuals may have more positive deviations. (D) Trajectories of senescence for different lifespan cohorts in relative time. As in the “negative hypothesis”, shorter-lived individuals are systematically healthier at any given fraction of adult lifespan. (E) Lifespan is plotted against “average deviation”, where neutral decline is defined as the straight line between the population mean prognoses at reproductive maturity and death. Longer-lived individuals have negative deviation, while short-lived individuals experience positive deviation. (F) After controlling for differences in starting and ending prognosis, the “negative hypothesis” still applies qualitatively and (G) quantitatively. Figure 5 Healthspan and gerospan analysis In both chronological (A) and relative (B) time, the trajectory of physiological aging can be thresholded into a span of high physiological function (“healthspan”; time spent above dotted line) and a span of low function (“gerospan”; time below dotted line). (C) In chronological time, longer-lived cohorts generally have longer period of good prognosis. However the differences in healthspan between these cohorts are small compared to the differences in gerospan. (D) In relative time, it is clear that longer-lived individuals are healthy for a smaller fraction of their total lifespan than shorter-lived individuals. (E) Data from a previous experiment using spe-9(hc88); fer-15(b26) individuals on standard C. elegans culture conditions (Stroustrup et al., 2013) confirm that individuals with longer lifespans spend a larger fraction of their life in poor physiological function, as measured by fraction of life spent moving very poorly or not at all (n = 55 in each group). (F) An equivalent analysis of movement data from our culture apparatus produces similar results (n = 146 in each group). Across our population, lifespan positively correlates with both (G) healthspan (as calculated in panel A), and (H) gerospan. Compared to healthspan, variability in gerospan explains almost twice as much of the variability in lifespan (r2 of 0.302 vs. 0.672). (I) This is because, despite having the same mean duration by construction, gerospan (red curve) is more variable across our study population than healthspan (green curve). The mean of both distributions is 5.0 days, with standard deviations of 1.3 and 1.9 days for healthspan and gerospan respectively. Figure 6 Summary of key findings We evaluated the process of senescence in long- vs. short-lived individual, based on a “prognosis” score that aggregates multiple measures of aging physiology. First, based on our physiological measurements, long- and short-lived individuals are indistinguishable at the beginning of adulthood. Second, soon after the onset of reproductive maturity, short- and long-lived individuals diverge rapidly. Overall, short-lived individuals experience faster physiological aging than long-lived individuals. In addition, short-lived individuals often die “prematurely”, while still healthy-appearing. Third, we discovered that long-lived individuals spend a disproportionate fraction of their lives in highly senescent, ill-appearing states. This extended “twilight period” of low physiological function has the paradoxical effect of reducing the overall average physiological health of long-lived individuals to below that of short-lived individuals. Highlights Fully automated C. elegans culture allows for study of inter-individual variation. Short and long-lived individuals start adulthood in equal physiological health. Short-lived individuals age more quickly but have a better average quality of life. The span of poor health is more variable among individuals than that of good health. Author Contributions WZ and ZP designed the experiments. WZ designed and implemented the image segmentation and analysis software and analyzed the data. WZ, DS, and WP conducted the experiments. WP, WZ, DS, and ZP developed the single-worm culture system. ZP designed and built the custom microscope control and incubation hardware, and ZP and EH wrote the custom microscope control software. NS provided data and analysis for validation of key results in standard culture conditions. WZ and ZP wrote the manuscript with feedback from DS and NS. This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final citable form. Please note that during the production process errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain. 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LICENSE: This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. 101601398 42374 Expert Opin Orphan Drugs Expert Opin Orphan Drugs Expert opinion on orphan drugs 2167-8707 27867771 5111812 10.1517/21678707.2016.1128322 NIHMS797925 Article Prospect and progress of oncolytic viruses for treating peripheral nerve sheath tumors Antoszczyk Slawomir PhD Research Associate in Neurosurgery 12 Rabkin Samuel D. PhD Professor of Neurosciences 123 1 Molecular Neurosurgery Laboratory, Department of Neurosurgery, Massachusetts General Hospital 2 Department of Neurosurgery, Harvard Medical School, Boston MA 3 Corresponding Author: Molecular Neurosurgery Laboratory, Department of Neurosurgery, MGH-Simches, 185 Cambridge St., CPZN-3800, Boston, MA 02114, Phone: 617 726-6817, Fax: 617 643-3422, rabkin@mgh.harvard.edu 25 6 2016 26 12 2015 2016 01 1 2017 4 2 129138 This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. Introduction Peripheral nerve sheath tumors (PNSTs) are an assorted group of neoplasms originating from neuroectoderm and growing in peripheral nerves. Malignant transformation leads to a poor prognosis and is often lethal. Current treatment of PNSTs is predominantly surgical, which is often incomplete or accompanied by significant loss of function, in conjunction with radiotherapy and/or chemotherapy, for which the benefits are inconclusive. Oncolytic viruses (OVs) efficiently kill tumor cells while remaining safe for normal tissues, and are a novel antitumor therapy for patients with PNSTs. Areas covered Because of the low efficacy of current treatments, new therapies for PNSTs are needed. Pre-clinically, OVs have demonstrated efficacy in treating PNSTs and perineural tumor invasion, as well as safety. We will discuss the various PNSTs and their preclinical models, and the OVs being tested for their treatment, including oncolytic herpes simplex virus (HSV), adenovirus (Ad), and measles virus (MV). OVs can be ‘armed’ to express therapeutic transgenes or combined with other therapeutics to enhance their activity. Expert opinion Preclinical testing of OVs in PNST models has demonstrated their therapeutic potential and provided support for clinical translation. Clinical studies with other solid tumors have provided evidence that OVs are safe in patients and efficacious. The recent successful completion of a phase III clinical trial of oncolytic HSV paves the way for oncolytic virotherapy to enter clinical practice. virotherapy MPNST HSV soft tissue sarcoma 1. Introduction To Peripheral Nerve Sheath Tumors And Oncolytic Viruses Peripheral nerve sheath tumors (PNSTs) are relatively rare neoplasms originating from neuroectoderm and growing in the peripheral nerves, causing pain, reducing nerve function and leading to disability. PNSTs are typically benign, schwannomas and neurofibromas, and sporadic or caused by genetic disorders of the nervous system, such as neurofibromatosis, and are categorized as soft tissue tumors 1, 2. Malignant peripheral nerve sheath tumors (MPNST) are very aggressive and characterized by a high mortality rate 3, 4. Benign plexiform neurofibromas (PNF) can transform to a malignant form 5. These are common tumors in patients with neurofibromatosis type 1 (NF1) and 2 (NF2) 1. The most recent classification of nerve sheath tumors is summarized in the WHO Classification of Tumors of Soft Tissue and Bone 6. We will not discuss the rarer PNSTs, such as myxoma, perineurioma, and triton tumors. Carcinoma perineural invasion also involves tumor growth in peripheral nerves and thus has treatment issues that overlap with PNSTs. Although the idea of using virus infection to induce tumor cell death, virotherapy, has been known more than 100 years 7, the advances in genetic engineering provided new possibilities to modify viruses for safety and efficacy. Oncolytic viruses (OVs) selectively replicate in tumor cells without harming normal tissue, making new infectious virus that can then spread and kill additional tumor cells 7, 8. They can kill tumor cells not only by direct cytopathic effect, oncolysis, but also by indirect mechanisms, such as inducing anti-tumor immune responses or attacking the tumor vasculature 9-11. OVs include those viruses that: (i) have a natural propensity to replicate in tumor cells, i.e. myxoma and Newcastle disease viruses (NDV); (ii) are vaccine strains that have been attenuated, i.e. measles (MV), poliovirus (PV), and vaccinia virus (VV); or (iii) are genetically engineered with mutation/deletions in pathogenic genes, genes required for replication in normal cells, and/or retargeted to tumor cell receptors, i.e. adenovirus (Ad), herpes simples virus (HSV), and vesicular stomatitis virus (VSV) 12. OVs can be ‘armed’ with therapeutic transgenes, including; immunomodulatory, anti-angiogenic, and cytotoxic genes, that are expressed in the tumor after infection 13, 14. Depending on the tumor type, OVs can be used: (i) as single agents, (ii) in combination with chemo- or/and radio-therapy, or (iii) expressing therapeutic transgenes. During the last two decades, numerous OVs have entered into clinical trials for a large variety of cancers 7, 15. However, there has been only one clinical trial to date reporting OV treatment for PNST, using oncolytic Ad 16. Recently, the first oncolytic virus, talimogene laherparepvec, an oncolytic HSV, was approved by the FDA in the US for the treatment of advanced melanoma 17, 18. Because of this lack of completed clinical trials for PNST, we will focus on OVs that have been explored preclinically for the treatment of PNSTs (Table 1), strategies to improve OV efficacy in PNSTs, safety, and future virotherapy directions. 2. Peripheral Nerve Sheath Tumors (PNST) and Perineural Invasion in Cancer 2.1. Schwannoma Normal Schwann cells form myelin, a protective sheath around peripheral nerves. Schwannomas, the most common PNST in adults and comprised of abnormal Schwann-like cells, are benign, slow-growing, circumscribed, encapsulated, solitary, and non-infiltrating tumors 2, 19. NF2 patients develop schwannomas, often multiple, in cranial, spinal, and peripheral nerves, with bilateral vestibular schwannomas a hallmark 2, 19. NF2 is an autosomal dominant disease (affects about 1:25000 births) caused by inactivating mutations of the NF2 tumor suppressor gene located on chromosome 22q12, and characterized by the development of nervous system tumors, ocular abnormalities, and skin tumors 20. The NF2 gene, encoding merlin (moesin-ezrin-radixin-like protein), is also mutated or lost in most sporadic schwannomas 21, 22. Schwannomas are often asymptomatic, although vestibular schwannomas often lead to hearing loss, and can usually be treated with surgical resection 2, 20. A broader understanding of the molecular mechanism of NF2 pathogenesis should lead to new therapies, with a number of downstream effectors of merlin being tested in clinical trials, i.e.: erlotinib (Her-1/EGFR inhibitor), lapatinib (Her-2/EGFR inhibitor), and everolimus (mTOR inhibitor) 23, 24. While the targeted therapies are promising, they have not been curative, so virotherapy is an attractive approach. 2.2. Neurofibroma Neurofibromas are benign PNSTs arising from Schwann cell precursors that include fibroblasts, mast cells, and distinct from schwannomas, a matrix of collagen fibers 2, 5. Typically they occur sporadically, however approximately 10% are associated with NF1, where they are a diagnostic criteria 25. NF1 is a frequently occurring autosomal dominant genetic disease (affects about 1:3500 births), caused by mutations in the NF1 gene located on chromosomal segment 17q11.2 and encoding neurofibromin 26. Neurofibromin contains a Ras-GTPase activating protein (Ras-GAP) domain that negatively regulates Ras activity, so that NF1 is a member of the RASopathy cancer predisposing syndromes 27. Unlike schwannoma, neurofibromas are not encapsulated and infiltrate between the nerve fascicles. There are three subtypes of neurofibroma based on their location and appearance: (i) localized cutaneous or dermal neurofibromas, which are the most common, appear at puberty and grow from small nerves in the skin or just under the skin. They have limited growth, remaining benign throughout life, and do not transform into malignant PNSTs 5; (ii) diffuse or subcutaneous neurofibromas are typically located within the subcutaneous tissues of the head and neck, are often pigmented or with melanocytic differentiation 25, 28, and in NF1 are associated with internal neurofibroma tumor burden and mortality 29, 30; and (iii) plexiform neurofibromas (PNF) are usually congenital, occurring in about a third of NF1 patients, and present anywhere in the body but often internal where they can remain aysmptomatic 26. They involve multiple nerve fascicle trunks and infiltrate surrounding tissue 25. Importantly, PNFs can undergo malignant transformation and progress to MPNST, which occurs in about 5-10% of cases 5, 31, 32. PNFs are typically debulked by surgery when indicated, but this can be associated with nerve damage and hemorrhage, and is often incomplete 5, 33. Based on our understanding of neurofibromin, a small phase II clinical trial examined imatinib mesylate (Gleevec), a kinase inhibitor, to treat PNF 34. 2.3. Malignant peripheral nerve sheath tumor (MPNST) MPNST is a soft-tissue sarcoma arising from peripheral nerves or benign PNSTs that displays nerve sheath differentiation 25, 35. They account for about 10% of soft tissue sarcomas, but half arise in NF1 patients. There are histological and clinical differences between sporadic and NF1-associated MPNSTs 33, 36, although a recent meta-analysis suggested that the survival differences have been converging in the last decade 37. MPNST frequently occurs in the extremities, often in major nerve trunks like the sciatic nerve 35. Like other malignancies, metastasis may also occur, often to the lung, liver, brain, soft tissue, bone, regional lymph nodes and retroperitoneum 32. In NF1, loss-of-heterozygosity of NF1 occurs in over 90% of tumors 38, with tumors having constitutively activated RAS and downstream activation of the Akt and MAPK pathways 39. However, the complex karyotypes in MPNSTs suggests that additional genetic alterations, such as in p53, CDKN2A, CDK4, contribute to malignancy 35. Surgical resection is the main treatment option for MPNST, however it is often incomplete, with a local recurrences ranging up to 65% depending on the tumor location, and associated with potentially significant loss of function 33, 40. Radiotherapy is recommended for high-grade lesions when surgery is not possible or incomplete, but hasn't been shown to improve survival 33, 40. Adjuvant chemotherapy, ifosfamide and doxorubicin, may have some activity in pediatric patients and non-NF1 patients 40, 41. The long-term survival of MPNST patients is poor, around 50% at 5 years 37, 40, 41, so there is a critical need for novel therapeutic approaches. 2.4. Perineural invasion in cancer Perineural invasion (PNI), the presence of tumor cells within any of the layers of the nerve sheath, is a route of metastasis distinct from vascular or lymphatic dissemination 42. It is very common and often the typical route of metastasis in head and neck squamous cell carcinoma (∼80%), prostate (∼80%), gastric (∼50%), and colorectal cancers (∼30%), and almost all pancreatic tumors 42-44. PNI is an independent prognostic factor in these tumors, with 5 year survival often decreased by half, and is also associated with severe pain, especially in pancreatic cancer 42, 43, 45. Understanding the molecular mechanisms of PNI is lagging and it is still unclear how tumor cells penetrate the nerve sheath and layers of collagen and basement membrane, or why some carcinomas have a penchant for PNI. The lack of targeted treatments and poor prognosis for PNI makes this an important target for novel therapies and potentially OVs. 3. Oncolytic Viruses 3.1. Herpes simplex virus (HSV) HSV-1 is an enveloped virus with a 152 kb double-stranded DNA genome encoding about 84 genes 46. Viral glycoproteins in the envelope bind to host attachment factors on the cell surface (heparin sulfate, nectin-1 (PVRL1), PILRα, and HVEM (TNFRSF14)) and induce membrane fusion 46. This can impact cancer cell susceptibility, for example HVEM is not expressed on most MPNST cell lines, including sensitive cells, while the levels of nectin-1 expression correlate with virus yields 47. In permissive cells, the HSV replication cycle is usually completed in less than 24 hr, and cells release viral progeny ready to infect adjacent cells. HSV is a neurotropic virus that can invade the nervous system and infect neural cells. HSV can be genetically engineered to mutate/delete viral genes that confer selective replication in tumor cells and attenuate neurovirulence, make them oncolytic. For example: (i) the thymidine kinase (TK) and ribonucleotide reductase (ICP6) genes are involved in nucleotide metabolism and necessary for virus replication in nondividing cells, but not in tumor cells; and (ii) γ34.5 is a major determinant of HSV pathogenicity, so that deletions of γ34.5 significantly reduce neurovirulence permitting treatment of nervous system tumors 48. 3.2. Oncolytic HSV (oHSV) A number of oHSVs with different mutations/deletions (ICP6, γ34.5) have been tested in a variety of PNST models (Table 1). G47Δ, a third generation oHSV (ICP6-, γ34.5Δ, ICP47Δ), was examined in a number of human xenograft and mouse transgenic schwannoma models 49, 50. In a NF2 transgenic model, spontaneous subcutaneous schwannomas were treated with a single intratumoral injection of G47Δ after MR imaging to identify the tumors 49. This led to a decrease in tumor volume within 2 weeks in G47Δ-treated tumors, however, in some cases control-treated tumors also regressed. This is an issue not only with the mouse models, but also in human patients 51, and confounds both preclinical and clinical studies of benign tumors with variable growth rates. In addition, it took about 18 months for the transgenic schwannomas to become apparent, making treatment studies difficult. To get around this problem, human schwannoma xenografts were generated by subcutaneous implantation of schwannoma tissue from patients with NF2 or schwannomatosis in immunocompromised mice 49. These tumors were histologically schwannomas and susceptible to G47Δ infection and replication 49. Treatment with two doses of G47Δ resulted in a reduction in tumor volume, while the vehicle-treated tumors continued to grow 49. In a separate study, subcutaneous tumors were established in nude mice with a human immortalized schwannoma cell line HEI193 or a mouse line (NF2S-1), and treated two successive times with G47Δ 50. Both tumors showed significant inhibition of tumor growth or regression compared with control animals, however, the NF2S-1 tumors regrew at about 7 weeks after treatment 50. These positive results in a variety of schwannoma models strongly support the use of oHSV for the treatment of schwannomas. MPNST is a lethal tumor and there are more MPNST cell lines available as models than for benign PNSTs, making it a more frequent target for OV therapy. Initial studies in vitro, showed that a set of human MPNST cell lines were sensitive to oHSV G207 and hrR3 (Table 1), regardless of Ras activation, whereas normal human Schwann cells were not permissive to virus replication 52. In contrast, the susceptibility of mouse MPNST cells isolated from transgenic mouse tumors to G207 was dependent upon elevated levels of Ras activation 53. Both G207 and hrR3 were able to inhibit tumor growth and survival after intraperitoneal injection of mice bearing intraperitoneal xenografts of human STS26T MPNST 54. rQLuc, similar to G207, but expressing luciferase (Table 1), was efficacious in subcutaneous xenografts of STS26T and S462.TY after intratumoral injection 55. Luciferase expression permits non-invasive monitoring of virus spread using bioluminescence imaging. Transcriptionally-targeting of oHSV is a way to drive replication selectively in tumor cells 48. Midkine (MDK) is overexpressed in MPNST cells compared to fibroblasts and Schwann cells 56 and thus the MDK promoter should drive MPNST-specific transcription. To enhance oHSV replication, γ34.5 was placed under the MDK promoter, generating oHSV-MDK-34.5 (Table 1) 56. oHSV-MDK-34.5 had increased viral replication and cytotoxicity in human STS26T MPNST cells in vitro, and inhibited tumor growth and increased survival in subcutaneous xenografts compared with the control virus oHSV-MDK 56. Recently, a new orthotopic MPNST model was developed by implantation of mouse NF1 transgenic MPNST cell lines or human NF1 MPNST stem-like cells (MSLCs) into the sciatic nerves of immunocompetent and immunodeficient mice, respectively 57. In this model, mice develop progressive hind limb deficits, which can be quantified to evaluate treatment efficacy. Neurologic deficits are apparent prior to palpable tumors, which provides an indication that the tumor is established and growing and thus suitable for treatment. MSLCs were isolated from an established human MPNST cell line, S462, which could self-renew, had increased expression of stem cell markers, could differentiate into cells from multiple lineages, and were more tumorigenic 58. About a third of mice bearing human MSLC-derived tumors treated with a single low dose intratumoral injection of only 2×105 plaque forming units (pfu) of G47Δ were long-term survivors, with no evidence of tumor and limited neurologic deficit, in contrast to mock-treated mice which all succumbed to tumor growth 57. In the immunocompetent mouse MPNST model, a single dose of G47Δ significantly delayed tumor growth, improved neurologic score, and significantly extended survival compared with control, with the 35% long-term survivors lacking macroscopically detectable tumor or ultrastructural abnormalities 57. Therefore, oHSV has been shown to be very effective in treating PNSTs, both benign schwannomas and malignant MPNSTs. PNI can be modeled by tumor cell implantation into sciatic nerves. The first description of oHSV treatment in such a model was the demonstration that a single intratumoral injection of G207 could extend the survival of mice bearing tumors after implantation of human neuroblastoma IMR32 cells into the sciatic nerve 59. Tumors were similarly established in the sciatic nerve with human carcinoma cell lines from pancreatic (MiaPaCa2), squamous cell (QLL2), and prostate (PC3, DU145) cancers, and treated with oHSV NV1023 (Table 1) 60, 61. While all saline-treated mice developed complete hindlimb paralysis, most NV1023-treated mice had preserved nerve function and significant tumor regression 60, 61. A similar oHSV, NV1020, has been in clinical trial for metastatic colorectal carcinoma to the liver 62. 3.3. oHSV expressing therapeutic transgenes While OVs are effective therapeutic agents, their activity can be enhanced by ‘arming’ them with therapeutic transgenes. Expression of transgenes in the tumor can target uninfected tumor cells and normal cells and extracellular matrix of the tumor microenvironment 14, 63. A number of different transgenes have been inserted into oHSV and examined in MPNST models, including those encoding antiangiogenic factors, immunomodulatory cytokines, receptor decoys, and proteinase inhibitors 48. rQT3 encodes human tissue inhibitor of metalloproteinase 3 (TIMP3) (Table 1), blocking the activity of matrix metalloproteinases, which promote tumor invasion and are expressed in MPNST cells 55. rQT3 was much more effective than G207 or rQLuc at inhibiting MPNST STS26T and S462.TY tumor growth 55. G47Δ expressing anti-angiogenic factors platelet factor 4 (PF4) and dominant-negative fibroblast growth receptor (dnFGFR) have been constructed 64, 65. Mouse MPNST cell lines expressing dnFGFR or PF4 had reduced tumor growth and angiogenesis in vivo 64, 65. Infection of human endothelial cells with G47Δ-dnFGFR or G47Δ-PF4 was more cytotoxic than control G47Δ-empty and conditioned media from infected tumor cells reduced endothelial migration in vitro 64, 65. In vivo, G47Δ expressing dnFGFR or PF4 significantly inhibited subcutaneous mouse MPNST growth in nude mice and decreased vascular density compared with control G47Δ alone 64, 65. The effects of PF4 and IL-12 expression on oHSV efficacy in an immunocompetent setting were examined using the orthotopic sciatic nerve mouse MPNST implant model. G47Δ-PF4 was not as effective in immunocompetent mice and only significantly extended survival compared to G47Δ-empty 57. In contrast, G47Δ-IL12 was significantly better than G47Δ-empty at inhibiting neurologic deficit progression and tumor growth, and increasing survival 57. 3.4. oHSV in combination with drugs MPNST is resistant to standard single agent chemotherapy 41, 66. Using oncolytic virotherapy in combination with existing chemotherapeutics may lead to synergistic interactions that increase therapeutic effects not achievable by either therapy alone 67. oHSV has been successfully combined with a number of chemotherapeutic and molecularly targeted drugs in a variety of solid tumors 67. So far this promising strategy has not been explored in PNST models, except for erlotinib (inhibitor of EGFR tyrosine kinase), and in the oncolytic Ad clinical trial. In vitro, erlotinib in combination with hrR3 or G207 was more cytotoxic to STS26T MPNST cells than either treatment alone 54. Unfortunately, combination treatment of the tumors did not enhance efficacy over oHSV alone 54. 3.5. oHSV safety Wild type HSV is highly neuroinvasive in the peripheral and central nervous system and neuropathogenic 46. After footpad inoculation, HSV-1 invades the CNS via the sciatic nerve, causing paralysis and death 68. Direct injection of wild type HSV-1 into the sciatic nerve causes nerve demyelination, Wallerian degeneration, and inflammation at early times, followed by paralysis and lethal encephalitis 59-61, 69. In contrast, sciatic nerve injection of NV1023 at a 10-fold higher dose caused no significant toxicity, with only mild Wallerian degeneration 61. Similarly, sciatic nerve injection of G47Δ was non-toxic, with mice gaining weight and exhibiting transient neurologic deficits no different than PBS-injected control mice 57. The G47Δ-injected sciatic nerves did not exhibit any ultrastructural abnormalities, with the exception of focal needle track damage that was also seen in the PBS-injected nerves 57. 3.6. Adenovirus Oncolytic Ad ONYX-015 is a hybrid Ad2/Ad5 derived from mutant of Ad dl1520 containing a deletion of E1b-55K protein 70. E1b-55K protein together with the E4orf6 protein target p53 for degradation, so that ONYX-015 selectively replicates in tumor cells with mutated p53. More recent studies suggest that E1B-55K is also involved in blocking DNA damage responses and export of late viral RNAs 71. ONYX -015 has been evaluated in a large number of clinical trials for a variety of cancers 72. In 2005, Galanis et al. 16 reported on completed results from the first clinical trial using ONYX-15 to treat patients with advanced sarcoma in combination with mitomycin-C, doxorubicin, and cisplatin chemotherapy. Among the six patients treated was one patient with metastatic MPNST (p53+, MDM2-), who received the highest ONYX-015 dose (1010 pfu) 16. This was the only patient who achieved a partial response, in both the injected bulky tumor and 2 small uninjected lesions, which lasted 11 months. Unfortunately, clinical testing with ONYX-015 was halted during a pivotal phase III trial when Onyx divested the program. A similar oncolytic Ad, H101, has been approved in China for use in head and neck cancers in combination with chemotherapy 72. Since then many new oncolytic Ad vectors have been constructed. Ad5/3-D24-GMCSF (CGTG-102) (Table 1) selectively replicates in p16/Rb-defective cells and has been evaluated in patients with advanced solid tumors 73. Ad5/3-D24-GMCSF has been examined in an immunocompetent Syrian hamster soft-tissue sarcoma (STS) model in combination with doxorubicin and ifosfamide 74. The combination drug/virus treatment was highly effective and resulted in synergistic antitumor efficacy compared with single agent treatments 74. These studies suggest that oncolytic Ad in combination with chemotherapy may be an attractive strategy for PNST. 3.7. Measles virus (MV) MV, a Morbillivirus in the family Paramyxoviridae, is an enveloped virus with a non-segmented, negative-strand RNA genome 75. Several cases of spontaneous tumor regression in individuals with lymphoma after MV infection have been reported, suggesting that MV may have oncolytic properties 75. Wild type MV uses the cellular receptor SLAM (signaling lymphocyte activation molecule) for cellular entry, which is not commonly expressed on tumor cells, however, attenuated vaccine MV strains like Edmonston are adapted for cellular entry using CD46, which is highly expressed on human tumor cells, including MPNST 76, 77. The human sodium iodide symporter (NIS) has been inserted into MV-Edmonston (MV-NIS) (Table 1) to enable non-invasive monitoring of virus infection and spread using 125I SPECT 76. NIS expression can also facilitate radiotherapy with 131I administration 76. MV-NIS is currently in clinical trials for multiple myeloma, ovarian cancer, and mesothelioma 76. MPNST cell lines were very susceptible to MV-NIS cytotoxicity, while normal Schwann cells were not, despite high-level expression of CD46 77. In vivo, intratumoral injection of MV-NIS was efficacious in inhibiting the growth of subcutaneous MPNST ST88-14 and S462TY tumors 77. NIS expression permitted the detection of MV-infected cells in mice bearing tumors 77. MV is associated with a number of serious neurologic complications in the CNS, but there is no evidence that it invades or causes pathology in the PNS 78. 3.8. Vesticular stomatitis virus (VSV) VSV is a non-segmented negative-strand RNA virus from the Rhabdoviridae family 79. VSV oncolytic selectivity is due to its extreme sensitivity to type 1 interferon (IFN) and innate antiviral responses, which are defective in most cancer cells 79. VSV can be further attenuated by disrupting the gene order, as in VSV-G/GFP, which was used to isolate VSV-rp30a (Table 1) by positive selection on glioblastoma cells 80. VSV-rp30a also grew and killed human MPNST cell lines S462-TY and STS-26T better than its parent VSV-G/GPF, and growth was not inhibited by pretreatment with INF-α 81. Primary fibroblasts and vascular endothelia cells were about 10-fold less sensitive to VSV-rp30a than the MPNST cells 81. In a human subcutaneous fibrosarcoma model, a single intravenous dose of VSV-rp30a completely inhibited tumor growth 81. A clinical trial is currently ongoing with VSV expressing IFNβ in patients with refractory hepatocellular carcinoma (http://clinicaltrials.gov/ct2/show/NCT01628640). 4. Conclusions OVs have multiple mechanisms of action, including; direct tumor cell killing, amplification in situ, and induction of anti-tumor immunity. This makes them powerful therapeutic agents. They have unique properties that derive from the biology of the viruses from which they were generated. The results we describe from preclinical studies demonstrate that OVs have robust anti-PNST activity and warrant clinical translation. Most of the studies have been conducted with oHSV, a neurotropic virus that can be genetically engineered to selectively replicate in tumor cells but not normal tissue. Safety studies with oHSV demonstrated no toxic effects or nerve damage after direct injection into the sciatic nerve. Arming oHSV with therapeutic transgenes enhances anti-tumor activity. Other OVs have also been armed, but so far none examined in PNST models. The availability of a number of MPNST preclinical models and the lack of targeted therapies or significant improvements in outcomes for this malignancy, make it a prime target for OV therapy, which has demonstrated impressive efficacy in preclinical models. Even benign PNSTs are highly susceptible to oHSV therapy. There have been fewer studies with other OVs, but oncolytic Ad ONYX-015 is the only OV to be administered to a patient with PNST. Preliminary studies with MV and VSV, suggest that they also have potential to treat PNST. 5. Expert Opinion Despite the great progress in understanding the molecular mechanisms of pathogenesis of PNSTs, surgical resection of these tumors remains the main treatment paradigm. Due to size or location, these tumors are often inoperable or entail a risk of nerve damage. On the other hand, they are not very susceptible to chemotherapy or radiotherapy, and effective molecularly targeted drugs have not been identified. Therefore, new therapeutic strategies are necessary for both benign and malignant PNSTs. OVs are one new promising approach that has been underexplored. Unfortunately, the lack of preclinical animals models for benign PNSTs has hampered progress in developing and testing new therapies, including OVs. However, where models are available, OVs have demonstrated robust anti-tumor activity. The number and types of preclinical models has increased and improved dramatically over the past decade and include models more representative of the clinical situation, such as cancer stem cells, patient-derived xenografts (PDX), and transgenic mice. All models have limitations, but having multiple options improves the likelihood of successful clinical translation. Advances in genetic engineering allows the construction of OVs that are safe and with specificity for the molecular diversity of tumors. Arming OVs with therapeutics transgenes can target the tumor microenvironment locally. The normal cells and stroma comprising the tumor are a critical component in tumorigenesis and an important target for therapy. The size of transgene to be inserted will vary depending on the virus, but for oHSV this can be between 10-30 kb, sufficient for even multiple transgenes. The choice of transgene is unlimited; be it reporter genes to monitor OV activity, cytotoxic agents or prodrug activating enzymes to kill cells, antiangiogenic factors to inhibit neovascularizaton, immune modulatory factors to enhance anti-tumor immunity, or extracellular matrix modifying agents to enhance OV spread or inhibit tumor cell migration. Importantly, expression is regulated by the selectivity of the OV, so that it is typically expressed locally within the tumor, limiting systemic toxicity. OVs derived from 12 different viruses have entered clinical trials for a large variety of cancers 15. There is no obvious reason why OVs, in addition to those described here, should not also be effective in treating PNSTs. Talimogene laherparepvec, an oHSV similar to G47Δ except expressing GMCSF, was recently approved by the FDA for the treatment of advanced melanoma. This is the first OV approved for clinical use in the US and should significantly increase the interest of the pharmaceutical industry and clinicians in the use of OVs. This is an exciting time for the field of oncolytic virotherapy and PNST is an excellent target for this new therapeutic strategy. Table 1 OVs used in PNST pre-clinical models Abbreviations: GFP, enhanced green fluorescent protein; h, human; IL, interleukin; LacZ, β-galactosidase; NIS, sodium/iodide symporter; pro, promoter; TIMP3, tissue inhibitor of metalloproteinases 3; IE4/5, immediate-early gene 4/5. Oncolytic Virus Genetic Modifications Transgene Drug Combination PNST Model Ref. oHSV G47Δ γ34.5Δ, ICP6-, ICP47Δ, LacZ+ MPNST orthotopic sciatic nerve, Transgenic schwannoma, Subcutaneous schwannoma 49, 50, 57, 65 G207 γ34.5Δ, ICP6- Subcutaneous and intraperitoneal human MPNST in athymic mice 52, 54 NV1023 UL56Δ/1 copy of ICP0, ICP4 and γ34.5 Perineural invasion model in sciatic nerve 60, 61 G207 γ34.5Δ, ICP6- Erlotinib Subcutaneous and intraperitoneal: human MPNST in athymic mice 54 rQT3 γ34.5Δ, ICP6- IE4/5pro-TIMP3, ICP6-GFP fusion in ICP6 MPNST xenograft models 55 hrR3 ICP6-, LacZ+ Subcutaneous and intraperitoneal human MPNST in athymic mice 54 oHSV-MDK-34.5 Mdk pro-γ34.5 and ICP6-GFP fusion in ICP6 Subcutaneous human MPNST in athymic mice 56 G47Δ-PF4 γ34.5Δ, ICP6-, ICP47Δ, ICP47pro-Us11 PF4 Subcutaneous MPNST xenograft, MPNST orthotopic sciatic nerve in immunocompetent mice 57 G47Δ-dnFGFR γ34.5Δ, ICP6-, ICP47Δ, ICP47pro-Us11 dnFGFR Subcutaneous MPNST xenograft, MPNST orthotopic sciatic nerve in immunocompetent mice 64 G47Δ-mIL12 γ34.5Δ, ICP6Δ mIL-12 MPNST orthotopic sciatic nerve in immunocompetent mice 65 Other OVs Ad5/3-D24-GMCSF Ad5/3 fiber, E1A 24-bpΔ, E3Δ hGMCSF doxorubicin, ifosfamide leiomyosarcoma cells in Syrian hamster 74 MV-NIS Edmonston vaccine strain NIS Subcutaneous human MPNST in athymic mice 77 VSV-rp30a Disruption of gene order In vitro human MPNST cell lines 81 Article Highlights Oncolytic viruses efficiently kill tumor cells while remaining safe for normal tissues. Oncolytic viruses, especially oncolytic HSV, have demonstrated efficacy and safety in treating PNST and perineural invasion in cancer. ‘Arming’ oncolyltic viruses with therapeutic transgenes or combining with other therapeutic agents enhances antitumor activity. A limited number of preclinical tumor models for PNST has slowed progress in the development of new therapeutic strategies. 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LICENSE: This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. 0413066 2830 Cell Cell Cell 0092-8674 1097-4172 27814522 5111816 10.1016/j.cell.2016.10.019 NIHMS823453 Article From Whole-Brain Data to Functional Circuit Models: The Zebrafish Optomotor Response Naumann Eva A. 13 Fitzgerald James E. 2 Dunn Timothy W. 12 Rihel Jason 3 Sompolinsky Haim 24 Engert Florian 125* 1 Department of Molecular & Cellular Biology, Harvard University, Cambridge, MA 02138, USA 2 Center for Brain Science, Harvard University, Cambridge, MA 02138, USA 3 Department of Cell and Developmental Biology, University College London, London WC1E 6BT, UK 4 Racah Institute of Physics and the Edmond and Lily Safra Center for Brain Sciences, The Hebrew University of Jerusalem, Jerusalem 91904, Israel 5 Lead Contact * Correspondence: florian@mcb.harvard.edu 18 10 2016 3 11 2016 03 11 2017 167 4 947960.e20 This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. SUMMARY Detailed descriptions of brain-scale sensorimotor circuits underlying vertebrate behavior remain elusive. Recent advances in zebrafish neuroscience offer new opportunities to dissect such circuits via whole-brain imaging, behavioral analysis, functional perturbations, and network modeling. Here, we harness these tools to generate a brain-scale circuit model of the optomotor response, an orienting behavior evoked by visual motion. We show that such motion is processed by diverse neural response types distributed across multiple brain regions. To transform sensory input into action, these regions sequentially integrate eye- and direction-specific sensory streams, refine representations via interhemispheric inhibition, and demix locomotor instructions to independently drive turning and forward swimming. While experiments revealed many neural response types throughout the brain, modeling identified the dimensions of functional connectivity most critical for the behavior. We thus reveal how distributed neurons collaborate to generate behavior and illustrate a paradigm for distilling functional circuit models from whole-brain data. Graphical Abstract INTRODUCTION How neurons across the brain collaborate to process information that ultimately guides behavior is not well understood. Most progress toward understanding comprehensive sensorimotor circuits has been made in invertebrates (Kato et al., 2015; Ohyama et al., 2015). For example, the processes by which environmental stimuli drive specific motor patterns in C. elegans (Bounoutas and Chalfie, 2007; Chalasani et al., 2007) and Drosophila (Borst et al., 2010; Ruta et al., 2010; Silies et al., 2014) have been dissected at the level of individual neurons and their synapses. In these cases, the stereotypy and small size of the invertebrate brain and the identifiability of its neurons were indispensable for precisely measuring neural circuit structure and dynamics. With a few notable exceptions (Heiligenberg and Konishi, 1991; Lisberger, 2010), isolating the neural circuits implementing vertebrate behavior has only been successful for peripheral reflexes (Fink et al., 2014; Korn and Faber, 2005). This is partly due to technical limitations, as information processing in vertebrates is typically coordinated by many neurons in various brain regions (Felleman and Van Essen, 1991). Consequently, most research has focused on microcircuits that are spatially localized and functionally coherent, e.g., within the retina (Masland, 2012) or cortex (Ko et al., 2011). This leaves the understanding of central brain mechanisms linking sensation to action incomplete. Moreover, neural response properties in vertebrates appear heterogeneous and redundant (Bianco and Engert, 2015; Rigotti et al., 2013), yet the origins and significance of this redundancy and response variability remain poorly understood (Sompolinsky, 2014). Without access to brain-scale neuronal activity in well-defined behavioral contexts, it seems unlikely that we will understand why the vertebrate brain has, despite immense energy constraints, evolved its heterogeneous, multilayered architecture. The larval zebrafish is a small and translucent vertebrate, permitting cellular resolution optical imaging of nearly all its ~100,000 neurons (Ahrens et al., 2013a). Recent studies using brain-wide imaging have revealed that sensorimotor processing is indeed widely distributed across the entire zebrafish brain (Ahrens et al., 2012, 2013a; Portugues et al., 2014). However, the overwhelming complexity of whole-brain imaging data has made it difficult to establish links between brain- and circuit-level descriptions of behavior. Such links must be established by applying both experimental and theoretical approaches to behaviors that are simple enough to characterize in mechanistic detail but sophisticated enough to engage complex sensorimotor transformations. The zebrafish optomotor response (OMR), a position-stabilizing reflex to whole-field visual motion, offers an opportunity to dissect the central circuits underlying such a behavior using closed-loop stimulus delivery, detailed behavioral analysis, whole-brain imaging, functional perturbations, and network modeling. These approaches allowed us to follow the flow of visual information through nuclei that integrate binocular retina input to motor centers that drive turning and forward swims, resulting in a functional whole-brain circuit model that describes the sensorimotor transformation in terms of experimentally observed neural response types. RESULTS The Optomotor Response Is Driven by Egocentric Processing of Optic Flow For binocular animals to perform the OMR, the brain must integrate motion signals from each eye. We thus sought to dissect this sensorimotor transformation using independent stimulus presentation to each eye. A closed-loop system allowed us to continuously update the stimulus in each monocular visual field (Figure 1A; Movie S1), ensuring that fish continually experienced a particular motion pattern relative to the body axis. For leftward or rightward motion, we labeled these component monocular stimuli egocentrically, with medial motion going toward the midline and lateral motion going away from the midline (Figure 1A, right). Following a psychophysics approach, we presented stimuli from a matrix of all possible combinations of static (no motion), medial, and lateral motion, along with forward and backward motion (Figure 1B). By comparing the behavioral responses to monocular (i.e., motion to one eye only), coherent (e.g., leftward motion comprising medial “approaching” motion to the right eye and lateral “leaving” motion to the left eye), and conflicting stimuli (i.e., “inward” medial-medial motion or “outward” lateral-lateral motion to both eyes), we quantified basic algorithmic properties by which the brain combines binocular inputs to generate a motor output. As expected, leftward and rightward coherent stimuli led to leftward and rightward turning, respectively (Figures 1C and S1A–S1C). In addition, average turning was larger to coherent motion than to monocular stimuli and were similar to the sum of the responses to each monocular component (Figure 1C). Interestingly, the contributions of medial and lateral components were not equal; medial contributed substantially more to turning than lateral. Furthermore, response latencies to stimuli containing medial motion were shorter than to stimuli containing only lateral motion (Figure S1D). Together, these observations reveal several algorithmic properties of the OMR, which are necessarily implemented in the brain: (1) the direction of whole-field coherent motion dictates the direction of behavioral output; (2) the average turning response to coherent motion approximates the sum of responses to medial plus lateral motion; and (3) despite representing environmentally equivalent motion cues, medial and lateral motion are differentially processed by the zebrafish brain to generate different behaviors. Eye- and Direction-Specific Motion Differentially Affect Forward Swimming and Turning Examination of discrete swim bouts (Figures S1E and S1F) revealed that histograms of individual bout angles in response to each stimulus were typically trimodal (Figures 1D, S1G, and S1H), with a central peak corresponding to forward swimming and left/right peaks corresponding to left/right turning. As these peaks changed dramatically across the stimulus set, we focused our analyses on their amplitude changes. Coherent stimuli enhanced turning in the direction of motion (“correct”) relative to the baseline static condition, while turning in the opposite direction of motion (“incorrect”) was suppressed. Similar to coherent stimuli, monocular medial stimuli increased forward swims and correct turns while suppressing incorrect turns (Figure 1D, inset). In contrast, monocular lateral stimuli slightly decreased forward swimming and modulated turning less than medial stimuli. Hidden by averaged turning responses (Figures S1B and S1C), this analysis revealed fundamental differences in the behavioral responses to conflicting stimuli. While each conflicting stimulus eliminated the turning responses observed under monocular stimulation (Figure 1D), inward stimuli enhanced forward swimming, resulting in behavior that looked much like that in response to forward motion, and outward stimuli suppressed forward swimming, mirroring backward motion responses. These data thus establish two additional algorithmic properties of the OMR. First, visual motion drives correct turns and suppresses incorrect turns, and these effects are both stronger for medial than for lateral motion. Second, turning and forward swimming are modulated separately, with medial motion driving swimming, akin to forward motion, and lateral motion suppressing swimming, akin to backward motion. To illustrate the minimal computational requirements for these observed sensorimotor transformations, we implemented a neural circuit architecture in which direction-selective retinal ganglion cells (DSRGCs) send monocular motion signals to premotor neurons presumed to independently drive peak frequencies of turning (T) and forward swimming (F, central diagram, Figure 1E). These premotor neurons represent ventromedial spinal projection neurons (vSPNs, T) (Huang et al., 2013) and the nucleus of the medial longitudinal fasciculus (nMLF, F) (Orger et al., 2008). Forward swimming was well modeled in this architecture as the sum of monocular components (left panels, Figure 1E), with medial motion driving swimming and lateral motion suppressing it. Although turning frequencies depended nonlinearly on monocular components, a biologically plausible input-output nonlinearity could reproduce the required transformation (right panels, Figure 1E). Thus, as few as three dedicated neurons could conceivably transform direct monocular inputs into the observed pattern of forward swimming and turning, concretely instantiating the aforementioned algorithmic properties of the OMR (Figures S1H and S1I). Whole-Brain Imaging Identifies Regions Activated during the OMR To map brain areas for response features consistent with revealed algorithmic properties, we measured neural activity to visual motion using two-photon calcium imaging in transgenic Tg(elavl3:GCaMP5G) zebrafish. Though animals were restrained during imaging, we made motor nerve recordings (Ahrens et al., 2013b) in a subset of fish and observed a pattern of bout frequency modulation that matched freely swimming fish (Figures S2A and S2B). Combined with known zebrafish neuroanatomy (Figure 2A) (Burrill and Easter, 1994), these whole-brain maps highlight the route of information flow. Because the OMR was modulated by the overall direction of motion (Figures 1C, 1D, S1A–S1C), we first examined the spatial distribution of direction-selective neural units (Figure 2B), which revealed that motion information was distributed and segregated across a handful of brain areas (Figure 2C). Of the ten arborization fields (AFs) of retinal axons (Robles et al., 2014), AF6 and 10 were strongly activated by motion stimuli (Figures 2B, S2C, and S2D). Near AF6, responses in the pretectum (Pt) (Figures 2B and 2C) were lateralized, with the left Pt responding primarily to leftward motion, and the right Pt responding to rightward motion. Responses to forward motion were bilaterally distributed across the Pt. Directional signals were demixed in the hindbrain and midbrain. In particular, forward-selective neurons were anatomically segregated from lateralized left- and right-selective neurons. This response segregation is reminiscent of the behavioral segregation of forward swimming and turning. To visualize binocular integration of coherent monocular signals, we generated maps overlaying responses to monocular medial and lateral stimuli presented sequentially to the eyes (Figures 2D and S2D). While responses in the AFs were exclusively monocular, neurons in the Pt exhibited the binocular integration required of the OMR, and downstream neurons in the anterior hindbrain (aHB) and vSPNs displayed qualitatively similar binocular responses (Figures S2D and S2E). These response maps suggest a qualitative brain-scale functional-anatomical model underlying the zebrafish OMR (Figure S2F). To move beyond map-making and characterize the local computations, we focused analyses within specific brain regions. STARting at the sensory end, we extracted fluorescence time series from motion-sensitive regions containing retinal terminals. As AF10 ablations spare the OMR (Roeser and Baier, 2003), we concentrated on AF6. Consistent with completely decussated retinal projections, responses in AF6 were exclusively monocular (Figure 2E, top). AF6 also showed localized regions of highly tuned directional responses for all direction of motion, roughly matching the size of synaptic boutons (>1 μm2) (Figure 2F, top). To test whether information arriving in AF6 is necessary for the OMR, we ablated it unilaterally and found behavioral deficits specific to contralateral eye stimulation (Figures S3A–S3C). Thus, AF6 is an important site of retinal input to the OMR circuit. To generate the OMR, neurons must integrate this monocular information to form binocular representations. We observed neurons in the Pt (Figure 2E, bottom) that showed sustained, binocular responses and sent neurites into the ipsilateral AF6 (Figure S3D). In addition, average Pt activity reflected several algorithmic properties of the behavior, including ipsilateral inhibition to medial stimuli (Figures S3E–S3G). Moreover, the Pt showed enhanced and lateralized direction selectivity (Figure 2F, bottom; Figure S3F) and receives direct retinal input in other species (Gamlin, 2006). The Pt is thus well positioned to support the sensorimotor transformation underlying the OMR. Pretectal Activity as a Neural Correlate of Optomotor Behavior The Pt exhibited considerable diversity at the neuronal level, with individual neurons responding in various patterns to monocular, coherent, and conflicting motion (Movie S2; Figure S3F). To investigate the representation, we analyzed individual neurons (3,070 Pt neurons, 12 fish). If the Pt coordinates the OMR, it must encode all directions of motion (Orger et al., 2008). Consistent with this, most neurons were strongly tuned to a particular direction of motion (Figure 3A, left), with forward-tuned neurons clustered near the midline (Figure 3A, right). Most neurons were binocularly excited (Figure S3H). These binocular neurons preferred medial to lateral motion and linearly integrated the monocular components of whole-field motion (Figure 3B). Most Pt neurons showed at least partial suppression to conflicting motion (Figure 3C, left), mirroring the reciprocal suppression of turns seen behaviorally. Finally, we found that, much like the behavior, Pt neuron responses to forward and inward motion were associated (Figure 3D). Similar associations were seen between backward and outward motion. Together, these data provide neural correlates for many OMR algorithmic properties, suggesting that the Pt links motion information from the retina to appropriate motor actions. Posterior Commissure Ablation Disrupts Binocular Integration As retinal input is exclusively monocular, binocular Pt response properties (Figures 3B and 3C) require both excitatory and inhibitory signals to re-cross the midline. In particular, coherent motion responses require interhemispheric excitation from lateral motion, and negated responses to inward stimuli require interhemispheric inhibition from medial motion. A strong anatomical candidate for these connections is the posterior commissure (PC) (Figure 4A), which passes between the left and right Pt and has been proposed to carry motion information in rodents (Giolli et al., 1984). After confirming that Pt neurons project through the PC (Figure S4A), we laser-ablated the commissure (Figure 4B, left; Figure S4B). As expected, when we imaged Pt responses before and after PC ablation, both average Pt and single neuron Pt responses to inward motion were enhanced (Figure 4B, right), and responses to stimuli with lateral components were attenuated. We also measured behavior following PC ablation and found that contributions of lateral motion to average turning diminished (Figure 4C), as responses to monocular lateral were eliminated, and differences between coherent and monocular medial were reduced (Figure 4C, inset). This was not a non-specific perturbation, as overall bout frequencies were indistinguishable from controls (Figure S4C). Instead, these deficits resulted from a reduction in both correct and incorrect turn modulation in PC-ablated fish (Figures 4D and 4E). In response to inward motion, PC-ablated fish did not exhibit behavioral alternation between leftward and rightward turning, as might be expected from two lateralized medial turning signals that could not inhibit each other. Thus, although the PC carries some medial inhibition, additional inhibition must be communicated elsewhere. Moreover, we observed that forward swimming in response to medial was reduced (Figure S4C, inset). This suggests that some forward swim drive is relayed through the PC. Simulating PC ablation in the minimal model (Figure 1E) further supported these hypotheses (Figure S4E). Combining the PC ablation results with anatomy (Figure S4F) suggests that medial signals bilaterally activate, via the PC, the downstream region known to drive swimming (i.e., the nMLF) and that the suppression of incorrect turns by medial motion should occur via additional interhemispheric connections (Figure 4F). Most Pt Neurons Can Be Classified into a Few Functional Response Types Our results suggest that Pt neurons separately drive downstream circuits that control forward swimming and turning. To investigate how response heterogeneity across the Pt population might support these parallel functions, we first classified Pt neurons into functional response types (Figures 5A and S5A–S5C; Table S1; STAR Methods). Eight bilaterally symmetric (Figure S5D) response types occurred with elevated frequency, together comprising more than 66% of the Pt population. Four of these eight classes were binocularly activated by both medial and lateral stimuli (Figures 5B, top, 5C, left), and the remaining “monocular” classes responded to at most one monocular stimulus (Figures 5B, bottom, 5C, right). Within the binocular group, all classes responded most strongly to coherent stimuli (Figure 5B), but they were distinguishable by patterns of inhibition revealed only by their responses to conflicting stimuli. For example, response type ioB, a binocular neuron (ioB) exhibiting responses to conflicting inward (ioB) and outward (ioB) motion, responded to both conflicting stimuli. On the other hand, response type B (binocular neuron) did not respond to either conflicting stimulus, despite responding to both monocular stimuli. This suggests that the left-selective B type might play a specific role in generating left turns, as conflicting stimuli do not enhance turning. Consistent with this role, the B type was selective for directions of motion associated with turning (Figure 5B, far right). The monocular classes were distinguished both by patterns of excitation in response to monocular medial or lateral stimuli and by inhibition in response to conflicting motion. For example, response class iMM was a monocular (iMM) neuron, responsive to medial motion (iMM), and activated by inward motion (iMM). Because it showed a strong preference for forward motion and responded to all stimuli that promoted forward swimming, it is a good candidate to drive this behavioral module. In order to generate all of the observed Pt response types, we predict the existence of at least three types of relay units (Figure 5D). First, excitatory oML neurons might cross the midline to generate binocular responses. Second, inhibitory oML neurons could suppress responses to conflicting outward motion in B and iB neurons. Third, inhibitory iMM neurons could project across the midline to suppress responses to conflicting inward stimuli. Finally, an excitatory iMM neuron may relay retinal signals within the Pt, as suggested by inhomogeneous retinal innervation across the Pt in other species (Gamlin, 2006). Altogether, the overrepresented response types compactly summarize the neural correlates of forward swimming and turning behaviors. Network Modeling Demonstrates Requirements of Downstream Processing With this response diversity, the Pt could, in theory, implement the minimal model derived from behavior (Figure 1E). However, no single overrepresented response class exhibited an activity profile that precisely matched the behavior. For instance, neurons directly driving turning should not respond to backward and forward motion, as neither of these stimuli significantly increased turning, yet every Pt response type was activated by backward and/or forward stimuli. Furthermore, although the B type responded most similarly to the turning behavior, many other response types reproduced features of turning, and no type predicted the suppression of incorrect turns. This reinforces our hypothesis that turning opponency occurs downstream of the Pt. The observed response heterogeneity, together with the lack of a single response type that could explain the behavior, motivated an interpretation of the data wherein a combination of several response types underlies the OMR. To quantitatively formulate this hypothesis, we applied neuronal network modeling. Since the major Pt neural types correlated strongly with each other and with behavior, it is a priori possible that any of them contributed to the behaviors. We thus included all overrepresented classes in the model network (Figure 5E, left). Because representations were lateralized, we assumed that the left and right Pt drove leftward and rightward turning, respectively. However, since none of the major Pt response types were appreciably suppressed below baseline levels by opposing motion signals, we did not force the Pt network to suppress incorrect turns (Figure 5E, right). Aside from this limitation, the model architecture was able to account for the behavior. Hindbrain Circuitry Refines Pt Representations To complete the model, we examined other brain regions revealed by whole-brain imaging (Figures 2B and S6) and investigated how Pt signals are refined. Recall that neurons preferring stimuli that promote forward swimming were anatomically segregated in the nMLF, RoL, and cHB (Figures 2A–2C andS7A). We found that monocular medial stimuli bilaterally recruited these regions (Figure S7B), explaining the reduction in forward swim frequency observed after PC ablation. Neurons responding to swim-promoting stimuli were sparsely distributed within these regions (Figure S7C) and could ultimately drive forward swimming. Elsewhere in the hindbrain, especially in the aHB and vSPNs, neurons preferred stimuli associated with turning (Figure 6A). Neurons in the aHB are anatomically positioned between visual neurons in the Pt and premotor vSPNs and were thus good candidates for mediating the additional interhemispheric inhibition necessary to suppress incorrect turns. To test this hypothesis, we first classified aHB neurons into functional response types. We found four overrepresented types that were a subset of the Pt types (Figures 6B and S7D–S7F; Table S2) and hypothesize that only this subset of Pt neurons sends projections to the aHB. Intriguingly, the aHB representation enhanced the B type, the strongest functional candidate for driving turns. Furthermore, the B type clustered within the Pt and aHB (Figure 6C1). Neurons ultimately driving turning should not respond to either forward or backward motion. We found that B neurons responding to forward and backward motion were enriched in the Pt (Figure 6C2), and B neurons lacking these responses were enriched in the vSPN region (Figure 6C3). More interestingly, anatomically organized subpopulations of aHB and anterior rhombencephalic turning region (ARTR) neurons were associated with the Pt or vSPN representation (Figures 6C2 and 6C3). We refer to these sub-regions as the early (EHB) and late (LHB) hindbrain, respectively, as the EHB is functionally associated with visual areas (i.e., Pt) and the LHB is associated with motor areas (i.e., vSPNs). Many of the B neurons in the LHB were suppressed to levels not seen in the Pt but expected from the behavioral output (Figure 6D3, right), indicating that necessary interhemispheric inhibition lies within the hindbrain. By dissecting these hindbrain circuits, we provide a critical link between visual processing in the Pt and behavior. Quantitative Model for Pt and aHB Control of Behavior These considerations lead us to a model of how the Pt generates forward swimming and the Pt and aHB cooperate to generate turning (Figure 7A). Neurons in each major Pt response category drive premotor neurons controlling forward swimming. Since brain responses associated with forward swimming are bilaterally symmetric (Figure S7A), we assume that the left and right Pt contribute symmetrically (green lines, Figure 7A). Thus, the transformation of Pt signals into forward swimming behavior consists of eight functional connection weights, from each Pt response type to premotor nMLF units. To refine turn-related signals, we suppose that a subset of Pt neurons project to aHB. Both EHB and LHB receive ipsilateral inputs from the four Pt types common to the aHB (Figure 6B). LHB also receives contralateral input from EHB. Thus, the transformation of right Pt and left EHB signals into rightward turning consists of eight functional connection weights onto neurons in right LHB, which then drives turn generation (Figure 7A). The model is symmetric across the midline for leftward turning and accounts for the missing turn suppression (Figure S7G, cf. Figure 5E). Identifying Critical Dimensions of Functional Connectivity The experimentally informed circuit architecture (Figure 7A) can account for the behavioral responses. However, one would not expect the model to predict every feature of the functional connectivity that might be revealed by future experiments, as current experiments only provide a low-dimensional view of the brain (Gao and Ganguli, 2015). For example, our stimuli did not isolate behavioral drive to individual functional response types, as multiple sets of connections (Figure S7H, top) lead to similar behavioral predictions (Figure S7H, bottom). Nevertheless, a successful model should accurately predict behavior in experiments probing functional elements well-constrained by the current data. To identify critical determinants of model performance, we examined the full ensemble of models that linearly generate sensorimotor transformations via the circuit architecture of Figure 7A (STAR Methods). The model architecture could accurately predict the behavioral data using a range of functional connections (Figure 7B), and even the signs of connections were ambiguous. Such flexibility is common in multiparameter models when correlated parameter changes compensate to avoid error (Fisher et al., 2013; O’Leary et al., 2015). Individual connections could compensate in our model (Figure 7C, left), so we identified connectivity patterns that independently affect model accuracy (Figure 7C, right). We term these patterns functional modes. Figure 7D represents the functional modes as columns in a matrix, where each row represents a response type in Pt for forward swims (Figure 7D, left) and in Pt or EHB for turns (Figure 7D, right). For example, the eighth functional mode of swimming (8F) positively weighted connections from every response type (Figure 7D, left). The modes are ordered so that parameter changes along high-numbered modes induce large errors (Figure 7D, top). The models in Figure S7H performed similarly because they differed along the first mode. The functional modes can also be interpreted as population activity patterns that contribute independently to the accuracy of the sensorimotor transformation, so we could calculate the fraction of error eliminated by each mode (Figure 7D, bottom). A few modes eliminated the vast majority of model error, and the signs of abstract functional connections from these modes were reliably determined and positive. The seventh functional mode of swimming (7F) eliminated the most error, while 6F and 8F repaired discrepancies. Similarly, the seventh mode of turning (7T) was most important, while 5T refined model predictions. Thus, one significant mode mostly explained each behavior, but secondary modes helped shape detailed behavioral patterns. Similar considerations reveal reliable optogenetic predictions. The model predicts that activation of a response type or functional mode will cause a behavioral response if there was a significant functional connection between them. The model also predicts that uniform activation of left Pt would drive forward swimming (p = 0.002), drive leftward turning (p = 2.7 × 10−13), and suppress rightward turning (p = 0.0018). Selective activation of all binocular response classes in left Pt would likely suppress swimming (p = 0.11), drive left turning (p = 4.8 × 10−12), and have no effect on right turning (p = 0.41). Selective activation of all monocular classes in left Pt would likely drive swimming (p = 0.051), suppress left turning (p = 0.0069), and have no effect on right turning (p = 0.48). Finally, our model predicts that Pt is functionally multiplexed, with different aspects of the population response driving the behaviors. For example, mode 7F weighted response types according to their preference for inward versus outward motion (Figure 7E), which made this mode a component of the population response that was activated by stimuli promoting forward swimming and suppressed by stimuli reducing forward swimming (Figure 7F). Importantly, the model also predicts that certain aspects of the population response are functionally irrelevant. The irrelevance of 8T (Figure 7D, right) means that matched responses in right Pt and left aHB do not drive behavior. Nevertheless, such activity characterized several stimulus conditions (e.g., forward motion). Unsupervised techniques for parsing population activity risk equating response frequency with relevance. Since brains must multiplex their functions in ethological conditions, it is critical that future work integrate model and experiment to align responses to specific functions. DISCUSSION Here, we combine experiment and theory to delineate a sensorimotor transformation within the zebrafish brain, from sensory input to locomotor output. By sequentially evaluating possible models with behavioral, functional, and anatomical data, we arrived at a quantitative whole-brain circuit model that accounts for the observed aspects of the OMR using experimentally identified neural response types. We note that analyses at the behavioral, whole-brain, and systems levels were critical for defining a biologically plausible and functionally relevant circuit architecture. Yet, we acknowledge that our treatment ignores processing in the retina and spinal cord. Dedicated experiments to decipher these peripheral mechanisms will complement our model of central processing. Overall, our methodology establishes a roadmap for digesting large-scale neural data from vertebrate brains and raises fundamental questions that are broadly relevant to whole-brain descriptions of function and behavior. Relevance of Eye-Specific Motion Processing We dissected the routes of sensory input by decomposing motion egocentrically. For a given eye, left- and rightward motion should, a priori, be perceptually symmetric. Yet, sensorimotor circuitry maintained asymmetries (i.e., lateral versus medial) throughout. These functional asymmetries might survive from an evolutionary past in which eye-specific pathways did not converge, reflecting vestigial functional inefficiencies: only lateral signals must re-cross the midline to drive turning behavior. The large inhibitory influence of medial motion on contralateral turning might be a corresponding consequence of the early emphasis on medial pathways. Instead, medial motion might be privileged due to the ethologically relevance of approaching motion in other behaviors, and reciprocal inhibition from opponent motion signals may help stabilize motor outputs in noisy environments (Mauss et al., 2015). Homologs of Optomotor Response Circuitry Several features of the zebrafish OMR likely translate to processing in higher-order vertebrates. The mammalian anatomy of retinal projections and the Pt suggests that binocular integration may occur via the PC (Sun and May, 2014). The zebrafish OMR is established by separate visual channels controlling multiple behavioral parameters. As visual information is organized into channels in other brains (Gollisch and Meister, 2010; Huberman et al., 2009; Yonehara et al., 2009), we hypothesize that distinct channels may activate segregated motor nuclei to generate flexible behavior in other vertebrates. In particular, the nMLF or neighboring neurons may be functional homologs of the mesencephalic locomotor region in mammals (Dunn et al., 2016; Ryczko and Dubuc, 2013; Severi et al., 2014), whereas the vSPNs are functionally and anatomically similar to neurons in the mammalian reticular formation (Armstrong, 1988). Furthermore, the prevalence of caudal interhemispheric connections in the mammalian brain (Chédotal, 2014) is reminiscent of the zebrafish hindbrain, and these connections might also refine lateralized motor streams in higher-order vertebrates. In zebrafish, OMR circuitry overlaps with circuits activated in other stabilizing reflexes, such as the optokinetic reflex (OKR) of the eyes (Kubo et al., 2014; Portugues et al., 2014). In particular, neurons in the Pt are consistently recruited by stimuli that evoke the OKR, but binocular neural activation is far less common than during the OMR, perhaps suggesting that different subpopulations coordinate each behavior. Notably, Kubo et al. also identified frequent response types in the Pt and hypothesized a Pt circuit that could generate the response types (cf.Figure 5D). Quantitative Modeling To understand the requirements of the system, we first built a minimal model to explain the measured sensorimotor transformation (Figure 1E). As this model conflicts with anatomical and functional details of the brain, we reassessed the model with each new result to eventually obtain a candidate whole-brain description (Figure 7G). This iterative migration between experiment and theory will be necessary to illuminate the mechanisms of complex sensorimotor transformations, which are underconstrained by conceivable experiments (Gao and Ganguli, 2015). Functional similarity between neurons resulted in a model whose output was insensitive to some aspects of connectivity. This will be common going forward, as neuroscientists typically characterize high-dimensional systems using a few stimuli and behaviors (Fisher et al., 2013; Gao and Ganguli, 2015; O’Leary et al., 2015). Nevertheless, a few combined parameters were critical to explain the behavior, thereby distilling the behaviorally relevant features of the population response. Thus, although we did not assign unique functional roles to each response class, we could identify model features that were well constrained by the data to make testable predictions for collective encoding. The model architecture also makes predictions for connectivity between Pt response classes, aHB classes, and premotor nuclei that can be tested with viral tracing, connectomics, channelrhodopsin-assisted circuit mapping, and electrophysiology. Validation of Microcircuitry Our model uses DSRGCs and monocular relays to construct the overrepresented Pt response types. All retinal input arrives in AF6 from the contralateral visual field, so excitatory and inhibitory relays are necessary for binocular integration and reciprocal suppression. Not all Pt neurons receive direct retinal input in other animals (Fite, 1985; Koontz et al., 1985; Scalia, 1972; Vanegas and Ito, 1983), and relays might distribute input signals throughout the Pt. Future experiments measuring coarse projections, detailed connectivity, and neurotransmitter identity of candidate relay are necessary. We predict that lateral relay neurons (oML) exist in excitatory and inhibitory forms that differ in their projection patterns. One could use transgenic lines specifically labeling glutamatergic and GABAergic populations to test this hypothesis. Our model also predicts that LHB neurons are excited by specific ipsilateral Pt response types and inhibited by contralateral EHB neurons. The latter prediction is consistent with known organization in the zebrafish hindbrain (Kinkhabwala et al., 2011; Randlett et al., 2015; Sassa et al., 2007) and with the prevalence of commissures in the rhombencephalon (Koyama et al., 2011; Lee et al., 2015), but the detailed organization proposed here must be verified. Furthermore, a rigorous definition of EHB and LHB requires further experiments to distinguish each structure anatomically and functionally. A Generalizable Framework We provide an eminently testable framework for future studies and a detailed description of the neural circuitry underlying the OMR. We chose the OMR because it is an accessible gateway to a fundamental sensorimotor transformation layered with rich complexity. While we address the feed-forward foundation of the OMR with a simple stimulus set, the circuit properties revealed here provide a basis for future studies. Indeed, complementary studies of visuomotor behaviors that aim to explain learning, decision making, and multimodal processing must first ground themselves in the circuits controlling basic behaviors. More generally, our study establishes a computational and experimental scaffold for generating testable circuit models on large scales. Our work in larval zebrafish provides a critical link between efforts in smaller model organisms and those in vertebrates, an essential step toward tackling the complexity of mammalian brains. STAR*METHODS KEY RESOURCES TABLE REAGENT or RESOURCE SOURCE IDENTIFIER Chemicals, Peptides, and Recombinant Proteins Alpha-Bungarotoxin Life Technologies B1601 Deposited Data Pretectal Response Distribution. See Table S1 This study N/A Anterior Hindbrain Response Distribution. See Table S2 This study N/A Experimental Models: Organisms/Strains Tg(elavl3:GCaMP5G) (Ahrens et al., 2013a) N/A Tg(elavl3:GCaMP2) (Ahrens et al., 2013b) N/A Tg(alpha-tubulin:C3PA-GFP) (Ahrens et al., 2013b) N/A Software and Algorithms Labview (Behavioral acquisition framework) National Instruments http://www.ni.com/en-us.html MATLAB (Behavioral and imaging analysis, modeling) MathWorks http://www.mathworks.com/?requestedDomain=www.mathworks.com Open GL (Stimulus rendering) OpenGL https://www.opengl.org/ C# (.NET Framework 3.5) (Two-photon acquisition) Microsoft/ (Ahrens et al., 2013b) http://www.microsoft.com/en-us/ FIJI (ImageJ) (Neural tracing) NIH http://fiji.sc Automatic ROI segmentation (Portugues et al., 2014) / This study N/A CONTACT FOR REAGENTS AND RESOURCE SHARING Further information and requests for resources and reagents should be directed to the Lead Contact Florian Engert (florian@mcb.harvard.edu). EXPERIMENTAL MODEL AND SUBJECT DETAILS Zebrafish For all experiments, we used 5-7 days post-fertilization (dpf) wild-type (AB or TL) or transgenic nacre −/− zebrafish; nacre −/− mutants lack pigment in the skin but retain wild-type eye pigmentation. All measured behavioral variables in nacre −/− fish were similar to wild-type, heterozygous siblings. Zebrafish were maintained on a 14 hr. light /10 hr. dark cycle and fertilized eggs were collected and raised at 28.5 °C. Embryos were kept in E3 solution (5 mM NaCl, 0.17 mM KCl, 0.33 mM CaCl2, 0.33 mM MgSO4). All experiments were approved by Harvard University’s standing committee on the use of animals in research and training. All imaging experiments in this study were performed on transgenic zebrafish Tg(elavl3:GCaMP5G), a generous gifts from Drs. Michael Orger, Drew Robson and Jennifer Li or in double transgenic Tg(elavl3:GCaMP5G); Tg(α-tubulin:C3PA-GFP). The Tg(α-tubulin:C3PA-GFP) was kindly provided by Dr. Michael Orger. Tg(elavl3:GCaMP2), also a gift from Drs. Michael Orger, Drew Robson and Jennifer Li was used as anatomical reference in laser ablation of the posterior commissure. METHOD DETAILS Behavior in freely swimming zebrafish Zebrafish swam freely in a clear 5 cm diameter petri dish (VWR) in filtered E3 solution at 3-5 mm height, minimizing variability of visual angle. Illumination of the fish was achieved by a circular array of infrared light-emitting diodes (810 nm) directed from below. Fish behavior to various motion stimuli was recorded at 200 Hz using an infrared-sensitive, high-speed, monochrome charge coupled device (CCD) camera (Pike F-032, 1/3,” Allied Vision Technology, Germany). A zoom lens (Edmund Optics, USA) was used with an infrared pass filter (RG72, Hoya, Japan). The center of the dish was aligned with the center of an appropriately zoomed camera image such that the edge of the dish was not visible in the field of view; this simplifies the fish detection algorithm by not having to handle sidewall reflections. Stimuli were projected onto a 12 by 12 cm diffusing screen after reflection by a 4 × 4 inch cold mirror (both Edmund optics, USA) 5 mm directly below the fish using a commercial DLP projector (Optoma, USA). Custom image processing software (Labview, National Instruments, USA and Visual C++, Microsoft, USA) extracted the position (center of mass) and orientation (vector anchored by detection of swim bladder and center of mass between eyes) of the fish at the camera acquisition frame rate (200 Hz) from a background-subtracted frame. This information was used to continuously update a stimulus rendered in real-time using OpenGL to provide consistent motion stimulation with respect to the body axis. To begin each trial, fish were induced to swim to the center of the camera field of view by concentric circular, converging sinusoidal gratings (Movie S1). Detection of the fish near the center triggered a trial. Each trial began with a 500 ms static period in which gratings (running parallel relative to the fish body axis, spatial period of 1 cm) were locked to fish orientation in a closed loop configuration. These orientation-locked gratings then began to move at 10 mm/s (or remained stationary throughout the trial, depending on the particular stimulus identity, Movie S1). Stimulus presentation continued until either the fish aborted the trial early by leaving the active area or the maximum trial duration (30 s) was reached. To independently stimulate each eye, a 0.8 cm area was blanked (black) directly underneath the fish. In control experiments, we widened the blanked area and did not observe any effect on behavioral outcome (data not shown); this is consistent with independent stimulation of each eye. Only fish that completed at least 10 repetitions in less than 3 hr were included in further analysis or ablation experiments. Extracted the position and orientation were further analyzed as described in Quantification and Statistical Analysis. Fictive behavior Transdermal motor nerve recordings of fictive behavior were performed as outlined in (Ahrens et al., 2013b). Larval zebrafish (5-7 dpf) were paralyzed by immersion in a drop of fish water with 1 mg/ml alpha bungarotoxin (Sigma-Aldrich) and embedded in a drop of 2% low melting point agarose, after which the tail was freed by cutting away the agarose around it. Two suction pipettes were placed on the tail of the fish at intersegmental boundaries, and gentle suction was applied until electrical contact with the motor neuron axons was made, usually after about 10 min. These electrodes allowed for the recording of multi-unit extracellular signals from clusters of motor neuron axons, and provided a readout of intended locomotion. Extracellular signals were amplified with a Molecular Devices Axon Multiclamp 700B amplifier and fed into a computer using a National Instruments data acquisition card. Custom software written in C# (Microsoft) recorded the incoming signals. These signals were then analyzed offline in MATLAB (Mathworks, USA). Please seeQuantification and Statistical Analysis for detailed analysis. Two-photon Ca2+ imaging In-vivo two-photon fluorescence imaging of neural activity was performed in 5-7 dpf Tg(elavl3:GCaMP5G) zebrafish larvae. Prior to imaging, larvae were paralyzed in α-Bungarotoxin (1 mg/ml, Sigma, USA) and embedded in low melting point agarose (2% w/v), which prevented movement artifacts. Viability was monitored before and after imaging by observing the heartbeat and blood flow through brain vasculature. All data acquisition and analysis was performed using custom Labview (National Instruments, USA), MATLAB (Mathworks, USA) and C# software. Imaging was performed with a custom two-photon laser-scanning microscope, using a pulsed Ti-sapphire laser tuned to 920 nm (Spectra Physics, USA). Stimuli were projected from below with a DLP or LCOS projector (Optoma, USA or AAXA Technologies, USA, respectively) using only the red channel, which allowed for simultaneous visual stimulation and detection of green fluorescence. Visual stimuli were blanked with a black bar underneath the fish, as in free behavior experiments. Stimuli were 8.5 s in duration, which was long enough for neural activity to reach characteristic peaks (for transient responses) or plateaus (for sustained responses, see Figure 5B), and were separated by 11.5 s of static (no motion) gratings. For brain-wide mapping experiments, images were acquired at 2 Hz. For pretectal imaging, frames were acquired at 3.6 Hz, as afforded by the smaller field of view. For experiments spanning smaller brain volumes (e.g., specific pretectal imaging), 10 stimulus repetitions were presented per z-plane. For experiments across large brain volumes (e.g., whole-brain experiments), 3 stimulus repetitions were presented per z-plane. The resulting image time and depth series were analyzed in MATLAB (Mathworks, USA). Subsequent analysis was performed as described in Quantification and Statistical Analysis. Tracing pretectal projection patterns Double Tg(α-tubulin:C3PA-GFP); Tg(elavl3:GCaMP5G) fish at 6 dpf were embedded in 2% agarose in a 35 mm petri dish. We modified the tracing protocol developed by Datta et al. (Datta et al., 2008) to trace projections from a subset of Pt neurons (Figure S3D). While presenting whole-field motion stimuli from below, fish were first imaged under a two-photon microscope at 925 nm to identify motion-sensitive neurons. Then, after taking anatomical stacks of the region, individual motion-sensitive Pt neurons were selected on one side of the brain. PA-GFP in selected neurons was then activated using 5-10 pulses (100 ms – 2 s) of 770 nm pulsed infrared laser light. Selective photoconversion was confirmed by switching to 925 nm and imaging the selected plane for increased fluorescence. The activation protocol was repeated until photoconverted fluorescence no longer increased significantly. Anatomical stacks of projection patterns were acquired 2 hr post-activation. The pre and post activation two-photon stacks were then aligned and analyzed using FIJI (ImageJ) software. For highlighting of the posterior commissure (Figure S4A and S4F, right), anatomical pre-activation stacks of Tg(α-tubulin:C3PA-GFP) were acquired, before activating a small region with the same protocol as described above. The pre and post activation two-photon stacks were then aligned and analyzed using FIJI (ImageJ) software in separate color channels. Two-photon laser ablations After embedding zebrafish in low melting agarose, areas were targeted using neuroanatomical landmarks, stereotypical blood vasculature, and/or neuronal activity patterns in Tg(elavl3:GCaMP2) or Tg(elavl3:GCaMP5G) larvae. Mode-locked laser power (885 nm, 120-135 mW maximum at sample) was linearly increased while the beam was scanned in a spiral pattern over the targeted region (typically 0.5 – 10 s). The laser scan was immediately terminated upon the detection of fluorescence saturation, which is presumed to result from the creation of highly localized plasma via multi-photon absorption. For single cells, this method resulted in the complete destruction of the target cell without affecting adjacent cells. Ablations in neuropil regions (like the PC) required additional validation. Due to the depth and anatomical position of the PC, nearly 50% of ablated fish showed non-specific side effects such as nearby necrotic tissue or changes in the optical density of the optic tectum, likely due to blood vessel cauterization from out-of-focus heating. These fish were excluded from post-ablation analysis. Before and after PC ablation imaging was performed in only a subset of fish. After freeing fish from agarose and a recovery period (10-120 min, until fish were swimming spontaneously), fish were tested in the behavioral assay. For the AF6 ablation, we specifically monitored fluorescence before and after ablation across AFs. Only fish that exhibited functional perturbations specific to AF6 were further analyzed. Quantitative modeling Behavior-only modeling We built the model in Figure 1E to illustrate that a simple circuit architecture could account for the observed binocular visuomotor transformation. For all behavioral model results error bars are SEM across fish (N = 38). The synaptic inputs onto the forward swimming center were 0.0395 from the medial responsive RGCs and −0.0088 from the lateral responsive RGCs. The magnitudes of synaptic inputs onto the two turning centers were 0.0133 from the medial responsive RGCs and 0.0068 from the lateral responsive RGCs. The sign of each connection onto a turning center was positive when the direction of the RGC matched the direction of the turning center. After summing the monocular components of the motion stimuli, we converted the resultant retinal input signals into the model rate through a transfer function. For forward swimming, this transfer function was the sum of the retinal input and the baseline static swimming rate (0.0836). For turning, we fit a cubic transfer function to generate the behavioral turning rates from the retinal input signals. The resulting transfer function was f(x) = 114.6x3 + 17.48x2 + 0.5168x + 0.006175, where x denotes the retinal input signal. To simulate the ablation experiment in Figure S4E, we removed those synaptic inputs that could not reach the lateralized turning centers without an interhemispheric connection within the zebrafish brain. Quantifying the visuomotor transformation Larval zebrafish responded to optomotor stimuli by modulating at least three elements of behavior: forward swimming; turning to the left; and turning to the right (Figure 1D). For each stimulus condition and element of behavior, we quantified the response magnitude as the amplitude of the associated peak of the mean bout frequency histogram. We similarly quantified the uncertainties of each mean response magnitude using the SEM of the histogram. Since neuronal fluorescence responses were measured relative to the background set by the static stimulus, we shifted the behavioral responses to also be relative to the static stimulus. We accordingly corrected the uncertainty of each stimulus response to account for the uncertainty of the static response. Since the static stimulus is zero by construction, we are left with ten non-trivial stimulus conditions. For each of the three behavioral classes, we construct a 10-dimensional vector y whose components are the experimental motor response magnitudes for the 10 stimulus conditions. We also define the 10×10 diagonal matrix C whose diagonal elements, σi2, are the squares of the response uncertainties. Suppose that y^ is a 10-dimensional vector of predicted response magnitudes by some circuit model. We quantify the error of the model as e=(y−y^)TC−1(y−y^)=∑i=110(yi−y^i)2σi2 where the superscript T denotes the matrix transpose, and i indexes the stimulus condition. Note that e is simply the squared error weighted by the uncertainty in each stimulus condition. Linear regression framework for functional connectivity As discussed in the main text and illustrated by Figure 7A, our model uses functional connections from neurons in the major Pt and aHB response categories to premotor neurons to generate each element of behavior. For example, eight functional connection strengths, from the {oB, B, iB, ioB, iMM, MM, oML, S} major Pt neuron categories (and their rightward selective counterparts) to nMLF neurons, parameterize the forward swimming component of the visuomotor transformation (green lines, Figure 7A). The model parameters for the rightward turning component of the visuomotor transformation also consists of eight functional connection weights, now from the {oB’, B’, iMM’, S’} major right-selective Pt neuron categories and the {oB, B, iMM, S} major left-selective aHB neuron categories to right LHB units. The circuit driving leftward turning is the mirror-reflection of the circuit driving rightward turning. Our task is to understand how the choice of these functional connection weights affects the accuracy of the modeled visuomotor transformation. Since the formalism does not depend on the element of behavior under consideration, we henceforth use abstract notation to describe the general method. Let X denote the n×p response matrix, which comprises the mean fluorescence response of p neurons to each of n stimuli. Note that n = 10 and p = 8 for each type of behavior considered here. For example, the columns of X correspond to the responses of the {oB’, B’, MM’, S’} major right-selective Pt neuron categories and the {oB, B, MM, S} major left-selective aHB neuron categories to the 10 stimulus conditions, when considering rightward turning behavior. We model the visuomotor transformation as a linear combination of these responses y^=Xβ, where β denotes the p-dimensional weight vector of functional connection weights. Choosing the weight vector to minimize e is mathematically equivalent to performing maximum likelihood parameter estimation with the generative model y=Xβ+η, where η is an n-dimensional vector of zero-mean Gaussian noise with covariance matrix C. In particular, the log-likelihood function for this model is l(β)=−12e(β)+A, where A is a constant that does not depend on the model parameters. We thus applied standard techniques from maximum likelihood parameter estimation to compute confidence intervals for the best-fit model parameters (Figures 7B–7D). Similarly, we computed p-values for the model’s predictions regarding the effects of optogenetic activation of a neural activity pattern, x, by considering the null hypothesis that xTβ = 0. Structure of the error function With the assumptions described in the previous sections, the error associated with the visuomotor transformation is a quadratic function of the functional connection strengths e(β)=emin+(β−β^)TH(β−β^), where β^=H−1U is the best fit functional connection strengths (colored bars in Figure 7B), H=XTC−1X is proportional to the Hessian matrix of the error function, and U is defined by U=XTC−1y. The minimal error achievable by the model architecture is emin=yTC−1y−UTH−1U, Let V denote the p×p matrix in which each column is a right eigenvector of H. Then VVT = VTV = I, where I is the identity matrix, Λ = VTHV is a diagonal matrix whose diagonal contains the eigenvalues of H, and VTβ is the weight vector in the basis of eigenvectors of H. The matrices in Figure 7D simply show V for both swimming and right turning behavior. The eigenvectors of H correspond to the principal axes of the quadratic error surface, and we refer to each eigenvector of H as a functional connectivity mode. The basis of functional modes is useful because the error function receives independent contributions from the component of the weight vector along each functional mode, e(β)=emin+∑i=1pλi(γi−γ^i)2, where the λi are eigenvalues of H, γi=(VTβ)i=∑j=1pVjiβj is the projection of β onto the ith mode, and γ^i is the projection of the optimal weight vector onto the ith mode. Note that the black bar plots in Figure 7D show the eigenvalue associated with each functional mode. Departures of β from when the optimal weight induce large errors they project onto modes that are associated with large eigenvalues. Thus, the confidence interval for γ^i is narrow for the modes associated with large eigenvalues. This basis transformation is also useful because the projections of the optimal weight vector along each mode contribute independent error reduction to model. In particular, note that we can rewrite the minimal error as emin=yTC−1y−∑i=1p(VTU)i2λi=yTC−1y(1−∑i=1pri2), where ri2=1yTC−1y(VTU)i2λi. Because the error of the fully disconnected model is yTC−1y, ri2 is the fraction of error eliminated by each mode. The bottom panels in Figure 7D shows ri2 for each mode. Interpreting the functional modes as neural activity patterns In the previous section, we defined V as the p×p matrix in which each column is a right eigenvector of H. If x is a p-dimensional pattern of neural activation across a population of behaviorally relevant major neuron categories, then VTx represents the same activity pattern in the basis defined by the columns of V, and any activity pattern can be written as a linear combination of the columns of V. Thus, we can thus think of the columns of V as defining functional modes of activity. Thus, an activity mode is the pattern of activation that maximizes the projection of the response vector onto the corresponding vector of connectivity weights. In this framework, the functional modes replace the major neuron categories as the elemental components of neural population activity. Figure 7F displays the stimulus response profiles of several functional modes (6F, 7F, 5T, 7T). Each component of the functional connectivity, γi, corresponds to a functional connection strength from one functional mode of activity to a premotor neuron driving behavior. The characterization of the error surface provided in the previous section implies that the functional modes define patterns of activity from which functional connections contribute independently to the accuracy of the modeled visuomotor transformation. The bottom panels of Figure 7D show that the functional modes provide a description of neural activity in which only a few dimensions contribute to the model’s ability to generate appropriate motor activity under the experimental stimulus conditions. QUANTIFICATION AND STATISTICAL ANALYSIS Quantification of swim kinematics Offline behavioral analysis was performed using custom MATLAB scripts (Mathworks, USA). Because we did not assume that data were normally distributed, we used non-parametric statistics for all hypothesis testing. Angular velocity for each fish was calculated as total angle turned over total stimulus presentation time. Single swim bouts were extracted by peak detection in traces obtained via multiplication of orientation change records by box-smoothed (20 ms) swim velocity records (calculated from fish center-of-mass). Latency was calculated as time between motion onset of moving gratings and first detected swim bout. Bout frequency was computed as the total number of detected swim bouts over total stimulus time. Heading angle change for each bout was calculated as orientation directly before (2 ms) and after (10 ms) a detected swim bout. By convention, negative values indicate rightward (or clockwise) and positive values indicate leftward (or counterclockwise) heading angle change. For Figure S1C, we corrected for innate turn biases by subtracting the angular velocity measured during the static stimuli from all other measurements on a fish-by-fish basis before averaging. For all behavioral bar graphs (Figures 1C, 4C, and 4E) error bars represent standard error of the mean (SEM) across fish. For histograms, shaded error is SEM across fish for angle bout type (Figures 1C and 4D). For supplemental figures, consult associated legends. Fictive behavior analysis Analysis of fictive behavior was performed on filtered signals, which consist of the standard deviation of the raw signal in 17 ms time bins. For fictive bout frequency analysis, bouts were marked at peaks in the filtered signal separated by at least 100 ms and crossing an amplitude threshold (adjusted for signal noise: 1 fish at 4.35, 2 fish at 1.95 times the peak baseline noise, as assayed by frequency histogram). Visual stimuli were presented as outlined in two-photon Ca2+ imaging, below. Because baseline fictive swim frequency was reduced relative to freely swimming experiments, we restricted our analyses only to active stimulus epochs (at least 0.1 Hz bout frequency). Functional imaging analysis To generate activity maps (Figures 2E, 2F, S3E, and S3F), fluorescence movies were averaged separately across all frames corresponding to each individual stimulus. A baseline image, the average of all frames during interstimulus periods, was then subtracted from these average images, which were masked to exclude regions outside of the brain. The resulting images, which were thresholded at 0.5* standard deviation (STD) above the mean and eroded and dilated to reduce noise, reflected normalized activity for each stimulus that was less polluted from noise in regions of low baseline fluorescence than traditional ΔF/F maps. These activity images, specific to each individual stimulus, were then combined to produce each type of map. For maps of direction selectivity, activity images for each of the 8 directions of whole-field motion were linearly combined using weighted projections into HSV color space, such that the combined color is related to the vector sum of activity elicited in response to each direction of motion: ultimately, the hue indicates directionality, the value reflects overall motion sensitivity, and the saturation represents the vector magnitude (strength of direction selectivity). For maps of medial/lateral selectivity, activity images for medial and lateral stimulus epochs were combined similarly, with the medial activity image represented in the green channel and the lateral activity image represented in the magenta channel. All other maps were generated analogously, with colors adjusted as indicated. To generate whole-brain activity maps, Figures 2D and S2D, we used a method that better captured correlated activity in neuropil regions, as follows. First, we constructed an average regressor based on strongly responding voxels, as extracted from manual ROIs in persistently active regions, which we deduced were more related to the OMR, given the persistent properties of the behavior. We used this regressor to calculate the correlation coefficient for each pixel time series in every plane of the acquired image stack for each individual stimulus. Maps were then generated by assigning the resulting correlation images to appropriate color channels and combining as in the activity maps above. Map shown in Figure 2D is a maximum intensity projection through 135 μm of brain tissue, with ventral AF10 as the most dorsal plane. The quantifications of pretectal data presented in Figure 3 were based on ROI selection using a method adapted from Ahrens et al. (2013a). For this analysis, an activity map for each imaged plane was first extracted by sweeping a square ROI roughly equal to half the size of a cell body across the spatial extent of an imaging movie. For each swept ROI, the spatially averaged fluorescence time series was normalized by the ROI’s mean fluorescence across time and the average fluorescence of all pixels across space and time. This signal was then cubed to amplify peaks, and each square’s average processed signal was assigned to each square’s spatial location. This analysis produced maps of activity that were robust to noise in regions of low baseline fluorescence. These activity maps were then overlaid on mean fluorescence images (reflecting anatomy) and used to guide manual neuron ROI selection. To make composite maps of the pretectal population across fish, all imaged planes were registered to a standard Tg(elavl3:GCaMP2) brain, which has an expression pattern indistinguishable from Tg(elavl3:GCaMP5G), using cross-correlation. Fluorescence traces from these ROIs were then divided by a stable baseline amplitude averaged across all interstimulus intervals to generate ΔF/F traces. The means of trial-averaged ΔF/F for individual stimuli were then used to calculate functional indices. Binocularity index was calculated as [(xM or xL)max – (Mx or Lx)max]/[(xM or xL)max + (Mx or Lx)max], where xM and xL are right-eye monocular medial and lateral responses, respectively, and Mx and Lx are left-eye monocular medial and lateral responses, respectively. By construction, a value of 0 corresponds to equal activation by left and right eyes, and −1 and 1 correspond to exclusive activation by the left or right eye, respectively. The inward medial-medial suppression index was computed as [(xM or Mx)max – MM]/[(xM or Mx)max + MM], where MM is the response to inward motion. By construction, an index of 0 corresponds to no suppression and an index of 1 indicates that medial motion in the contralateral eye completely suppresses the response to medial motion in the other. The outward lateral-lateral suppression index was calculated analogously. To restrict indices to the [−1 1] range, all values were thresholded at 10% ΔF/F (calculated noise floor) to exclude negative ΔF/F deflections (or suppressed responses), which we did not integrate into our indices. To calculate direction selectivity vectors, we performed a vector sum of responses to the 8 directions of motion after normalizing to the maximum response across all directions. For automatic ROI segmentation (Figures 2 and 6), we adapted a method from Portugues et al. (Portugues et al., 2014). In brief, we performed a neighborhood correlation analysis for each pixel in each plane of the fluorescence movie to generate maps of local correlation. This metric was typically high for pixels within the same cell body and discrete, local regions of high local correlation were easily segmented into individual ROIs automatically by seeding an ROI at a pixel with a local correlation maximum and growing the ROI spatially until the correlation dropped below a fixed threshold (0.15). To support ROI selection at the single cell level, ROIs were also limited in size between 30 and 200 pixels, or cells approximately 1.7 to 4.3 microns in radius at standard imaging resolution. Because this method was blind to the underlying anatomy, this automatic ROI segmentation also selected correlated regions of neuropil that met the stated size requirements. Classification of functional response types As we were confronted with complex response patterns in each brain region (Figure S6; Movie S2), we classified neural response types with barcode analysis. We assigned each neuron an 8-bit barcode (Kubo et al., 2014), which encodes whether or not the neuron significantly increased its fluorescence upon motion onset for each of the coherent, monocular, and conflicting stimuli. ΔF/F fluorescence traces for ROIs were trial-averaged for each individual stimulus (Figure 1B) but excluding forward and backward epochs, as we were primarily interested in how information from both eyes was combined. The resulting traces were then baseline corrected with a first-degree polynomial fit to the baseline period. We then assessed whether activity during stimulus periods was significantly different from its baseline. For a given neuron and stimulus, if the mean of the trial-averaged signal exceeded 1.8*STD above its baseline, then the neuron was assigned a ‘1’ for that particular stimulus; otherwise, it was assigned a ‘0.’ This resulted in a binary barcode for each neuron across all stimuli in the orthogonal set. Based on these 8 stimuli, neurons could fall into 256 (28) different response combination classes. This method, and the associated significance threshold, provided the most consistent classification across fish during visual inspection of individual neurons, and deviations from this threshold did not markedly change relative frequency distributions. While we tried other clustering methods, our barcode technique provided the most intuitive results reflecting the stimulus-behavior relationship. Other methods we tested, like k-means clustering, required arbitrary parameterizations of the data (like estimated number of clusters). We labeled a response class as over-represented if, in sorted histograms of class frequency, the class (or its mirror-symmetric partner) was separated from the others by a graphical non-linearity (see Figure 5C) and was present in all fish. These functional response types allowed us to summarize this heterogeneity in our model. Although studies have analyzed heterogeneous population responses without classifying neurons, our classification helped us in several ways. First, a model that references response types rather than individual neurons can make predictions for how activity of sub-populations of neurons will translate into behavior. Second, Kubo et al. classified Pt responses during the OKR using this scheme (Kubo et al., 2014), permitting a comparison of Pt responses across behaviors. Third, response type classification helped us to identify elements of the representation that transformed across brain areas. Fourth, certain response types had a natural interpretation (e.g., Pt relay neurons). These neuronal response classes could have subtypes that are crucial to more complex behaviors and stimuli. For analyses where relative differences in activity across stimuli were most meaningful (e.g., Figure 2F, right, Figure 3B, left, Figure 5B), we used normalized ΔF/F metrics. In these cases, we calculated trial-averaged ΔF/F traces for each ROI and then divided by the maximum ΔF/F value across all time points and stimuli. These normalized traces were then averaged across ROIs (where indicated). All ΔF/F metrics using single values from stimulus epochs (Figure 2F, right, Figure S3E, bottom, Figure S3F, bottom, Figure S3G, Figure 3B, left, Figure 3D) were calculated as mean normalized ΔF/F across all time points during each respective stimulus presentation. DATA AND SOFTWARE AVAILABILITY Data Resources We are providing two supplemental data files (Tables S1 and S2) containing information for the pretectum and anterior hindbrain for each response type, including frequency, average peak calcium response, and identifying metadata (e.g., monocular versus binocular, barcode representation). Other data on behavior or imaging will be made available upon request. Software Software for data acquisition, analysis and quantitative modeling will be made available upon request. Supplementary Material 1 2 3 4 Supplementary Material ACKNOWLEDGMENTS We thank Michael Orger for providing Tg(alpha-tubulin:PA-GFP) fish and Michael Orger, Drew Robson, and Jennifer Li for providing Tg(elavl3:GCaMP5G) fish. Misha Ahrens, Isaac Bianco, and Martin Haesemeyer helped with useful discussions. Furthermore, we thank Ruben Portugues, Mariela Petkova, Andrew Bolton, Bence Ölveczky, and Alexander Schier for reading the manuscript and providing feedback, we thank Adam Kampff for help with software development and rig design; NIH grants U01NS090449, DP1 NS082121; the Simons Foundation SCGB#325207, R24NS086601; the European Research Council; and the Marie Curie Fellowship provided financial support. Figure 1 Eye- and Direction-Specific Optic Flow Evoke Distinct Orienting and Locomotion Patterns (A) Behavioral setup. Left, freely swimming fish are monitored with a camera while moving gratings are presented. Heading (Δν) and position (Δx, Δy) are extracted to lock visual motion direction to body axis. Right, illustration of each monocular visual field (purple, green, 163°) and the small binocular overlap (dark gray, 12°). Scale bar, 500 μm. (B) Stimulus set composed of static, medial and lateral motion, and forward and backward stimuli. Arrowheads indicate motion direction. Circular icons represent eyes, and white tick marks show the direction of motion. These icons and colors are used throughout the paper. (C) Bar graph of average angular velocity (heading direction change per second) during behavioral responses. The white bar represents the linear combination of monocular medial and lateral motion. Error bars are SEM across fish (n = 38). (D) Average histograms of absolute frequency per swim bout angle. Left, conflicting stimuli affect forward swim frequency (center peak, added “swims”) relative to the static condition (inward versus static, p = 6.6 × 10−6; outward versus static, p = 7.7 × 10−8, paired Wilcoxon). Inward reciprocally suppressed turns (open circles). Middle, left/right stimuli increased correct (in motion direction, filled circles) and decreased incorrect (opposite of motion direction, open squares) turn frequency (inset). Medial enhanced but monocular lateral stimuli suppressed swimming (lateral versus static, p = 0.006). Shaded error is SEM, n = 38. Right, forward stimuli increased, backward stimuli significantly reduced forward swim frequency (versus static, p = 2.1 × 10−6). n = 30. (E) Comparison of measured bout frequencies and minimal model output. DSRGCs connect to motor centers for forward swimming (F) and left (TL) and right turning (TR). Left, forward swimming. Each point is the mean peak response to a stimulus; lighter center indicates leftward motion. Right, turning behavior. correct turns, filled circles; incorrect turns, open circles; non-directional stimuli, open squares. Model input-output functions for each behavioral component, top right and left. Dotted lines indicate baseline rates. Figure 2 Whole-Brain Activity Maps Reveal Processing Stages Underlying the OMR (A) Dorsal overview of zebrafish neuroanatomy. DSRGCs (black dots) project via the optic chiasm (OC) to ten contralateral retinal arborization fields (AFs). Pt, pretectum; nMLF, nucleus of the medial longitudinal fasciculus; aHB, anterior hindbrain; RoL, neurons in rhombomere 1; ARTR, anterior rhombencephalic turning region; vSPNs, ventromedial spinal projection neurons; cHB, caudal hindbrain; M/HB, midbrain-hindbrain border; rh1–5, rhombomeres 1–5. A, anterior; P, posterior. (B) Distribution of all motion-sensitive units (n = 76,604) across 14 Tg(elavl3:GCaMP5G) fish. Each unit is a dot, color coded for preferred motion direction (see Dir. color wheel). Bottom left, histogram of direction preference. Scale bars, 50 μm. (C) Histograms of direction preference for specific brain regions. (D) Binocular activity map generated from sequential presentation of monocular leftward motion to each eye. Pixels are colored for medial versus lateral preference (STAR Methods). Binocular regions appear white. Anatomy in gray. (E) Left, two-photon micrographs from single AF6 and Pt planes. Right, average ΔF/F for regions of interest (ROIs) (dashed white lines). Gray rectangles indicate stimulus presentation periods. Shaded areas are SEM over n = 10 stimulus repetitions. (F) Left, responses to eight whole-field motion stimuli, see color wheel, top. Right, polar plots (±SEM, shaded area) of average normalized ΔF/F in n = 7 fish. Figure 3 Population Activity in the Pretectum (A) Left, direction selectivity vectors for neurons in the Pt (see color wheel, top). Gray, magnitudes smaller than 0.4; black, population average vectors. Right, anatomical distribution of direction preference. A, anterior; P, posterior; L, left; R, right. Dashed line, brain midline. (B) Left, Linear binocular integration of normalized ΔF/F responses. *p = 1.2 × 10−37, paired Wilcoxon. Bars are mean ± SEM across all neurons. Right, scatterplot of individual Pt neuron responses. Red, least-squares regression line; dashed black, unity line. (C) Histogram of Pt neuron suppression indices (STAR Methods). (D) Normalized ΔF/F to conflicting motion for neurons preferring either backward (−135° to +135°, n = 191) or forward (−45° to +45°, n = 678) motion. Figure 4 Laser Ablation of Posterior Commissure Disrupts Binocular Integration (A) The posterior commissure (PC) connects the left and right Pt, providing a putative conduit for lateral excitation (purple arrow) and medial inhibition (green triangle). Red spiral, target for laser ablation. (OC) optic chiasm. (TL) motor center for turning. (B) Left, anatomy before (top) and after (bottom) PC ablation. Red spiral, ablation site. Red arrowheads, bottom, tissue debris (compare to top). Right, average ΔF/F before (colored) and after (gray) PC ablation for the three ROIs. n = 6 stimulus repetitions. Vertical lines represent stimulus presentation periods. (C) Average orientation change per bout in control (n = 38 fish) and ablated (post, n = 14 fish) animals. Inset, difference between coherent binocular and monocular medial responses (p = 6.2 × 10−5, unpaired Wilcoxon). C, control; P, post. Post-ablation monocular lateral versus static baseline, p = 0.2; Post-ablation coherent versus control monocular medial, p = 0.08. (*) p < 10−4, n.s., not significant, p > 0.05. (D) Average histograms of absolute frequency per bout angle post-ablation (n = 14 fish). (E) Change in peak turn probability (post-ablation minus control) for incorrect and correct turns. *p < 0.05. (F) PC ablation reveals effect of medial motion on behavior. Medial motion activates the contralateral nMLF directly and the ipsilateral nMLF indirectly via the PC to drive forward swimming (F). Medial motion suppresses incorrect turns (TL) via the PC but also via other interhemispheric connections, potentially in the hindbrain. Figure 5 Pretectal Neurons Cluster into Distinct Functional Response Types (A) Heatmap of mean normalized ΔF/F within monocular and binocular response categories (STAR Methods). Column width, relative frequency neuron types; brightness, mean normalized ΔF/F. Top types: oB, outward-responsive binocular neuron; B, binocular; iB, inward-responsive binocular; ioB, inward- and outward-responsive binocular; iMM, inward-responsive monocular (medial-selective); MM, monocular (medial-selective); oML, outward-responsive monocular (lateral-selective); S, selective for coherent motion. (‘) matching right-selective types. (B) Left, average normalized ΔF/F for the top 8 left-selective response types, ranked by frequency. Shaded area, SEM across neurons. Mirror-symmetric right-selective types in Figure S5D. Right, average direction selectivity. Vector width is bootstrapped standard error for each x and y vector component. (C) Sorted histograms of response type frequency. Major Pt types (dashed boxes) lie above the indicated discontinuity threshold (gray line, STAR Methods). (D) Hypothesized circuit for generating Pt types via monocular relay neurons. In this example, the B neuron is activated by leftward medial and lateral but inhibited by rightward medial and lateral motion. (E) Left, Model using overrepresented Pt response types generated from relay neurons that integrate DSRGCs signals. Pt neurons project ipsilaterally to left and right turning centers (TL, TR) and to a forward swimming center (F). Right, comparison of measured bout frequencies and minimal model output. Insufficient suppression of Pt neurons caused model failure for incorrect turns (open squares, inset). Figure 6 Hindbrain Circuitry Refines Turning Behavior (A) Distribution of all motion-sensitive units with higher peak ΔF/F responses to any direction over forward (n = 44,047, n = 14). Each unit is color coded for preferred direction of motion. Anatomical labels as in Figure 2. (B) Average normalized ΔF/F in response to each stimulus for the four overrepresented aHB response types (left selective). Right, average direction selectivity vectors for each respective class (cf. Figure 5B). Neurons named as in Figure 5. (C) C1 Distribution of all binocular units (B), colored for preferred motion direction. C2 B units activated by forward and backward motion. C3 Left, B units without significant responses to forward and backward motion. Right, motion-opponent B units suppressed by the opposite direction of motion. Traces show mean normalized ΔF/F traces for each population of B units. (*), active above baseline (>1.8*STD); arrowhead, suppressed below baseline (< −1.8*STD); circles, no significant response. Figure 7 Neural Network Modeling Identifies Significant Dimensions of Functional Connectivity (A) Model incorporating hindbrain circuitry. Green, F, forward premotor units. Gray circles, Pt neurons projecting to the ipsilateral early hindbrain (EHB, ovals) and late hindbrain (LHB). Red, T, turn premotor circuitry. Neurons numbered as in Figures 5B and 6B. (B) Best-fit connection strengths (95% confidence intervals) between neuron types and premotor units. Only two types predict significant non-zero connections (darker bars). (C) Left, model error as a function of connectivity strength between neuron type 1 and F and neuron type 2 and F; all others connected by best-fit connection strengths. Right, while Pt neurons do not behave independently, we identified independent dimensions of population connectivity (functional modes) by rotating the error surface. Each axis now corresponds to a pattern of activation and suppression across neuron types (STAR Methods). (D) Top, independent connectivity patterns for neuronal response types (rows) within each functional mode (columns), sorted according to the model’s sensitivity to perturbations in the direction of each mode (black bars, top). Bottom, fraction of error eliminated by each mode. (*) modes with a reliable influence on behavior (STAR Methods). (E) Illustration of how modes contribute to model output in response to stimuli (here shown only for coherent rightward motion). (F) The behavioral output associated with individual swimming modes (ModeF) and turning modes (ModeT). Top two rows show output for the two most significant swimming (left) and turning (right) modes. Bottom row shows collective output for the six most and two most significant swimming and turning modes, respectively. Bars are colored by stimulus identity. (G) Quantitative whole-brain model for the OMR, reflecting the best-fit connectivity in Figure 7B. Neuron types are represented by symbols illustrating activation and suppression by motion stimuli (see legend). Highlights Optomotor response is driven asymmetrically but linearly by visual motion to each eye Dedicated circuits differentially process eye- and direction-specific motion Neural representations are distributed over select overrepresented response types Behavior as well as neural activity is captured by realistic whole-brain circuit model In Brief Whole-brain imaging and behavioral analysis combined with network modeling reveal key circuit elements contributing to a complex sensorimotor behavior in zebrafish larvae and provide a framework for building brain-level circuit models. STAR*METHODS Detailed methods are provided in the online version of this paper and include the following: KEY RESOURCES TABLE CONTACT FOR REAGENTS AND RESOURCE SHARING EXPERIMENTAL MODEL AND SUBJECT DETAILS ○ Zebrafish METHOD DETAILS ○ Behavior in freely swimming zebrafish ○ Fictive behavior ○ Two-photon Ca2+ imaging ○ Tracing pretectal projection patterns ○ Two-photon laser ablations ○ Quantitative modeling QUANTIFICATION AND STATISTICAL ANALYSIS ○ Quantification of swim kinematics ○ Fictive behavior analysis ○ Functional imaging analysis ○ Classification of functional response types DATA AND SOFTWARE AVAILABILITY ○ Data Resources ○ Software SUPPLEMENTAL INFORMATION Supplemental Information includes seven figures, two tables, and two movies and can be found with this article online at http://dx.doi.org/10.1016/j.cell.2016.10.019. AUTHOR CONTRIBUTIONS F.E. and E.A.N. conceived of the project. E.A.N. and T.W.D. performed the experiments. E.A.N., J.E.F., and T.W.D. analyzed data. 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PMC005xxxxxx/PMC5112117.txt
LICENSE: This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. 9432918 8591 Immunity Immunity Immunity 1074-7613 1097-4180 27793595 5112117 10.1016/j.immuni.2016.10.005 NIHMS821381 Article Dendritic Cells Regulate Extrafollicular Autoreactive B cells via T cells Expressing Fas and Fas Ligand Ols Michelle L. 1 Cullen Jaime L. 1 Turqueti-Neves Adriana 3 Giles Josephine 23 Shlomchik Mark J. 3* 1 Department of Laboratory Medicine, Yale University School of Medicine, New Haven, CT 06519, USA 2 Department of Immunobiology, Yale University School of Medicine, New Haven, CT 06519, USA 3 Department of Immunology, University of Pittsburgh School of Medicine, Pittsburgh, PA 15261 * Correspondence and Lead Contact: Mark J. Shlomchik, mshlomch@pitt.edu 7 10 2016 25 10 2016 15 11 2016 15 11 2017 45 5 10521065 This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. The extrafollicular (EF) plasmablast response to self-antigens that contain Toll-like receptor (TLR) ligands is prominent in murine lupus models and some bacterial infections, but the inhibitors and activators involved have not been fully delineated. Here, we used two conventional dendritic cell (cDC) depletion systems to investigate the role of cDCs on a classical TLR-dependent autoreactive EF response elicited in rheumatoid-factor B cells by DNA-containing immune complexes. Contrary to our hypothesis, cDC depletion amplified rather than dampened the EF response in Fas-intact but not Fas-deficient mice. Further, we demonstrated that cDC-dependent regulation requires Fas and Fas ligand (FasL) expression by T cells, but not Fas expression by B cells. Thus, cDCs activate FasL-expressing T cells that regulate Fas-expressing extrafollicular helper T cells (Tefh). These studies reveal a regulatory role for cDCs in B cell plasmablast responses and provide a mechanistic explanation for the excess autoantibody production observed in Fas-deficiency. Graphical abstract INTRODUCTION B cells are pivotal in the development of systemic autoimmune diseases, which are characterized by the selective loss of tolerance to self-Ags such as DNA, RNA, and IgG (Shlomchik, 2009). In addition to autoantibody-mediated damage, B cells promote disease by stimulating T cell activation and expansion, presumably via antigen (Ag) presentation, and possibly through cytokine secretion (Shlomchik, 2009). Autoreactive B cells are often activated in extrafollicular (EF) foci, via co-ligation of B cell receptors (BCRs) and toll-like receptors (TLRs) by antigens (Ags) containing DNA and RNA. These autoreactive, EF-localized, TLR-driven B cell responses consist of short-lived plasmablasts, as found in MRL/MpJ-Faslpr/J (MRL.Faslpr), and other autoimmune mouse models, such as NZB/W, as well as in human disease (Daridon et al., 2012; Hoyer et al., 2004; Tipton et al., 2015). The EF response is not restricted to autoimmunity, and perhaps evolved to provide pathogen-specific protection. Indeed, EF B cell foci develop in response to various types of T-dependent (TD) and T-independent (TI) Ags, including viruses and bacteria (Cunningham et al., 2007; Di Niro et al., 2015; Maclennan et al., 2003). Such pathogen-induced EF responses are normally transient, indicating that they are tightly regulated. However, in the case of autoimmunity, EF responses persist for the life of the animal, becoming sites of extensive and prolonged clonal expansion, hypermutation, and affinity maturation (William et al., 2002; William et al., 2005b). How normal EF responses become dysregulated in autoimmunity remains unclear. To study how autoreactive EF B cell responses are regulated, we have used mice transgenic (Tg)—either ectopically inserted or site-directed (sd)—for an immunoglobulin (Ig) heavy chain encoding the anti-IgG2aa rheumatoid factor (RF), AM14 (Sweet et al., 2010). In autoimmune prone MRL.Faslpr and MRL/MpJ mice, AM14 B cells spontaneously expand, class switch, hypermutate and develop into antibody forming cells (AFCs) within EF foci in the spleen (Sweet et al., 2010; William et al., 2002; William et al., 2005b). This spontaneous, TLR-dependent autoactivation occurs in vivo by AM14 BCR binding to DNA- and RNA-containing immune complexes (ICs) (Herlands et al., 2008). We can also induce EF AM14 activation on the BALB/c background by administration of a model physiologic ligand, the IgG2aa anti-chromatin antibody, PL2-3 (Herlands et al., 2007), which results in a plasmablast response that is phenotypically and histologically indistinguishable from the spontaneous model. Like the spontaneous RF and anti-nuclear response, the PL2-3-induced response is TLR7, TLR9, and MyD88 dependent, as well as autoantigen-specific (Herlands et al., 2008). In contrast to the unpredictable onset and variable magnitude of the spontaneous system, the PL2-3 induced response enables precise timing and a directed approach for determination of proximal factors required for autoreactive EF B cell activation. Thus, the PL2-3 induced response has been used by a number of labs to study how a classical autoreactive B cell response is induced (Giltiay et al., 2013; Nundel et al., 2015; Sang et al., 2014). We initially hypothesized that cDCs are critical supporting cells for the EF response, in part because cDCs are prominent components of such EF foci (Maclennan et al., 2003; William et al., 2002). An activating role for cDCs in the EF response has been inferred from experiments in which anti-CD40 was used to induce cDC proliferation, and appeared to thereby increase EF plasmablast survival in response to a TI-2 Ag (Maclennan et al., 2003). Although cDCs are best known for their interactions with T cells, a small body of literature indicates that cDCs can promote B cell activation. cDCs secrete factors, such as B cell activating factor (BAFF), a proliferation inducing ligand (APRIL), and interleukin-6 (IL-6), which support B cell development, activation and differentiation (MacLennan and Vinuesa, 2002; Mohr et al., 2009). cDCs have also been shown to deliver Ag to, and directly interact with, B cells in lymph nodes (Gonzalez et al., 2010; Qi et al., 2006), and in the spleen (Balázs et al., 2002), thereby promoting B cell activation and the development of humoral immunity. In particular, via a non-degradative Ag uptake and processing pathway, cDCs can present whole Ag on their cell surface to B cells (Bergtold et al., 2005; Zelenay et al., 2012). Although these data suggest that cDCs might aid B cell responses, a more direct cDC ablation study has shown that cDCs are not required for the generation of an EF TI-2 response to 4-hydroxy-3-nitrophenylacetyl (NP)-Ficoll (Hebel et al., 2006), calling into question earlier conclusions that DCs played nonredundant roles. The autoreactive response to nucleic acids and to the ICs containing them has characteristics of TI-1, TI-2 (Herlands et al., 2008), and TD responses (Sweet et al., 2011). Such nucleic acid-driven responses are therefore likely to be regulated differently from TI-2 responses. In addition, chromatin-containing immune complexes (ICs) have a distinctive capacity to stimulate myeloid cells through both the Fc gamma receptor (FcγR) and TLRs (Boulé et al., 2004). To ask whether cDCs are required for the activation of this type of autoreactive B cell response, we employed both acute (Jung et al., 2002) and constitutive (Birnberg et al., 2008; Teichmann et al., 2010) cDC ablation systems. Both cDC-depletion systems yielded the finding that cDCs negatively regulate, rather than activate, this autoreactive B cell response. Furthermore, we found that this cDC regulatory effect was dependent on Fas and was not observed in Fas-deficiency. We further determined that cDC-dependent regulation of the EF response required Fas and FasL expression by T cells; whereas, Fas expression on B cells was not relevant for this effect. We thus propose that cDCs activate FasL-expressing T cells to regulate Fas-expressing T cells that, in turn, help B cells in EF sites. In addition to revealing a clear regulatory role for cDCs, these studies elucidate an additional mechanism whereby Fas controls autoreactive EF plasmablast responses, helping explain how Fas-deficiency promotes hypergammaglobulinemia, high autoantibody titers, and autoimmunity. RESULTS The EF AM14 Rheumatoid Factor Response Does Not Acutely Require, but is Regulated by, cDCs To determine whether cDCs are required for the generation of the EF AM14 rheumatoid factor B cell response, we made radiation chimeras with bone marrow (BM) from mice expressing the diphtheria toxin (DT) receptor (DTR) and green fluorescent protein (GFP) under a Itgax promoter (Itgax-DTR) (Jung et al., 2002), administered DT to deplete cDCs, transferred in sd-Tg AM14 B cells, and injected the activating Ag, PL2-3 (schema in Figure S1). Repeated DT treatment is well tolerated in BM chimeras (Zammit et al., 2005). Because the transferred AM14 B cells do not carry the Itgax-DTR locus, CD11clo AM14 plasmablasts are not deleted by DT in this system (Hebel et al., 2006). The AM14 cells with rheumatoid factor specificity were tracked by ELISpot analysis and flow cytometry using the anti-idiotype marker, 4-44. Notably, we observed 3, 5, 4 and 7-fold increases in the numbers of 4-44+ AM14 cells, CD22lo CD44hi plasmablasts, IgM and IgG2a antibody forming cells (AFCs), respectively, in cDC-depleted hosts as compared to controls (Figure 1). The location of the response in the cDC-depleted animals was EF (Figure S2), similar to that observed in untreated controls, and as reported (Herlands et al., 2008; Herlands et al., 2007; Sweet et al., 2011; William et al., 2002). Few, if any 4-44+ peanut agglutinin (PNA)+ germinal centers (GCs) could be detected by histology at day 6 (not depicted). These data indicate that cDCs are not required for, and—given the several-fold enhancement in their absence—may regulate, the EF AM14 response. cDCs are not Required Constitutively for the AM14 Response Although acute depletion of cDCs suggested that they are not required for the activation of AM14 B cells, it remained possible that essential cytokines produced by cDCs are retained in the extracellular matrix (Mohr et al., 2009), in which case acute cDC depletion would not reveal an effect of cDCs on B cell activation. We were also concerned that acute local DT-induced cDC death could provide an additional source of chromatin Ag, that could account for the increased AM14 response observed in the acute cDC ablation system. To address these issues, we generated recipient mice constitutively lacking cDCs by crossing mice expressing the Rosa26-flox-stop-DTA locus (Ivanova et al., 2005) to mice expressing Itgax-Cre (Caton et al., 2007), which we call ΔDC mice. We had both strains of these mice fully backcrossed onto the MRL.Faslpr background (Teichmann et al., 2010), which were suitable for our studies, because we used young, pre-diseased animals, as previously reported (Herlands et al., 2007). As had been shown for ΔDC mice, there was extensive depletion of cDCs and a substantial loss of pDCs as well as increased CD11b+ cells (Birnberg et al., 2008; Ohnmacht et al., 2009; Teichmann et al., 2010) (Figure S3). We transferred sd-Tg AM14.MRL. Faslpr B cells into these recipients on day 0, administered the activating Ag, PL2-3 on days 0, 2 and 4, and assessed the response on day 6. In contrast to our acute ablation experiments in BALB/c mice, EF AM14 B cell responses in ΔDC MRL.Faslpr mice were similar to those of control recipients (Figure 2). These results confirm that cDCs are not required either acutely or constitutively for the activation of the autoreactive AM14 B cell response. That cDCs were not required for the EF response was somewhat unexpected, because MacLennan and colleagues have concluded that cDCs are a limiting factor in plasmablast generation and survival in response to TI-2 Ags (Maclennan et al., 2003). Additionally, since we did not observe enhanced EF responses in ΔDC mice, it remained possible that acute DT-induced cDC death within the spleen of Itgax-DTR mice enhanced the AM14 B cell response. Regulation of the AM14 Response by cDCs Requires Fas However, another important difference between the acute and the constitutive cDC ablation systems was the genetic background of the mice: BALB/c in the former, and MRL.Faslpr, in the latter. Because Fas-deficient mice have prominent spontaneous autoreactive EF responses (Shlomchik, 2009; William et al., 2002), it was possible that Fas could limit this EF response in normal mice. If this role of Fas were cDC-dependent, then depletion of cDCs in Fas-intact BALB/c mice would result in an increased response, as we observed (Figure 1). However, in Fas-deficient mice, cDC elimination would have no effect on the response, as we also observed (Figure 2). This logic is shown schematically in Figure S4. To test this idea, we compared constitutive cDC depletion on the same MRL genetic background, but in the presence or absence of functional Fas. Notably, in Fas-sufficient ΔDC MRL.Faslpr/+ mice, there was a large enhancement (3, 9, 2, 5, and 4 fold, respectively) of splenic 4-44+ AM14 B cell and plasmablast numbers, as well as, IgM, IgG2a, and IgG2b AFCs, compared to control recipients (Figure 3). Again, this AM14 response was EF (Figure 3G and S5). Hence, enhancement of the EF AM14 response upon cDC depletion was seen in both acute and constitutive cDC depletion, but only when Fas was intact. Therefore, we conclude that cDCs regulate the EF AM14 plasmablast response via a Fas-dependent mechanism. Fas-Dependent cDC Regulation of the AM14 Response is AM14 B Cell Extrinsic Next, we investigated which cell type was required to express Fas for proper regulation of the response. Because EF helper T cells (Odegard et al., 2008) enhance AM14 B cell expansion (Sweet et al., 2011), it was possible that FasL-killing of Fas-expressing helper T cells could limit EF B cell responses. Alternatively, because B cells are sensitive to FasL-mediated killing (Rothstein et al., 1995), Fas-expressing AM14 B cells could be directly targeted. To distinguish these possibilities, we transferred Fas-deficient sd-Tg AM14.MRL.Faslpr B cells into Fas-sufficient ΔDC.MRL.Faslpr/+ mice or littermate controls, and induced the AM14 response with PL2-3 (Figure 4). Although caution is required in comparing across experiments, as expected, the response size of these Fas-deficient B cells appeared larger than what we had observed in prior experiments. However, if Fas expression on B cells were responsible for cDC-dependent regulation of AM14 B cells, we would have expected to see, upon transfer of Fas-deficient B cells, similar responses within the ΔDC and cDC-intact mice. Rather, we still saw a large enhancement of the AM14 response within ΔDC recipient mice as compared to controls, even when the B cells could not have been influenced by FasL. In fact, the splenic 4-44+ AM14 B cell, plasmablast, and IgM, IgG2a, and IgG2b AFC numbers were 10, 20, 4, 9, and 9 fold higher, respectively, in recipients lacking cDCs than in controls. Thus, we conclude that cDCs regulate EF autoimmune responses in a Fas-dependent, B cell-extrinsic manner. Recipient Mice Lacking Fas, cDCs, or Both Have Higher Numbers of Activated CD4+ T Cells than Control Mice Since Fas-dependent killing of B cells was not the mechanism for Fas-dependent regulation of the AM14 B cell response by cDCs, regulation must depend on a different cDC-dependent, Fas-expressing cell. T cells that help the EF response (Lee et al., 2011; Odegard et al., 2008) would be a leading candidate for such a Fas-expressing cell. Reciprocally, FasL expression could be required either on other T cells or on cDCs (Lu et al., 1997; Süss and Shortman, 1996; Van Parijs and Abbas, 1996) in order to kill the Fas-expressing EF helper T cell (Tefh). The notion that cDCs could activate both Fas-sensitive Tefh and FasL-expressing killer T cells is reasonable, because T cells are regulated by Fas-FasL interactions (Van Parijs and Abbas, 1996), and cDCs can both activate and regulate T cell responses (Reis e Sousa, 2006). Furthermore, T cells can promote AM14 activation and differentiation via CD40L and IL-21 (Sweet et al., 2011). With these possible cDC-T and T-B interactions in mind, we first assessed our three systems of AM14 B cell transfer into ΔDC mice for cDC and Fas-dependent alterations in T cell activation (Figure 5). Fas-intact ΔDC MRL mice had a higher proportion of CD4+ T cells that were CD44hi, CD62Llo than the cDC-sufficient littermate controls. Absolute numbers of this T cell subset were also elevated. These cDC-dependent differences in the T cell compartment were Fas-dependent, because the increases were only seen in Fas-sufficient and not Fas-deficient MRL recipients. Of note, similar differences were present even in mice that had not received Ag or B cell transfer, although Ag injection with B cell transfer also enhanced T cell activation above controls (Figure S6). Further analysis of DT-treated Itgax-DTR.BALB/c bone marrow chimeras revealed that the increase in CD4+ T cells observed in DC-depleted mice included an increase in the PD-1+. Bcl-6+ Tefh cell subset (Figure S6). These data imply that cDC-dependent regulation of AM14 B cells involves the elimination of Fas-expressing Tefh cells. Regulation of AM14 Plasmablasts by cDCs Requires T Cells Expressing Fas and FasL To more definitively determine cell-specific roles for Fas and FasL in limiting autoreactive EF plasmablast responses, we performed a series of mixed bone marrow (BM) chimera experiments. First, we made mice in which irradiated BALB/c recipients received a mix of donor BM that was 80% from BALB/c.Tcra−/− mice and 20% from BALB/c.Faslpr mice. Thus, all T cells within the chimeric animals lacked Fas, while other cell types had normal Fas expression on the great majority of their cells (Figure 6). Control animals received BM that was either 100% BALB/c or a mix of 80% BALB/c.Tcra−/− and 20% BALB/c. In these experiments, when T cells lacked Fas, the AM14 B cell response was enhanced by 3, 7, and 10 fold for IgM, IgG2a, and IgG2b AFCs, respectively. Finally, we made mice in which irradiated BALB/c recipients received a mix of donor BM that was 80% from BALB/c.Tcra−/− mice and 20% from BALB/c.FasLmut mice (Gregory et al., 2011). In these chimeras, no T cells had active FasL, while other cell types were normal (Figure 7A-F). Control mice received BM that was either 100% BALB/c or a mix of 80% BALB/c.Tcra−/− and 20% BALB/c. Here, when T cells could not signal via FasL, AM14 IgM, IgG2a, and IgG2b AFC numbers were 2, 3, and 8 fold higher, respectively. As expected, when T cells lacked either Fas or FasL, an activated T cell subset was elevated in frequency (Figures 6F, G & 7F, G). These experiments confirm that cDC-dependent regulation of autoreactive plasmablasts requires FasL-expressing T cells to regulate Fas-expressing Tefh cells. Loss of cDCs Reduces Cell Death of Splenic CD4+ T Cells During the AM14 B Cell Response To determine if cDCs increase the ability of FasL-expressing T cells to kill Fas-expressing helper T cells during the AM14 B cell response, we used the TUNEL assay to detect apoptotic cells in tissue sections of DT-treated Itgax-DTR.BALB/c bone marrow chimeras. Indeed, less TUNEL+ CD4+ cells were detected in cDC-depleted than control mice (Figure 7G,H). These data further support the idea that cDC-dependent regulation of AM14 B cells involves the killing of Fas-expressing helper T cells by FasL-expressing T cells. DISCUSSION In normal responses to non-replicating TI and TD Ags, the EF response is transient (Maclennan et al., 2003), though the mechanisms that constrain it are not yet defined. A limiting component is likely the inherent propensity of plasmablasts to die, which does not depend on Fas (Do et al., 2000; Ursini-Siegel et al., 2002; William et al., 2005a). Although regulatory T (Treg) cells can restrain humoral immunity, they have been implicated in GC, rather than EF responses (Sage and Sharpe, 2015), and Treg cell neutralization with the anti-CD25 Ab PC61 had no effect in our system (not depicted). Determining the identity and function of the negative regulators of EF plasmablasts is important for understanding both normal (Di Niro et al., 2015) and pathogenic, autoimmune responses. That the EF plasmablast response was greatly enhanced in the absence of cDCs was an important and unexpected finding, as it revealed a regulatory rather than stimulatory role for cDCs in the humoral immune response. That cDCs were not even required for the EF response was also somewhat unexpected based on prior reports, albeit in different contexts. MacLennan and colleagues have concluded that cDCs are a limiting factor in plasmablast generation and survival in response to TI-2 Ags (Maclennan et al., 2003). CD11c+ cells are also prominently seen in juxtaposition with dividing and differentiating EF AM14 B cells (William et al., 2002), supporting the notion that cDCs are critical in promoting the response. However, an essential role of cDCs in the EF response has been called into question by Jung, et. al., who found that cDC depletion does not alter the extent of a TI-2 response elicited by NP-Ficoll (Jung et al., 2002). Of note, the response we tested was not a TI-2 response, but one with qualities of TI-1 (given the TLR requirement), TI-2 (giventhe polymeric nature of the Ag) and TD (given the ability of T cells, when present, to enhance it). Because EF responses are typical of autoreactive and probably bacterial (Di Niro et al., 2015) and viral pathogen responses, the EF response we studied may be more physiologically relevant than idealized TI or TD protein antigens given in artificial adjuvant. There have been few reports of negative regulation of B cells by cDCs. Three groups have observed inhibition of B cell responses by cDCs in vitro via either an IL-6 and soluble CD40L-dependent mechanism (Gilbert et al., 2007), or a mechanism requiring CD22 expression by the B cells (Santos et al., 2008; Sindhava et al., 2012). None of these systems was translated in vivo. Moreover, it is unlikely that they relate directly to our in vivo observations. In the former case only anergic B cells are affected, but AM14 B cells are not anergic (Hannum et al., 1996). In the latter cases CD22 is required, but CD22 is rapidly downregulated early in plasmablast differentiation (William et al., 2005b). Use of multiple systems for cDC depletion allowed us to rule out some alternate explanations for the enhanced EF response observed in the absence of cDC. Because we saw an elevated AM14 response in both the transient and constitutive cDC depletion systems the acute release of Ag (ie. chromatin) from dying CD11c+ cells that might occur upon DT treatment in the Itgax-DTR system was not the primary cause of the enhanced AM14 responses seen in the absence of cDCs. Macrophage hyperplasia, which we observed to some degree in both cDC depletion systems and as noted by others (Birnberg et al., 2008), was also likely not the cause of enhanced EF responses, because this macrophage expansion was also present within cDC-deficient MRL.Faslpr mice, which did not have an altered frequency of AM14 AFCs. Finally, a role for pDCs is unlikely, because pDCs were not depleted in the CD11c-DTR system, in which acute cDC depletion substantially increased the AM14 AFC response. We found that the mechanism by which cDCs regulate the EF autoimmune response in vivo was dependent on Fas: cDCs did not regulate the AM14 response in Fas-deficient animals. In this case, the regulatory pathway was short-circuited because the Fas-signaling was already “off.” Depleting cDCs in addition to Fas, therefore, had no additional effect. Fas has previously been implicated in controlling autoimmunity via a number of mechanisms, but the pathway revealed by our studies appears different. For example, FasL and Fas are required for elimination of anergic B cells by CD4+ T cells in vivo (Rathmell et al., 1995). However, AM14 B cells are not anergic (but remain ignorant), and do not need to escape anergy to break tolerance (Hannum et al., 1996; Wang and Shlomchik, 1999). GC B cells upregulate Fas, which regulates the duration and extent of the GC reaction and the generation of long-lived plasma cells (Butt et al., 2015; Hao et al., 2008; Takahashi et al., 2001). In contrast, the response we are studying is EF and generates short-lived plasmablasts. cDC regulation did not depend on Fas expression by the B cell itself, even though activated B cells can be sensitive to FasL-mediated killing (Rothstein et al., 1995). Rather, we demonstrated that the FasL targets were Fas-expressing T cells that help amplify the EF B cell response, namely Tefh cells (Lee et al., 2011; Odegard et al., 2008; Sweet et al., 2011). Because Tfh cells express Fas (Rasheed et al., 2006), we would expect that the Tefh cells in our system would also be sensitive to elimination by a FasL-expressing cell: either another T cell, the activation of which is cDC-dependent, or the cDC itself (Lu et al., 1997; Süss and Shortman, 1996). We also showed that the FasL-expressing cells required in this system were indeed T cells. There is precedent for such a mechanism, because regulation of T cells by Fas-FasL interactions is well documented (Van Parijs and Abbas, 1996), and T cell restricted Fas- or FasL-deficiency leads to autoantibody production (Mabrouk et al., 2008; Stranges et al., 2007). Seo et al also noted that B cell-specific Fas expression is not required to regulate autoreactive B cell responses to strong T cell help (Seo et al., 2002). Thus, our observations are consistent with prior studies, but extend our knowledge by demonstrating that cDCs can regulate an EF plasmablast response via a mechanism that requires Fas ligation on T cells—most likely Tefh cells—rather than on B cells directly. We previously showed, using constitutive cDC-depletion, that cDCs can amplify disease in aged MRL.Faslpr mice, although they are not required for disease initiation (Teichmann et al., 2010). These studies did not reveal a regulatory role for cDCs, and in fact, certain types of autoantibodies were reduced in aged cDC-deficient MRL.Faslpr mice. Similarly, Fas expression on cDCs suppresses autoimmunity in older mice (Stranges et al., 2007). This presents the paradox that, in the short term, cDCs negatively regulate the initiation of the EF response, whereas in the long-term cDCs promote specific, chronic aspects of disease. We suggest two ways to understand this paradox. First, as in many complex cellular networks in vivo, cDCs likely have both positive and negative effects. When integrated over the life of an autoimmune-prone animal, these effects are seen as mainly promoting disease, in particular, by aiding the growth of tissue cellular infiltrates (Teichmann et al., 2015; Teichmann et al., 2010). Over time cDC-driven positive feedback cycles of T cell activation could override any short-term negative effects. Second, and most relevant to the present context, our previous study of constitutively cDC-deficient mice was on the Fas-deficient MRL.Faslpr background. In that model, the regulatory effects of cDCs would not have been observed, because the Fas-dependent mechanism was already short-circuited. These insights into the Fas-dependent regulatory role of cDCs in the generation of autoantibodies could apply to other EF plasmablast responses. The EF response can be driven by simultaneous TLR and BCR signals. In the AM14 system, chromatin-containing ICs promote the EF response in a TLR7- and TLR9-dependent manner (Herlands et al., 2008; Leadbetter et al., 2002). A more general effect of combined TLR and BCR stimulation in directing the EF response has been demonstrated in elegant studies in which a BCR signal was engineered to have a TLR9 signal associated with it on the same synthetic bead (Eckl-Dorna and Batista, 2009). Similarly, many bacteria and viruses contain Ags that can directly stimulate B cell-expressed TLR4, 7, and 9 as well as ligate relevant BCRs. This dual recognition promotes vigorous EF plasmablast responses that can undergo isotype switch, and is probably critical for the early control of pathogens like Salmonella (Cunningham et al., 2007; Di Niro et al., 2015; Neves et al., 2010). Thus, the cDC-regulated pathway we have observed could also be important during the primary response to pathogens. Initial EF responses are typically supplanted by the GC response, which provides definitive B cell memory and long-lived AFCs. GC and T-dependent responses engage multiple mechanisms to enforce self-tolerance. In contrast, the primary EF response is less selective and partially T-independent, thus making it more liable to be subverted into autoimmunity. Here we have demonstrated a Fas- and cDC-dependent pathway that reduces the magnitude of the EF response by 3-6 fold over the course of a week. cDCs are, therefore, potent regulators of the autoreactive EF response, and possibly of EF responses in general. EXPERIMENTAL PROCEDURES Mice BALB/c, BALB/c.Rag1−/−, MRL/MpJ- Faslpr/J (MRL. Faslpr), MRL/MpJ and BALB/c FVB-Tg(Itgax-DTR/EGFP)57Lan/J (Itgax-DTR.BALB/c) (Jung et al., 2002) mice were purchased from Jackson Laboratories (Bar Harbor, Maine). BALB/c sd-Tg AM14 mice were previously described (Sweet et al., 2011), and were also backcrossed greater than 10 times onto MRL.Faslpr. AM14.BALB/c mice were used at 7-9 weeks of age. AM14.MRL.Faslpr mice were used at 5-7 weeks of age. AM14.MRL.Faslpr/+ mice were used at 5-10 weeks of age. C57BL/6 CD11c-Cre BAC transgenic (Caton et al., 2007) and Rosa26-eGFP-flox-stop-DTA transgenic (Ivanova et al., 2005) mice, gifts from Boris Reizis (Columbia University) and Juan Martinez-Barbera (University College London), respectively, were backcrossed greater than 10 times onto MRL.Faslpr (Teichmann et al., 2010). These two strains were then intercrossed to obtain cDC-deficient (ΔDC MRL.Faslpr), CD11c-Cre+ Rosa26-eGFP-DTA+ mice. Single positive and WT littermates were used as controls. Mice were used at 6-7, 5-9.5 and 7-9 weeks of age in three experiments with equivalent results. To obtain Fas-sufficient cDC-deficient mice (ΔDC.MRL.Faslpr/+) mice and controls, double positive, ΔDC.MRL.Faslpr females were outcrossed to MRL/MpJ males for one generation. Mice were used at 6-7 weeks of age in three experiments and 6-10 weeks of age in two experiments, with equivalent results. BALB/c.Faslpr mice were obtained from Thomas Ferguson (Washington University) and used at 4-9 weeks of age. BALB/c.Tcra−/− mice (Sweet et al., 2011) were obtained from Kim Bottomly (Yale University) and used at 5-7 weeks of age. BALB/c.FasLmut mice, gifted from Ann Marshak-Rothstein (Gregory et al., 2011) were used at 7-9 weeks of age. All animals were housed under SPF conditions and handled according to IACUC approved protocols. B cell Purification and Adoptive Cell Transfer Splenocyte suspensions were made in 2% fetal calf serum (FCS), 1mM EDTA, phosphate buffered saline (PBS). B cells were purified using an EasySep Mouse B cell Enrichment Kit (Stemcell Technologies). 3-12 × 106 cells suspended in PBS per mouse (as indicated) were injected intravenously (IV) on day 0. Anti-Chromatin Preparation and Immunization PL2-3, an IgG2aa anti-chromatin hybridoma (Losman et al., 1992) was prepared as ascites in Rag−/− mice as described (Herlands et al., 2008; Sweet et al., 2011). PL2-3 protein concentration was determined by IgG2a ELISA. Mice were immunized intraperitoneally (IP) with 0.5 mg equivalent of PL2-3 on days 0, 2, and 4. AM14 B cell activation was assayed on day 6. Bone Marrow Chimeras and Diphtheria Toxin Treatment BM from CD11c-DTR donors or Tg-negative littermates was processed in 0.5% bovine serum albumin (BSA), 5mM EDTA, penicillin, streptomycin in PBS. After red blood cell lysis with ACK solution, BM cells were washed with BSA, PBS and resuspended in injection buffer (2.5% v/v ACD-A, 10mM HEPES, penicillin, streptomycin, PBS). Eight week old BALB/c recipients received 450 Rad of irradiation twice from a 137Cs source with a 3-4 h rest period between doses. 1-2 h after the second dose, 8-10 × 106 BM cells were injected IV. Animals were allowed to recover for 6 weeks prior to cDC depletion or B cell transfer. Diphtheria toxin (Sigma) was administered IP at 4-8 ng/g weight on days -2 and -1 prior to and on days 1, 3 and 5 after B cell transfer. Effectiveness of chimerism and depletion was assessed by flow cytometry of splenocytes (Figure S1). ELISpot Assay ELISpot assays were performed as described (Hannum et al., 1996). Spots were counted using a dissecting microsope. Flow Cytometry Splenocytes were suspended in staining media (SM: 3% FCS, 5 mM EDTA, 0.05% sodium azide, PBS) with the FcR blocking antibody, 2.4G2 and ethidium monoazide (EMA) for live/dead discrimination. Reagents used for staining were either prepared in house: 4-44-biotin, PDCA1 (927)-Alexa 647, CD62L (MEL-14)-Alexa 647; or purchased from Biolegend: CD44 (1M7)-APC/Cy7, CD11c (N418)-PE/Cy7, CD4 (GK1.5)-PE/Cy7, Gr1 (RB6.8C5)-biotin; from BD: CD22.2 (Cy34.1)-PE, TCRβ (H57-597)-PE, I-A/I-E (M5/114.15.2)-PE; from eBioscience: CD11b (MAC-1)-PE, streptavidin-PE/Cy7; or from Invitrogen: streptavidin-PacBlue. Surface stained cells were fixed with 1% PFA, washed and resuspended in SM. For intracellular staining, cells were fixed in 4% PFA in BD Perm/Wash Buffer, washed, blocked (with 5% rat serum), and stained with 4-44-Alexa 647 or GFP-FITC (Rockland) in the BD Perm/Wash Buffer, with a final wash in SM. Cytometry was performed on a LSRII (BD) and data analyzed with FlowJo software. Immunofluorescence Histology CD11c-DTR and control spleens were fixed in paraformaldehyde-lysine-periodate (PLP) solution (1% paraformaldehyde, 95 mM L-lysine, 10 mM sodium M-periodate, 0.1 M phosphate buffer (PB), pH 7.2) for 1-7 days at 4°C. They were then washed three times with PB, dehydrated stepwise in 10%, 20%, and 30% sucrose/PB and frozen in OCT (TissueTek). Alternatively, for Bcl-6 and TUNEL staining, spleens were fixed with 4% paraformaldehyde for 2-4h at 4°C and washed for 2-4h in cold PBS and frozen in OCT medium. Spleens from CD11c-cre × Rosa26-eGFP-flox-stop-DTA mice were first frozen in OCT and fixed after cryostat sectioning with 4°C acetone for 10 min. 7-10 μm cryostat sections were cut, rehydrated with PBS, blocked for 20 min with 10% rat serum, 1% BSA, 0.1% Tween-20 in PBS, stained for 1 h with respective antibodies in BSA, Tween-20, PBS, washed three times with BSA, Tween-20, PBS and once with PBS. Staining reagents were either prepared in house: 4-44-biotin, B220 (RA3-6B2)-488, B220 (RA3-6B2)-Dylight 405, B220 (RA3-6B2)-PE, CD4 (GK1.5)-Alexa 647, F4/80 (BM8)-Alexa 647, PNA-Alexa 647, CD19 (1D3.2)-Alexa 647; or purchased from Invitrogen: streptavidin-Alexa 555; from Vector Laboratories: PNA-FITC; from BD: anti-Bcl-6 (K112-91)-Alexa 647; from BioLegend: anti-CD4 (GK1.5)-PE. For the visualization of apoptotic cells by the TUNEL method, ApoAlert DNA Fragmentation Assay Kit (Clontech) was used as per manufacturer’s instructions. After air-drying, slides were mounted with Prolong Antifade (Molecular Probes). Images were captured either with a 10 × lens on a Nikon Exlipse Ti automated wide field microscope with a QImaging Retiga 200R CCD camera (Figures 3, S2, & S5) using NIS Elements software or with a 20 × lens on an Olympus IX83 microscope (Figures 7 & 6S) with an ORCA-flash 4.0 camera (Hamamatsu) using Olympus CellSens Dimension 1.15 software. Images were further processed with Adobe Photoshop software, and CellSens software assisted in TUNEL+ cell quantitation. Statistical Analysis P-values were calculated by one-way ANOVA with Tukey’s multiple comparisons test, two-tailed Mann-Whitney U-test, or unpaired T-test, as indicated, using Prism software (Graphpad). Supplementary Material 1 2 ACKNOWLEDGMENTS We thank Dr. Juan Martinez-Barbera and Boris Reizis for Rosa26-eGFP-DTA and CD11c-cre mice, respectively. Cuiling Zhang, Yuqi Zhang and Colin Smith provided outstanding technical assistance. Kevin Nickerson assisted in our experimental response to the reviewers. We thank the Yale Animal Resources Center and the Yale Cell Sorter Facility for their excellent services. This work was supported by the National Institutes of Health grant AI073722 (to MJS), a Ruth. L. Kirschstein National Research Service Award NIH T32 AI07019-30 (to MLO), and an Arthritis Foundation Postdoctoral Fellowship (to MLO). Figure 1 The EF AM14 Rheumatoid Factor Response does not Acutely Require, but is Regulated by cDCs (A) Experiment design. Itgax-DTR.BALB/c or Tg-negative littermates were used to make BM chimeras. cDCs were depleted with DT on days -1, -2, 1, 3 and 5. 9-10 × 106 AM14.BALB/c B cells were transferred into the mice on day 0, and activated with PL2-3 on days 0, 2 and 4. Spleens were harvested on day 6. (B) Representative flow cytometry gating of live AM14 B cells by surface and intracellular 4-44 (anti-idiotype) staining, and further subgating for CD22lo, CD44hi plasmablasts. (C) Number of AM14 B cells (surface and intracellular 4-44+) per spleen. (D) Number of AM14 plasmablasts (4-44+, CD22lo, CD44hi) per spleen. (E & F) ELISpot assays for the number of 4-44+, IgM+ or IgG2a+ AFCs per spleen. Data were combined from 2 experiments to obtain 4-8 mice per group. Bars represent mean and SEM. *p < 0.05; **p < 0.01 by ANOVA. See also Figures S1 and S2. Figure 2 cDCs are not Required Constitutively for the AM14 Response (A) Experiment design. 4 × 106 AM14.MRL.Faslpr B cells were transferred into MRL.Faslpr recipients that were either double positive for both the CD11c-cre and Rosa26-flox-stop-DTA Tgs, and thus lacked cDCs (ΔDC mice), or into single Tg positive littermates (Cntrl) on day 0. The AM14 B cell response was activated with PL2-3 on days 0, 2 and 4, or left untreated (no Ag). As additional controls, some mice did not receive cell transfer or Ag (no Tfr). Spleens were harvested on day 6. (B) Number of AM14 B cells (4-44+) per spleen. (C) Number of AM14 plasmablasts (4-44+, CD22lo, CD44hi) per spleen. (D, E, & F) ELISpot assays for the number of 4-44+, IgM+, IgG2a+, or IgG2b+ AFCs per spleen. Data were combined from 3 experiments to obtain 12-24 mice per group receiving PL2-3 and 2-12 mice in the untreated groups. Bars represent mean and SEM. See also Figure S3. Figure 3 Regulation of the AM14 Response by cDCs Requires Fas (A) Experiment design. 8-9 × 106 Fas-sufficient AM14.MRL.Faslpr/+ B cells were transferred into Fas-sufficient MRL.Faslpr/+ recipients that either lacked cDCs (ΔDC) or into littermate controls (Cntrl) on day 0. The AM14 B cell response was activated with PL2-3 on days 0, 2 and 4, or left untreated (no Ag). Some mice did not receive cell transfer or Ag (no Tfr). Spleens were harvested on day 6. (B) Number of AM14 B cells (4-44+) per spleen. (C) Number of AM14 plasmablasts (4-44+, CD22lo, CD44hi) per spleen. (D, E, & F) ELISpot assays for the number of 4-44+, IgM+, IgG2a+, or IgG2b+ AFCs per spleen. Data were combined from 5 experiments to obtain 15-29 mice per group receiving PL2-3 and 2-7 mice in the other groups. Bars represent mean and SEM. ****p < 0.0001 by Mann-Whitney U test. (G) Immunofluorescence histology was performed on spleens from experimental mice. Images were taken at a magnification of 100x. Red, AM14 B cells (4-44+); green, B cell follicles (B220+); blue, T cell zones (CD4+). White scale bars are 200 μm. See also Figures S4 and S5. Figure 4 Fas-Dependent cDC Regulation of the AM14 Response is AM14 B Cell Extrinsic (A) Experiment design. 8 × 106 Fas-deficient AM14.MRL.Faslpr B cells were transferred into either Fas-sufficient, cDC-deficient (ΔDC) MRL.Faslpr/+ recipients or into littermate controls (Cntrl) on day 0. The AM14 B cell response was activated with PL2-3 on days 0, 2 and 4. Some mice did not receive cell transfer or Ag (no Tfr). Spleens were harvested on day 6. (B) Number of AM14 B cells (surface and intracellular 4-44+) per spleen. (C) Number of AM14 plasmablasts (4-44+, CD22lo, CD44hi) per spleen. (D, E, & F) ELISpot assays for the number of 4-44+, IgM+, IgG2a+, or IgG2b+ AFCs per spleen. Data were combined from 2 experiments to obtain 8-15 mice per group receiving PL2-3 and 2 no Tfr controls. Bars represent mean and SEM. ***p < 0.001 by Mann-Whitney U test. See also Figure S7. Figure 5 Recipient Mice Lacking Fas and/or Dendritic Cells Have Higher Numbers of Activated CD4+ T Cells than Control Mice Splenic T cells from experimental mice shown in Figures 2-4 were analyzed by flow cytometry. (A) Representative sample showing the gating of live splenocytes for CD4+, TCRβ+ cells (top) that were further sub-gated (bottom) by their activation markers (CD44hi, CD62Llo). (B) Number of CD4+, TCRβ+ cells per spleen. (C) Percent of CD4+, TCRβ+ cells that are activated (CD44hi, CD62Llo). (D) Number of CD4+, TCRβ+, CD44hi, CD62Llo cells per spleen. ΔDC, mice that lack cDCs; Cntrl, littermate controls. Bars represent mean and SEM. **p < 0.01; ***p < 0.001 by Mann-Whitney U test. See also Figure S6. Figure 6 Regulation of AM14 Plasmablasts by cDCs Requires T Cells Expressing Fas (A) Experiment design. BALB/c mice were used to make chimeras with BM mixed from WT, Tcra−/− or Faslpr mice. 3 × 106 AM14.BALB/c B cells were transferred into the mice on day 0, and activated with PL2-3 on days 0, 2 and 4. Spleens were harvested on day 6. (B, C, & D) ELISpot assays for the number of 4-44+, IgM+, IgG2a+, or IgG2b+ AFCs per spleen. (E) Number of CD4+, TCRβ+ cells per spleen. (F) Percent of CD4+, TCRβ+ cells that are activated (CD44hi, CD62Llo). (G) Number of CD4+, TCRβ+, CD44hi, CD62Llo cells per spleen. Data were combined from 2 experiments to obtain 6-12 mice per group receiving PL2-3 and 4-8 controls. Bars represent mean and SEM. *p < 0.05; **p < 0.01; ***p < 0.001; ****p < 0.0001 by Mann-Whitney U test. See also Figure S7. Figure 7 Regulation of AM14 Plasmablasts by cDCs Requires T Cells Expressing FasL and Increases the Death of CD4 T Cells (A-F) Experiments performed as described and arranged in same order as in Figure 6, except BM was mixed from WT, Tcra−/− or FasLmut mice. Data were combined from 2 experiments to obtain 6-12 mice per group receiving PL2-3 and 3-8 controls. (G & H) As described in Figure 1, CD11c-DTR.BALB/c BM chimeras were generated and depleted of cDCs using 16 ng per g weight doses of DT. 8 × 106 AM14.BALB/c B cells were transferred and activated with PL2-3. Spleens were harvested on day 7. Data for untreated versus DT-treated mice are shown. (G) Representative histology of the spleen, taken at a magnification of 200x. Arrowheads indicate TUNEL+, CD4+ cells. Inset upper left shows a digital magnification of a TUNEL+ CD4+ cell in the white box of the larger image. Scale bars are 50 μm. (H) Quantification of TUNEL+, CD4+ cells from a total of 8 fields combined from 2 representative mice per group. Bars represent mean and SEM. *p < 0.05; **p < 0.01; ***p < 0.001 by Mann-Whitney U test. See also Figures S6 and S7. HIGHLIGHTS - cDCs are not required for extrafollicular (EF) autoreactive B cell activation - Loss of cDCs markedly enhances the EF B cell response - cDC regulation of the EF response requires B cell extrinsic Fas - Loss of Fas or FasL on T cells enhances autoantibody production IN BRIEF cDCs negatively regulate extrafollicular B activation and autoantibody production. Using two cDC ablation systems, Ols and colleagues observe elevated autoantibody production in the absence of cDCs. They further show that the regulatory effect of cDCs on B cells requires Fas and FasL expression by T cells. This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final citable form. Please note that during the production process errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain. SUPPLEMENTAL INFORMATION Supplemental information includes seven figures and supplemental methods for PD-1 and Bcl-6 staining by flow cytometry. AUTHOR CONTRIBUTIONS M.L.O. designed and performed experiments, analyzed data, and wrote the manuscript. J.L.C., A.T-N., and J.G. performed experiments and analyzed data. M.J.S. designed experiments, supervised the study, and wrote the manuscript. The authors declare that they have no competing financial interests. 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PMC005xxxxxx/PMC5112153.txt
LICENSE: This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. 8711562 6325 Oncogene Oncogene Oncogene 0950-9232 1476-5594 27181203 5112153 10.1038/onc.2016.175 NIHMS780459 Article p27T187A knockin identifies Skp2/Cks1 pocket inhibitors for advanced prostate cancer Zhao Hongling 13 Lu Zhonglei 134 Bauzon Frederick 1 Fu Hao 15 Cui Jinhua 1 Locker Joseph 2 Zhu Liang 1 1 Department of Developmental and Molecular Biology, and Ophthalmology & Visual Sciences, and Medicine, The Albert Einstein Comprehensive Cancer Center and Liver Research Center, Albert Einstein College of Medicine, Bronx, NY 10461, USA 2 Department of Pathology, University of Pittsburgh School of Medicine, Pittsburgh, PA 15261, USA Corresponding author: Dr. Liang Zhu, Department of Developmental and Molecular Biology, Albert Einstein College of Medicine, 1300 Morris Park Avenue, Room U-521, Bronx, NY 10461, USA, Phone: 718-430-3320, Fax: 718-430-8975, liang.zhu@einstein.yu.edu 3 Co-first authors. 4 Present address: College of Biological Science and Engineering, Fuzhou University, Fuzhou, Fujian, 350108, China. 5 Present address: Department of Biochemistry, Shenyang Medical College, Shenyang, Liaoning, 110034, China. 22 4 2016 16 5 2016 05 1 2017 05 7 2017 36 1 6070 This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. SCFSkp2/Cks1 ubiquitinates Thr187-phosphorylated p27 for degradation. Over-expression of Skp2 coupled with under-expression of p27 are frequent characteristics of cancer cells. When the role of SCFSkp2/Cks1 mediated p27 ubiquitination in cancer was specifically tested by p27 Thr187-to-Ala knockin (p27T187A KI), it was found dispensable for KrasG12D induced lung tumorigenesis but essential for Rb1 deficient pituitary tumorigenesis. Here we identify pRb and p53 doubly deficient (DKO) prostate tumorigenesis as a context in which p27 ubiquitination by SCFSkp2/Cks1 is required for p27 down-regulation. p27 protein accumulated in prostate when p27T187A KI mice underwent DKO prostate tumorigenesis. p27T187A KI or Skp2 knockdown (KD) induced similar degrees of p27 protein accumulation in DKO prostate cells, and Skp2 KD did not further increase p27 protein in DKO prostate cells that contained p27T187A KI (AADKO prostate cells). p27T187A KI activated an E2F1-p73-apoptosis axis in DKO prostate tumorigenesis, slowed disease progression, and significantly extended survival. Querying co-occurrence relationships among RB1, TP53, PTEN, NKX3-1, and MYC in TCGA of prostate cancer identified co-inactivation of RB1 and TP53 as the only statistically significant co-occurrences in metastatic castration resistant prostate cancer (mCRPC). Together, our study identifies Skp2/Cks1 pocket inhibitors as potential therapeutics for mCRPC. Procedures for establishing mCRPC organoid cultures from contemporary patients were recently established. An Skp2/Cks1 pocket inhibitor preferentially collapsed DKO prostate tumor organoids over AADKO organoids, which spontaneously disintegrated over time when DKO prostate tumor organoids grew larger, setting the stage to translate mouse model findings to precision medicine in the clinic on the organoid platform. p27 phosphorylation and accumulation Skp2/Cks1 pocket inhibitors advanced prostate cancer prostate cancer organoids Introduction Levels of p27, a cyclin-dependent kinase inhibitor, can be regulated by mRNA expression, protein synthesis, and protein degradation. One down-regulation mechanism is its ubiquitination by SCFSkp2/Cks1 ubiquitin ligase, which prepares p27 for degradation in the proteasomes (1). SCFSkp2/Cks1-mediated p27 ubiquitination requires its phosphorylation on Thr187. Replacing Thr187 with alanine (p27T187A) to render this position unphosphorylable prevents p27 binding to and ubiquitination by SCFSkp2/Cks1 (2, 3). This is because T187p and a conserved E185 together mediate p27 binding to a pocket formed jointly by Skp2 and the accessory protein Cks1 (4–6). To test the physiological significance of this biochemical mechanism, p27T187A/T187A (p27T187A KI) mice were generated (7). p27T187A KI mice do not show p27 protein accumulation, demonstrating that p27 ubiquitination by SCFSkp2/Cks1 is dispensable for p27 degradation in normal physiology. p27 is a haplo-insufficient tumor suppressor (8), whose reduced expression is frequently associated with aggressive cancers (9). Knockout of p27 induces spontaneous pituitary tumorigenesis and can accelerate tumorigenesis induced by a large number of oncogenic events in numerous tissues, suggesting that stabilizing p27 can be therapeutic for many types of cancer. However, when p27 KO accelerated lung tumorigenesis in KrasG12D/+ mice, p27T187A KI did not have a protective effect (10), suggesting that p27 ubiquitination by SCFSkp2/Cks1 is dispensable for p27 degradation in lung tumorigenesis by KrasG12D. On the other hand, p27 KO accelerated pituitary melanotroph tumorigenesis in Rb1+/− mice (11) and p27T187A KI blocked it (12). Thus, the role of SCFSkp2/Cks1 in mediating p27 degradation can be highly critical in promoting tumorigenesis but only in specific contexts. Finding additional tumorigenic contexts in which SCFSkp2/Cks1 plays a critical role in promoting tumorigenesis could be challenging, since most tissues resist tumorigenesis by deletion of Rb1 alone. It is however evident that, once the susceptible contexts are identified, inhibition of SCFSkp2/Cks1 is technically feasible (13, 14), affects a highly select sub-group of SCFSkp2 substrates, and is forecasted by the p27T187A KI mice to be non-toxic. Here we identify pRb and p53 doubly deficient (DKO) prostate tumorigenesis as an additional susceptible context. We further make the case for translating mouse model findings to clinical metastatic castration resistant prostate cancer (mCRPC) on the organoid platform. Results p27T187A KI accumulates p27 in pRb and p53 doubly deficient prostate Based on our previous findings that Skp2 KO and p27T187A KI accumulated p27 in Rb1 KO melanotroph tumorigenesis (15) and Skp2 KO accumulated p27 in Rb1 and Trp53 DKO prostate tumorigenesis (16), we hypothesized that p27T187A KI could also accumulate p27 in DKO prostate tumorigenesis. To test this hypothesis, we generated mice of p27+/+, p27T187A/T187A, and PB-Cre4;Rb1lox/lox;Trp53lox/lox on p27+/+ or p27T187A/T187A background to determine p27 expression in their prostate epithelium by IHC. At 5–6 months of age, co-deletion of Rb1 and Trp53 induced neoplastic lesions only in proximal prostate acini. We show p27 staining in distal prostate acini to compare the four genotypes in normal appearing tissues (Figure 1Aa,c,e,g). Similar p27 staining were observed in p27+/+ and p27T187A/T187A prostates (Figure 1Ab,d). When Rb1 and Trp53 were co-deleted, p27 staining reduced in p27+/+ prostate (Figure 1Af), but increased in p27T187A/T187A prostates (Figure 1Ah). p27 Western blot of the prostate ventral and anterior lobes provided similar findings (Figure 1B). This Western blot also revealed increased Skp2 protein levels in DKO prostate in p27+/+ and p27T187A/T187A mice. This finding resembles similar findings in human prostate cancer and explains in part the reduction of p27 in p27+/+ prostate but increase of p27 in p27T187A/T187A prostate (please see Discussion for more details). To learn the molecular basis for this requirement for p27 Thr187 phosphorylation, we established early passage prostate cells from DKO prostate in p27+/+ mice (called DKO cells) and in p27T187A/T187A mice (AADKO cells). We found that Skp2 knockdown in DKO cells increased p27 protein levels while AADKO cells intrinsically contained similarly increased levels of p27 (Figure 1C). RT-qPCR and CHX experiments suggest that p27 accumulation in AADKO prostate cells was not due to increased expression of p27 mRNA (Figure 1D) but was due to increased protein stability (Figure 1E). If p27T187A KI prevented p27 ubiquitination by SCFSkp2/Cks1 to accumulate p27, knockdown of Skp2 in p27T187A KI cells would not further increase p27, and this proved true (Figure 1C). These genetic and molecular findings suggest that ubiquitination of p27T187p by SCFSkp2/Cks1 became rate-limiting in preventing p27 accumulation in prostate when Rb1 and Trp53 were co-deleted in it. p27T187A KI activates a p27-E2F1-p73-apoptosis axis in DKO prostate tumorigenesis Skp2 KO or p27T187A KI inhibited pRb deficient pituitary melanotroph tumorigenesis by E2F1 induced apoptosis (Figure S1A) (15, 17). To determine whether this E2F1 induced apoptosis could remain effective when Trp53 is additionally deleted, we determined the contribution of p73, an E2F1 target gene and a p53 family member, to this apoptosis. As shown in Figure S1B. Rb1 deletion did not increase apoptosis, measured as sub-G1 cells, in Skp2 WT MEFs, but increased them to 19% of the population in Skp2 KO MEFs. Combining knockdown of p73 reduced sub-G1 cells to 7–8% of the population (Figure S1C), demonstrating that p73 contributed about half of the E2F1 induced apoptosis in this context. We next investigated whether p27T187A KI activated this p27-E2F1-p73 axis in AADKO prostate tumor cells. We found that Skp2 knockdown in DKO cells increased p73 protein. AADKO cells intrinsically contained a similarly increased level of p73 protein, which Skp2 knockdown did not further increase (Figure 2A). Thus, effects of Skp2 knockdown and p27T187A KI on p73 protein mirrored those on p27 protein. At mRNA levels however, p27T187A KI significantly increased expression of p73 mRNA in AADKO cells compared to DKO cells (Figure 2B), different from p27 (Figure 1D). The increased p73 mRNA expression was accompanied by significantly increased occupancy of E2F1 and p73 promoters (both are typical E2F target genes) but not GAPDH promoter (a housekeeping gene) by E2F1 in AADKO cells compared to DKO cells (Figure 2C, left). E2F4 occupancy on E2F1 and p73 promoters did not increase in AADKO cells (Figure 2C, middle), which is consistent with the fact that E2F4 does not bind cyclin A. ChIP with normal IgG did not enrich E2F1 or p73 promoter sequences in AADKO cells (Figure 2C, right). We next determined p73 protein expression in prostate tissues. Of the four genotypes examined, we found robust anti-p73 staining only in p27T187A/T187A;PB-Cre4;Rb1lox/lox;Trp53lox/lox prostate (Figure 2D). Western blot of prostate tissues confirmed the staining findings (Figure 2E). p73 protein similarly increased in Skp2−/−;PB-Cre4;Rb1lox/lox;Trp53lox/lox prostate (Figure S2). The Western blot also revealed accumulation of cleaved caspase 3 in p27T187A/T187A;PB-Cre4;Rb1lox/lox;Trp53lox/lox prostate tissues (Figure 2E), suggesting that the increased p73 in this genotype induced apoptosis in the absence of p53. We next used TUNEL staining to demonstrate that DKO neoplastic lesions contained more apoptosis in p27T187A/T187A mice than in p27+/+ mice (Figure 3A,B,C). p73 can induce apoptosis independent of p53 likely because the TAp73 isoform activates similar target genes for cell cycle arrest (p21) or apoptosis (PUMA, BAX) as p53 (see (18) for a recent review). To determine whether p73 contributed to this apoptosis, we determined the effects of p73 knockdown (Figure 3D) in AADKO prostate tumor cells. In untreated AADKO cell culture, 8.8% of the population showed sub-G1 DNA content. Knockdown of p73 reduced the sub-G1 population to 1.4%, which was confirmed by a 2nd shp73 (Figure 3E). We further show that DKO prostate tumor cells contained little sub-G1 cells (0.6%), which was increased to 17% by Skp2 knockdown, additional knockdown of p73 reduced it to background levels (Figure 3F). These findings delineate a p27-E2F1-p73-apoptosis pathway activated by p27T187A KI in DKO prostate tumorigenesis (Figure S3). p27T187A KI significantly delays progression of DKO prostate tumorigenesis to lethality DKO prostate tumorigenesis is invasive, metastatic, castration resistant, and becomes lethal within 7–10 months (19), but cannot progress beyond PIN stages in Skp2 KO mice (16). Skp2 KO mice are significantly smaller and less fertile (20), which are not seen in p27T187A KI mice (7). We next determined how DKO prostate tumorigenesis progressed in p27T187A KI mice. In addition to inducing p53-independent apoptosis via a p27-E2F1-p73 axis, p27T187A KI inhibited cell proliferation in DKO prostate tumorigenesis, as measured by Ki67 (Figure S4A,C) and pHH3 (Figure S4B,D) staining. At 5–7 months of age, 50% of PB-Cre4;Rb1lox/lox;Trp53lox/lox mice contained gross prostate tumors but none of the p27T187A/T187A;PB-Cre4;Rb1lox/lox;Trp53lox/lox mice did so; by 8–9 months, 80% of PB-Cre4;Rb1lox/lox;Trp53lox/lox mice contained gross prostate tumors compared to 50% of p27T187A/T187A;PB-Cre4;Rb1lox/lox;Trp53lox/lox mice (Figure 4A,B). When characterized by survival, 2 of 30 PB-Cre4;Rb1lox/lox;Trp53lox/lox mice were alive pass 9 months, while 13 of 38 p27T187A/T187A;PB-Cre4;Rb1lox/lox;Trp53lox/lox mice survived pass 10 months (Figure 4C). Thus, remarkably, the innocuous p27T187A mutation can delay progression of the aggressive DKO prostate tumorigenesis to significantly extend survival. Co-occurrences of RB1 and TP53 inactivation is statistically significant in mCRPC To determine how often both RB1 and TP53 are genetically inactivated in human prostate cancer, we queried the genetic status of RB1, TP53, PTEN, NKX3-1, and MYC (five known prostate cancer drivers) in TCGA of prostate cancer on cBioPortal (21) (Table 1). Inactivation of RB1 and TP53 did not co-occur in three cohorts of primary prostate cancer but co-occurred with statistical significance in two of the three metastatic castration resistant prostate cancer (mCRPC) cohorts. Many of the co-occurred inactivation are likely biallelic since they were detected together with shallow deletions of RB1 and TP53 (Figure S5). None of the other possible pairs among these five genes showed statistically significant co-occurrences for their alterations. Inactivation of TP53 and activation of MYC co-occurred with statistical significance in one primary prostate cancer cohorts but the co-occurrences lost statistical significance with disease progression to mCRPC. About one quarter of the patients develop metastatic prostate cancer after prostatectomy or at presentation. These cases are treated with androgen deprivation therapies, but invariably the cancer would relapse in the form of mCRPC. Inhibitors of residual androgen synthesis, such as abiraterone acetate, 2nd generation AR antagonist, such as enzalutamide, and chemotherapies with taxane can be effective but the efficacies are not durable. Currently, mCRPCs kill 27,000 men annually in US alone. Our TCGA analyses suggest that DKO prostate tumorigenesis could serve as a mouse model for mCRPC to identify pressingly needed new therapy strategies. A small molecule Skp2/Cks1 pocket inhibitor inhibits DKO and DU 145 cells Using a structure-based in silico screen, small molecules that occupy Skp2/Cks1 pocket to inhibit its interaction with p27T187p were identified (13) (Figure 5A). We employed one of such inhibitors, Compound 1 (C1), to determine the pharmacologic effects of inhibiting the Skp2/Cks1-p27T187p interaction in DKO prostate tumor cells. We also tested C1 on AADKO prostate tumor cells, in which the Skp2/Cks1-p27T187p interaction is not present, to genetically interrogate its mechanism of action. There are six human metastatic prostate cancer cell lines in CCLE (Cancer Cell Line Encyclopedia (22)); one of them, DU145, is hormone-insensitive and contains truncating mutation K715* in RB1 and inactivating mutation V274F in TP53. We included DU145 as a model for human mCRPC to test the effects of C1 (Figure 5B). At 1.25 μM, C1 reduced DKO cell proliferation by 80% relative to DMSO vehicle control but reduced AADKO cell proliferation by only 20%. This selectivity for DKO cells continued when C1 concentration was increased to 2.5 μM. AADKO cells proliferated significantly more slowly than DKO cells in the absence of C1 (Figure 5C), but C1 at 5.0 μM still reduced AADKO proliferation by 75% relative to DMSO control (Figure 5B). We found that C1 treatment increased p27 only in DKO cells but increased p21 in both DKO and AADKO cells (Figure 5D). These findings support the designed mechanism of action of C1 and reveal a therapeutic advantage in pharmacological targeting of the Skp2/Cks1 pocket over p27T187A KI (Figure 5A). In DU145 cells, C1 inhibited proliferation and increased p27 and p21 to a degree comparable to DKO prostate tumor cells (Fig. 5B,C,D), suggesting that inhibition of the Skp2/Cks1 pocket is a potential therapeutic strategy for mCRPC (also see Discussion). Skp2/Cks1 pocket inhibitor inhibits DKO prostate tumor organoids Recently, six organoid lines from mCRPC biopsies from contemporary patients were reported, 5 of them contain mutations and/or gene deletions in both RB1 and TP53 (23). Unlike monolayer cultures, organoids respond to therapeutics in acini-like structures. To translate mouse model findings to clinical mCRPC on the same organoid platform, we next generated DKO and AADKO prostate tumor organoids (Figure 6A,B). At day 15 after plating, DKO and AADKO cells generated organoids with similar efficiencies and size ranges (Figure 6E,G,H). Longitudinal monitoring revealed most DKO organoids grew larger while most AADKO organoids spontaneously disintegrated into debris piles over a six-day period (Figure 6C). As such, a prominent difference between DKO and AADKO organoid cultures is the 1.9 fold increase in debris piles in the latter in untreated cultures (Figure 6F,H). These characteristics differed from monolayer cultures, where AADKO cells proliferated much more slowly than DKO cells (Figure 5C), and demonstrate the ability of DKO and AADKO organoid cultures to more closely model autochthonous DKO and AADKO prostate tumors. We then tested the effects of C1 on DKO and AADKO prostate tumor organoids. At 1.25 μM, C1 reduced organoid forming efficiency by 1.7 fold for DKO organoids compared to 1.1 fold for AADKO organoids (Figure 6G); and increased debris piles 2.9 fold for DKO organoids compared to 1.1 fold for AADKO organoids (Figure 6H). This selectivity for DKO organoids largely disappeared when C1 concentrations were increased to 5.0 μM, although about 20% of small AADKO organoids remained in AADKO culture. These organoid findings provide further genetic and functional validation for the therapeutic potential of Skp2/Cks1 pocket inhibitors for pRb and p53 deficient prostate cancer. Discussion Prostate cancer is one of the major cancer types that showed Skp2 overexpression coupled with p27 under-expression. A tissue microarray study of 4 normal prostate samples, 74 high grade prostatic intraepithelial neoplasm (HGPIN), and 622 primary prostate cancer specimens (24) documented significant Skp2 overexpression in HGPIN over normal tissue, in primary prostate cancer over HGPIN, and Skp2 overexpression significantly correlated with p27 under-expression (Table S1). pRb inhibits Skp2 binding to p27 (25), represses Skp2 mRNA expression via E2F (26, 27), and promotes Skp2 protein degradation via APC/CCdh1 (28). Pten also inhibits Skp2 expression but the mechanisms are not known. Pten overexpression in human glioblastoma cells decreased Skp2 expression while Pten KO MEFs show increased Skp2 expression (29). To determine whether these findings could explain Skp2 overexpression in primary prostate cancer, we queried RB1, TP53, PTEN; and Skp2 in a cohort of 333 primary prostate cancer specimens in cBioPortal (Table S2). Inactivation of TP53 or PTEN tend to co-occur with activation of Skp2, but neither reached statistical significance. Inactivation of RB1 does not co-occur with Skp2 activation, likely because RB1 is inactivated in only 0.9% of the samples in this cohort,. When we made the same queries to a cohort of 150 mCRPC specimens, in which inactivation of RB1 and activation of Skp2 both become more frequent, they co-occurred with statistical significance. These TCGA findings provide one explanation for overexpression of Skp2 in prostate cancer and might explain the inhibition of Rb1 and Trp53 DKO prostate tumorigenesis or inhibition of Pten KO prostate tumorigenesis by Skp2 KO (16, 30). Skp2 has a growing list of substrates in addition to p27; p27T187A KI can test the contribution of lacking p27 ubiquitination by SCFSkp2/Cks1 to the effects of Skp2 KO. In Rb1 deficient pituitary tumorigenesis, p27T187A KI largely phenocopied Skp2 KO to block this tumorigenesis (12, 15). On the other hand, p27T187A KI did not inhibit KrasG12D/+ induced lung tumorigenesis. In this study, we determined the effects of p27T187A KI on DKO prostate tumorigenesis, which represents a more challenging tumorigenic context, since co-deletion of Rb1 and Trp53 wound disable most of the antitumor mechanisms in the cells. Co-deletion of Rb1 and Trp53 confers dependency on SCFSkp2/Cks1 to prevent p27 protein accumulation in prostate p27 can be ubiquitinated by several ubiquitin ligases, including SCFSkp2/Cks1, Pirh2 (31), KPC1 (32), Cul4 (33), and WWP1 (34). Combined activities of these ligases, rather than any single ligase, likely determine the stability of p27 protein. pRb inhibits Skp2 via at least three mechanisms (described in the previous section); pRb loss may thereby greatly enhance Skp2 activity, leading to greatly enhanced p27 ubiquitination by SCFSkp2/Cks1 in Rb1 deficient pituitary melanotroph tumorigenesis. In this context, p27 protein degradation became dependent on Thr187 phosphorylation; p27T187A KI therefore can inhibit Rb1 deficient pituitary tumorigenesis (12, 15). In another context, DNA damage-activated p53 stimulates expression of Pirh2 and KPC1 as typical p53 target genes to degrade p27 in mouse embryonic fibroblasts (16). Deletion of Trp53 in prostate however did not induce p27 protein accumulation (our unpublished results), likely because p53 is not activated in prostate development and small reductions in Pirh2 and KPC1 can be compensated by other p27 ubiquitin ligases. Co-deletion of Trp53 and Rb1 reduced p27 protein (Fig. 1Ae,f), likely because the other p27 ubiquitin ligases now included increased (Fig. 1B) and activated Skp2 due to pRb loss. In this context of increased and activated Skp2 and reduced Pirh2 and KPC1, p27T187A KI accumulated p27 protein (Figure 1A and B). Our unpublished results further show that deletion of Rb1 in Skp2 KO or p27T187A KI prostate also did not accumulate p27, likely because p53 is activated by Rb1 deletion to stimulate expression of Pirh2 and KPC1. These findings, together with the results from cultured DKO and AADKO prostate cells (Figure 1C to E) provide the first combined genetic and biochemical evidence for the relevance of SCFSkp2/Cks1-mediated p27 ubiquitination in preventing p27 accumulation in vivo (please also see Introduction). p27T187A KI identifies substrate-specific inhibitors of protein degradation for mCRPC With FDA approval for the use of a proteasome inhibitor, bortezomib, to treat multiple myeloma, targeting ubiquitin-mediated protein degradation has become a validated cancer therapy strategy (35, 36). The current challenge is to add specificity to this strategy, since unspecific inhibition of protein degradation generates serious side-effects, which could explain at least in part the negative outcome of a phase II trial of bortezomib for castration resistant metastatic prostate cancer (37). In the ubiquitination mediated protein degradation hierarchy, inhibitors of the Skp2/Cks1 pocket are perhaps the most substrate selective, affecting only p27 and p21 (and possibly p57 by sequence prediction). Our findings that p27T187A significantly inhibited progression of DKO prostate tumorigenesis to extend survival provide a basis for identifying prostate cancer patients for treatment with such inhibitors. Indeed, in the above mentioned phase II trial of bortezomib, one of 24 evaluable patients with castration resistant metastatic prostate cancer achieved the primary end point (defined as no increase in PSA from baseline and no radiographic progression at 12 weeks) (37). It is regretful that the genetic status of RB1 and TP53 in this patient’s prostate cancer was not determined and documented in the pre-TCGA era. It is highly likely that many mCRPC patients could be indicated for therapy with Skp2/Cks1 pocket inhibitors since RB1 and TP53 inactivation co-occurred statistically significantly in mCRPC based on the most recently available TCGA of primary prostate cancer and mCRPC (Table 1). Our findings with p27T187A KI also provided genetic support for the mechanisms of action of the currently available inhibitor compound 1 (C1), since it inhibited DKO prostate tumor cells far more effectively than AADKO prostate tumor cells (in which the interaction between Skp2/Cks1 pocket and p27 is already prevented) and, furthermore, demonstrated the superiority of such inhibitors over p27T187A KI, since C1 at higher concentration can still inhibit AADKO prostate tumor cells. Since higher concentrations of C1 induced similar p21 accumulation in DKO and AADKO cells, C1 may increase p27 and p21, likely p57 and other yet to be identified substrates of the Skp2/Cks1 pocket to exert stronger inhibition of the Skp2/Cks1 pocket than p27T187A KI. However, it is important to note that regulation of p21 and p27 protein degradation are by different as well as shared mechanisms. While SCFSkp2/Cks1 can promote degradation of p27 and p21, p21 degradation is also promoted by MDM2/MDMX (38), APC/CCdc20 (39), CRL4Cdt2 (40), and CRL2LRR1 (41), which are not known to promote p27 degradation. Furthermore, although the comparison between DKO and AADKO prostate tumor cells support the designed action mechanism of C1, the likelihood of its having other substrates, off-target effects, or both, still exists. This is especially true in human prostate cancer cell lines, such as DU145, which likely contain far more genetic and epigenetic alterations and overall far more heterogeneous than targeted mouse prostate cancer cells, such as DKO and AADKO cells. Inhibition of DKO prostate tumorigenesis by p27T187A KI is notably weaker than that by Skp2 KO, the latter blocked DKO prostate tumorigenesis inside the PIN stage (16). It is therefore of great interest to test inhibitors that target Skp2 as a whole, such as the more recently reported inhibitor Compound 25, which blocks Skp2-Skp1 interaction in the SCFSkp2 ligase (42). The broadening of substrate spectrum would however likely result in undesirable side effects. In this respect, Skp2 KO mice are significantly smaller and less fertile while p27T187A KI mice are virtually normal. Translating mouse model findings to clinical precision medicine on organoid platform DU145 cell line was established about 40 years ago (43), and is the only prostate cancer cell line containing inactivating mutations in RB1 and TP53. Extended monolayer culture of established cancer cell lines can encourage secondary genomic alterations that are not present in the original cancer specimens (44, 45), and monolayer culture bears no resemblance to the prostate when testing therapeutic effects of potential therapeutics. Organoid cultures are emerging as an alternative since cancer cell organoids demonstrate stable genomic landscapes faithful to the original cancer specimens, and respond to therapeutics in acinus-like structures (46, 47). Prostate cancer organoid cultures can be generated from mouse models (48, 49), and we have now established organoid cultures from DKO and AADKO prostate tumor models. We provide evidence that the proliferation and survival characteristics of DKO and AADKO organoids more closely resemble those in DKO and AADKO autochthonous prostate tumors than DKO and AADKO monolayer cells. While monolayer AADKO cells simply proliferated much more slowly than DKO monolayer cells, their respective organoids formed with similar efficiency. The difference is in the expansion of the organoids: when DKO organoids were growing larger, AADKO organoids spontaneously disintegrated into debris piles. In this scenario, the inhibitor C1 collapsed DKO organoids into debris piles, mimicking AADKO organoids. Six recently established mCRPC organoid lines from contemporary patients contained frequent inactivation of RB1 and TP53 while maintaining stable genomic landscapes faithful to the biopsy specimens that they were derived from (23). Based on this success, more mCRPC organoid lines from contemporary patients are being generated potentially reaching the scale of a biobank, as recently reported for colorectal cancer (47). Testing potential therapeutics on prostate cancer organoids established from mouse prostate cancer models and human clinical cancer specimens side-by-side could increase the predictive value of the observed effects in selecting candidates for further development and in guiding clinical trial designs. Materials and Methods Mice PB-Cre4 mice (50), Rb1lox/lox mice (51), Trp53lox/lox mice (52), and p27T187A/T187A mice (7) were described previously. All male mice used for experiments are on FVB, C57BL6J, and 129Sv hybrid background. Animals were allocated to experimental groups based on their genotypes and ages. Investigators were not blinded to the genotypes and ages. We did not estimate sample sizes before the experiments. All samples were included in analysis when control samples validated the experiments. Sample sizes were chosen when we obtained a p value, which was based on at least three biological replicates. Mice were maintained under pathogen-free conditions in the Albert Einstein College of Medicine animal facility. Mouse experiments protocols were reviewed and approved by Einstein Animal Care and Use Committee, conforming to accepted standards of humane animal care. IHC, IF, TUNEL Assay and microscopy Tissue sections and staining have been described previously (16). Briefly, paraffin embedded prostate tissues were sectioned at 5 μm thickness. Slides were deparaffinized, hydrated, and incubated in a steamer for 20 minutes in sodium citrate buffer (Vector Labs, H3301) for antigen retrieval. Sections were first treated with 3% H2O2 to quench endogenous peroxidase, washed several times, blocked with 10% normal goat serum, and then incubated in primary antibodies at 4°C overnight. For immunohistochemistry (IHC) and immunofluorescence (IF) staining, antibodies included: phospho-histone H3 (Cell Signaling Technology, #9701), Ki67 (Vector Labs, SP6), rabbit anti-p27 (Abcam, ab92741) and p73 (Abcam, ab40658). TUNEL staining was performed with an Apoptosis Detection Kit (Millipore, S7100). IHC staining was counterstained with Harris Hematoxylin (Poly Scientific R&D Corp, S212), and IF staining were counterstained with DAPI (Sigma-Aldrich, D-9564). Images were visualized with a Nikon Eclipse Ti-U microscope and captured with Olympus DP71 camera and DP Controller software (3.2.1.276), and saved with DP manager software (3.1.1.208). The images were further processed by Adobe Photoshop. For staining quantification, pictures ere taken under 400× magnificence, about 300–400 cells were counted in each image and 3 images from each mouse were counted. The data were presented as means of 3 mice. Early Passage Prostate Cancer Cell Cultures, DU145 Cell Line, Cell Proliferation Measurement, Organoid Cultures, and Treatments Primary prostate tumor cells were prepared from 0.3 cm × 0.3 cm tumor tissues, which were minced and dissociated in collagenase A in DMEM for 2 hours at 37°C. Primary prostate tumor cells were cultured in DMEM containing 10% FBS and their genotypes were confirmed by PCR genotyping of Rb1, Trp53, p27, and PB-Cre4. DU145 cell line was obtained from ATCC and we did not perform STR profiling on this line. DU145 was cultured in DMEM containing 10% FBS. Measurement of cell proliferation was performed as previously described (16). Prostate tumor cell organoid cultures were generated based on published protocols (48, 49). Quantification in Figure 5 was based on photographs of ten 10x lens fields, each field yielding 3–5 photographs focusing on consecutive planes inside Matrigel layers. Two duplicate wells were counted in this manner. Knockdown of Skp2 or p73 was by lenti-shRNA vectors obtained from the Einstein shRNA core facility (shSkp2: 5′-GCAAGACTTCTGAACTGCTAT-3′; shp73 (12753): 5′-GCGCCTGTCATCCCTTCCAAT-3′ and shp73 (12757): 5′-CAGCCTTTGGTTGACTCCTAT-3′); controlled by scrambled shRNA (shScrmbl). Generation of lentiviral stocks and transduction of cells were as described (53). Successful lentiviral transduction was ensured by puromycin (#BP2956-100, Fisher Scientific) resistance, followed by mRNA (RT-qPCR) and protein (Western blots) measurements. Compound 1 (C1, which inhibits interaction between Skp2/Cks1 and p27T187p (13)) was purchased from Xcess Biosciences Inc. (#432001-69-9). Prostate cancer cells were plated overnight and then treated with C1 for 2 days at the indicated concentrations. Western Blot, CHX, RT-qPCR, ChIP Assays Western blot, CHX, RT-qPCR, ChIP experiments were described previously (16, 17). Antibodies for Western blots are Skp2 (Santa Cruz Biotechnology, H435), p21 (Santa Cruz Biotechnology, SC-397), p27 (BD Bioscience, #610242), p73 (Abcam, ab40658), activated Caspase 3 (Cell Signaling Technology, #9661), and α-tubulin (Sigma-Aldrich, T6074). RT-qPCR primers for p27 are sense: 5′-GCGGTGCCTTTAATTGGGTCT and antisense: 5′-GGCTTCTTGGGCGTCTGC T; p73 sense: 5′-AACGCCGAGCATCAATCC) and antisense: 5′-AGCCCAGACTCTGAGCACTT; GAPDH sense (5′-GGTTGTCTCCTGCGACTTCA and antisense 5′-GGTGGTCCAGGGTTTCTTAC. ChIP antibodies are E2F1 (Santa Cruz Biotechnology, SC-193X), E2F4 (Santa Cruz Biotechnology, SC-866X), IgG (Santa Cruz Biotechnology, SC-2027). ChIP primer sequences are: E2F1: sense 5-CTTTGGAGGTGAGCCTGAAGAG-3′, antisense 5′-GGGTCTGGCGAAGCGAACA-3′; p73: sense 5′-TGAGAGTGCGGTTCTATTGGC-3′, antisense 5′-GCCCTGAACATCTGCGTCTC-3′; GAPDH: sense 5′-GAGTTCTGGGAGTCTCGTGG-3′, antisense 5′-CTCTTCGGGTGGTGGTTCA-3′. Flow Cytometry Analysis for sub-G1 Cell Populations Cells were plated for 16 hours. Cells were washed with PBS, trypsinized with 0.25% trypsin-EDTA at 37°C for 3–5 minutes, and resuspended with 0.5 ml PBS. Then cells were fixed with ice-cold 80% EtOH at 4°C overnight. The fixed cells were spun down and resuspended in 0.5 ml 0.25 mg/ml RNAse A and 30 μg/ml propidium iodide in PBS. Cells were filtered using 40 μm cell strainer before DNA content analysis using DXP10 Calibur at Einstein FACS core facility. Data were analyzed using Flowjo software. Statistical Analyses In Kaplan-Meier survival analysis, p value, hazard ratio and 95% confidence interval of hazard ratio were analyzed by log-rank test (GraphPad Prism 6 Software). p values for differences in Ki67, phospho-histone H3, and TUNEL positive cells, cell proliferation, RT-qPCR, and ChIP between indicated samples were analyzed by Student’s t-test. All statistical analyses are two-sided. p<0.05 is considered as statistically significant. We have not determined whether test data conform to normal distribution and we did not determine variance for any group of data. Supplementary Material Suppl This work was supported by NIH grants RO1CA127901and RO1CA131421 (LZ), Albert Einstein Comprehensive Cancer Research Center (5P30CA13330) and Liver Research Center (5P30DK061153) provided core facility support. HZ was a recipient of DOD PCRP Postdoctoral Fellowship (PC121837), and LZ was a Irma T. Hirschl Career Scientist Award recipient. We thank Dr. James Roberts for providing the p27T187A KI mice. Figure 1 p27T187A/T187A mice accumulated p27 protein in DKO prostate (A) Representative (from ten mice of each genotype) H&E and p27 IHC staining of consecutive prostate sections of the four genotypes as marked. (B) Protein levels were determined by Western blot of prostate ventral and anterior lobes of the indicated genotypes. A/A is abbreviated from T187A/T187A. (C) DKO and AADKO prostate cells were transduced with lentiviruses expressing the indicated shRNA (Scrmbl, scrambled sequences). Following antibiotic selection, the transduced cells were subject to Western blot for the indicated proteins. The same cells were subject to RT-qPCR to determine levels of p27 mRNA relative to GAPDH mRNA (D) and CHX chase to determine p27 protein stability compared to α-tubulin (E). Error bars indicate s.e.m. of the means of three samples. p value is by two-sided t test. Figure 2 p27T187A KI activated an E2F1-p73 axis (A) DKO and AADKO prostate cells treated with the indicated shRNA (as in Figure 1C) were subject to Western blot. (B) The same cells were used for RT-qPCR to determine levels of p73 mRNA relative to GAPDH mRNA. (C) ChIP assay using antibody for E2F1 (left), E2F4 (middle), or normal IgG as control, to determine recruitment of E2F1 and E2F4 onto E2F1, p73, and GAPDH promoters in DKO and AADKO prostate cells. Error bars indicate s.e.m. of the means of three samples. p values are by two-sided t test. ns, not significant (p > 0.05). (D) Representative (of three, see also Figure S2) p73 IHC staining of prostate sections of the four genotypes as indicated. (E) Protein levels were determined by Western blot with prostate ventral and anterior lobes of the indicated genotypes. Figure 3 p27T187A KI increased apoptosis in DKO prostate tumorigenesis and p73 played a major role in the apoptosis (A and B) Consecutive prostate sections of four genotypes, as indicated, stained with H&E or TUNEL. (C) Quantification of apoptosis. Arrows in the photograph demonstrate how total apoptosis was quantified. About 200 cells on each section/mouse were counted. The bar graph was based on the average of quantifications from three mice. p value is by two-sided t test comparing the combined apoptosis in p27+/+ and p27T187A/T187A mice. (D) RT-qPCR to determine knockdown efficiencies by two shp73 constructs. Error bars are s.e.m. (E and F) Propidium iodide based DNA content FACS (representative of two experiments) to detect and quantify apoptosis as sub-G1 cell% in the population, as marked above the brackets. Figure 4 Progression of DKO prostate tumorigenesis was inhibited in p27T187A/T187A mice (A) Representative H&E stained prostate sections of the indicated genotypes at the indicated ages. (B) Pathological diagnoses of prostate lesions as PIN of four stages, invasive carcinomas, and gross tumors. Numbers of mice examined in each age group are indicated below the chart. (C) Kaplan-Meier survival analysis comparing the p27+/+ and p27T187A/T187A cohorts of mice undergoing DKO prostate tumorigenesis. Hazard ratio = 2.514, 95% confidence interval = 2.077 to 6.222, p is by log-rank test. Figure 5 A specific inhibitor of SCFSkp2/Cks1 selectively inhibited DKO prostate tumor cells and DU145 cells in monolayer cultures (A) The designed inhibition mechanism for SCFSkp2/Cks1 inhibitor Compound 1 (C1) compared to p27T187A KI (p57 is a predicted substrate). (B) Proliferation chart showing cell numbers relative to the vehicle (DMSO) following treatment with Skp2/Cks1 pocket inhibitor Compound 1 (C1) at three concentrations after 2 days in monolayer cultures of the indicated cells. (C) p27T187A KI inhibited proliferation of DKO prostate tumor cells in monolayer culture (representative of three independent experiments). Error bars are s.e.m. of the means of triplet plates. p value is by two-sided t test. Cell numbers were counted in triplicate plates every two days for six days. (D) Western blot following treatment with C1 (5 μM) for 2 days. Figure 6 A specific inhibitor of SCFSkp2/Cks1 selectively inhibited DKO prostate tumor cell in organoid cultures. (A and B) Organoid cultures of DKO and AADKO prostate tumor cells after 15 days in culture. (C and D) The same areas of the organoid cultures were photographed on day 15 and day 21. Solid red arrows point to some examples of organoids growing larger, dashed red arrows point to some examples of organoids disintegrated into debris piles. (E) Organoids of various sizes in (A, a, b, and c in red) were cropped out and shown at the original photograph size. (F) Debris piles in (B, a and b in blue) were cropped out and shown. (G) Counting of organoids and debris piles of various sizes following treatment with C1 at various concentrations for 15 days with vehicle (DMSO) control. (H) Fractions of organoids of the indicated sizes and debris piles. Table 1 Pairwise co-occurrence relationships among RB1, TP53, PTEN, NKX3-1 and MYC in primary prostate cancer and metastatic castration-resistant prostate cancer (mCRPC) Primary prostate cancer mCRPC Studies MSKCC, 20101 Broad/Cornell 2012 TCGA, 2015 MSKCC, 20101 Michigan, 20122 Robinson et al, 2015 Specimen #s 157 109 333 28 502 150 RB1 inactivation3 3.2% 0.0% 0.9% 10% 29% 8.6% TP53 inactivation3 1.9% 6.4% 7.5% 10% 54% 50% PTEN inactivation3 5.7% 7.3% 17% 39% 50% 40% NKX3-1 inactivation3 3.8% 0.0% 16% 3.6% 18% 3.3% MYC activation4 40% 1.8% 13% 50% 25% 19% Co-occurrence5 PPt, RM, PM, PtM PPt PM, RM, RPt, PPt RP, RN, PN, RPt, RM, PPt, NM, RN, PN, RPt, RP RP, PPt, NM, PM, RPt, PN, Statistic significance6 p = 0.033 p = 0.023 p = 0.039 We retrieved published data (54–58) and analyzed them on cBioPortal. 1 This study included both primary prostate cancer and mCRPC. 2 mCRPC specimens were obtained at autopsy. 3 Inactivation of RB1, TP53, PTEN, and NKX3-1 is queried for HOMDEL MUT. 4 Activation of MYC is queried for AMP MUT EXP > 2 (larger than 2 SD from the mean). 5 Tendency for co-occurrence is by Log Odds Ratio; R, P, Pt, N, and M are short for RB1, TP53, PTEN, NKX3-1, and MYC, respectively, to indicate the pairs. 6 p value is by Fisher Exact Test. p < 0.05 is considered statistically significant, which is highlighted by bold font. Other pairs show tendencies with p values between 0.083 and 0.575. Tendency pairs with p values between 0.631 (the next higher value) to 0.907 (the highest) are not shown. RB1 and TP53 often incur Shallow Deletions, suggesting biallelic inactivation for some Mutation samples, as shown by the Oncoprints for two studies in Figure. S5. 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PMC005xxxxxx/PMC5112159.txt
LICENSE: This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. 8806104 2772 Comput Med Imaging Graph Comput Med Imaging Graph Computerized medical imaging and graphics : the official journal of the Computerized Medical Imaging Society 0895-6111 1879-0771 27373749 5112159 10.1016/j.compmedimag.2016.05.003 NIHMS800935 Article Stain Normalization using Sparse AutoEncoders (StaNoSA): Application to digital pathology Janowczyk Andrew 1 Basavanhally Ajay 2 Madabhushi Anant 1 1 Case Western Reserve University, Cleveland, Ohio 2 Inspirata, Inc., Tampa, Florida 12 7 2016 16 5 2016 4 2017 01 4 2018 57 5061 This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. Digital histopathology slides have many sources of variance, and while pathologists typically do not struggle with them, computer aided diagnostic algorithms can perform erratically. This manuscript presents Stain Normalization using Sparse AutoEncoders (StaNoSA) for use in standardizing the color distributions of a test image to that of a single template image. We show how sparse autoencoders can be leveraged to partition images into tissue sub-types, so that color standardization for each can be performed independently. StaNoSA was validated on three experiments and compared against five other color standardization approaches and shown to have either comparable or superior results. digital histopathology stain normalization deep learning image processing 1. Introduction Digital pathology (DP) is the process by which histology slides are digitized to produce high resolution images via whole slide digital scanners [1]. These digitized slides afford the possibility of applying image analysis techniques to tissue images for the purpose of object detection, segmentation, and tissue classification. These automated image analysis algorithms are very relevant for nuclei detection, mitosis quantification, and tubule counting. Additionally these image analysis algorithms provide the ability of performing higher level, supervised learning tasks such as disease grading, thereby enabling the development of decision support algorithms for pathologists [2]. Prior to evaluation of the specimen under the microscope by a pathologist, the tissue is invariably treated by artificial or natural agents, to stain the various cellular structures. Hemotoxylin and Eosin (H&E) is one of the the most routinely used stains for evaluating disease morphology, an example of which is shown in Figure 1. The hemotoxylin provides a blue or purple appearance to the nuclei while the eosin renders eosinophilic structures (e.g., cytoplasm, collagen, and muscle fibers) a pinkish hue. Since the staining process is a chemical one, there are many variables which can drastically change the overall appearance of the same tissue. For example, the specimen thickness, concentration of the stain, manufacturer, time, and temperature at which the stain is applied can have significant implications for the appearance of the final tissue specimen. Figure 1a, shows an H&E stained gastrointestinal (GI) biopsy tissue image. Figure 1b shows a sample taken from the same specimen but stained using a slightly different protocol (i.e. a different concentration of H&E respectively), and as such, appears significantly darker. The staining process is not the only source of visual variability in imaging of tissue specimens. The digitization process also could potentially induce changes and variability in tissue image appearance. For example Figure 1 shows the same physical specimen scanned using two different scanners. Differences in the scanning platform (e.g., bulbs, ambient illumination, sensor chips), image stitching algorithms, and acquisition technologies (e.g., compression, tiling, whiteness correction) can also induce substantive differences in appearance of the resulting tissue image. Pathologists are specifically trained to be able to cope with these variations and for the most part do not struggle with diagnostic decision making or object counting/quantification (e.g., nuclear or mitosis counting). On the other hand, image analysis methods, especially supervised learning/classification algorithms for nuclei segmentation or tissue partitioning, typically find it more difficult to cope with variations in image appearance and staining [3]. For instance if an algorithm is trained to identify nuclei based off chromatic cues from a singe site, the variations in staining might cause the algorithm to have a large number of errors for slightly differently stained images from a different site. This is further compounded when we consider extremely large datasets that are curated from many different sites, such as The Cancer Genome Atlas (TCGA). These variations in stain and tissue appearance have spurred recent research in development of color standardization and normalization algorithms to help improve performance of subsequent image analysis algorithms [3, 4]. Often, this occurs by identifying a single image with the most optimal tissue staining and visual appearance, and designating this image as the ”template”. Subsequently all other images to be standardized have their intensity distributions mapped to match the distribution of the template image. Previous works [5, 6, 7] have suggested that partitioning the image into constitute tissue subtypes (i.e., epithelium, nuclei, stroma, etc.) and attempting to match distributions on a tissue-per-tissue basis is more optimal compared to an approach which involves simply aligning global image distributions between the target and template images. In the context of histopathology this process might involve first identifying stromal tissue, nuclei, lymphocytes, fatty adipose tissue, cancer epithelium both within the target and template images and then specifically establishing correspondences between the tissue partitions in the two images. Subsequently the tissue specific distributions could then be aligned between the target and template images. While these tissue specific alignment procedures [8] have had more success compared to global intensity alignment approaches [9], successfully identifying the partitions remains an open challenge. For example, nuclei segmentation on its own is a large area of research [10, 11, 12, 13], yet represents only a single histologic primitive. It is therefore clear that more powerful and flexible approaches are needed for automated partitioning of the entire tissue image into distinct tissue compartments. Our approach, Stain Normalization using Sparse AutoEncoders (StaNoSA), is based off the intuition that similar tissue types will be clustered close to each other in a learned feature space. This feature space is derived in an unsupervised manner, releasing it from the requirement of domain specific knowledge such as having to know the ”true” color of the tissue stains, a requirement for a number of other approaches [14]. Our approach employs sparse-auto encoders (SAE), a type of deep learning approach which through an iterative process learns filters which can optimally reconstruct an image. These filters provide the feature space for our approach to operate in. Once the pixels are appropriately clustered in this deep learned feature space into their individual tissue sub-types, tissue distribution matching (TDM) can occur on a per channel, per cluster basis. This TDM step allows for altering the target image to match the template image's color space. The main contribution of this work is a new TDM based algorithm for color standardization for digital pathology images and which employs sparse autoen-coders for automated tissue partitioning and establishing tissue specific correspondences between the target and template images. Autoencoding is the unsupervised process of learning filters which can most accurately reconstruct input data when transmitted through a compression medium. By performing this procedure as a multiple layer architecture, increasingly sophisticated data abstractions can be learned [15]. Additionally as part of our approach we perturb the input data with noise and attempt to recover the original unperturbed signal, an approach termed denoising auto-encoders [15], that has been shown to yield robust features. StaNoSA is thus a fully automated way of transforming images of the same stain type to the same color space so that the amount of variance from (a) technicians, (b) protocols, and (c) equipment could be minimized. The rest of the paper is organized as follows. Section 2 involves a review of the previous work in the field. Section 3 describes the approach (StaNoSA) and associated algorithms. Section 4 rigorously evaluates the method across 2 different datasets and compares the approach with a state of the art approach and 4 other common methods. Section 5 contains the discussion. Finally, in Section 6 we present our concluding remarks. 2. Previous Work and Novel Contributions Previous approaches [8] to color normalization for digital histopathology images tend to fall into one of two categories. The first set of approaches exploit staining characteristics directly, such as Beer-Lambert's law through color de-convolution [16]. They attempt to divide the image color space into individual stain contributions and normalize these individually. The second category of algorithms take a statistical approach which rely on finding clusters of pixels belonging to a similar tissue-types (e.g., nuclei, epithelium, stroma). Once these partitions are identified, and correspondences across different images is established, the color distributions can be matched to a template distribution, so that each histologic entity can be manipulated separately. While a thorough review of the state of the art is out of the scope of this paper, below, we briefly discuss and differentiate approaches most relevant to StaNoSA. Specifically, while many previous works operate solely in the gray color space [17, 18, 19], we limit our discussion primarily to color based approaches since the specific application considered in this work is digital pathology (and specifically H&E stained imagery). We do however direct the interested reader to a very recent review of state of the art [8] approaches for color normalization. 2.1. Stain Specific Algorithms The most popular and well cited backbone for stain specific normalization algorithms is color deconvolution (CD) [16]. CD is based on the idea that the individual stains can be separated and subsequently normalized independently. Subsequently, the normalized color channels can be recombined to recreate an improved version of the original color image. The underlying stain signals are identified and separated by taking advantage of the Beer-Lambert's law [16] which is then used to linearly estimate the contribution of each stain to the final pixel color. The stain matrix describes, through coefficients for each stain, how much each stain contributes to the final pixel color value. This approach has been shown to work well when the color matrix can be reliably and definitively determined [16]. On the other hand, identifying this matrix requires either (a) images which are scanned on the same scanner using only a single stain to compute the deconvolution matrix (a type of color calibration approach) or (b) a semi-supervised approach wherein users are required to select pixels corresponding to the relevant classes as shown in [20]. While in [16] the authors were able to obtain accurate estimations of the stain matrix on their specific dataset, the same stain matrix may not adequately generalize to images from other sites and scanning platforms. They describe how ideal matrices can be estimated but the process requires the usage of control tissue and a single stain scanning process which may not always be possible. It may also not be possible to identify a stain matrix that simultaneously addresses variations due to scanning platforms. Magee et al. in [21] discussed this limitation as well by alluding to the difficulty in identifying the appropriate parameters for the deconvolution matrix. 2.2. Clustering Type Algorithms A second category of approaches aims to identify distinct tissue clusters in a feature space and aims to perform a cluster-to-cluster distribution alignment across the template and target images. Some approaches have attempted to decompose an image using non-negative matrix factorization [22], only requiring knowledge of the number of stains used. Other approaches aim to classify every pixel in the image to one of multiple different tissue classes. In [23] the Expectation Maximization approach was employed to create a fuzzy labeling of the image into distinct tissue classes. However, these approaches [8] may not work optimally if the individual tissue clusters are not proportionately represented in the target and template images. For example, the EM approach in [23] could end up mapping similar appearing regions from distinct tissue classes to the same cluster. During the the TDM process this can lead to distorted color density distributions. 2.3. Novel Contributions In this paper we present a novel technique, StaNoSA, for fully unsupervised normalization of images to a template image. StaNoSA solely requires as input a template image, as opposed to domain specific information such as mixing coefficients or stain properties. This approach therefore enables the ability to shift a target image in the color domain to more accurately resemble the template image. We extend the approach initially presented in [23] by considering not solely chromatic value of pixels for clustering. Instead, we employ a fully unsupervised deep learned bank of filters. These filters represent optimal [24] filters for image reconstruction via compression. By operating in this filtered space, we obtain significantly more robust pixel classes. These classes are not tightly coupled to individual stain classes, and thus the approach has a greater likelihood of success in the case of challenging images, images where one might find new tissue classes or a disproportionate tissue distribution compared to the template image. A representative result showing the application of StaNoSA is presented in Figure 1, where we normalized the target image (Figure 1b) into the color space of the template image (Figure 1a) to produce a result (Figure 1c), which has very similar color characteristics as the template color space. This process was applied by clustering the pixels in a sparse auto-encoded feature space so that respective tissue partitions could be aligned using their respective color distributions. By using individual tissue partitions, StaNoSA is able to more sensitively modify the color space as compared to a global method where all pixels are considered concurrently. We can see the resulting density functions of the pixels in 3 channel RGB, from which we can see that the target image's distribution (Figure 1e) is heavily skewed towards the left. After normalization (Figure 1f) the probability distribution of the 3 channels more closely resembles that of the template image (Figure 1d). The primary novel contributions of this work may be summarized as follows. StaNoSA is a domain agnostic approach, in that it does not rely on specifically knowing stain values or tissue values allowing the user to choose the template to standardize to. StaNoSA leverages a sparse auto-encoder (SAE) [15, 25] as the core method to automatically partition the image into distinct tissue categories. DL methods have been shown to be robust and accurate for image partitioning [14]. First of its kind study in which we quantitatively measure intra-scanner and inter-scanner variances of digitized H&E histology images. 3. Methods 3.1. Notation For all methods, we define the dataset Z={C1,C2,…,CM} of M images, where an image C=(C,ψ) is a 2D set of pixels c ∈ C and ψ is the associated vectorial function which assigns RGB values. T=Ca∈Z is chosen from Z as the template image by which all other images in the dataset will be normalized to. Without loss of generality we chose S=Cb∈Z to be the ”target image”, which is to be normalized into the color space of T. See Table 1 for additional notation used in this manuscript. 3.2. Deep Learning of Filters from Image Patches Denoising auto-encoders are leveraged in this work to learn representative feature spaces for optimizing tissue partitioning. We present them briefly below. 3.2.1. One Layer Autoencoder From T we randomly select p∈Rv×v×3 sub-images, or patches, of v × v dimension in 3-tuple color space (RGB) (see Figure 3). We set V = v × v × 3 to simplify notation. These values are reshaped into a data matrix X∈Rp×V of x∈R1×V samples. This matrix X forms the basis from which the filters will be learned. A simple one layer auto-encoder can be defined as having both an encoding and decoding function. The encoding function encodes a data sample from its original dataspace of size V to a space of size h. Consequently, the decoding function decodes a sample from h space back to V space. We use notation from [15] where they show a typical encoding function for a sample x is (1) y=fθ(x)=s(Wx+b), parameterized by θ = {W, b}. W is a h × V weight matrix, b∈R1,V is a bias vector, and s is an activation function (in this work s is assumed to be the hyperbolic tangent function). The reconstruction of x, termed z, proceeds similarly using a decoding function z = gθ′ (y) = s(W′y + b′) with θ′ = {W′, b′}. Here W′ is a V × h weight matrix, and b′∈R1,h is a bias vector. We use stochastic gradient descent [26] to optimize both θ and θ′ relative to the average reconstruction error, θ*. To further use notation from [15], this error is defined as: (2) θ⋆,θ′⋆=argminθ,θ′1p∑i=1pL(x(i),z(i)) where the loss function L is a simple squared error L(x, z) = ||x – z||2. 3.2.2. Expansion to Multiple Layers and Denoising It has been shown that by applying these auto-encoders in a greedy layer wise fashion, higher level abstractions, in a lower dimensional space, may be learned. In particular, this means taking the output from layer l, i.e., y(l), and directly using that as the input (x(l+1)) at the next layer to learn a further abstracted output y(l+1) by re-applying Equation 2. Layer 1 has input x(1) of size R1×V and output y(1) of size R1×h(1). Layer 2 thus has x(2) = y(1) of size R1×h(1) and output y(2) of size R1×h(2). This layering can continue as deemed necessary. Additionally, by intentionally adding noise to the input values of X, more robust features across all levels may be learned. Briefly, we formalize this by saying X̂ = ϵ(X), where ϵ is a binomial corrupter which sets elements in X to 0 with probability ϕ. Using x̂ in place of x in Equation 1, results in the creation of a noisy lower dimensional version ẑ. This reconstruction is then used in Equation 2 in place of z, while the original x remains in place. 3.2.3. Generating feature space representations for image Once the filters are learned for all levels, we apply the full hierarchy of encoders on both the template image, T, and a ”moving image”, S. The main assumption of our approach is that regardless of visual appearance, pixels belonging to the same tissue class will have similar responses to the learned filters. Figure 4 shows an example of this procedure using two images of the same tissue stained, but with different stain concentrations. It can be seen that although the visual appearance of these two images is quite different, the filters appear to elicit a similar response to similar tissue classes in the image. As such, this feature space allows for an unsupervised clustering process to identify tissue partitions. In Figure 4(c) and 4(f), each unique grayscale value represents a different cluster, suggesting that pixels of similar textural appearance tend to be grouped into the same cluster. However we note that there is no obvious connection between the individual clusters and the tissue classes present in the image. This therefore suggests that we need a subsequent unsupervised clustering step in order to align the tissue partitions. 3.3. Unsupervised Clustering Once we obtain the filter responses for T and S, i.e., T. and S. respectively, we aim to cluster them into individual partitions. To this end, we employ a standard k-means approach on T. to identify K cluster centers. Subsequently, we assign each of the pixels in S. to its nearest cluster, without performing any updating. This process yields S˚, a cluster indicator variable. This approach helps to assuage some of the typical instability issues commonly associated with k-means. We note that although the clustering is taking place on a pixel level, the feature space has been computed on a 32 × 32 window around each pixel, providing the necessary context for our clusters to be better informed. In [23], for instance, the K clusters loosely corresponded to individual tissue classes such as nuclei, stroma or lymphocytes. However, the maximum K that could be chosen in [23] was implicitly limited. In the case of StaNoSA, we use a much larger K, on the order of 50. A larger number of clusters potentially allows for more precisely tuned clusters. 3.4. Histogram Shifting Once the clusters are defined, a more precise color standardization process can take place. For each K, operating on a per channel basis, we standardize the distribution of the moving images to that of the template images [9]. We present this approach in Algorithm 2 which is the basis for the implementation of the imhistmatch function in Matlab. As was mentioned in Section 2, a common problem with global normalization techniques is the inability to account for both tissue class proportions and in cases where the color distributions are already similar, StaNoSA is able to minimize the overall error (see Experiment 1 in Section 4). By assigning the pixels in S to a larger number of clusters, but not performing updating, the disproportional class representation is effectively managed. 4. Experimental Evaluation To rigorously evaluate our approach, we perform three experiments, each focused on directly addressing a different reason for variance in color and appearance of pathologic tissue slides. Specifically we attempted to address variations induced by (a) differences in platform and scanners, and (b) staining. Additionally we also evaluated the performance of a nuclear detection algorithm on the pre- and post-standardized images to evaluate the role of color standardization methods in facilitating object detection. Using three different datasets, as shown in Table 2, we attempted to evaluate StaNoSA when (a) different concentrations of H&E were deliberately varied in the same tissue section and (b) when the same slide was scanned multiple times on two different platforms. Additionally we also compare our approach to 5 other color normalization approaches. 4.1. Datasets 4.1.1. Dual Scanner Breast Biopsies The S1 dataset consists of 5 breast biopsy slides. Each slide was scanned at 40x magnification 3 times on a Ventana whole slide scanner and once on a Leica whole slide scanner, resulting in 20 images of dimension 100,000 × 100,000 pixels. Each set of 4 images (i.e., 3 Ventana and 1 Leica), were mutually co-registered so that from each biopsy set, 10 sub-regions of 1,000 × 1,000 could be extracted. This resulted in 200 images: 10 sub-images from 4 scans across 5 slides. The slides were formalin fixed para n embedded and stained with Hematoxylin and Eosin (H&E), each slide having some evidence of cancer presence. Since the sub-images are all produced from the same tissue slide, this allows for a rigorous examination of intra- and inter-scanner variation. 4.1.2. Gastro-Intestinal Biopsies of differing protocols The S2 dataset consists of slices taken from a single cancer positive Gastro Intestinal (GI) biopsy. The specimen was formalin fixed paraffin embedded and had 7 adjacent slices sectioned from the same biopsy tissue and subjected to different staining protocols: HE, H↓E, H↑E, ↓HE, ↓H↓E, ↑HE, and ↑H↑E, where ↑ and ↓ indicate over- and under-staining of the specified dye. These intentional staining differences were intended to simulate the typical variability seen in clinical settings, especially across different sites. Each slide was then digitized using an Aperio whole-slide scanner at 40× magnification (0.25 μm per pixel), from which 25 random 1,000 × 1,000 resolution images were cropped at 20× magnification. Representative images within S2 can be seen in Figure 6. 4.1.3. Gastro-Intestinal Biopsies of differing protocols with annotations The S3 dataset is a subset of S2 manual annotations of the nuclei. From each of the 7 different protocols, as discussed above, a single image patch of about 1,000 × 1,000 pixels was cropped at 40× magnification. Nuclear boundaries were then delineated by an expert pathologist. 4.2. Comparative Color Standardization Schemes 4.2.1. DL Normalization The parameters used for each experiment associated with our approach (StaNoSA) are as follows: 250,000 patches of size (v) 32 × 32, were extracted from only template image. A 2 layer SAE was created with the first layer containing 100 hidden nodes (h1) and the second layer ten (h2). The denoising variable was set to ϵ = .2. Histogram equalization took place using Q = 128 bins. Additionally, the following pre-processing steps were applied to each cohort of images: ZCA whitening and global contrast normalization [27]. 4.2.2. Direct This ”approach” only employs the raw image without any modifications to quantify what would happen if no normalization was undertaken at all. 4.2.3. Global Standardization This approach is similar to Algorithm 2, except assuming that K = 1, in which all pixels in the image belong to a single cluster. Again, Q = 128 bins were used for the histogram matching process. 4.2.4. Four Additional Approaches We also compared StaNoSA against the publicly available stain normalization toolbox presented in [8]. This toolbox also comprises four additional approaches, Reinhard et al. (RH) [20], Macenko et al. (MM) [28], Histogram Specification (HS) [9], and Khan et al. (DM) [8]. We direct the reader to their respective papers for implementation details. 4.3. Implementation Details It took 5 hours to train the deep learning network using a Nvidia M2090 GPU with 512 cores at 1.3ghz and under 3 minutes to generate each output image needed for the clustering mechanism. Subsequently, for images of size 1,000 × 1,000, the entire clustering and shifting process takes under 1 minute on a 4 core 2.5ghz laptop computer. All deep learning was developed and performed using the popular open source library Pylearn2 [29] which uses Theano [30] for its backend graph computation. 4.4. Experiment 1: Standardization across scanners 4.4.1. Design We aim to evaluate the extent of differences between colors for the same slide scanned multiple times on the same scanner (Cj,iin, where i ∈ {1, 2, 3} represents the scan number and j ∈ {1, . . . , N} represents the image number) to compute intra-scanner error (μi,kin=∑jSSD(Cj,1in,Cj,2in)∕N, i ∈ {1, 2, 3}, k ∈ {1, 2, 3})) and the error in scanning the same slide across a different platform (Cjit,j∈ {1, ..., N}) to compute the inter-scanner error (μiit=∑jSSD(Cj,iin,Cj,1it)∕N, i ∈ {1, 2, 3})). The SSD error involves taking each color channel and computing a 128 bin histogram and use the sum of the squared difference of the bins for each of the color channels. The optimal error would of course be 0 if both images were identical. Our aim in this experiment was to evaluate whether StaNoSA could help bring μit into μin range. More specifically the goal was to assess whether |μit – μin| < γ where γ is a predefined threshold that represents σin, typical intra-scannar variance. While ideally we would have liked to perform a pixel level mean squared error difference between a template and target image, this was not possible on account of two issues. Firstly, the image resolution for slides digitized on the scanners is not identical. This in turn would actually require image re-scaling and interpolation which in turn would likely induce additional error. Secondly, there are visible tiling artifacts visible on both the intra/inter scanner images, making the pixel level error nearly impossible to determine. Instead, we use the SSD measure (introduced above) as a surrogate. Using the 200 images from dataset S1, we perform two experiments. First, we compute the mean and variance SSD per image (μin, σin) across the 3 Ventana scans (S1,Vi, i ∈ {1, 2, 3}) and apply StaNoSA to determine if it is possible to reduce μit, σit. Second, we use the co-registered Leica scan (S1,L) from each set and apply StaNoSA to S1,Vi, i ∈ {1, 2, 3}, measuring μit before and after StaNoSA is performed. 4.4.2. Results After comparing errors, we note that the SSD μin is about .03 (see Figure 5). The global normalization (GL) approach when applied to S1 seems to exacerbate the existing error. On the other hand, StaNoSA is clearly shown to not only reduce μin (.01) but also substantially reduce the σin seen within samples. We additionally also examined if and how variations in image appearance on account of the use of different scanners could be reduced (see Figure 5). In this instance, we see that the GL technique does indeed reduce μit from about .14 to .096, but our StaNoSA approach reduces the error down even more substantially to .047 which is on the order of μin as shown in Figure 2(b) which has a μin of .0473. In all cases, we can see that StaNoSA reduces both μin, μit and σin, σit. 4.5. Experiment 2: Standardization Across Stain Protocols 4.5.1. Design We aim to determine how well StaNoSA can succeed at minimizing SSD by bringing S into the color space of T. In this experiment we use S2 as a way to quantify how well the mean SSD error (μp,q=∑iSSD(Cp,Cqin)∕N,i∈{1,…,N}, where p, q represent any of the 7 stain proctols (e.g., HE, H↓E, H↑E, ↓HE, ↓H↓E, ↑HE, and ↑H↑E) can be reduced across S2. In each instance we arbitrarily select T from the group and attempt to standardize the remaining 6 images to that image and compute μp,q and the variance σp,q. We do this for all protocol pairings (i.e., p, q) and images: 7 protocols versus the remaining 6 with 25 images each resulting in 1,050 normalization operations. We report both μp,q and σp,q across all protocols. 4.5.2. Results The confusion matrix shown in Table 3 contains μp,q and σp,q for all p, q. Here we stress that it is impossible for the μp,q to be zero as images are adjacent slices, not replicates as in S1. Hence there are guaranteed to be slight differences in the visual appearance of the slides. It can be seen that StaNoSA consistently provides the smallest μp,q. In Figure 6 we present images of S2 for qualitative evaluation, choosing specifically the most extreme of the images to normalize: ↓H↓E and ↑H↑E. We can see that although the stains are notably different in S2, our approach can successfully alter S to match the color space of T. 4.6. Experiment 3: Evaluate standardization via object detection 4.6.1. Design In this experiment we evaluate the effect of color standardization on a particular object detection task, namely nuclei detection. Our experiment involves selecting two H&E images to be used as templates (Figure 7), one which is not anomalous (Figure 7a) and one which is (see Figure 7b). The large proportion of red blood cells in the image tends to affect the balance of representation of tissue classes and hence can affect the performance of various color standardization algorithms. We perform color deconvolution using the H&E stain matrix as presented in [16]. Subsequently, we identify the optimal threshold (ψ = .914 in this instance) on the T image, by which to separate the nuclei stained pixels from other pixels in the resultant H channel. Lastly we normalize the 7 images of S3 to T, and process them in similar fashion: (a) color deconvolution followed by (b) thresholding. To evaluate the results, we compute the Dice coefficient [31] (μϕ=∑iϕ(i)∕N, i ∈ {i, ..., N}) and its variance (σϕ) of the resulting nuclei as compared to the manually annotated ground truth for all approaches (e.g., Direct, GL, StaNoSA, DM, HS, MM, and RH). We chose an H&E image from S2 to act as T, but one in particular which does not have balanced class proportions (Figure 7b). We specifically selected the template image in Figure 7b to determine if the methods we compare against (Direct, GL, StaNoSA, DM, HS, MM, and RH) are robust against imbalanced tissue class representations. To provide a comparison, T shown in Figure 7a does not have any unusual artifacts which disrupt the relative class proportionality. 4.6.2. Results As we can see from Figure 8 and Figure 9, the StaNoSA is able to improve μϕ by 10% while reducing σϕ. One of the difficulties with color deconvolution, as discussed in [8], is the fact that the approach needs careful selection of the appropriate stain matrix in order to achieve satisfactory results. In this case, because we have seven different staining protocols, it is unlikely that the same matrix would consistently work well. Instead, using StaNoSA, we find T which works well and then shift S3 to that image. In the cases of ↑H and ↑H↑E we see significant improvements in color constantcy across S3 as a result of StaNoSA. As expected, GL and HS (global normalization techniques) perform poorly because of the large red blood cell artifacts. On the other hand, when these artifacts are not present, the GL, HS, and StaNoSA normalization technique perform comparably. 5. Discussion Color standardization of digital histopathology images is critical to reducing stain variability and improving the robustness of computer assisted diagnostic and image quantification algorithms such as nuclei and mitoses detection. Previous approaches have potentially been handicapped by the necessity of accurately defining a stain matrix or requiring images to have similar tissue type representations in the image (i.e., similar proportions of stroma, nuclei). StaNoSA is able to circumvent the need for a stain matrix by identifying tissue sub-types within the image in an unsupervised manner. The large number of tissue sub-types produced affords the opportunity of managing class imbalances better than previous approaches, by providing greater specificity through more tightly defined clusters. In this manner, only very similar pixels in the template image are used to normalize a target pixel, as opposed to all pixels at a histologic primitive level (e.g., all epithelial pixels). The larger number of clusters helps manage situations where there is a significant proportional difference in the presence of individual tissue classes in the target and template images. Traditionally, the most important aspect of a normalization process is choosing an optimal template image. While it makes sense to develop algorithms with as much robustness as possible, inferring cohort parameters from a poor template image will typically be a challenging proposition. The most important quality associated with a good template image, especially in the context of color standardization approaches, is that it should be representative of the other cases within the cohort. Theoretically one would ideally wish to have a correspondence from every pixel value (or color) within the template image to a corresponding pixel color in each of the cohort images, so that the color distributions can be brought into alignment. Since having such an idealized template image is highly unlikely, we attempt to select one which comes as close as possible to such an ideal image. This therefore implies the need for template images which proprtionately cover the various tissue classes of interest - nuclei, stroma, epithelium, blood vessels, etc. The presence of these tissue classes are imperative within the target and template images in order to be able to identify and align tissue clusters. In general, normalization of images becomes increasingly difficult when the variations in staining of the slides increases. Our results show that in many cases, when the moving and template images are similar in terms of their staining characteristics, less sophistocated approaches tend to do very well. It is in scenarios where there is large discrepancy in staining variations between slides that the StaNoSA approach is able to demonstrate a substantial improvement over the state of the art. As StaNoSA is computationally more burdensome, it may be possible to selectively invoke StaNoSA in only those settings where it is determined that the tissue class representation for the target and template images differ substantially. 6. Concluding Remarks In this work, we present a new color standardization approach called Stain Normalization using Sparse AutoEncoders (StaNoSA) which attempts to address the limitations of previous related approaches. We leverage the intuition that filters learned via deep learning tend to respond similarly to tissue sub-types having similar characteristics, even across images. This invariance allows for accurate, and unsupervised, partitioning of the tissue compartments for subsequent histogram matching and alignment. In a comparison of StaNoSA with 4 different color standardization approaches (one of them being a recent state of the art scheme), StaNoSA was able to (1) reduce inter scanner color variance to within the range observed in images scanned multiple times on the same scanner, (2) reduce extreme variations in color induced by differential staining, slide preparation, and slide digitization, and (3) improve performance of subsequent image processing algorithms, specifically nuclei detection. In a majority of cases, StaNoSA outperformed the other comparative approaches, in many cases by over 50%. In conclusion, StaNoSA appears to be able to handle situations wherein tissue classes are disproportionately represented between target and template images. Future work will entail a more rigorous and automated way of identifying the algorithmic parameters (e.g. number of clusters K) and larger scale validation studies. Acknowledgments Research reported in this publication was supported by the National Cancer Institute of the National Institutes of Health under award numbers 1U24CA199374-01, R21CA167811-01, R21CA179327-01; R21CA195152-01 the National Institute of Diabetes and Digestive and Kidney Diseases under award number R01DK098503-02, the DOD Prostate Cancer Synergistic Idea Development Award (PC120857); the DOD Lung Cancer Idea Development New Investigator Award (LC130463), the DOD Prostate Cancer Idea Development Award; the Ohio Third Frontier Technology development Grant, the CTSC Coulter Annual Pilot Grant, the Case Comprehensive Cancer Center Pilot Grant VelaSano Grant from the Cleveland Clinic the Wallace H. Coulter Foundation Program in the Department of Biomedical Engineering at Case Western Reserve University. The content is solely the responsibility of the authors and does not necessarily represent the official views of the National Institutes of Health. Figure 1 Visual appearance of the H&E slides can differ greatly depending on protocols and equipment used for staining. A GI stained H&E sample (a) acts as a template image, while the target image (b) is another H&E GI image in which we can see a strong visual difference due to staining protocol. Finally, after applying StaNoSA we can see (c) a shifted version of (b) which is in the same color space as (a). Their respective intensity distributions for each of the R, G, B color channels are presented in panels (d)-(f) respectively, which in turn show that the color distributions for the target images histogram (e) is heavily skewed towards the left. After applying StaNoSA (f) the intensity distribution for each of the 3 channels begins to more closely resemble that of the template image (d). Panels (g) and (h) show the same tissue slide but digitized with a (g) Leica scanner and (h) Ventana scanner, respectively. We can see that even though the only difference between the two images is the fact that they were digitized on two different scanners, panel (g) reveals more of a pink hue while (h) presents with a darker purple appearance. These differences are reflected in the corresponding color distributions ((i), (j)) for the two images in (g) and (h) respectively. Figure 2 An illustrative flowchart showing the StaNoSA process of color standardization. Figure 3 Original image (a) used as T with a sampling of (b) random training patches. For a sparse autoencoder to learn representative filters well, we need to ensure an image is well represented from the patches which are extracted. We can see in (b) that our sampling procedure provides a nice distribution of the various classes which are present in the image such as background (red arrow), nuclei (green arrow), lymphocytes (blue arrow), and stroma regions (yellow arrow). Figure 4 Illustration of different filter responses via the StaNoSA algorithm on H&E images. We can see that both the (a) template image and (d) moving image respond to an arbitrarily selected (b) & (e) filter in similar ways. Extracted from the green boxes of (a) and (d), the assignment of each pixel to one of 50 clusters can be viewed in gray scale shown in (c) and (f), respectively. Figure 5 Box and Whisker plots showing μin and σin for intra scanner differences ((a)-(c)). We compare (a) S1,V1 to S1,V2, and (b) S1,V3 and then (c) S1,V2 to S1,V3. Red line indicates μin, the blue box bounds the 25th percentile and the black whiskers extend to the 75th percentile. It can be seen quite clearly that our StaNoSA approach not only reduces μin, but also reduce variance across σin. Additionally, we compare ((d)-(f)) S1,L to S1,Vi i ∈ {1, 2, 3} and see a similar trend for μit and σit. Figure 6 The original ↓H↓E and ↑H↑E images in the top row. In the middle row we normalize to the others color space, such that ↑H↑E gets normalized to ↓H↓E and ↓H↓E gets normalized to ↑H↑E. Lastly, we show both of them being normalized to the standard HE image. In all cases, we can see that the images strongly resemble their template image color characteristics. Figure 7 Typical (a) T versus a (b) T used which was specifically chosen because of the class dis-proportionality. In particular we see the large pink object, of red blood cells in (b), on the right side of the screen. It would be expected that this affects the GL and HS approachs as non-red blood cells in S are aligned with the red blood cells histogram components. Figure 8 Box and Whisker plots showing μϕ and σϕ before normalization and normalization using Direct, Global Histogram (GL), Reinhard et al. (RH) [20], Macenko et al. (MM) [28], Histogram Specification (HS) [9], and Khan et al. (DM)[8]. Panel (a) shows the instances where the template and moving image share similar tissue class proportions, while (b) illustrates the consequences of having imbalanced class proportions. The Red line indicates the mean, the blue box bounds the 25th percentile and the black whiskers extend to the 75th percentile. Figure 9 Bar plots showing μϕ on a per staining protocol basis (HE, H↓E, H↑E, ↓HE, ↓H↓E, ↑HE, and ↑H↑E, where ↑ and ↓ indicate over- and under-staining of the specified dye) before normalization and after normalization using Direct, Global Histogram, Reinhard et al. (RH) [20], Macenko et al. (MM) [28], Histogram Specification (HS) [9], and Khan et al. (DM)[8] Table 1 List of common mathematical notation in this paper. Symbol Description T Template Image T. Feature space representation of T T˚ A pixel-wise cluster indicator of T S Target Image p Number of patches v Width and height of patches V Number of elements per patch (i.e., v × v × 3 in RGB) x Vector version of p of size 1 × V X Data matrix of size p × V W Weight Matrix of size h × V b Bias vector of size 1 × V θ Encoding function paramterised by {W,b} θ* Optimal θ found by gradient descent ε Bionomial corrupter X̂ A corrupted version of X (i.e., ε(X)) l Layer indexing variable x (l) Representation of x at layer l Table 2 The three unique datasets used in the evaluation of Stanosa Name Organ Stain Images Importance S 1 Breast HE 25 at 40× Same slides scanned on different equipment S 2 GI HE 175 at 40× Adjacent slices stained using different protocols S 3 GI HE 7 at 40× A subset of S2 containing manual annotations of nuclei boundaries Table 3 Confusion matrix showing μp,q and σp,q across all 7 protocols of 25 images for Direct, Global Histogram (GL), Reinhard et al. (RH) [20], Macenko et al. (MM) [28], Histogram Specification (HS) [9], and Khan et al. (DM) [8]. Lowest μp,q for each group is bolded. In almost all cases, StaNoSA has the lowest μp,q. HE ↑H↑E ↓H↓E ↓HE H↓E H↑E ↑HE HE N/A 0.35±0.02 0.43±0.03 0.43±0.03 0.45±0.03 0.46±0.03 0.54±0.03 Direct N/A 0.09±0.00 0.12±0.00 0.12±0.00 0.11±0.00 0.11±0.00 0.10±0.00 GL N/A 0.05±0.00 0.06±0.00 0.05±0.00 0.04±0.00 0.04±0.00 0.04±0.00 StaNoSA N/A 0.07±0.00 0.10±0.00 0.10±0.00 0.08±0.00 0.09±0.00 0.07±0.00 DM N/A 0.41±0.02 0.34±0.02 0.37±0.02 0.33±0.02 0.35±0.02 0.38±0.02 HS N/A 0.35±0.05 0.42±0.03 0.42±0.03 0.45±0.03 0.45±0.03 0.45±0.03 MM N/A 0.48±0.02 0.43±0.03 0.43±0.03 0.48±0.02 0.47±0.02 0.55±0.02 RH ↑H↑E 0.35±0.02 N/A 0.39±0.01 0.36±0.01 0.29±0.01 0.27±0.01 0.25±0.02 Direct 0.28±0.01 N/A 0.14±0.00 0.12±0.00 0.10±0.00 0.10±0.00 0.10±0.00 GL 0.17±0.00 N/A 0.07±0.00 0.07±0.00 0.05±0.00 0.05±0.00 0.04±0.00 StaNoSA 0.28±0.01 N/A 0.13±0.00 0.12±0.00 0.10±0.00 0.10±0.00 0.09±0.00 DM 0.31±0.03 N/A 0.18±0.02 0.17±0.01 0.16±0.01 0.15±0.01 0.17±0.02 HS 0.96±0.14 N/A 0.22±0.01 0.22±0.01 0.20±0.02 0.20±0.02 0.21±0.02 MM 0.31±0.01 N/A 0.24±0.01 0.24±0.01 0.25±0.01 0.24±0.01 0.29±0.01 RH ↓H↓E 0.43±0.03 0.39±0.01 N/A 0.10±0.01 0.19±0.01 0.24±0.01 0.41±0.01 Direct 0.33±0.02 0.16±0.01 N/A 0.10±0.00 0.10±0.00 0.10±0.00 0.09±0.00 GL 0.28±0.01 0.16±0.01 N/A 0.03±0.00 0.04±0.00 0.05±0.00 0.06±0.00 StaNoSA 0.34±0.02 0.15±0.01 N/A 0.07±0.00 0.08±0.00 0.08±0.00 0.07±0.00 DM 0.37±0.02 0.22±0.02 N/A 0.12±0.02 0.11±0.01 0.15±0.01 0.22±0.03 HS 1.04±0.17 0.37±0.18 N/A 0.09±0.01 0.14±0.01 0.16±0.01 0.23±0.02 MM 0.38±0.00 0.43±0.00 N/A 0.32±0.01 0.36±0.00 0.34±0.01 0.45±0.00 RH ↓HE 0.43±0.03 0.36±0.01 0.10±0.01 N/A 0.14±0.00 0.20±0.00 0.39±0.01 Direct 0.34±0.02 0.16±0.01 0.11±0.00 N/A 0.09±0.00 0.09±0.00 0.09±0.00 GL 0.27±0.01 0.15±0.01 0.06±0.00 N/A 0.05±0.00 0.05±0.00 0.06±0.00 StaNoSA 0.34±0.02 0.16±0.01 0.10±0.00 N/A 0.08±0.00 0.08±0.00 0.07±0.00 DM 0.39±0.02 0.21±0.02 0.11±0.01 N/A 0.11±0.01 0.11±0.01 0.18±0.01 HS 1.02±0.14 0.35±0.17 0.10±0.01 N/A 0.12±0.00 0.15±0.00 0.22±0.01 MM 0.36±0.00 0.42±0.00 0.29±0.00 N/A 0.34±0.00 0.32±0.00 0.43±0.01 RH H↓E 0.45±0.03 0.29±0.01 0.19±0.01 0.14±0.00 N/A 0.11±0.00 0.30±0.01 Direct 0.37±0.02 0.18±0.01 0.15±0.00 0.13±0.00 N/A 0.09±0.00 0.09±0.00 GL 0.28±0.01 0.15±0.01 0.07±0.00 0.06±0.00 N/A 0.03±0.00 0.04±0.00 StaNoSA 0.36±0.02 0.18±0.02 0.15±0.00 0.13±0.00 N/A 0.08±0.00 0.08±0.00 DM 0.27±0.02 0.22±0.02 0.12±0.01 0.11±0.01 N/A 0.12±0.01 0.20±0.02 HS 1.25±0.14 0.36±0.18 0.17±0.00 0.16±0.00 N/A 0.09±0.00 0.17±0.01 MM 0.34±0.00 0.36±0.00 0.26±0.01 0.26±0.01 N/A 0.26±0.01 0.36±0.01 RH H↑E 0.46±0.03 0.27±0.01 0.24±0.01 0.20±0.00 0.11±0.00 N/A 0.28±0.01 Direct 0.37±0.02 0.18±0.01 0.15±0.00 0.13±0.00 0.10±0.00 N/A 0.10±0.00 GL 0.27±0.01 0.14±0.01 0.07±0.00 0.06±0.00 0.03±0.00 N/A 0.04±0.00 StaNoSA 0.36±0.02 0.17±0.01 0.14±0.00 0.12±0.00 0.08±0.00 N/A 0.08±0.00 DM 0.32±0.02 0.18±0.02 0.14±0.01 0.12±0.01 0.11±0.01 N/A 0.17±0.02 HS 1.24±0.12 0.38±0.20 0.21±0.01 0.19±0.00 0.09±0.00 N/A 0.17±0.01 MM 0.31±0.00 0.35±0.00 0.23±0.00 0.22±0.00 0.26±0.00 N/A 0.34±0.00 RH ↑HE 0.54±0.03 0.25±0.02 0.41±0.01 0.39±0.01 0.30±0.01 0.28±0.01 N/A Direct 0.38±0.02 0.20±0.02 0.17±0.00 0.15±0.00 0.11±0.00 0.12±0.00 N/A GL 0.28±0.01 0.15±0.02 0.09±0.00 0.08±0.00 0.05±0.00 0.05±0.00 N/A StaNoSA 0.38±0.02 0.19±0.02 0.16±0.00 0.14±0.00 0.10±0.00 0.11±0.00 N/A DM 0.27±0.02 0.19±0.02 0.15±0.02 0.13±0.01 0.14±0.01 0.13±0.01 N/A HS 1.50±0.12 0.44±0.26 0.27±0.01 0.26±0.01 0.16±0.01 0.16±0.01 N/A MM 0.29±0.00 0.22±0.01 0.22±0.00 0.22±0.00 0.18±0.00 0.18±0.00 N/A RH Algorithm 1 LearningFilters Input: A template image T, a target image S, patch matrix X, number of levels L, architecture configuration h Output: T.∈R∣T∣×h(L),S.∈R∣S∣×h(L)     1: T.=ψ(c),∀c∈(T)     2: S.=ψ(c),∀c∈(S)     3: for l = 1 to L do     4:     Find θ(l)*, θ′(l)* using Equation 2     5:     X = fθ(l)* (X)     6:         T.=fθ(l)⋆(T.)     7:         S.=fθ(l)⋆(S.)     8: end for     9: return T.,S. Algorithm 2 HistogramMatching Input: T,T˚,S,S˚,K, number of bins Q Output: final normalized image S~     1: for k = 1 : K do     2:     T^=subset of T which has T˚=k     3:     S^=subset of S which has S˚=k     4:     for h = {R, G, B} do     5:         fT = Cumulative Sum of ψT^,h(T^) using Q bins     6:         fS = Cumulative Sum of ψS^,h(S^) using Q bins     7:         Δ is a function which minimizes ∣fS(Δ(q))−fT(q)∣∀q∈{1,…,Q}     8:                 ψS,h(S^)=Δ(S^)     9:         end for     10: end for     11: return R(q) Highlights Digital histopathology slides have many sources of variance These variances can cause algorithms to perform erratically Stain Normalization using Sparse AutoEncoders (StaNoSA) in introduced It standardizes color distributions of a test image to a single template image Validated using 3 experiments with 5 other color standardization approaches This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final citable form. Please note that during the production process errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain. References 1 Gurcan M Boucheron L Histopathological image analysis: a review. IEEE Rev Biomed Eng 2009 2 147 171 20671804 2 Veta M Pluim J Breast cancer histopathology image analysis: a review. IEEE Trans Biomed Eng 2014 61 5 1400 1411 24759275 3 Monaco J Hipp J Image segmentation with implicit color standardization using spatially constrained expectation maximization: detection of nuclei. 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PMC005xxxxxx/PMC5112176.txt
LICENSE: This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. 2985117R 4816 J Immunol J. Immunol. Journal of immunology (Baltimore, Md. : 1950) 0022-1767 1550-6606 25786692 5112176 10.4049/jimmunol.1401220 NIHMS664582 Article The TNF-family ligand TL1A and its receptor DR3 promote T-cell mediated allergic immunopathology by enhancing differentiation and pathogenicity of IL-9 producing T cells1 Richard Arianne C. *2 Tan Cuiyan †2 Hawley Eric T. * Gomez-Rodriguez Julio ‡ Goswami Ritobrata § Yang Xiang-ping ¶ Cruz Anthony C. * Penumetcha Pallavi * Hayes Erika T. * Pelletier Martin * Gabay Odile * Walsh Matthew ‖ Ferdinand John R. *# Keane-Myers Andrea ** Choi Yongwon ‖ O'Shea John J. ¶ Al-Shamkhani Aymen # Kaplan Mark H. § Gery Igal † Siegel Richard M. *2 Meylan Françoise *2 * Immunoregulation Section, Autoimmunity Branch, NIAMS, NIH † Experimental Immunology Section, NEI, NIH ‡ Genetic Disease Research Branch, NHGRI, NIH § Department of Pediatrics and Microbiology and Immunology, Indiana University School of Medicine ¶ Molecular Immunology and Inflammation Branch, NIAMS, NIH ‖ Department of Pathology and Laboratory Medicine, University of Pennsylvania, Philadelphia, PA # Cancer Sciences Academic Unit, Faculty of Medicine, University of Southampton, Southampton, UK ** Biological Defense Research Directorate, Biological Naval Medical Research Center, Fort Detrick, MD Corresponding author: Richard M. Siegel, M.D, Ph.D. Bldg 10 Rm 13C103A, NIH Bethesda MD, 20892, rsiegel@nih.gov, Ph: 301-496-3761, FAX: 301-451-5394 2 Equal Contributors 28 3 2015 18 3 2015 15 4 2015 16 11 2016 194 8 35673582 This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. The TNF family cytokine TL1A (Tnfsf15) costimulates T cells and type 2 innate lymphocytes (ILC2) through its receptor DR3 (Tnfrsf25). DR3-deficient mice have reduced T cell accumulation at the site of inflammation, and reduced ILC2-dependent immune responses in a number of models of autoimmune and allergic diseases. In allergic lung disease models, immunopathology and local Th2 and ILC2 accumulation is reduced in DR3 deficient mice despite normal systemic priming of Th2 responses and generation of T cells secreting IL-13 and IL-4, prompting the question of whether TL1A promotes the development of other T cell subsets that secrete cytokines to drive allergic disease. Here we find that TL1A potently promotes generation of murine T cells producing IL-9 (Th9) by signaling through DR3 in a cell-intrinsic manner. TL1A enhances Th9 differentiation through an IL-2 and STAT5-dependent mechanism, unlike the TNF-family member OX40, which promotes Th9 through IL-4 and STAT6. Th9 differentiated in the presence of TL1A are more pathogenic, and endogenous TL1A signaling through DR3 on T cells is required for maximal pathology and IL-9 production in allergic lung inflammation. Taken together, these data identify TL1A-DR3 interactions as a novel pathway that promotes Th9 differentiation and pathogenicity. TL1A may be a potential therapeutic target in diseases dependent on IL-9. Introduction Cytokines in the TNF superfamily have important roles in host defense and amplification of both innate and adaptive immune responses. The TNF family cytokine TL1A costimulates T cells and innate lymphocytes through its unique receptor DR3 (Tnfrsf25). TL1A is synthesized in response to TLR ligands and other proinflammatory stimuli and optimizes T cell responses to bacterial pathogens such as salmonella and viral infections (1, 2). TL1A may also be involved in autoimmune disease pathogenesis, as TL1A levels are elevated in chronic inflammatory diseases such as rheumatoid arthritis and inflammatory bowel disease (3-5). Genetic variants in the TL1A locus are associated with human inflammatory bowel disease (6, 7), and a duplication in the DR3 locus has been linked to rheumatoid arthritis (8). TL1A/DR3 interactions are required for maximal pathology in diverse autoimmune disease models including collagen-induced arthritis (CIA), experimental autoimmune encephalomyelitis (EAE), and multiple forms of induced colitis (9-13). In allergic disease models, TL1A plays an important role in T cell-dependent airway hypersensitivity induced by ovalbumin (10, 14) and in ILC2-driven allergic lung disease triggered by papain exposure (15, 16). While TL1A has been shown to activate ILC2s and promote IL-13 production in allergic disease (15, 16), the mechanism by which TL1A enhances the adaptive arm of allergic responses remains less clear. IL-9 is an important driver of allergic disease (17-21), and although its production was historically attributed to the Th2 subset of CD4+ T cells, recent work has highlighted another T cell subset, named Th9, as a major producer of IL-9 (22). Th9 can be generated from naïve T cell precursors by activation in the presence of TGFβ and IL-4, with IL-4 acting through Signal Transducer and Activator of Transcription 6 (STAT6) (23-25). Alternative cytokines and signaling molecules such as IL-25, IL-1, TSLP, Jagged-2, calcitonin gene-related peptide and the TNF-family member OX40 ligand (OX40L) have been proposed to enhance Th9 differentiation and/or T-cell production of IL-9 (17, 26-30), while cyclooxygenase-2-derived prostaglandins, programmed cell death ligand 2, and 1,25-dihidroxyvitamin D3 inhibit Th9 polarization (31-33). In addition to murine allergic lung disease, T cell production of IL-9 has been shown to promote T-cell mediated inflammatory eye disease, EAE, colitis, and clearance of intestinal nematode infection (23, 24, 34-38). In the lung, IL-9 acts on mast cells, epithelial cells and smooth muscle cells to promote production of cytokines and chemokines such as IL-8, IL-13 and eotaxin, which enhance recruitment and activation of neutrophils, eosinophils and mast cells in allergic inflammation. IL-9 also induces smooth muscle hyperplasia and goblet cell metaplasia, important factors in the airway remodeling seen in asthma and allergic airway disease (19, 39, 40). Importantly, IL-9 has been shown to induce airway remodeling in an IL-13 dependent manner, placing IL-9 ‘upstream’ of IL-13 in these disease models (37, 41). We investigated the role of TL1A in promoting IL-9 production in allergic and autoimmune disease, and found that during T cell-dependent induced airway hypersensitivity and the T cell phase of allergic lung disease, total IL-9 and the number of IL-9-producing T cells are reduced in concert with decreased allergic pathology in Tnfrsf25-/- mice, leading to the hypothesis that TL1A may drive Th9 differentiation. Indeed, TL1A specifically and potently enhances the differentiation of IL-9 secreting T cells from naïve T cell precursors. Enhancement of IL-9 secretion depends on cell-intrinsic signaling through DR3, as well as TGFβ. TL1A can act independently of STAT6, but IL-2 signaling through STAT5 is absolutely required for its enhancement of Th9 differentiation. TL1A also acts independently of the ETS family transcription factor PU.1, which has previously been found to be important for Th9 generation (18). In addition to promoting Th9 differentiation, TL1A enhances pathology induced by Th9 in models of experimental eye inflammation and allergic airway disease. DR3-deficient Th9 transferred into a wild-type host are defective in inducing allergic airway inflammation, indicating that endogenous TL1A signaling through DR3 is necessary for Th9 to promote allergic pathology. These results define TL1A as a cytokine that can promote the generation and pathogenicity of IL-9 secreting T cells through a pathway distinct from those previously defined for this T helper subset. Materials and Methods Mice Wild-type C57BL/6 and CD45.1+ mice were obtained from Taconic. Tnfrsf25-/- mice were generated as previously described (42), and were back-crossed to the C57BL/6 background for at least ten generations. This line was subsequently crossed to OT-II Rag-deficient mice. Stat5a/bfl/fl CD4Cre OT-II and Stat5a/bfl/fl OT-II mice were from the NIAMS Taconic mouse colony, and Stat6-/- mice were from Jackson Labs. Sfpi1fl/fl LckCre mice were produced as previously described (18). Mice used for the analysis of ocular inflammation were (FVB/N×B10.BR) F1 hybrids, transgenically expressing either HEL in their eyes (“HEL-Tg”), or HEL-specific TCR by their T- cells (“3A9”) (43). T cell specific TRAF6-deficient mice were previously described (44). T cell differentiation assays Lymph nodes and spleens were harvested from mice of the appropriate genotypes and cells were passed through a 40 μm strainer. Red blood cells were lysed with Ack lysis buffer, and cells were sorted for CD4+ T cells using the EasySep Mouse CD4+ T Cell Enrichment Kit (Stemcell Technologies), according the manufacturer's protocol. CD4+ T cells were then stained with anti-mouse CD4 PerCP-Cy5.5, anti-mouse CD44 APC, anti-mouse CD62L PE, and anti-mouse CD25 FITC (eBioscience and BD Biosciences). Naïve CD4+ T cells identified as CD4+, CD44lo, CD62Lhi, and CD25lo were separated by fluorescence-activated cell sorting on a FACSAria Flow Cytometer (BD Biosciences). For certain experiments, cells were CFSE-labeled. Cells were cultured in complete RPMI medium (RPMI with 10% fetal calf serum, 10 mM HEPES, 1 mM sodium pyruvate, 10 U/ml penicillin, 10 U/ml streptomycin, 2 mM glutamine and 0.05 mM β-mercaptoethanol). Cells were plated at 50,000-100,000 cells per well on 96-well plate or 100,000-400,000 cells per well on a 48-well plate. For activation and costimulation, plates were either coated with anti-CD3 (clone BE0001-1) and anti-CD28 (clone 37.51) or cells were cultured in the presence of T-depleted splenic antigen-presenting cells (APC) (5:1, APC:T cells) and soluble anti-CD3 and anti-CD28. APC were prepared from total mouse splenocytes that were strained, treated with Ack lysis buffer, and depleted of T cells by staining with biotin-conjugated Thy1.1 and using magnetic biotin beads in an AutoMACS Depletes sort (Miltenyi Biotec). APC were then irradiated at 1000 rad to prevent growth. Polarization conditions were as follows: for Th0, 10 μg/mL anti-IFNγ (clone XMG1.2) and 10 μg/mL anti-IL-4 (clone 11B11); for Th1, 20 ng/mL murine IL-12 and 10 μg/mL anti-IL-4 (clone 11B11); for Th2, 20 ng/mL murine IL-4 and 10 μg/mL anti-IFNγ; for Th9, 20 ng/mL murine IL-4 and 5 ng/mL human TGFβ; for Th17, 20 ng/mL murine IL-6, 5 ng/mL human TGFβ, 10 μg/mL anti-IFNγ (clone XMG1.2), 10 μg/mL anti-IL-4 (clone 11B11), and 10 μg/mL anti-IL-2 (clone S4B6); and for iTreg, 100 units/mL human IL-2, 10 ng/mL human TGFβ, 10 μg/mL anti-IL-4 (clone 11B11), and 10 μg/mL anti-IFNγ (clone XMG1.2). In presence of APC, anti-IL-12 was added for Th0, Th2 and iTreg conditions. Additional conditions included the following as indicated: 10 ng/mL TL1A, 10 ng/mL OX40L, 10 μg/mL anti-IL-9 (clone 222622), 10 μg/mL anti-IL-13 (ratIgG1) obtained from Centocor/Johnson and Johnson (Horsham, PA), 10 μg/mL anti-IL-2 (clone S4B6), 10 μg/mL anti-CD25 (clone PC61), 20 ng/mL murine IL-6, or 100 units/mL human IL-2. Cells were cultured for 3 days. For Ova-specific Th9 cells, OT-II Rag-deficient T cells were purified and cultured with T-depleted APC with 10 ng/mL murine IL-4, 2 ng/mL human TGFβ, 0.5 μg/ml anti-CD28 (clone 37.51) 10 μg/ml of anti-IFNγ (clone XMG1.2), and 1 μM ovalbumin in complete IMDM medium for 3 days. To generate HEL-specific TCR transgenic Th9 cells we used the culture system described in detail elsewhere (45). Surface DR3 was stained with anti-mouse DR3 biotin (R&D Systems) followed by streptavidin-conjugated eFluor 450 (eBioscience). For analysis of cytokine production, cells were restimulated with 10 nM PMA, 1 μM ionomycin, and monensin for 4 hours, harvested and washed for staining. After labeling with surface antibodies, cells were fixed overnight with Cytofix/Cytoperm (BD Biosciences) or FoxP3 Fixation/Permeabilization buffer (eBioscience). Cells were blocked and stained with the following intracellular antibodies as indicated: anti-mouse/rat FoxP3 eFluor 450 (eBioscience), anti-mouse IL-9 APC (BioLegend), anti-mouse IL-17A FITC (eBioscience), anti-mouse IL-13 PE (eBioscience), anti-mouse IFNγ PE (BD Biosciences) and/or anti-mouse IL-4 FITC (eBioscience). Fluorphore-conjugated isotype control antibodies were used to check for non-specific binding. Cells were then washed and analyzed by flow cytometry. For phosphorylated STAT5 staining, cells were fixed in 4% paraformaldehyde, washed in PBS, and permeabilized with methanol overnight at -20 °C. Cells were stained in PBS with 0.5% Triton X-100 and 0.1% bovine serum with anti-phospho-STAT5 PE (BD Biosciences) and anti-CD4 at room temperature in the dark for 60 minutes. Fluorphore-conjugated isotype control antibodies were used to check for non-specific binding. Cells were then washed and analyzed by flow cytometry. Induction and quantification of Th9-mediated ocular inflammation HEL-specific Th9 cells generated in culture, at the indicated numbers were injected via the tail vein into syngeneic mice transgenically expressing HEL in their lens. The recipient eyes were collected at day 7 (or an alternative indicated time point) and analyzed by histological examination for inflammatory changes, using a scale of 0-9, as previously described (46). To test the effect of local TL1A, mice were intraocularly injected with TL1A (2 μg/eye) or PBS on days 2 and 3 post cell transfer, and eyes were examined for histological changes on day 4. To test TL1A blockade, mice were intraperitoneally injected with 20 mg/kg of the blocking anti-mouse TL1A monoclonal antibody 5.4G6 or hamster Ig control on days -1 and 3 post cell transfer. To test the effect of adding IL-10, recipient mice were treated intraperitoneally with a daily dose of 50 μg/kg (2 experiments) or 100 μg/kg (2 experiments) murine IL-10 starting 3 hours before cell injection until day 6 post cell injection. For measuring proliferation of transferred cells, Th9 cells were labeled with Cell Proliferation Dye eFluor 670, as recommended by the manufacturer (eBioscience). Five million labeled cells were injected into HEL-Tg recipient mice and spleens of these recipients were collected for flow cytometric analysis of the proportion of donor (1G12+) cells, as indicated. Ovalbumin and Papain Induced Lung Inflammation For ovalbumin-induced lung inflammation, mice were sensitized systemically on days 0 and 7 via a 200 μl intraperitoneal (i.p.) injection containing either 100 μg Chicken Ova (Sigma) or PBS emulsified in an equal volume mixture with alum (Thermo Scientific). For assessment of pulmonary inflammation, mice were challenged with 100 μg Ova or PBS/30 μl inoculum intratracheally (i.t.) on day 14 and intranasally (i.n.) on day 15. Mice were euthanized 24-72 hours after the final challenge to evaluate cell infiltration, cellular inflammation in the lung, and cytokine levels in the sera and bronchoalveolar lavage (BAL). BAL fluid was obtained by direct cannulation of the lungs with a 20-gauge intravenous catheter and lavage with 500 μl 1% fetal bovine serum (FBS) in PBS (for cytokine analysis) and with 750 μl 1% FBS in PBS (for analysis of cellular infiltration). Samples for cellular analysis were prepared as a cytospin (Thermo-Shandon, Pittsburgh, PA) for differential cellular analysis after staining with HEMA 3 stain set (Fisher Scientific), and a portion was used to determine total cell counts. Lung tissues were fixed in 4% neutral buffered formaldehyde, embedded in paraffin, sectioned, and stained with hematoxilin and eosin (H&E) or periodic acid-Schiff (PAS) stain. Cells were isolated from lungs by incubating lung fragments with 100U collagenase for 1 hour. Cells were stained for surface antigens and intracellular cytokines after stimulation with PMA/ionomycin for 4 hours with LIVE/DEAD Fixable Blue Dead Cell Stain (Life Technologies) and the following antibodies: TCRβ APC-eFluor 780 (eBioscience), CD45.2 PeCy7 (BioLegend), CD44 AlexaFluor 700 (eBioscience), CD4 V500 (BD Biosciences), IL-9 PE (BioLegend), IL-13 eFluor 660 (eBioscience), IL-17 FITC (eBioscience), IL-10 PerCP-Cy5.5 (eBioscience), IFNγ eFluor 450 (eBioscience). Cells from the BAL were stained using antibodies against CD45, SiglecF, F4/80, Ly6G and CD11b. Eosinophils were identified as CD45+ F4/80- Ly6G- CD11b+ SiglecF+. For RNA extraction, lung tissue was stored in Trizol and homogenized with a Precellys 24 (Bertin Laboratories) before chloroform extraction and purification with the PureLink RNA Mini Kit (Life Technologies). mRNA transcripts were measured by Taqman gene expression assays described below. For analysis of the pathogenic potential of Th9 in allergic lung disease, ovalbumin-specific wild-type or Tnfrsf25-/- Th9 cells (106 T cells in 200 μl PBS) were adoptively transferred into CD45.1 congenic wild-type recipient mice via tail vein injection. Mice were challenged twenty-four hours after cell transfer i.t. and forty-eight hours after cell transfer i.n. with 100 μg Ova. Mice were then sacrificed 12 hours after last challenge for further analyses described above. For papain-induced lung inflammation, mice were anaesthetized with isoflurane and exposed intranasally to 25 μg papain (Calbiochem) in 30 μL PBS on day 0, 3, 6 and 14. 12-16 hours after the last challenge, bronchoalveolar lavage was performed as described above. Lung-isolated cell analyses, RNA extraction and gene expression assays were performed as above. Lung histology was scored on H&E and Periodic Acid Schiff (PAS) stained sections by a reader with experimental conditions masked, using a scoring system modified from that described previously (47). Perivascular and peri-bronchiolar cuffing (PVC and PBC) were each scored as follows: 0: No visible infiltrate. 1: Patchy infiltrate in <25% of bronchioles or vessels, 2: Patchy infiltrate in <50% of bronchioles or vessels, 3: Widespread infiltrate >50% of bronchioles or vessels with circumferential infiltrates in most bronchioles or vessels. 4. Criteria for score of 3 plus vascular obliteration (for PVC) or bronchiolar plugging (for PBC). Interstitial inflammation was graded from 0-3 depending on the extent of cellular infiltrate into alveoli. Goblet cell hyperplasia was scored for small airways as follows: 0: No visible hyperplasia or mucous production, 1: patchy hyperplasia and/or PAS staining in <25% of bronchioles or vessels, not circumferential, 2: patchy hyperplasia and/or PAS staining of <50% of bronchioles, 3: widespread hyperplasia and >50% PAS staining in most bronchioles, 4: criteria for 3 plus bronchiolar plugging or obliteration. Scores reported were the total score for each lung (0-15). Lung immunohistochemistry Lungs were perfused with PBS and filled with OCT via the trachea. Lungs were subsequently embedded in OCT and frozen using an iso-pentane bath cooled with dry ice. Sections were cut to 5 microns using a cryostat (Leica CM1850) cooled to -23 °C and mounted on superfrost plus slides (Fisher). All subsequent steps were carried out at room temperature. Sections were dried for at least 1 hour and fixed in acetone for 10 minutes. Sections were blocked with 2.5% (v/v) normal goat serum (Vector laboratories) for 30 minutes and stained with 10 μg/ml Tan 2-2 (Rat anti mouse TL1A, was generated as described previously (9)) in PBS plus 0.05% Tween-20 (Sigma) for 2 hours. Slides were incubated with in 0.3% H2O2 in MeOH for 20 minutes to suppress endogenous peroxidases. Sections were incubated with ImmPRESS anti Rat Ig peroxidase (Vector laboratories) for 30 minutes and developed using DAB peroxidase substrate kit (Vector laboratories) for 7 minutes. Tissue was counterstained using Hematoxylin (Vector laboratories) for 2.5 minutes, washed with 2% glacial acetic acid and blued with 0.45% NaOH in 70% ethanol for 30 seconds. Slides were mounted using VectaMount AQ (Vector laboratories) and imaged using a Keyence microscope (Digital Microscopes). Image backgrounds were adjusted to white using Adobe Photoshop. Measurement of allergic airway reactivity Bronchial reactivity was determined 12h after the last challenge of Ova in the Ova-induced lung inflammation model or of papain in the papain-induced model. Mice were anesthetized by i.p. administration of ketamine/xylazine mixture (1 ml ketamine [100 mg/ml], 0.5 ml xylazine [20 mg/ml], and 8.5 ml PBS). A 18-gauge blunt-end needle was inserted into the trachea, and the animals then were ventilated mechanically. Baseline measurements were recorded after the aerosol administration of saline, followed by doubling doses of methacholine (6.25–100 mg/ml) using flexiVent (Scireq Scientific Respiratory Equipment). Cytokine measurement and analysis Supernatants from CD4+ T cell differentiation cultures were collected at day 3 after activation and analyzed for cytokines by a multiplex, bead-based protein detection assay. Supernatants were probed for 23 different cytokines and chemokines using BioRad's Bio-Plex Pro™ Mouse Cytokine 23-plex Assay according to the manufacturer's protocol. Protein concentrations were detected and calculated using a Bio-Plex 200 instrument and Bio-Plex Manager 6.0 (BioRad). Ratios were calculated for each cytokine produced in the presence of TL1A versus in the absence of TL1A. The natural logarithms of these ratios were hierarchically clustered using uncentered correlation in Cluster 3.0 (Michael Eisen) and visualized in Java TreeView (Alok Saldanha). For measurement of IL-9 from the supernatant of wild-type and PU.1-deficient T cells, cells were stimulated with plate bound anti-CD3 (2 μg/ml) for 24 hours. Cell-free supernatant was used to detect IL-9 by ELISA using anti-IL-9 capture antibody (D8402E8; BD Biosciences) and biotin-labeled anti-IL-9 detection antibody (D9302C12; Biolegend). For measurement of IL-9 and IL-10 in HEL-specific T cell cultures, supernatant cytokine concentrations were measured with ELISA kits from RayBiotech and R&D Systems, respectively. For cytokine measurements in lung homogenates, the middle right lung lobes were snap frozen in liquid nitrogen and stored at -80 until analysis. The frozen lungs were weighed and immediately transferred to tubes containing 500 uL Tissue Protein Extraction Reagent (ThermoScientific) with 5 uL HALT Protease Inhibitor Cocktail (ThermoScientific, 100X). Lung tissues were homogenized using a Precellys® instrument, and then centrifuged at 9,000 × g for 10 minutes at 4 degrees. Supernatants were transferred to clean microcentrifuge tubes. Total protein concentrations in the lung tissue homogenates were determined using a BCA kit. Cytokines were measured using the MAGPIX ® multiplexing system with BioPlex reagents (BioRad). Retroviral transduction Naïve CD4+ T cells were activated with plate-bound anti-CD3, anti-CD28 and anti-IFNγ for 24 hours. The activated cells were transduced with supernatants containing hNGFR retrovirus or hNGFR-caSTAT5 retrovirus in the presence of polybrene (8 μg/ml) by centrifuge at 2500 rpm for 90 minutes at 30°C. The same procedure of transduction was repeated 24 hours later and differentiation cytokines were added for 2 days. Flow cytometry analysis gated live, NGFR+ cells before examining cytokine production. Chromatin Immunoprecipitation (ChIP) ChIP for STAT5 binding was performed as described previously (48). Naïve CD4+ T cells were activated and polarized for 3 days followed by cross-linking for 8 minutes with 1% formaldehyde. The cells were harvested and lysed by sonication. After pre-clearing with protein A agarose beads (Upstate, VA), cell lysates were immunoprecipitated with anti-STAT5A/STAT5B antibody (R&D Systems) overnight at 4°C. After washing and elution, crosslinks were reversed at 65°C for 4 hours. The eluted DNA was purified, and samples were analyzed by quantitative-PCR with customer-designed primers and probes (Supplemental Table 1) using a 7500 real time PCR system (both Applied Biosystems, CA). The Ct value for each sample was normalized to corresponding input value. ChIP for PU.1 and IRF4 binding was performed as previously described (25). Gene expression analysis Where indicated, mRNA levels were measured by Taqman Gene Expression Assays (Life Technologies): IL-9 (Mm00434305_m1), IL-13 (Mm00434204_m1), IL-2 (Mm00434256_m1), IL-10 (Mm00439614_m1), IRF4 (Mm00516431_m1), B2M (Mm00437762_m1), Tbx21 (Mm00450960_m1), Gata3 (Mm00484683_m1), Rorc (Mm01261022_m1). Cytokine RNA expression measurements were made using the iTaq Universal Probes One-Step Kit (BioRad) on a CFX96 Real-Time PCR Detection System (BioRad). For transcription factor expression measurements, RNA was first converted to cDNA using the SuperScript VILO cDNA Synthesis Kit (Life Technologies) and then qPCR reactions using Taqman Gene Expression Master Mix (Life Technoliges) were run on a CFX384 Touch Real-Time PCR Detection System (Bio-Rad). All reactions were run in triplicate. For low-expressed genes, RNA input was increased until detectable and consistent Ct values were obtained across technical replicates. Several PBS-treated mice expressed no detectable IL-9 in the lung even with increased RNA input, and these were excluded from analysis. Replicate Ct values were normalized to replicate reference gene (B2M) Ct values (deltaCt), and fold-changes were calculated with respect to the indicated reference sample (2 raised to the power of delta-deltaCt). Results DR3 is required for optimal production of IL-9 and IL-13 in allergic airway disease DR3 knockout (Tnfrsf25-/-) mice or animals treated with blocking anti-TL1A antibodies are resistant to allergic disease induced by sensitization and airway challenge with ovalbumin (Ova), and less IL-13 mRNA is detected in the lung (10, 14). We examined the kinetics of IL-9 and IL-13 production in the lung of wild-type (WT) and Tnfrsf25-/- mice in this T-cell-dependent model (Figure 1A). We found that in WT mice IL-9 mRNA was elevated on day 16, one day after the last challenge with Ova, whereas IL-13 production was higher at day 18. Strikingly, in Tnfrsf25-/- mice, IL-9 mRNA was not induced at either time point, and IL-13 was significantly reduced at day 18 (Figure 1B). To determine whether T cells infiltrating the lung also depend on DR3 for efficient IL-9 and IL-13 secretion, we isolated cells from the lung at day 16 and determined the frequency of IL-9 and IL-13 producing T cells after brief restimulation in vitro. Although total lung IL-13 mRNA is very low at this time-point, IL-13 detection by flow cytometry in individual T cells enables examination of differences in this small population of infiltrating cells. As shown in Figure 1C, numbers of IL-9 and IL-13 secreting cells increased approximately 10-fold in Ova-sensitized WT mice compared to PBS-sensitized controls, whereas no such changes in cells secreting IL-9 nor IL-13 could be seen in Tnfrsf25-/- mice. This was not due to a general failure of the T response in the lung, because total numbers of CD4+CD44hi cells were still significantly increased by Ova priming in Tnfrsf25-/- mice. Despite correlated changes in IL-9- and IL-13-producing T cells, no double-producers were observed, and CD4+CD44hi cells did not secrete IL-10, IL-17, or IFNγ (Supplemental Figure 1A). Histological examination revealed reduced goblet cell hyperplasia and cellular infiltrates of Tnfrsf25-/- lungs compared to those from WT Ova-sensitized mice at day 16 (Figure 1D). Lung pathology in Ova-challenged Tnfrsf25-/- mice was significantly reduced compared to that in WT mice at day 16 (Figure 1D, lower panel), similar to what we previously observed at day 18 (10). Measurements of airway resistance in response to methacholine challenge revealed less airway hyperreactivity (AHR) in Tnfrsf25-/- mice challenged with Ova as compared to WT mice (Figure 1E). Bronchoalveolar lavage (BAL) of Tnfrsf25-/- mice challenged with Ova also showed reduced numbers of eosinophils and neutrophils at day 16 (Figure 1F), and as expected, IL-5 protein from whole lung homogenates paralleled eosinophil reduction (Supplemental Figure 1B). These data suggest that TL1A-DR3 interactions are important for IL-9 and IL-13 production by T cells early in the lung hypersensitivity response, which may shape the ensuing allergic pathology. To test whether DR3 is required to support Th9 development and lung inflammation in the setting of a local allergic response, we exposed WT or Tnfrsf25-/- mice to inhaled papain, an environmental protease known to induce pulmonary allergic responses and induce IL-9 along with other Th2 cytokines (Figure 2A). We chose to analyze responses after two weeks of exposure to papain, the time at which T cells play a role in disease (49-51). As with mice sensitized and challenged with Ova, the BAL fluid of Tnfrsf25-/- mice sensitized to papain contained reduced numbers of eosinophils and neutrophils compared to WT mice (Figure 2B), and lung IL-5 protein expression was again reduced (Supplemental Figure 2A). Of note, immunohistochemical staining revealed that papain induced the expression of TL1A on cells localized near blood vessels (Figure 2C). WT mice treated with papain developed severe immunopathology with goblet cell hyperplasia and cellular infiltration in the perivascular, interstitial and peribroncheal areas, while Tnfrsf25-/- mice were substantially less affected (Figure 2D). Similar to Ova-induced lung disease, papain-exposed Tnfrsf25-/- mice showed less AHR than WT in response to methacholine challenge (Figure 2E). Transcription of IL-9 and IL-13 was highly induced after 2 weeks of papain exposure, and DR3-deficient mice were defective in induction of both IL-9 and IL-13 mRNA, with the reduction in IL-9 even more pronounced than that in IL-13 (Figure 2F). Because ILC2s have been identified as the main producers of papain-induced IL-9 in the early allergic response (51), we restimulated total lung cells with PMA and ionomycin and analyzed protein production by flow cytometry to specifically determine whether T cell production of allergic cytokines was dependent on DR3. We found that numbers of T cells expressing either IL-9 or IL-13 were strikingly reduced in DR3 deficient mice (Figure 2G). Similar to ovalbumin-induced lung disease, there were no IL-9 and IL-13 double-producing T cells, and we found very little induction of IL-10 and IFNγ in response to papain. However, in contrast to the ovalbumin model, papain exposure did induce IL-17-producing effector T cells separate from IL-9-producing cells, which were also reduced in antigen-challenged Tnfrsf25-/- mice (Supplemental Figure 2B). These results show that DR3 also governs the production of cytokine secreting T cells and disease pathology after exposure to an inhaled allergen. TL1A promotes Th9 differentiation in the presence of TGFβ and either IL-4 or IL-2 TL1A may exert the effects we observed in the lung through enhancing differentiation of naïve T cells or promoting proliferation or survival of activated T cells. To investigate the effects of TL1A on T cell differentiation, we activated T cells under conditions optimized for differentiation into various T cell subsets in the presence or absence of TL1A. We previously found that DR3 was not required for generation of Th1, Th2 or Th17 cells, but that TL1A-DR3 signaling suppressed generation of FoxP3-expressing iTreg (10, 13). Consistent with previous reports (52), TL1A increases the percent of IFNγ-producing T cells in Th1 differentiation conditions to a moderate extent, but we do not see any consistent effects on Th2 or Th17 differentiation (Supplemental Figure 3A). Expression of lineage-defining transcription factors generally paralleled flow cytometry measurements of signature cytokines (Supplemental Figure 3B). When T cells were cultured under iTreg-inducing conditions in the presence of IL-2 and TGFβ, we found that in addition to reducing the percentage of FoxP3-expressing cells, TL1A promoted the production of IL-9 (Figure 3A). The effect was particularly strong in the presence of antigen presenting cells (APC), which enhanced T cell costimulation as evidenced by increased secretion of many cytokines and chemokines (Supplemental Figure 3C). Suppression of FoxP3 and induction of IL-9 was dependent on DR3, as Tnfrsf25-/- T cells were unaffected by TL1A treatment (Figure 3A). TL1A did not induce IL-9 production in T cells cultured for 3 days under non-polarizing Th0, Th1 or Th2 conditions, and TL1A did not enhance the production of cells expressing IL-4 or IL-13 under Th2 conditions (Supplemental Figure 3A), suggesting that the TGFβ and IL-2 included in iTreg polarization conditions are important for the ability of TL1A to induce IL-9 production. Interestingly, under Th17 conditions (TGFβ, IL-6 and blocking antibodies to alternative lineages), TL1A-induced IL-9 production was suppressed compared with that of iTreg cultures, which differ only in their lack of IL-6 and presence of IL-2 (1.6 % vs. 17.5 % in Figure 3B), while IL-17 production remained largely unaffected. This suggests that IL-6-derived signals antagonize the ability of TL1A to promote Th9 differentiation, or that IL-2 signaling enhances it. In the presence of IL-4 and TGFβ, conditions previously found to direct T cells to become IL-9-producing effector cells (23, 24, 53), TL1A significantly enhanced the development of IL-9-producing cells, both in the presence and absence of APC. In the presence of APC, some cells producing both IL-13 and IL-9 were induced by TL1A (Figure 3C). As with iTreg conditions, the enhancement of IL-9 production by TL1A was completely dependent on DR3. Although DR3 deficient T cells differentiated normally into Th9, endogenous TL1A produced under these culture conditions may not be sufficient to influence Th9 differentiation, as the bulk of TL1A is produced by APC induced by inflammatory stimuli such as TLR ligands, TNF and IL-1b (54). Titration of TGFβ showed that TL1A could enhance Th9 differentiation across a wide range of concentrations of TGFβ above 0.1 ng/ml, and TL1A lowered the amount of TGFβ necessary to induce Th9 differentiation by approximately 10-fold (Figure 3D). TL1A was extremely potent at enhancing Th9 differentiation, doubling the percentage of IL-9-producing T cells at concentrations as low as 0.1 ng/ml, and sharply augmenting IL-9 production with increasing concentration before plateauing between 1 and 10 ng/ml (Figure 3E). T cell subset-specific responses to TL1A may reflect differential expression of the TL1A receptor DR3. To test this possibility we measured DR3 surface expression under various polarization conditions (Figure 3F). DR3 expression was upregulated under all conditions with TGFβ (Figure 3F), indicating that TGFβ signaling enhances cellular responsiveness to TL1A. However, DR3 expression on Th9-polarized cells decreased with addition of TL1A (Figure 3G), suggesting downregulation of the receptor by its ligand. These results show that TL1A potently promotes differentiation of IL-9-producing T cells in a TGFβ-dependent manner but does not induce a positive feedback loop by inducing DR3 expression. Since TL1A can costimulate T cell proliferation, the increase in IL-9-producing T cells we observed might be due to enhanced proliferative responses. To explore this possibility, we examined IL-9 production in cultures of CFSE-labeled T cells to simultaneously track cell division and IL-9 production. Addition of exogenous TL1A only slightly enhanced proliferation in the absence of APC (data not shown), while no difference was detected in the presence of APC (Figure 3H). This is consistent with previous data showing that TL1A affects proliferation mainly under suboptimal stimulatory conditions (10). TL1A enhanced IL-9 production in all cells that had divided at least once, increasing IL-9 production in the first division by a factor of eight whether APC were absent or present (data not shown, and Figure 3H). TL1A enhanced the percentage of IL-9 producing cells at least 10-fold in cells that had divided twice. These data show that the TL1A primarily induces Th9 differentiation and IL-9 production as opposed to increasing T cell proliferation. TL1A can co-stimulate cytokine production and may therefore promote Th9 differentiation by inducing production of other cytokines that act in an autocrine manner. We measured cytokines in the supernatants of T cells activated in the presence or absence of TL1A under a number of polarization conditions by multiplex cytokine detection assays. In addition to IL-9, TL1A enhanced the production of IL-2, IL-3, IL-10, IL-13, and GM-CSF by purified T cells activated under Th9 conditions (Figure 3I, top panel). In the presence of APC, IL-5 and IL-6 were also upregulated by TL1A (Figure 3I, bottom panel). Unsupervised clustering of the TL1A-induced changes in cytokines secreted by various T helper subset differentiation cultures showed that while TL1A may be generally considered a costimulator, its effect depends on the polarization culture conditions. For example, IL-9 and IL-13 upregulation appeared strongest in Th9 and iTreg conditions in purified T cell culture. It is also interesting to note that the cytokines induced by TL1A under Th2 and Th9 conditions were closely correlated, which may reflect a common differentiation pathway of these two subsets (24). Induction of Th9 by TL1A depends on IL-2 and STAT5 To determine which cytokines may be responsible for enhanced Th9 differentiation, we considered those cytokines upregulated by TL1A that activate JAK/STAT signaling, which is well known to program T cell differentiation. IL-2, IL-3, IL-5, IL-6, IL-9, and GM-CSF fit these criteria and are upregulated by TL1A in both iTreg and Th9 conditions. To test whether IL-9 itself might positively influence Th9 differentiation, we added an IL-9 blocking antibody to T cells cultured under Th9 conditions in the presence and absence of TL1A. As shown in Figure 4A, blocking IL-9 did not reduce the frequency of IL-9-producing cells (Figure 4A, left panel). As in Th17 differentiation cultures containing IL-6 (Figure 3B), addition of IL-6 suppressed the ability of TL1A to induce Th9 (Figure 4A, middle panel), whereas blocking IL-6 antibodies enhanced Th9 differentiation in the presence of TL1A (Figure 4A, left panel). Addition of exogenous IL-2 did not increase Th9 producing cells over the TGFβ and IL-4 condition (Figure 4A, middle panel). However, a combination of anti-IL-2 and anti-CD25 antibodies, which completely blocks IL-2 signaling, dramatically suppressed Th9 differentiation in T cell activation cultures containing TGFβ and IL-4 and potently blocked the ability of TL1A to enhance Th9 differentiation (Figure 4A, right panel). Thus IL-2 appears to be a key autocrine factor in Th9 differentiation and its enhancement by TL1A, while IL-6 appears to antagonize this process, possibly though competition between IL-2-induced STAT5 and IL-6-induced STAT3 (48). To probe the relevant signaling pathways downstream of candidate cytokines induced by TL1A that might aid Th9 polarization, we used T cells deficient in the relevant STAT transcription factors that mediate their action. STAT6 is responsible for IL-4 and IL-13 signal transduction and is required for Th9 polarization induced by IL-4 (23-25). As expected, Stat6-deficient T cells were defective in IL-9 production under Th9 conditions, but, importantly, TL1A still enhanced numbers of IL-9-producing T cells by 10-fold (Figure 4B). Under iTreg conditions, deviation towards Th9 differentiation by TL1A was completely independent of STAT6 (Figure 4B). This shows that although signaling through STAT6 is required for conventional Th9 differentiation mediated by IL-4 and TGFβ, STAT6 is not required for the enhancement of Th9 differentiation mediated by TL1A. As a major signal transducer for IL-2, STAT5 is a good candidate for mediating the effects of TL1A. To determine the role of STAT5 in the enhancement of Th9 differentiation by TL1A, we activated naïve CD4+ T cells with conditional deletion of the STAT5A/B locus (Stat5CD4-/-) or control T cells (Stat5fl/fl) under Th9 polarization conditions with or without TL1A. Due to the requirement for STAT5 in T cell development (55), both STAT5-deficient and control T cells carried the OT-II transgenic TCR, but T cells were activated polyclonally. Under Th9 conditions, STAT5-deficient T cells were unable to differentiate into IL-9-producing cells, and importantly, IL-9 production by STAT5 deficient T cells could not be rescued by the addition of TL1A (Figure 4C). Only IL-13 production is increased by TL1A in the absence of STAT5 signaling (Figure 4C). To determine whether STAT5 is sufficient to drive Th9 development, we activated naïve T cells transduced with a retrovirus encoding a constitutively active STAT5 protein. These cells efficiently differentiated into IL-9-producing cells in the absence of TL1A or other T cell polarizing cytokines (Figure 4D), indicating that activated STAT5 is sufficient to drive Th9 differentiation. T cells expressing activated STAT5 differentiated into Th9 even in the presence of IL-6, suggesting that activated STAT5 can overcome the inhibitory effects of IL-6 acting through STAT3 on Th9 differentiation. Taken together, these data confirm that STAT5 is necessary and sufficient for Th9 differentiation, and show that TL1A, acting through autocrine IL-2 and STAT5, mediates a distinct pathway from IL-4 and TGFβ for inducing Th9 from naïve T cell precursors. To determine whether DR3 plays a cell-intrinsic role in Th9 differentiation beyond promoting autocrine IL-2 production, we mixed CD45 congenic WT naïve CD4+ T cells with DR3-deficient naïve CD4+ T cells, and activated them together under Th9 and iTreg conditions. Only wild-type cells responded to TL1A with an increase in IL-9 production under either iTreg or Th9 conditions (Figure 5A), indicating that T cells must receive a signal through DR3 in addition to IL-2 for optimal Th9 differentiation. These data suggested that DR3 signaling may potentiate the action of other transcription factors on the IL-9 promoter. PU.1 (Sfpi1), an ETS-family transcription factor that binds to the IL-9 promoter, enhances the generation of Th9 both in vitro and in vivo (18). As previously described, activating PU.1-deficient T cells under Th9 conditions resulted in a lower percentage of IL-9-producing cells and reduced IL-9 in the culture supernatant. However, TL1A enhanced IL-9 production in both WT and PU.1-deficient T cells to a similar degree (Figure 5B). Chromatin immunoprecipitation (ChIP) experiments also showed that TL1A did not significantly enhance PU.1 binding to the IL-9 promoter (Figure 5C). IRF4, which is induced by STAT6 and coordinately binds the IL-9 promoter with SMAD2/3 (25, 56), has also been identified as a key transcription factor in Th9 differentiation (57). ChIP experiments revealed a trend toward increased binding of IRF4 to the IL-9 promoter in the presence of TL1A (Figure 5D), but addition of TL1A did not increase IRF4 expression at the mRNA level (data not shown). Along with the data from STAT6-deficient T cells (Figure 4B), these results suggest that TL1A makes the IL-9 promoter more accessible to IRF4 but its effect is not directly through the STAT6-IRF4 pathway. Alternatively, we reasoned that DR3 signaling may enhance the ability of STAT5 to transactivate the IL-9 promoter. In support of this possibility, T cells activated under Th9 conditions in the presence of TL1A had higher baseline levels of phosphorylated STAT5 and increased STAT5 binding to the IL-9 promoter as assayed by ChIP (Figure 5E). These data support a role for TL1A, acting through DR3, in enhancing IL-2 signaling through STAT5 and increasing STAT5 promoter binding to promote differentiation of T cells capable of producing IL-9. OX40L, another member of the TNF superfamily, was recently reported to enhance Th9 differentiation through its receptor OX40, signaling via the non-canonical NF-κB pathway and TNF-receptor associated factor 6 (TRAF6) (26). To determine whether TL1A may induce Th9 through a TRAF6-dependent pathway, we activated naïve Traf6-/- T cells with TGFβ and IL-4. Unlike OX40L, we found that TL1A was able to enhance Th9 generation with similar efficiency in WT and Traf6-/- T cells (Figure 5F). Th9 differentiation by OX40L was dependent on IL-4 acting through STAT6, as OX40L only slightly increased the percentage of IL-9-producing cells differentiating from STAT6-deficient naïve T cell precursors (Figure 5G). These data show that TL1A mediates Th9 differentiation through mechanisms that are distinct from those of OX40L with respect to STAT6 and non-canonical NF-kB signaling through TRAF6. TL1A enhances the pathogenicity of antigen-specific Th9 in ocular and allergic lung inflammatory disease To determine whether TL1A enhances the pathogenicity of antigen-specific Th9 cells, we turned to a model system where T cells specific for hen egg lysozyme (HEL) trigger ocular inflammation when transferred into transgenic mice expressing HEL in the eye. HEL-specific T cells differentiated into Th1, Th17 and Th9 can all trigger ocular pathology when transferred into HEL-expressing recipients, and pathogenicity of Th9 correlates with their ability to produce IL-9 (45). We activated HEL-specific TCR transgenic T cells with antigen and APC under Th9 conditions in the presence or absence of TL1A. TL1A enhanced the differentiation of HEL-specific Th9 to an even greater extent than in polyclonal T cell cultures, increasing the percentage of T cells capable of producing IL-9 to more than 90% after 3 days of activation, the peak of IL-9 production, compared with 40% without TL1A (Figure 6A). TL1A also increased the percentage of IL-9-producing T cells after 4 days of activation (30% vs 8%), but after 6 days of activation, the percentage of IL-9-producing T cells fell to less than 3% with or without TL1A. IL-9 production was enhanced by TL1A at the RNA level as well, with a two-fold enhancement of IL-9 RNA at the peak of expression at day 3. IL-9 RNA expression steeply declined at day 4 with or without TL1A (Figure 6B). TL1A also greatly enhanced the amount of IL-9 in culture supernatants on days 3 and 4, with a ten-fold enhancement of IL-9 in the supernatant (Figure 6C). Interestingly, a significant fraction of T cells produced IL-10 after 6 days of culture, and TL1A almost completely extinguished IL-10 production by these ‘ex-Th9’ cells (Figure 6A). Measurement of IL-10 on days 3 and 4 by intracellular staining, in culture supernatants, and in RNA showed a smaller reduction with addition of TL1A, demonstrating that downregulation of IL-10 by TL1A occurred later after activation (Figures 6A-C). To assess the effects of TL1A on the pathogenic potential of Th9 cells, HEL-specific T cells differentiated under Th9 conditions for 3 or 4 days in the presence or absence of TL1A were transferred into mice expressing HEL in the eye. Examination of ocular pathology 7 days after transfer of Th9 cells revealed that TL1A added during T cell differentiation enhanced the ability of HEL-specific cells to induce ocular inflammation, even when the increased efficiency of Th9 generation in the presence of TL1A was taken into account by transferring proportionally fewer cells (Figure 6D). Histological changes in the recipients of Th9 cells included accumulation of inflammatory cells at the optic nerve head and limbus, as well as in the anterior chamber and throughout the vitreous. These changes were markedly more severe in the recipients of Th9 cells generated with the addition of TL1A (Figure 6E, left panels). Higher magnification showed the limbus and ciliary body area, with higher numbers of invading cells as compared with the control Th9 eye section (Figure 6E, right panels). In addition to intra-ocular changes, transferred Th9 cells uniquely invaded the conjunctiva, evoking changes reminiscent of allergic conjunctivitis. These changes were remarkably more severe in recipients of TL1A-stimulated donor cells (Figure 6F). To determine whether TL1A influences the proliferation of HEL-specific Th9 prior to their invasion of the recipient mouse eye, we monitored transferred cells on days 1, 2, 3, 4 and 7 post transfer in the spleens of recipient mice, where Th9 initially migrate and proliferate (45). We enumerated the percentage of TCR transgenic T cells in the CD4+ T cell pool using the anti-clonotypic monoclonal antibody 1G12. HEL-specific transgenic T cells exposed to TL1A during Th9 differentiation were present in greater numbers than control Th9 after transfer to HEL-expressing recipients (Figure 6G). Th9 cells generated in the presence of TL1A proliferated more rapidly than control Th9 cells (Figure 6H), demonstrating that while TL1A does not greatly enhance proliferation of Th9 during differentiation (as shown in Figure 3H), it does prime cells for more rapid expansion in vivo, which may contribute to their increased pathogenicity. To determine whether TL1A can also enhance the pathogenicity of Th9 at the site of inflammation we injected TL1A or PBS into the eyes of HEL-expressing recipient mice 2 and 3 days after transfer of HEL-specific Th9. Intra-ocular injection of TL1A into Th9 recipients slightly increased inflammation on day 4 post-transfer compared to those receiving PBS (Figure 6I). It is important to note that the ocular injection itself induced some inflammation and may have obscured the effects of TL1A, as evidenced by increased basal histological scores seen with Th9 transferred cells followed by intra-ocular PBS injection. Injection of TL1A alone induced very little ocular pathology. TL1A and DR3 have previously been found upregulated in experimental autoimmune uveitis, suggesting an endogenous role for this signaling pathway in ocular inflammation (58). To determine whether endogenous TL1A/DR3 interactions are important in vivo to enhance ocular pathology mediated by Th9, we treated recipient HEL-transgenic mice receiving HEL-specific Th9 cells with a blocking anti-TL1A antibody (13). Anti-TL1A significantly reduced ocular inflammation compared to control immunoglobulin (Figure 6J), with reduced cellular infiltration (Figure 6K). Anti-TL1A reduced the number of donor HEL-specific T cells in the eye (1.0% with isotype versus 0.6% with anti-TL1A), while the percentages of donor HEL-specific T cells in the spleen remained unchanged. Percentages of host cells in both organs only slightly decreased with anti-TL1A treatment (data not shown). We also examined the possibility that the effect of TL1A is related to the suppression of IL-10 production that we observed in vitro, but injection of IL-10 did not reduce ocular pathology induced by Th9 differentiated in the presence of TL1A (data not shown). Thus, TL1A appears to enhance Th9 pathogenicity independently of reducing IL-10 production. Taken together, these data show that in addition to improving the efficiency of Th9 differentiation, endogenously produced TL1A can increase pathology mediated by antigen-specific Th9. To determine whether endogenous TL1A can enhance the pathogenicity of Th9 cells in Ova-induced lung inflammation, we transferred WT or Tnfrsf25-/- OT-II Ova-specific T cells activated under Th9 conditions into congenic hosts. Recipient mice were then given two inhaled challenges of Ova and responses were measured 12 hours after the last challenge, the time point at which we observed maximal IL-9 expression (Figure 7A and 7B). At this time point, neutrophils predominated in the BAL, and there was a trend towards lower neutrophil counts in recipients of Tnfrsf25-/- OT-II cells (Figure 7C). Histological analysis revealed a significant reduction in pathology in recipients of Tnfrsf25-/- OT-II Th9 cells after challenge with Ova compared to mice receiving WT OT-II Th9 cells, including reduced perivascular and peribronchial infiltrates (Figure 7D). IL-9, IL-13 and IL-2 mRNA were significantly reduced in Ova-treated recipients of Tnfrsf25-/- OT-II T cells compared with mice that received WT OT-II T cells (Figure 7E). Expansion of donor OT-II Th9 was observed locally in the lung (Figure 7F) and the mediastinal lymph nodes but not in the spleen after Ova challenge (data not shown). Expansion of the total number of donor OT-II cells, as well as the number of OT-II cells producing IL-9, was significantly reduced when the cells lacked DR3, along with reduction in a much smaller number of OT-II cells producing IL-13 (Figure 7F). The mean fluorescence of IL-9 upon restimulation and intracellular cytokine staining was lower in Tnfrsf25-/- T cells (Figure 7F), suggesting that TL1A may potentiate their IL-9-producing phenotype. Because only T cells lacked DR3 in these experiments, these results demonstrate a requirement for interaction between endogenous TL1A and DR3 expressed on Th9 cells to promote the expansion and effector function of Th9 and immunopathology in this model of allergic lung disease. Discussion The importance of TL1A in animal models of allergic disease has been well characterized (10, 11, 14), but the mechanism by which TL1A promotes T cell-mediated immunopathology in allergic disease has remained elusive, as systemic Th2 polarization is unaffected in DR3-deficient mice despite reduced lung pathology. Here we find that TL1A acts on CD4+ T cells both to inhibit iTreg differentiation and to promote Th9 differentiation. The effects of TL1A are independent of IL-4 and STAT6, but require IL-2 acting through STAT5, as well as TGFβ signaling. TL1A also enhances the pathogenic potential of Th9, and TL1A-DR3 interactions in vivo are required for allergic lung inflammation and the accumulation of IL-9 secreting cells in the lung early in the inflammatory response. These findings provide a more specific mechanism by which TL1A can promote T cell mediated immunopathology and identify an alternate pathway for generation of IL-9-secreting T cells that is more efficient than TGFβ and IL-4 alone and generates higher numbers of pathogenic T cells. TL1A/DR3 interactions are not required for generation of Th1 or Th2 cells in vitro or during primary polarized T cell responses, and although TL1A has been shown to promote or inhibit Th17 differentiation depending on culture conditions, its interaction with DR3 is not necessary for Th17 formation (10, 11, 59). We here show that TL1A can divert T cells in iTreg differentiation cultures to become producers of IL-9 and enhance differentiation of Th9 in the presence of TGFβ and IL-4, conditions previously shown to bias naïve T cells towards IL-9 production (23, 24). However, TL1A can induce Th9 in the complete absence of STAT6 signaling, indicating that the action of TL1A is mechanistically distinct from Th9 differentiation induced by TGFβ and IL-4, which depends on STAT6 (24). Other cytokines, such as the IL-17 family member IL-25 (60) and the IL-1 family members IL-1β, IL-18, and IL-33 (28), have also been shown to enhance T cell production of IL-9, but unlike these cytokines, TL1A also enhanced differentiation of IL-9 producing cells from naïve precursors. More recently the TNF-family member OX40L was shown to limit iTreg differentiation and bias T cell differentiation towards IL-9 production (26). Like OX40L, TL1A-induced Th9 differentiation does not require the transcription factor PU.1, which independently enhances the generation of Th9 (18). However, unlike OX40L, TL1A promotion of Th9 differentiation is independent of IL-4 and STAT6. Rather than IL-4, we have found that IL-2 signaling through STAT5 is critical for the ability of TL1A to enhance Th9 differentiation. IL-2 has been previously identified as an enhancer of IL-9 production by T cells (53, 61). Mechanistically, TL1A enhances STAT5 activation and binding to the IL-9 promoter. Yao et al. have recently observed that TSLP can enhance IL-9 production by directly activating STAT5 in T cells (17), and STAT5 was necessary for increased IL-9 production by mice deficient in the SOCS protein CIS (62). The fact that TL1A was unable to induce IL-9 production under conditions with blocked IL-2 signaling suggests that DR3 signaling alone is not sufficient to promote IL-9. Rather, IL-2-STAT5 signaling is required in addition to the signal mediated by DR3 on the same cell to promote Th9 differentiation. TL1A enhancement of Th9 differentiation in the presence of IL-2 (iTreg cultures) was most efficient when T cells were activated in the presence of APC, suggesting that APC-derived costimulatory signals or cytokines are likely required for optimal effects of TL1A. As suggested by the global increase in cytokine production in the presence of APC (Supplemental Figure 3C), it is possible that the enhanced effect of TL1A is due to extra costimulatory capacity from B cells, macrophages, and dendritic cells present in these cultures. Future studies of separated APC subsets may help to identify specific cell types and factors responsible for this effect. DR3 signals similarly to TNFR1 through TRADD, RIP, and TRAF2, ultimately resulting in activation of MAP-kinases and NF-κB, or alternatively through FADD and Caspase-8 to activate apoptosis (63-67). TL1A signaling through DR3 is unlikely to directly induce STAT5 activation, but may enhance STAT5 activity indirectly. MEK and ERK kinases have been found to phosphorylate STAT5 (68, 69), and NF-kB and STAT proteins can bind coordinately to the promoters of a number of genes, including TLR2 (70), FcɛRII (71), and NOS2 (72). The IL-9 promoter contains binding sites for NF-κB and STAT5 making such transcriptional coordination possible (17, 73). Xiao et al. (26) have suggested that signaling through TRAF6 and the non-canonical NF-κB pathway is responsible for the ability of OX40 to bias T cell differentiation towards Th9. Interestingly, the same mechanism does not apply for DR3, suggesting that different TNF family members have unique ways to modulate T cell differentiation. In addition to enhancing the efficiency of Th9 differentiation, TL1A also enhances the pathogenicity of Th9 in animal models of ocular inflammation and allergic lung disease. In ocular inflammation, antigen-specific Th9 generated in the presence of TL1A induced significantly more pathology than conventional Th9, even when the increased percentage of IL-9-producing cells differentiated in the presence of TL1A was taken into account. In allergic lung disease, antigen-specific Th9 cells capable of DR3 signaling exhibited significantly greater pathogenicity than DR3-deficient Th9. Detection of TL1A-expressing cells in the perivascular region of inflamed lungs, as well as the reduction of ocular pathology seen after local injection of anti-TL1A, supports the notion that endogenous TL1A is likely the trigger for enhanced expansion of antigen-specific T cells which we observed in these models. We and others have found that TL1A costimulation of ILC2s plays a role in allergic lung disease (15, 16), and it has recently been shown that ILC2s can influence T cell responses in allergic diseases (49, 74). Thus, defective ILC2 activity in DR3-deficient mice may play a role in the reduced T cell accumulation and allergic response in the T-cell dependent allergic inflammation models that we studied. However, our results with transfer of DR3-deficient T cells show that TL1A-DR3 signaling on T cells plays an independent role in amplifying allergic lung disease mediated by Th9, as shown in this work, and as shown previously for Th2 cells (10). As IL-2 produced by T cells can promote ILC2 expansion (51, 74) and IL-9 can promote ILC2 survival (75), the reduced IL-2 and IL-9 production seen in the lungs of recipients of DR3-deficient Th9 suggests a mechanism by which T cells could reciprocally activate ILC2 in a DR3 dependent manner. Taken together, these results show that TL1A-DR3 interactions coordinately amplify both innate and adaptive immune responses in allergic disease. Our results predict that blockade of TL1A-DR3 interactions would be beneficial in diseases in which IL-9 plays an important role, including allergic asthma. Given the prominent role of STAT5 in mediating the effects of TL1A on Th9, blockade of STAT5 activity with small molecules directly targeting STAT5 or essential upstream kinases for STAT5 activation such as JAK3 (76) could also act to limit the pathological consequences of IL-9 production triggered by TL1A. Supplementary Material 1 We would like to thank Arian Laurence and Haydeé Ramos for discussions, provision of reagents and performing pilot experiments that led to this work, Jim Simone, Jeff Lay and Kevin Tinsley from the NIAMS flow cytometry core for cell sorting, Crystal Brobst-Wormell, Joe Woo and the NIAMS animal facility for excellent support in management of the mouse colonies. Figure 1 DR3 is required for optimal pathology and IL-9 and IL-13 production in T-cell driven allergic lung inflammation (A)Time line of antigen sensitization and challenge in this model; IP (intraperitoneal), IN (intranasal), and IT (intratracheal). (B) mRNA levels of IL-9 and IL-13 measured by qRT-PCR are shown for lung samples harvested 16 or 18 days after initial challenge with ovalbumin. Values were normalized to the average level of RNA in the PBS-treated wild-type (WT) mice at each time point (t-test statistics comparing Ova-treated WT and Ova-treated Tnfrsf25-/- mice, *p<0.05, **p<0.01). (C) Frequency of IL-9 and IL-13 producing CD4+CD44hi T cells in the lung are shown from cells harvested at day 16 from mice challenged as in (A). Right panels, absolute numbers with total number of CD4+CD44hi cells shown at the top. (D) PAS-stained sections of lungs harvested at day 16 from mice challenged as in (A); airways (aw), and blood vessels (bv) marked; scale bar = 50 μm. Bottom panel shows histopathology scores. (E) Airway resistance was measured in response to increasing doses of aerosolized methacholine in mice challenged as in (A). Results are a combination of 2 independent experiments (Two-way ANOVA comparing Ova-treated WT and Tnfrsf25-/- mice, **genotype term p<0.01). (F) Absolute numbers of eosinophils and neutrophils in the bronchoalveolar lavage (BAL) of mice treated as in (A) at day 16 are shown (Mann-Whitney test: *p<0.05, **p<0.01). (A-D and F) are representative of at least 2 independent experiments. Figure 2 DR3 is required for optimal pathology and IL-9 and IL-13 production by T cells in response to an inhaled allergen (A) WT or Tnfrsf25-/- mice were given intranasal PBS or papain according to the timeline. All mice were euthanized 12 hours after the last challenge. (B) Total cell counts, neutrophils and eosinophils present in the BAL. (C) Localization of TL1A expression in the lungs of WT mice treated with PBS or papain is demonstrated by immunohistochemistry. (D) Lung histology of WT and Tnfrsf25-/- mice (PAS staining, left panel). Scale bar= 50 μm. Histopathology scores of lung sections from the indicated groups of mice (right panel). (E) Airway resistance was measured in response to increasing doses of aerosolized methacholine in mice challenged as in (A) (Two-way ANOVA comparing papain-treated WT and Tnfrsf25-/- mice, ****genotype term p<0.0001). (F) IL-9 and IL-13 mRNA expression in the lung relative to β2m in each condition. Values were normalized to the average level of RNA in PBS-treated WT mice. (G) Frequency and total number of IL-9- or IL-13-producting CD45+TCRβ+CD4+CD44+ T cells, as well as total CD44high T cells, were measured by flow cytometry. In all panels, averages are indicated for each group and statistical significances between papain-treated WT and Tnfrsf25-/- mice are shown (Mann-Whitney, *p< 0.05, **p<0.01, ***p< 0.001, **** p<0.0001). (A-G) are pooled data from 2 experiments. Figure 3 TL1A enhances IL-9 production by T cells differentiated under Th9 and iTreg conditions (A) Naïve CD4+ T cells from WT and Tnfrsf25-/- mice were differentiated for 3 days under iTreg conditions with or without TL1A, in the absence or presence of T-depleted antigen presenting cells (APC). Intracellular staining shows a representative experiment, with a compilation of 4 independent experiments depicted below (Mann-Whitney test, *p<0.05). (B) Naïve CD4+ T cells from WT mice were differentiated into Th17 or iTreg with and without TL1A in the presence of APC. Intracellular staining is representative of 2 independent experiments. (C) Naïve CD4+ T cells isolated from WT and Tnfrsf25-/- mice were differentiated into Th9 in the absence or presence of APC with or without TL1A. Representative intracellular staining is shown with a compilation of 8 independent experiments (-APC) and 4 independent experiments (+APC) (Mann-Whitney test, *p<0.05, ***p<0.001). (D) Th9 differentiation was performed as in (C) in the absence of APC, with varying concentrations of TGFβ. Percentage of IL-9-producing cells by intracellular staining is representative of 2 independent experiments. (E) Th9 differentiation was performed as in (C) without APC, with varying amounts of TL1A. Percentage of IL-9-producing cells by intracellular staining is representative of 2 independent experiments. (F) DR3 surface expression vs. isotype control was measured by flow cytometry in naïve CD4+ T cell cultures differentiated in the absence of APC under various polarization conditions. Results are a compilation of 2 independent experiments; error bars represent +/- SEM. (G) DR3 surface expression was measured by flow cytometry in Th9 cultures with and without TL1A. Results are representative of 2 independent experiments. (H) Naïve WT CD4+ T cells were CFSE-labeled and differentiated under Th9 conditions as in (C) in the presence of APC: top row, CFSE dilution with the indicated expansion index; bottom row, CFSE dilution versus intracellular IL-9 with the percentage of cells producing IL-9 after each division shown above each box. Results are representative of 2 independent experiments. (I) Cytokines were measured in the supernatants from Th9 differentiation cultures without (top) or with T-depleted splenocytes (bottom). Heatmaps show TL1A-induced cytokine changes within each condition (red, increased; green, decreased; black, no change; grey, undetectable in one or both conditions). Results show average changes from two independent experiments. Only those cytokines detectable with and without TL1A in at least 4 polarization conditions are shown. Figure 4 TL1A-induced Th9 differentiation depends on IL-2 and STAT5 (A) Naïve CD4+ T cells were polarized under Th9 conditions with or without TL1A, with the indicated blocking antibodies or added cytokines; left and middle panels without APC, right panel with APC. IL-9 production assayed by flow cytometry is representative of 2 independent experiments. (B) WT and STAT6-deficient (Stat6-/-) naïve CD4+ T cells were differentiated in the presence of APC under Th9 and iTreg conditions with and without TL1A. Intracellular staining is representative of 3 independent experiments. (C) Control Stat5fl/fl and STAT5-deficient (Stat5CD4-/-) naïve CD4+ T cells were differentiated in the presence of APC under Th9 conditions with and without TL1A. Intracellular staining is representative of 2 independent experiments. (D) WT naïve CD4+ T cells were transfected with a constitutively active caSTAT5-retrovirus or control virus and differentiated under Th0, Th17 in the presence of IL-2, and regular Th17 (blocking IL-2) conditions. Intracellular staining is representative of 2 independent experiments. Figure 5 Cell-intrinsic effects of TL1A in Th9 differentiation are independent of PU.1 and Traf6 (A) Naïve CD4+ T cells from CD45.1+ congenic WT mice were mixed with an equal number of naïve CD4+ T cells from CD45.1- Tnfrsf25-/- mice and polarized under Th9 conditions without APC, or under iTreg conditions with APC, with and without TL1A. IL-9 intracellular staining versus CD45.1 surface staining with the percentages of CD45.1+ and CD45.1- cells expressing IL-9 is representative of 2 independent experiments. (B) WT and PU.1-deficient (Sfpi1lck-/-) naïve CD4+ T cells were differentiated without APC under Th9 conditions with and without TL1A. Left panel shows intracellular staining. Right panel shows IL-9 production in the supernatant of restimulated cells 5 days after polarization by ELISA. Results are representative of 2 independent experiments. (C) Naïve CD4+ T cells were differentiated without APC under Th9 conditions for 5 days and analyzed by ChIP assay for PU.1 binding to the IL-9 promoter. Error bars represent combined results from 3 mice, representative of 2 independent experiments. (D) As (C), cells were analyzed by ChIP assay for IRF4 binding to the IL-9 promoter. Error bars represent combined results from 4 mice in two independent experiments. (E) WT naïve CD4+ T cells were differentiated without APC under Th9 conditions for 3 days and stained for intracellular phospho-STAT5 (left panel), representative of 2 independent experiments. Cells were also analyzed by ChIP assay for STAT5 binding to the IL-9 promoter (right panels). Error bars represent SEM of technical qPCR replicates. Data is representative of 2 independent experiments. (F) WT and Traf6-/- naïve CD4+ T cells were polarized under Th9 conditions in the absence of APC, with or without TL1A. Intracellular staining is representative of 2 independent experiments. (G) WT and Stat6-/- naïve CD4+ T cells were polarized in the presence of APC under Th9 conditions with or without TL1A or OX40L. Intracellular staining is representative of 3 independent experiments. Figure 6 TL1A enhances ocular inflammation induced by Th9 (A) Naïve anti-HEL CD4+ TCR transgenic T cells were activated with HEL+APC under Th9 conditions, with or without TL1A. Cells were analyzed for intracellular IL-9 and IL-10 production at the indicated time points (Student's T test: * p<0.05, **p<0.01); combined results from 3 independent experiments. (B) IL-9 and IL-10 mRNA was measured relative to β-actin in cultures described in (A); combined results from 2 independent experiments. (C) Cytokine production was measured in the supernatants of cultures described in (A); combined results from 3 independent experiments. (D) Th9 cells generated as in (A) (5 million or 1.7 million to compensate for increased percentage of cells expressing IL-9 in the presence of TL1A) were adoptively transferred into syngeneic recipients expressing HEL in the lens. Inflammatory changes in recipients of Th9 cells activated for 3 or 4 days in culture were evaluated by histological analysis 7 days after transfer (Mann-Whitney *p<0.05, ****p<0.0005); combined results from 3 independent experiments. (E) H&E stained eye sections are examples of mice described in (D) receiving 5 million Th9 cells, differentiated for 3 days, and a mouse with no treatment (naïve); scale bars: 400 μM for low magnification and 50 μM for high magnification enlarged from the indicated boxes; representative of 3 independent experiments. (F) Histological sections showing conjunctivitis in recipients of Th9 and TL1A-stimulated Th9 cells are representative of 3 independent experiments. (G) As in (D), 5 million transgenic T cells were transferred into recipients after 3 days of differentiation. Recipient spleens were collected at the indicated time points and donor cells identified by flow cytometry with an anti-clonotypic monoclonal antibody (1G12), specific to the donor cell TCR. Graph shows mean +/- SEM of transgenic T cell yields from 2 independent experiments. (H) Th9 cells transferred as in (D) were labeled with Cell Proliferation Dye eFluor 670 and their division in vivo determined by dye dilution at the indicated times after transfer: black line, Th9 control; gray line and shaded graph, Th9+TL1A; representative of 2 independent experiments. (I) Naïve mice or recipients of Th9 transfer as in (D) were injected with PBS or TL1A intraocularly 2 and 3 days after transfer. Eye pathology was examined at day 4 (Mann-Whitney *p<0.05, **p<0.01); combined results from at least 2 independent experiments per condition. (J) Recipients of Th9 transfer as in (D) were administered anti-TL1A antibody or hamster Ig control on days -1 and 3. Recipient eyes were analyzed on day 7 (Mann-Whitney *p<0.05); combined results from 3 independent experiments. (K) Representative examples of ocular histological sections from transfer experiments in (J). Figure 7 TL1A enhances allergic lung inflammation induced by antigen-specific Th9 (A) Cytokine expression was measured in restimulated Th9-polarized OT-II T cells or Tnfrsf25-/- OT-II T cells. (B) Timeline of transfer experiment: 106 T cells were transferred into CD45.1+ congenic recipient mice and the recipient mice challenged with IT Ova 24 hours after transfer and IN Ova 48 hours after transfer. Control recipient mice were challenged with PBS. All mice were euthanized 12 hours after the last challenge. (C) Cell counts of neutrophils and eosinophils present in the BAL from each mouse are shown. (D) Representative lung histology of each group (left panel; H&E stain, 20x original magnification, black bar represents 50 μm), and summary of lung histopathology scores from the same experiment (right panel) are shown. (E) IL-9, IL-13 and IL-2 mRNA expression in the lung relative to β2M in each condition was measured by qRT-PCR. (F) Yields of total CD45.2+ donor T cells and IL-9- and IL-13-producing donor T cells per lung (left panel) are shown with representative FACS plots of IL-9 and IL-13 expression by restimulated T cells from each group (right panel). In all graphs, each point represents one mouse with the mean as a black line and significances of differences between Ova-treated groups indicated (Mann-Whitney *p<0.05, **p<0.01). A-D and F are representative of 2 independent experiments. 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Cheng G Arima M Honda K Hirata H Eda F Yoshida N Fukushima F Ishii Y Fukuda T 2002 Anti-interleukin-9 antibody treatment inhibits airway inflammation and hyperreactivity in mouse asthma model American journal of respiratory and critical care medicine 166 409 416 12153980 22 Kaplan MH 2013 Th9 cells: differentiation and disease Immunological reviews 252 104 115 23405898 23 Dardalhon V Awasthi A Kwon H Galileos G Gao W Sobel RA Mitsdoerffer M Strom TB Elyaman W Ho IC Khoury S Oukka M Kuchroo VK 2008 IL-4 inhibits TGF-beta-induced Foxp3+ T cells and, together with TGF-beta, generates IL-9+ IL-10+ Foxp3(-) effector T cells Nature immunology 9 1347 1355 18997793 24 Veldhoen M Uyttenhove C van Snick J Helmby H Westendorf A Buer J Martin B Wilhelm C Stockinger B 2008 Transforming growth factor-beta ‘reprograms’ the differentiation of T helper 2 cells and promotes an interleukin 9-producing subset Nature immunology 9 1341 1346 18931678 25 Goswami R Jabeen R Yagi R Pham D Zhu J Goenka S Kaplan 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Jetten AM Weaver CT 2011 Lineage-specific effects of 1,25-dihydroxyvitamin D(3) on the development of effector CD4 T cells The Journal of biological chemistry 286 997 1004 21047796 34 Tan C Gery I 2012 The unique features of Th9 cells and their products Critical reviews in immunology 32 1 10 22428852 35 Li H Nourbakhsh B Ciric B Zhang GX Rostami A 2010 Neutralization of IL-9 ameliorates experimental autoimmune encephalomyelitis by decreasing the effector T cell population Journal of immunology 185 4095 4100 36 Nowak EC Weaver CT Turner H Begum-Haque S Becher B Schreiner B Coyle AJ Kasper LH Noelle RJ 2009 IL-9 as a mediator of Th17-driven inflammatory disease The Journal of experimental medicine 206 1653 1660 19596803 37 Licona-Limon P Henao-Mejia J Temann AU Gagliani N Licona-Limon I Ishigame H Hao L Herbert DR Flavell RA 2013 Th9 Cells Drive Host Immunity against Gastrointestinal Worm Infection Immunity 39 744 757 24138883 38 Gerlach K Hwang Y Nikolaev A Atreya R Dornhoff H Steiner S 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essential for normal lymphoid development and differentiation Proceedings of the National Academy of Sciences of the United States of America 103 1000 1005 16418296 56 Tamiya T Ichiyama K Kotani H Fukaya T Sekiya T Shichita T Honma K Yui K Matsuyama T Nakao T Fukuyama S Inoue H Nomura M Yoshimura A 2013 Smad2/3 and IRF4 play a cooperative role in IL-9-producing T cell induction Journal of immunology 191 2360 2371 57 Staudt V Bothur E Klein M Lingnau K Reuter S Grebe N Gerlitzki B Hoffmann M Ulges A Taube C Dehzad N Becker M Stassen M Steinborn A Lohoff M Schild H Schmitt E Bopp T 2010 Interferon-regulatory factor 4 is essential for the developmental program of T helper 9 cells Immunity 33 192 202 20674401 58 Qin T 2011 Upregulation of DR3 expression in CD4(+) T cells promotes secretion of IL-17 in experimental autoimmune uveitis Molecular vision 17 3486 3493 22219644 59 Jones GW Stumhofer JS Foster T Twohig JP Hertzog P Topley N Williams AS Hunter CA Jenkins BJ Wang EC Jones SA 2011 Naive and activated T cells display differential responsiveness to TL1A that affects Th17 generation, maintenance, and proliferation FASEB journal : official publication of the Federation of American Societies for Experimental Biology 25 409 419 20826539 60 Angkasekwinai P Chang SH Thapa M Watarai H Dong C 2010 Regulation of IL-9 expression by IL-25 signaling Nature immunology 11 250 256 20154671 61 Monteyne P Renauld JC Van Broeck J Dunne DW Brombacher F Coutelier JP 1997 IL-4-independent regulation of in vivo IL-9 expression Journal of immunology 159 2616 2623 62 Yang XO Zhang H Kim BS Niu X Peng J Chen Y Kerketta R Lee YH Chang SH Corry DB Wang D Watowich SS Dong C 2013 The signaling suppressor CIS controls proallergic T cell development and allergic airway inflammation Nature immunology 14 732 740 23727894 63 Kitson J Raven T Jiang YP Goeddel DV Giles KM Pun KT Grinham CJ Brown R Farrow SN 1996 A death-domain-containing receptor that mediates apoptosis Nature 384 372 375 8934525 64 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PMC005xxxxxx/PMC5112770.txt
LICENSE: This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. 101525337 37346 ACS Chem Neurosci ACS Chem Neurosci ACS chemical neuroscience 1948-7193 25822288 5112770 10.1021/acschemneuro.5b00013 NIHMS798448 Article Azaphilones inhibit tau aggregation and dissolve tau aggregates in vitro Paranjape Smita R. 1 Riley Andrew P. 2 Somoza Amber D. 3 Oakley C. Elizabeth 1 Wang Clay C. C. 34 Prisinzano Thomas E. 5 Oakley Berl R. 1 Gamblin T. Chris 1 1 Department of Molecular Biosciences, Univ. of Kansas, Lawrence, KS 2 Department of Chemistry, University of Kansas, Lawrence, KS 3 Department of Chemistry, University of Southern California, Los Angeles, CA 4 Department of Pharmacology and Pharmaceutical Sciences, School of Pharmacy, University of Southern California, Los Angeles, CA 5 Department of Medicinal Chemistry, University of Kansas, Lawrence, KS 9 11 2016 15 4 2015 20 5 2015 17 11 2016 6 5 751760 This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. The aggregation of the microtubule-associated protein tau is a seminal event in many neurodegenerative diseases, including Alzheimer’s disease. The inhibition or reversal of tau aggregation is therefore a potential therapeutic strategy for these diseases. Fungal natural products have proven to be a rich source of useful compounds having wide varieties of biological activities. We have previously screened Aspergillus nidulans secondary metabolites for their ability to inhibit tau aggregation in vitro using an arachidonic acid polymerization protocol. One aggregation inhibitor identified was asperbenzaldehyde, an intermediate in azaphilone biosynthesis. We therefore tested 11 azaphilone derivatives to determine their tau assembly inhibition properties in vitro. All compounds tested inhibited tau filament assembly to some extent, while four of the 11 compounds had the advantageous property of disassembling preformed tau aggregates in a dose-dependent fashion. The addition of these compounds to the tau aggregates reduced both the total length and numbers of tau polymers. The most potent compounds were tested in in vitro reactions to determine whether they interfere with tau’s normal function of stabilizing microtubules (MTs). We found that they did not completely inhibit MT assembly in the presence of tau. These derivatives are very promising lead compounds for tau aggregation inhibitors and, more excitingly, for compounds that can disassemble pre-existing tau filaments. They also represent a new class of anti-tau aggregation compounds with a novel structural scaffold. Graphical Abstract Tau microtubule-associated protein aggregation inhibitor Alzheimer’s disease azaphilone natural products Aspergillus Aspergillus nidulans Introduction Alzheimer’s disease (AD) is the most common form of dementia. This devastating condition is made worse by the relative lack of therapies available for its treatment. Current therapeutics largely target cholinergic pathways and do little to slow or reverse the accumulation of aggregates of either beta amyloid or the microtubule-associated protein tau into senile plaques or neurofibrillary tangles respectively. The location and amount of tau aggregation into neurofibrillary tangles directly correlates with the type and severity of the disease progression1. Therefore, there is great interest in identifying small molecules that may inhibit or reverse tau aggregation. Recently a tau aggregation inhibitor, a stable, reduced form of methylthioninium chloride, has reached phase 3 clinical trials2, validating the potential of tau aggregation as a target, but there is certainly a need for additional lead anti-tau aggregation compounds for further development into therapeutics. An ideal tau aggregation inhibitor should inhibit the assembly of tau aggregates and disassemble pre-formed tau aggregates as well. Inhibitors of tau aggregation also should not impair the normal function of tau to bind and stabilize microtubules. Previously identified tau aggregation inhibitors, including molecules belonging to the anthraquinone class, have had widely diverse structures, with fused ring structures being a commonly occurring structural motif3. Recent emphasis has been placed on identifying natural products with novel scaffolds that may have useful properties for the treatment of AD by inhibiting tau aggregation4, 5. Fungi have historically been a good source of secondary metabolites, which have useful pharmacological properties such as antibiotics, immunosuppressants, and cholesterol-lowering drugs, among others6. We have identified numerous biosynthetic pathways in Aspergillus nidulans that lead to production of a wide range of secondary metabolites6–9. In a previous study, we tested several A. nidulans secondary metabolites for their ability to inhibit tau aggregation in vitro and found that several were active inhibitors at micromolar concentrations, although they did not have tau disaggregation properties10. Among these, two, ω-dihydroxyemodin and asperthecin, belonged to the anthraquinone class of compounds, a class that includes compounds shown to inhibit tau aggregation. A third compound, asperbenzaldehyde, however, was structurally distinct from previously identified tau aggregation inhibitors. Asperbenzaldehyde is also interesting in that it is an intermediate in the biological synthesis of azaphilone compounds11. Azaphilones are known to exhibit a great variety of biologically important activities including inhibitions of gp120–CD4 binding12 and heat shock protein 90 (Hsp90)13–15, among others. Several azaphilones have been shown to have lipoxygenase inhibitor activity11. Inhibition of lipoxygenases may help reduce fatty acid metabolite levels that are elevated in AD16. Azaphilones, including lipoxygenase-inhibiting azaphilones, can be obtained from asperbenzaldehyde using a 2–3 step semisynthetic route11. We therefore sought to determine whether azaphilones derived from asperbenzaldehyde inhibit tau aggregation, hoping that they might be a useful step in finding compounds with two biological targets relevant to treating AD. Beginning with asperbenzaldehyde, which was purified from a fungal strain engineered to overproduce this compound, the azaphilones were prepared as previously described using two schemes11. The first employs p-toluenesulfonic acid to form the 2-benzopyrilium salt followed by oxidation by lead tetraacetate with or without halogenation. The second scheme employs the hypervalent-iodine-mediated phenol oxidative dearomatization of the 2-benzopyrilium salt with o-iodoxy-benzoic acid followed by halogenation and/or a Wittig olefination with carbethoxymethylenetriphenylphosphorane. Using standard biochemical assays, we investigated the ability of these compounds to alter the aggregation of tau and its stabilization of microtubules. We found that while all compounds inhibited tau aggregation, a smaller subset had the added activity of disassembling pre-formed tau aggregates. The compounds most effective at inhibiting tau aggregation and disassembling pre-formed tau filaments also allowed tau to retain the majority of its microtubule stabilizing functions. Results Eleven compounds with the same azaphilone backbone differing at three points of diversity (R1, R2, and R3) were used in this study (Figure 1). Tau polymerization was initiated in vitro using a standard arachidonic acid induction assay17. To determine whether the compounds could inhibit assembly of tau filaments, each of the compounds, at a final concentration of 200 µM, was preincubated with 2 µM tau for 20 min before the addition of 75 µM arachidonic acid. The degree of tau aggregation inhibition for each compound was determined using a membrane filter assay18. This assay has been used previously to screen A. nidulans secondary metabolites including anthraquinones, xanthones, polyketides, a benzophenone and the asperbenzaldehyde compound that was the parent compound for the synthesis of the azaphilones used in this study10. A mixture of antibodies to the amino terminal region, central region and carboxy terminal region of tau (tau 12, tau 5, and tau 7 respectively) was used to detect tau aggregates. In this assay, only compound aza-11 significantly reduced the amount of tau aggregation detected (Figure 2A). Compounds aza-13 and aza-15 significantly increased the amount of tau aggregation and the remaining compounds had no significant effect (Figure 2A). However, when antibodies against toxic species of tau were employed for detection, very different results were observed. All aza compounds completely abolished recognition by the TOC1 antibody, which recognizes toxic oligomers in vitro and in Alzheimer’s disease tissue19, as compared to controls without compound (Figure 2B). Similarly, significant reductions in recognition by TNT1, an antibody that recognizes the phosphatase-activating domain of tau and is exposed in pathological forms of tau20, were observed for all aza compounds as compared to controls without compound (Figure 2C). When the resulting tau aggregates from the inhibition reactions were visualized by electron microscopy, there were abundant numbers of long filaments in the absence of added compound (Figure 3). Surprisingly, all the azaphilones inhibited the formation of long tau filaments that were observed in the absence of compounds. Instead, amorphous small aggregates were observed after treatment with the compounds (Figure 3). This degree of tau aggregation inhibition was similar to what was observed by electron microscopy for asperbenzaldehyde and asperthecin, and stronger than what was observed for 2,ω-dihydroxyemodin in a prior study10. Because tau aggregation inhibitors that inhibit filament formation have previously been shown to stabilize off-pathway soluble oligomers that are large enough to be trapped in the membrane filter assay21, we believe that the mixture of tau antibodies to normal tau was detecting these aggregates in the filter trap assay (Figure 2A). These aggregates do not seem to be toxic because of their lack of reactivity to TOC1 (Figure 2B) and TNT1 (Figure 2C). To determine whether these compounds can disassemble pre-formed tau aggregates, tau aggregation was allowed to proceed for six hours before the addition of compounds to a final concentration of 200 µM. After 12 hours the effect of compounds on the tau aggregation were examined by filter trap assay using the mixture of antibodies against normal tau (Figure 4). All compounds reduced the amount of preformed tau filaments, with compounds aza-8, aza-9, aza-11, aza-12, and aza-13 having the greatest activity. Electron microscopy was used to validate and extend the results from the filter trap assay. Compounds aza-8, aza-9, aza-12 and aza-13 substantially reduced the preexisting filament mass while the other compounds had less effect (Figure 5). To test whether compounds aza-8, aza-9, aza-12, and aza-13 were not simply blocking the adherence of tau filaments to the electron microscopy grids, compounds were added to pre-formed tau filaments and were immediately prepared for electron microscopy without allowing time for disassembly to occur. Under these conditions, none of the compounds blocked the binding of the filaments to the grid (Supplemental Figure S2). Quantitative analysis of the filament lengths in the presence and absence of compounds confirmed that compounds aza-8, aza-9, aza-12 and aza-13 had fewer aggregates overall compared to reactions without compound and virtually no filaments remaining greater than 200 nm in length (Figure 6). The IC50 of the four most potent compounds was determined using the filter trap assay. The amount of pre-formed filaments remaining following treatment with compounds for 12 hours was reduced in a concentration dependent manner for all four compounds tested (Figure 7). Compound aza-9 had an IC50 of 56 ± 14 µM, compared to 118 ± 19 µM, 98 ± 16 µM and 216 ± 18 µM for compounds aza-8, aza-12 and aza-13 respectively, indicating that aza-9 has the most activity for dissolving pre-formed tau filaments in vitro (Figure 7). In a number of studies heparin has been used to induce tau aggregation. Because heparin-induced tau filaments might be different from arachidonic acid induced filaments, we wished to determine if aza 9 inhibited heparin-induced tau aggregation or disassembled heparin assembled tau aggregates. We chose aza 9 because it was the most potent compound among the 11 azaphilones. Filter trap assays were performed using the mixture of antibodies against normal tau, the TOC1 antibody and the TNT1 antibody. Aza 9 significantly reduced the assembly of TOC1 and TNT1 positive aggregates (Figure 8A). The addition of aza 9 also resulted in the significant disassembly of pre-formed filaments recognized by the TOC1 and TNT1 antibodies (Figure 8B). We chose the most potent azaphilone derivatives aza-8, aza-9, aza-12 and aza-13 to determine their effects on the normal function of tau to stabilize microtubules. Tubulin was mixed with tau in the presence or absence of 90 µM compound and the resulting microtubule formation was monitored by turbidity. All polymerization curves were fit using a Gompertz growth equation (Figure 9). While all four compounds affected the apparent rate and maximum amount of microtubule formation at the concentration tested (Table 1), tau still retained a significant ability to stabilize microtubule formation. Discussion Tau based therapeutic strategies have recently been gaining additional attention largely due to the major role tau pathology plays in many neurological disorders including Alzheimer’s disease. Several tau-directed therapeutic strategies with disease-modifying potential have been identified including modulating tau phosphorylation, microtubule stabilization, tau aggregation inhibitors and tau clearance using antibodies22–30. Conversion of soluble monomeric tau into insoluble tau aggregates could, potentially, result in both loss of function and gain of function toxicities31. Therefore, inhibiting aggregation of tau might prevent formation of the toxic oligomers or tangles. Inhibiting aggregation could also increase the levels of monomeric tau, thereby increasing the chances for its clearance through chaperone mediated processes32. Previous studies have identified several tau aggregation inhibitor (TAI) molecules including those belonging to the class of anthraquinones, phenothiazines, and a benzothiazolidine derivatives among others3, 33, 34. One TAI, a stable, reduced form of methylthioninium chloride, is currently in Phase III clinical trials2, indicating this approach has promise and it is, consequently, worthwhile to identify additional structural backbones with this activity. Many of the previously identified TAIs are comprised of fused ring structures believed to be capable of interacting with the β-sheet structures formed in tau aggregates, thereby inhibiting formation of tau filaments10, 21. Fungal extracts are known to include pharmaceutically important secondary metabolites35. We therefore previously screened 17 secondary metabolites obtained from the fungus Aspergillus nidulans for TAIs due to their structural similarity to previously identified TAIs10. From this screen we identified 3 compounds that inhibited tau aggregation at micromolar concentrations. Two of these compounds belonged to the anthraquinone class of compounds and one was structurally unique from all the previously identified TAIs. We were particularly interested in this compound – asperbenzaldehyde. Asperbenzaldehyde is a precursor to an important class of natural products called azaphilones. Azaphilones are a structurally diverse group of polyketides that share a highly oxygenated bicyclic core and chiral quaternary center36. The azaphilones used in this study were obtained by semi-synthetic diversification of asperbenzaldehyde. All eleven azaphilones inhibited the formation of tau filaments but some of them produced small amorphous tau aggregates, which can be seen in the electron micrographs in Figure 3. These aggregates were not recognized by TOC119 and TNT120 antibodies, which bind to toxic forms of tau, therefore we believe these compounds promote the formation of small off-pathway aggregates of tau which are not toxic and do not act as seeds for further tau filament assembly. The induction of these aggregates could be similar to soluble aggregates of tau induced by porphyrin pthalocyanine tetrasulfonate that have a different conformation from insoluble toxic tau oligomers21. From a therapeutic point of view, TAIs would be more useful if they could also dissolve pre-formed tau filaments because they could theoretically be beneficial to patients that already demonstrate cognitive impairments. We found that a subset of the compounds, aza-8, aza-9, aza-12, and aza-13, showed this property. These four compounds have Br or Cl at position R1, while the other compounds have either I or H at R1 (Figure 1). Therefore, halogenation at position R1 may be not necessarily important for inhibition of tau filament formation, but electron-withdrawing groups at R1 specifically seem to enhance disassembly of tau filaments. Cl and Br are more electronegative (3.0 and 2.8 respectively), than I (2.5) and H (2.1) indicating that increased electronegativity at position R1 could have a significant impact on the activity of tau aggregation inhibitors with this scaffold. The four disassembly causing compounds have a ketone at position R3, while presence of the CHCO2Et moiety at the same position seems to virtually eliminate disassembly, even with halogenation. The impact of the chemical groups at the R2 position seems to be dependent upon the substitution at R1. Compounds aza-8 and aza-12 both have Cl at R1, but possess acetate and hydroxyl groups at R2, respectively. Despite this structural difference, there is no significant difference in their activity levels. However compounds aza-9 and aza-13 both containing Br at R1, and acetate and hydroxyl groups at R2, respectively differ in their levels of activity. Aza-9 is more potent than aza-13, therefore positioning of the acetate group at R2 in the presence of a Br at R1 might be important for compound activity. Additionally, all four disassembly causing compounds have lipoxygenase-1 inhibitory activity in the low micromolar range (IC50 of 2–8µm)11. Inhibition of LOX-1 may help reduce fatty acid metabolites of arachidonic acid and docasahexanoic acid that are elevated in Alzheimer’s disease16. These compounds could therefore have two positive therapeutic activities in tau dementias. The relatively high IC50 values of our compounds indicate that they are unlikely to be of therapeutic value and we do not know if they have suitable bioavailability or pharmacokinetic properties. It is important, however, to identify new scaffolds with the appropriate biological activity for further development. We believe these compounds provide a novel TAI scaffold with the added features that they inhibit LOX-1 and some of them disassemble pre-formed tau aggregates. In conclusion, this study shows that these compounds inhibit assembly of tau aggregates, disassemble preformed tau aggregates, and partially preserve tau’s ability to bind to tubulin and promote microtubule assembly. These compounds provide a promising novel scaffold for TAI molecules. The structure-activity relationship studies give us several leads for the probable important chemical groups required in this scaffold structure required for the anti-tau aggregation activity of the compounds. Further studies on the interaction between the compounds and tau will help to determine the precise mechanism of action of these compounds. Methods Chemicals and Reagents Full length 2N4R tau (441 amino acids) was expressed in E. coli and purified as described previously37. Arachidonic acid (ARA) was purchased from Cayman Chemicals (Ann Arbor, MI). Heparin sodium salt was purchased from SIGMA (St. Louis, MO). Asperbenzaldehyde was purified from Aspergillus nidulans and converted to the compounds aza-7 through aza-17 (Figure 1) as described previously11 with the following minor modifications. We constructed a number of strains with various promoter combinations and used a variety of induction conditions to maximize asperbenzaldehyde production. Our best yields were obtained with strain LO8355 (pyrG89, pyroA4, riboB2, nkuA::argB, stcJ::AfriboB, AN1029(p):: AfpyrG-alcA(p), AN1033::AfpyroA, alcR(p)::ptrA-gpdA(p)). In this strain, the promoter of asperfuranone biosynthesis transcription factor AN1029 (using the AspGD nomenclature (http://aspergillusgenomes.org/)) is replaced with the highly inducible alcA promoter and the alcR promoter is replaced with the strong, constitutive gpdA promoter (−1241 to −1). AN1033 is replaced with the AfpyroA gene to interrupt the asperfuranone biosynthesis pathway causing asperbenzaldehyde to accumulate. Growth was in lactose minimal medium (20 g/L lactose, 6 g/L NaNO3, 0.52 g/L KCl, O.52 g/L MgSO4,·7H2O, 1.52 g/L KH2PO4, 1 mL/L trace elements solution)38. Spores were inoculated at 106/mL into 500 mL of medium in a 2L flask. Incubation was at 37 °C on a gyratory shaker and induction was with 30 mM methyl-ethyl-ketone, added 55 hours after inoculation. Cultures were harvested six days after inoculation. Yields of purified asperbenzaldehyde were greater than 2 g/L representing an approximate conversion of 10% of the carbon source to final product. Additional information on the purity of the compounds can be found in supplemental materials. Inhibition of tau aggregation 75 µM arachidonic acid was used to initiate the aggregation of 2 µM tau in polymerization buffer (PB, 10 mM HEPES (pH 7.64), 5 mM DTT, 100 mM NaCl, 0.1 mM EDTA, and 3.75% ethanol) in vitro as previously described17. Compounds dissolved in DMSO were added to a final concentration of 200 µM and incubated with tau protein in PB 20 minutes prior to the addition of arachidonic acid. The reactions were allowed to proceed for 16 h at room temperature before analysis10. For heparin induced tau assembly inhibition reactions, 0.6 µM heparin was used to initiate aggregation on 2 µM tau in polymerization buffer (PB, 10mM HEPES (pH 7.64), 5 mM DTT, 17.7 mM NaCl) in vitro. Compounds dissolved in DMSO were added to a final concentration of 200 µM and incubated with tau protein in PB 20 minutes prior to the addition of heparin. The reactions were allowed to proceed for 16 h at 37 °C before analysis. Disassembly of pre-formed filaments Pre-formed tau filaments were generated with 2 µM tau and 75 µM ARA in PB as described above for 6 h at room temperature. Compounds dissolved in DMSO were added to the tau solution at final concentrations indicated in the Results section and figure legends. The reactions were allowed to proceed at room temperature for 12 h before analysis. For heparin induced tau aggregation assays, pre- formed tau filaments were generated with 2 µM tau and 0.6 µM heparin in PB as described above for 12 h at 37 °C. Compounds dissolved in DMSO were added to the tau solution at final concentrations indicated in the Results section and figure legends. The reactions were allowed to proceed at 37 °C for 24 h before analysis. Filter trap assay The amount of tau aggregates following assembly or disassembly reactions was determined by filter trap assay as described previously10. Reactions were diluted into TBS such that they contained 20 ng protein in 300 µL. For heparin induced tau aggregation reactions, the reactions were diluted into TBS such that they contained 60 ng protein in 300 µL. Solutions were passed through a nitrocellulose membrane using house vacuum in a dot-blot apparatus. The aggregates trapped on the membrane were detected by either general antibodies (a mixture of Tau 539 at 1:50,000 dilution, Tau 1240 at 1:250,000 dilution and Tau 741 at 1:250,000 dilution), or antibodies to toxic conformations (TNT119 at 1:200,000 or TOC120 at 1:7,000). All antibodies were a kind gift from Drs. Nick Kanaan and Lester I. Binder. HRP-linked Goat anti-mouse IgG (general antibodies and TNT1) or HRP-linked Goat anti-mouse IgM (TOC1) (Thermo Scientific, Rockford, IL) were used as the secondary antibodies and blots were developed using ECL (enhanced chemiluminescence) Western Blotting Analysis System (GE Healthcare, Buckinghamshire, UK). Images were captured with a Kodak Image Station 4000R or ChemiDoc-It2 Imager and were quantified using the histogram function of Adobe Photoshop 7.0. Statistical analyses were performed using unpaired t-tests to compare the triplicate values to control values. Transmission electron microscopy Polymerization reaction samples were diluted 1:10 in PB and fixed with 2% glutaraldehyde for 5 min. Fixed samples were placed on formvar carbon-coated grids and stained with uranyl acetate as previously described10. Images were captured with a Technai F20 XT Field emission transmission electron microscope (FEI Co., Hillsboro, OR) and Gatan Digital Micrograph imaging system (Gatan, Inc., Pleasanton, CA). The filaments were quantified using Image-Pro Plus 6.0 software (Media Cybernetics, Inc., Rockville, MD) as previously described10. For quantitative analysis, filament lengths were placed into bins as described in results. Statistical analyses were performed using unpaired t-tests to compare 4 or 5 replicates for each bin size with the no compound data serving as reference values. Tubulin Polymerization Assay Polymerization of tubulin was measured using a Tubulin Polymerization Assay kit BK006P (Cytoskeleton, Inc., Denver, CO) following the manufacturer’s protocol. Briefly, 2 mg/ml porcine tubulin was incubated with 1.5 µM tau and 90 µM aza-8, aza-9, aza-12 or aza-13 compounds. Tubulin polymerization was monitored by turbidity at 340 nm in a Varian 50 MPR microplate reader at 37 °C for 1 h. Experiments were performed in triplicate, averaged and fit to a Gompertz growth equation as previously described42 using the equation: y=ae−e−((t−ti)b) Where y is the amount of microtubule polymerization measured at time t, a is the maximum amount of microtubule polymerization observed at an absorbance of 340 nm (Max), ti is the point of inflection of the curve at the time of maximum growth rate in minutes, and b is inversely proportional to the apparent rate of polymerization (kapp, min−1). The average values for the parameters a, b and ti were determined and compared to the no-compound control using a paired t-test to determine statistical significance *p≤ 0.05; **p≤ 0.01; ***p≤ 0.001. Supplementary Material Supplemental Material We thank Adam Miltner for assistance with protein expression and purification. Funding was provided in part by P01-GM084077 from the National Institute of General Medical Sciences (CCCW and BRO), T32 GM008545 from the National Institute of General Medical Sciences (APR), R01-NS083391 from the National Institute of Neurological Disorders and Stroke (TCG) and by the H.L. Snyder Medical Foundation (BRO and TCG). We thank Drs. Nick Kanaan and Lester I. Binder for their kind gift of the antibodies used in this study. Figure 1 Compounds used in this study The core structure of the azaphilone compounds is shown with the positions of modications indicated by R1, R2 and R3. A.-K.: The structures of the 11 compounds used in this study: A) aza-7, B) aza-8, C) aza-9, D) aza-10, E) aza-11, F) aza-12, G) aza-13, H) aza-14, I) aza-15, J) aza-16, and K) aza-17. Figure 2 Filter trap assay of tau filament formation Tau polymerization reactions in A), B), and C) were performed with 2 µM tau and 75 µM arachidonic acid either with or without 200 µM compound. The compounds used are listed on the X- axis. The resulting amount of tau filament formation was determined using a filter trap assay. The values for tau filament formation were normalized to the amount of aggregation in the absence of compound (dashed line). Negative values indicate that there was less detectable tau on the filter after treatment with a compound than was observed with monomeric tau in the absence of arachidonic acid. The amount of tau on the filter was detected using A) a mixture of antibodies tau 5, tau 7 and tau 12, B) antibody TOC1, and C) antibody TNT1. The observation that the values are lower in B) and C) suggests that the tau aggregates that are retained on the filters are not in the toxic oligomeric form recognized by the TOC1 antibody and the phosphatase domain recognized by TNT1 antibody is not exposed. Values are the average of three trials ± SD. *P ≤ 0.05; ** P ≤ 0.01; *** P ≤ 0.001 Figure 3 Electron microscopy of tau filament formation in the presence of azaphilone derivatives Tau polymerization reactions were performed with 2 µM tau and 75 µM arachidonic acid either with or without 200 µM compound. Aliquots of the reactions were prepared for negative stain electron microscopy. Representative images are shown for A) no compound control, B) aza-7, C) aza-8, D) aza-9, E) aza-10, F) aza-11, G) aza-12, H) aza-13, I) aza-14, J) aza-15, K) aza-16, and L) aza-17. The scale bar in the lower right panel represents 1 µm and is applicable to all images. Figure 4 Filter trap assay of tau filament disassembly Tau polymerization reactions were performed with 2 µM tau and 75 µM arachidonic acid at room temperature. After 6 hours, 200 µM compound or an equal volume of DMSO was added to the reactions. The compounds used are listed on the X-axis. The resulting amount of tau filament formation was determined using a filter trap assay. The values for tau filament formation were normalized to the amount of aggregates detected in the absence of compound (dashed line). Negative values indicate that there was less detectable tau on the filter after treatment with a compound than was observed with monomeric tau in the absence of arachidonic acid. The amount of tau on the filter was detected using a mixture of antibodies tau 5, tau 7 and tau 12. Values are the average of three trials ± SD. *P ≤ 0.05; ** P ≤ 0.01; *** P ≤ 0.001 Figure 5 Electron microscopy of tau filament disassembly in the presence of azaphilone derivatives Tau polymerization reactions were performed with 2 µM tau and 75 µM arachidonic acid at room temperature. After 6 hours, 200 µM compound or equal volume of DMSO was added to the reactions. Aliquots of the reactions were prepared for negative stain electron microscopy. Representative images are shown for A) no compound control, B) aza-7, C) aza-8, D) aza-9, E) aza-10, F) aza-11, G) aza-12, H) aza-13, I) aza-14, J) aza-15, K) aza-16, and L) aza-17. The scale bar in the lower right panel represents 1 µm and is applicable for all images. Figure 6 Filament length distributions Tau disassembly reactions were performed and viewed by electron microscopy. The filaments remaining following incubation with or without compound were measured, and placed into bins according to their length (30–50 nm, 50–100 nm, 100–150 nm, 150–200 nm and > 200 nm). The lengths within a bin were summed to determine the total amount of filament length in each bin. A) Represents the length distributions for filaments in the control reaction without compound. The length distributions are also shown for filaments remaining following incubation in the presence of B) aza-7, C) aza-8, D) aza-9, E) aza-10, F) aza-11, G) aza-12, H) aza-13, I) aza-14, J) aza-15, K) aza-16, and L) aza-17. Each point is the average distribution for images of 5 different fields ± SD.*P ≤ 0.05; ** P ≤ 0.01; *** P ≤ 0.001. Figure 7 IC50 determination tau filament disassembly Polymerization reactions at 2 µM tau and 75 µM arachidonic acid were performed at room temperature. After 6 hours, compounds were added to these reactions at several different concentrations and incubated an additional 12 hours. The resulting amount of tau filaments in the reaction were determined by a filter trap assay detected by a mixture of antibodies to normal tau (Tau 5, Tau 7 and Tau 12). The amount of polymerization was normalized to controls in the absence of compound (100%). The normalized data was plotted against the log of the inhibition concentration and fit to a dose-response curve to determine the IC50 for A) Aza-8, B) Aza-9, C) Aza-12 and D) Aza-13. Data points are the average of three trials ± SD. Figure 8 Filter trap assay for filament assembly and disassembly of heparin-induced tau filaments A) For assembly inhibition, 100 µM aza 9 was incubated with 2 µM tau for 20 minutes before the addition 0.6 µM heparin. 16 hours after induction, the degree of aggregation was determined using the filter trap assay detected by a mixture of antibodies to normal tau (Tau 5, Tau 7 and Tau 12), an antibody to oligomeric tau (TOC1) and an antibody to a toxic conformation of tau (TNT1). The average of three independent trials ± SD is shown for no compound controls (white bars) and 100 µM aza 9 (black bars). B) 2 µM tau and 0.6 µM heparin were incubated together for 21 hours prior to the addition of 100 µM aza 9 or an equal volume of DMSO. Disassembly reactions proceeded for an additional 12 hours and the degree of aggregation was determined using the filter trap assay detected by a mixture of antibodies (Tau 5, Tau 7 and Tau 12), TOC1 and TNT1. The average of three independent trials ± SD is shown for no compound controls (white bars) and 100 µM aza 9 (black bars). *P ≤ 0.05; ** P ≤ 0.01; *** P ≤ 0.001. Figure 9 Microtubule assembly in the presence of the most potent azaphilone tau aggregation inhibitors Tubulin was incubated with either tau protein alone or tau in the presence of A) aza-8, B) aza-9, C) aza-12, or D) aza-13 at a concentration of 90 µM. Microtubule assembly was monitored by absorbance at 340 nm (y- axis) over time (x-axis). Each point is the average of three independent trails ± SD. All data were fit to Gompertz growth curve (dashed and solid lines for no compound and 90 µM azaphilones respectively). For clarity, only every second time point is shown on the graph.*P ≤ 0.05; ** P ≤ 0.01; *** P ≤ 0.001. Table 1 Statistical analysis of the effects of compounds aza-8, aza-9, aza-12, and aza-13 on the stabilization of microtubules. ti (min) kapp (min−1) Max (A340) Aza-8 − 3.08 ± 1.28 0.87 ± 0.14 0.76 ± 0.36 + 13.42 ± 6.59 0.12 ± 0.02*** 0.36 ± 0.14* Aza-9 − 2.26 ± 0.65 0.62 ± 0.08 0.65 ± 0.38 + 5.03 ± 1.93 0.26 ± 0.19* 0.38 ± 0.10* Aza-12 − 3.11 ± 1.22 0.78 ± 0.09 0.75 ± 0.10 + 12.83 ± 1.35*** 0.09 ± 0.02*** 0.50 ± 0.04* Aza-13 − 2.58 ± 1.29 0.86 ± 0.17 0.72 ± 0.06 + 15.65 ± 7.72* 0.12 ± 0.05** 0.30 ± 0.07** Max (A340) is the maximum amount of microtubule polymerization, ti is the point of inflection of the curve at the time of maximum growth rate in minutes, and b is inversely proportional to the apparent rate of polymerization (kapp, min−1) as determined from the fit of three individual microtubule polymerization curves for each condition to a nonlinear Gompertz growth function (see Methods). Competing Interests The authors declare that they have no competing interests. Author Contributions SRP carried out the tau assembly and disassembly experiments and drafted the manuscript. APR purified asperbenzaldehyde, generated and purified azaphilone derivatives, and assisted with analysis of structure/activity relationships. ADS purified asperbenzaldehyde, generated and purified derivatives of azaphilones. CEO constructed the A. nidulans strains for asperbenzaldehyde over-production and cultured the strains for overproduction. CCCW and BRO conceived of the generation and purification of derivatives of asperbenzaldehyde and azaphilones. TEP assisted with analysis of structure/activity relationships. BRO and TCG conceived of the study, and participated in its design and coordination and helped to draft the manuscript. All authors read and approved the final manuscript. 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PMC005xxxxxx/PMC5113143.txt
LICENSE: This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. 2985117R 4816 J Immunol J. Immunol. Journal of immunology (Baltimore, Md. : 1950) 0022-1767 1550-6606 27742832 5113143 10.4049/jimmunol.1601427 NIHMS817240 Article Small molecule inhibition of Rab7 impairs B cell class-switching and plasma cell survival to dampen the autoantibody response in murine lupus Lam Tonika *1 Kulp Dennis V. *1 Wang Rui *12 Lou Zheng * Taylor Julia * Rivera Carlos E. * Yan Hui * Zhang Qi * Wang Zhonghua § Zan Hong * Ivanov Dmitri N. § Zhong Guangming * Casali Paolo *3 Xu Zhenming *3 * Department of Microbiology, Immunology and Molecular Genetics, University of Texas School of Medicine, UT Health Science Center at San Antonio, TX 78229 § Department of Biochemistry, University of Texas School of Medicine, UT Health Science Center at San Antonio, TX 78229 Correspondence: Paolo Casali: Phone: (210) 567-3925; Fax: (210) 567-6612; pcasali@uthscsa.edu. Zhenming Xu: Phone: (210) 567-3964; Fax: (210) 567-6612; xuz3@uthscsa.edu 1 These authors contributed equally. 2 Current address: Xiangya School of Medicine, Central South University of China, Changsha, Hunan, China. 3 These authors jointly directed the study. 17 9 2016 14 10 2016 15 11 2016 15 11 2017 197 10 37923805 This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. IgG autoantibodies mediate pathology in systemic lupus patients and lupus-prone mice. Here we showed that the class-switched IgG autoantibody response in MRL/Faslpr/lpr and C57/Sle1Sle2Sle2 mice was blocked by the CID 1067700 compound, which specifically targeted Rab7, an endosome-localized small GTPase that was upregulated in activated human and mouse lupus B cells, leading to prevention of disease development and extension of life-span. These were associated with decreased IgG-expressing B cells and plasma cells, but unchanged numbers and functions of myeloid cells and T cells. The Rab7 inhibitor suppressed T cell-dependent and T cell-independent antibody responses, but did not affect T cell-mediated clearance of Chlamydia infection, consistent with a B cell-specific role of Rab7. Indeed, B cells and plasma cells were inherently sensitive to Rab7 gene knockout or Rab7 activity inhibition in class-switching and survival, respectively, while proliferation/survival of B cells and generation of plasma cells were not affected. Impairment of NF-κB activation upon Rab7 inhibition, together with the rescue of B cell class-switching and plasma cell survival by enforced NF-κB activation, indicated that Rab7 mediates these processes by promoting NF-κB activation, likely through signal transduction on intracellular membrane structures. Thus, a single Rab7-inhibiting small molecule can target two stages of B cell differentiation to dampen the pathogenic autoantibody response in lupus. Rab7 NF-κB AID CSR plasma cells autoantibodies lupus small molecule compound Introduction Class switch DNA recombination (CSR) in the IgH locus substitutes the IgH constant (CH) region, such as Cμ of IgM expressed in naïve B cells, with Cγ, Cα or Cε, thereby giving rise to IgG, IgA or IgE antibodies. Together with somatic hypermutation (SHM), CSR is central to the maturation of the antibody response to pathogens, as class-switched antibodies display wide tissue distributions and possess diverse biological effector functions (1). These traits also make IgG and IgA autoantibodies highly pathogenic and capable of mediating multiple organ damage in systemic lupus erythematosus (SLE) (2, 3). Un-switched IgM autoantibodies are mostly nonpathogenic and, rather, may mediate frontline immune protection as natural polyreactive antibodies (4). Class-switched B cells further differentiate into memory B cells or plasma cells, which secrete antibodies at a high rate. A hallmark of active lupus is the high number of IgG+ antibody-secreting cells (ASCs) that produce autoantibodies. These are diverse but generally target nuclear antigens, such as DNA (5, 6), making the mechanisms underlying B cell class-switching and plasma cell generation/maintenance targets of new lupus therapeutics. Like SHM, CSR requires activation-induced cytidine deaminase (AID, encoded by AICDA in humans and Aicda in mice). AID expression is mainly restricted in peripheral B cells activated by CD154 engagement of CD40 on the B cell surface or by complex antigens that engage both a Toll-like receptor (TLR) and the B cell receptor (BCR) (7). AID is elevated in B cells of lupus patients and lupus mice, consistent with the heightened CSR/SHM in these B cells (8), and AID deficiency abrogates IgG autoantibodies in lupus-prone MRL/Faslpr/lpr mice (8, 9). Inhibitors of AID deaminase activity are yet to be developed, thereby emphasizing the need for molecules that target the mechanisms underlying AID induction in order to dampen the class-switched pathogenic autoantibody response. Rab7 (encoded by RAB7A in humans and Rab7 in mice) is a small GTPase that, when bound to its GTP substrate, promotes endosome maturation and autophagy. As we have shown (10), Rab7 is induced in activated B cells in vivo (i.e., in PNAhi germinal center B cells) and in vitro, e.g., by CD154 and TLR ligands, the same stimuli that induce AID expression and CSR. It plays a B cell-intrinsic role in antibody responses, as mice that conditionally knockout Rab7 in activated B cells cannot mount mature antibody responses to T cell-dependent or -independent antigens (10). Rab7 promotes CSR (to IgG, IgE and IgA) and does so by mediating AID induction, as enforced expression of AID rescues CSR in Rab7 knockout B cells. Further, Rab7 plays an important role in CD40- or TLR-triggered activation of NF-κB, which directly regulates Aicda gene transcription by binding to the promoter and enhancers of this gene (1, 11, 12). Rab7 is, however, dispensable for Erk1/Erk2 activation and expression of Blimp-1, both of which critically mediate plasma cell generation (13, 14), and, as a consequence, B cell differentiation into plasma cells, suggesting that Rab7 and its associated intracellular membrane structures (i.e., endosomes) specify receptor-triggered signaling for selective gene expression and B cell differentiation processes (15). Whether Rab7 plays a role in the maintenance of plasma cells remains unclear. Here we hypothesized that the lupus autoantibody response can be suppressed by inhibition of CSR in B cells and impairment of generation or maintenance of plasma cells, ideally by a single molecule that can target both cell types. To test this hypothesis, we have used a high-affinity and specific Rab7 inhibitor, CID 1067700. This has been identified by high-throughput screening as the only compound to affect the binding of purified recombinant Rab7 to GTP and GDP (16). By analyzing the level of activated Rab7 form (GTP-bound Rab7, Rab7-GTP) in B cells treated with CID 1067700 and using B cell-specific Rab7 knockout mice as well as retroviruses that enforced specific gene expression, we have verified the specific targeting of Rab7 by this small molecule in B cells and the consequent impairment in NF-κB activation. By using our defined in vitro B cell and plasma cell culture systems, we have further analyzed the impact of Rab7 inhibition on B cell class-switching and plasma cell generation/survival as well as the role of Rab7-dependent NF-κB activation in these processes. Finally, by analyzing – for the first time – the in vivo effect of the Rab7 inhibition on antibody and autoantibody responses in normal C57BL/6 (C57) mice and two widely used lupus mouse strains, female MRL/Faslpr/lpr and C57/Sle1Sle2Sle3 mice (17, 18), we have outlined the potential of Rab7 as a therapeutic target in lupus and possibly other NF-κB-, CSR- and/or plasma cell-mediated disease conditions. Materials and Methods Mice, drug treatment, immunization and infection Female mice were used in all experiments. C57 (Stock # 000664), MRL/Faslpr/lpr (Stock #000485) and C57/Sle1Sle2Sle3 (Stock #007228) mice were from The Jackson Laboratory and maintained in a pathogen-free vivarium. Conditional Rab7 knockout Igh+/Cγ1-creRab7fl/fl mice and their “wildtype” Igh+/Cγ1-creRab7+/fl littermates on the C57 background were as described (10). Rosa26+/fl-STOP-fl-Ikkβca mice on the C57 background (19) were from The Jackson Laboratory (Stock #008242). For in vivo treatment, CID 1067700 (MLS000673908; SID 24798006; SID 57578339; Glixx Laboratories) dissolved in DMSO (stock concentration 40 mM, 16 mg/ml) was diluted with the solvent to the final volume of 50 μl and injected intraperitoneally (i. p.) once per week at the dose of 16 mg/Kg body weight. This dose was well tolerated by mice at all ages (data not shown); it is within the dose range used in patients and animal models for several drugs with comparable EC50 (10–100 nM) to their respective targets (higher doses led to variable mouse death, perhaps due to putative off-targeting effect of the drug). C57, MRL/Faslpr/lpr and C57/Sle1Sle2Sle3 mice injected i. p. with the vehicle DMSO (nil; 50 μl) showed no difference in examined parameters, as compared to their respective counterparts without any injection (data not shown). For survival studies and skin lesion analyses, MRL/Faslpr/lpr mice were treated with nil or CID 1067700 for 10 weeks and maintained until moribund (e.g., showing signs of severe loss of mobility, hunched back, piloerection, ruffled fur, dyspnea, gasping and weight loss), at which point they were euthanized. For other clinical, serological, cellular and molecular analyses (see below), mice were treated for 7 weeks in a “double-blind” manner, as their identities were made unknown to investigators who performed these assays. For immunization, C57 mice were treated with nil or CID 1067700 7 d before i. p. injection with 100 μg of NP-CGG (in average 16 molecules of 4-hydroxy-3-nitrophenyl acetyl, NP, conjugated to one molecule of chicken γ-globulin; Biosearch Technologies) in 100 μl of alum (Imject® Alum, Pierce) or 25 μg of NP-LPS (0.2 NP molecule conjugated to one LPS molecule; Biosearch Technologies) in 100 μl of PBS. Mice were treated with nil or CID 1067700 once every three days until being sacrificed. For Chlamydia muridarum infection, the Nigg strain was propagated in Hela cells for the isolation of the Nigg3G0.10.1 clone, as previously described (20). Purified Nigg3G0.10.1 elementary bodies (EB) were used to infect 6-week old C57 mice intravaginally with 2 × 105 inclusion-forming units (IFUs). Mice were injected with 2.5 mg of medroxyprogesterone (Depo-Provera; Pharmacia Upjohn) subcutaneously at d −5 to increase the susceptibility and nil or CID 1067700, starting at d −7, once a week for 5 weeks. Mice were monitored for vaginal live organism shedding up to d 63. All protocols were in accordance with rules and regulations of the Institutional Animal Care and Use Committee of the University of Texas Health Science Center at San Antonio (UTHSCSA). Human and mouse primary B cells Human PBMCs were prepared, following a standard protocol, from peripheral blood of de-identified SLE patients and healthy subjects, as collected by venipuncture. SLE patients, who were recruited with informed consent under the protocol approved by the Institutional Review Board of UTHSCSA, fulfilled at least four 1982 American Rheumatism Association revised criteria for SLE and had the SLE Disease Activity Index (SLEDAI) above 3. All donors were free of infection by HBV, HCV, HPV, HIV and EBV. To prepare human B cells for stimulation, PBMCs (5 × 107) were subjected to negative selection (against CD2, CD14, CD16, CD27, CD36, CD43 and CD235a) using Human Naïve B Cell Isolation Kit II (Miltenyl) following the manufacturer’s instructions, resulting in over 95% IgD+ B cells (generally over 3 × 106). Cells were analyzed or seeded at 3 × 105 cell/ml for culturing in RPMI 1640 medium (Invitrogen) supplemented with FBS (10% v/v, Hyclone), penicillin-streptomycin/amphotericin B (1% v/v) and 50 μM β-mercaptoethanol (RPMI-FBS). Mouse immune cells were isolated from single cell suspensions prepared from the spleen and pooled axillary, inguinal and cervical lymph nodes. Lymph node cells were directly lysed for immunoblotting studies. Spleen cells were resuspended in ACK Lysis Buffer (Lonza) to lyse red blood cells and, after quenching with RPMI-FBS, were resuspended in PBS for analysis or further preparation. To isolate B cells, spleen cells were subjected to negative selection (against CD43, CD4, CD8, CD11b, CD49b, CD90.2, Gr-1 or Ter-119) using EasySepTM Mouse B cell Isolation Kit (StemCellTM Technologies) following the manufacturer’s instructions, resulting in preparations of more than 98% IgM+IgDhi B cells. After pelleting, B cells were resuspended in RPMI-FBS before further analysis or stimulation. For cell sorting, spleen cells were stained with fluorophore-labeled anti–CD19 mAb, anti–CD138 mAb, anti–TCR mAb and/or peanut agglutinin (PNA) to purify B cells, activated B cells and plasma cells, as indicated, resulting preparations that were at least 98% pure by post-sorting analysis. Bone marrow cells were isolated form tibia and fibula for myeloid cell differentiation and ELISPOT experiments. B cell culture, stimulation and drug treatment Human B cells were stimulated with CD154 (3 U/ml) in the presence of recombinant IL-4 (20 ng/ml; BioLegend) and IL-21 (50 ng/ml; R&D Systems) for 48 h for transcript analyses or 120 h for flow cytometry analysis of class-switched IgG1 and other markers. CD154 was prepared as membrane fragments isolated from Sf21 insect cells infected by CD154-expressing baculovirus, as we described (10, 21) – membrane fragments from non-infected Sf21 cells failed to stimulate B cells. For CSR induction in mouse B cells, spleen B cells were cultured (3 × 105 cell/ml) in RPMI-FBS were stimulated for 96 h (or 48 h for transcript and protein analyses) by the following primary stimuli: CD154 (3 U/ml), LPS (3 μg/ml, from E. coli, serotype 055:B5, deproteinized by chloroform extraction; Sigma-Aldrich) or R-848 (30 ng/ml; Invivogen), a ligand of TLR7, which promotes lupus autoantibody responses in a B cell-intrinsic manner. Recombinant IL-4 (4 ng/ml), for CSR to IgG1 and IgE, and TGF-β (2 ng/ml; R&D Systems), for CSR to IgA, and anti–Igδ mAb (clone 11-26c conjugated to dextran, anti–δ/dex, 100 ng/ml; Fina Biosolutions), which crosslinks IgD BCR to potentiate CSR to IgA in primary B cells, were added as indicated. To induce CSR to IgA in the mouse IgM+ CH12F3 lymphoma cell line, these B cells (105 cell/ml) were cultured in RPMI-FBS and stimulated with CD154 (3 U/ml) or, as first shown here, by LPS at low concentrations (100 ng/ml), plus IL-4 and TGF-β for 48 h. To generate plasma cells in vitro, purified B cells were stimulated with LPS plus IL-4, TGF-β, anti–Igδ mAb conjugated to dextran (anti–δ/dex) and retinoic acid (RA, 10 μM; Sigma) for 66 h. This condition, as we first found here, resulted in CD19loCD138hi plasma cells representing over 70% of cells in the culture. To treat human and mouse B cells in vitro with the Rab7 inhibitor, CID 1067700 was diluted in DMSO and added to cell cultures to the final concentration of 40 μM (or as indicated). CID 1067700 or DMSO (nil) was added either at the time when B cell stimulation started, or 66 h after B cells were stimulated with LPS plus IL-4, TGF-β, anti–δ/dex and RA, as indicated, for analysis of plasma cell survival (see below). Analysis of CSR, cell proliferation and survival To analyze IgG-expressing B cells and plasma cells in vivo, spleen cells (2 × 106) were first stained with fluorophore-labeled mAbs to surface markers and 7–AAD (Supplemental Table 1). After washing, cells were resuspended in the BD Cytofix/CytopermTM buffer (250 μl, BD Biosciences) and incubated at 4°C for 20 m. After washing twice with the BD Perm/WashTM buffer, cells were stained in the same buffer with fluorophore-labeled mAb to IgM, IgG1, IgG2a or IgG2b followed by washing for flow cytometry analysis. Dead (7–AAD+) cells were excluded from analysis. For CSR analysis of B cells stimulated in vitro, B cells were analyzed by flow cytometry for surface expression of IgG and IgA as well as intracellular expression of IgE, as we have described (10, 21). For B cell proliferation analysis in vivo, mice were injected i. p. with 2 mg of bromodeoxyuridine (BrdU) in 200 μl PBS twice, with the first and second injection at 24 h and 20 h prior to sacrificing, respectively. Spleen B cells were analyzed for BrdU incorporation (by anti–BrdU mAb staining) and DNA contents (by 7–AAD staining after cells were permeablized) using a BrdU Flow Kit® (BD Biosciences) following the manufacturer’s instructions. For B cell proliferation analysis in vitro, naïve B cells were labeled with CFSE (Invitrogen) following the manufacturer’s instructions and then cultured for 96 h in the presence of appropriate stimuli. Cells were analyzed by flow cytometry for CFSE intensity, which was reduced by half after completion of each cell division, as CFSE-labeled cell constituents were equally distributed between daughter cells. The number of B cell divisions was determined by the “Proliferation Platform” of the FlowJo® software. To analyze B cell and plasma cell survival in MRL/Faslpr/lpr mice treated with CID 1067700 or DMSO in vivo, spleen cells were stained with anti–CD19 mAb, anti–CD138 mAb, anti–TCR mAb (to identify TCR−CD19+CD138− B cells and TCR−CD19−/loCD138+ plasma cells) in the presence of mAb Clone 2.4G2, which blocks the FcγIII and FcγII receptors, and 7–AAD without permeabilization (to identify apoptotic/necrotic cells) and analyzed by flow cytometry. To analyze in vitro survival of immune cells isolated from MRL/Faslpr/lpr mice, spleen cells were cultured in RPMI-FBS for 24 or 48 h in the presence of CID 1067700 or DMSO (nil). After staining with surface markers to identify different cell types and 7–AAD, cells were analyzed by flow cytometry. To analyze survival of in vitro generated plasma cells (after B cell stimulation with LPS plus IL-4, IL-5, TGF-β, anti–δ/dex and RA for 66 h), cells were washed with RPMI-FBS twice and cultured in RPMI-FBS, without any additional stimuli to block further plasma cell generation, for 24, 48 and 72 h, in the presence of nil or CID 1067700 (40 μM). Cells were collected and stained with mAbs to CD138 and CD19 (to mark plasma cells and B cells) as well as with Annexin V and 7–AAD to distinguish live cells (Annexin V−7–AAD−) from cells undergoing early (Annexin V+7–AAD−) and late (Annexin V+7–AAD+) apoptosis. Retrovirus transduction Retroviral vectors pMIG and pMIG-AID (encoding AID) were as described (10); pMIG-Cre (encoding the Cre recombinase) was from Addgene; pMIG-Rab7 and pMIG-Rab2a (encoding Rab7 and Rab2a, respectively) were constructed using specific oligonucleotides (Supplemental Table 2). These vectors were co-transfected with the packaging plasmid into 293T cells to produce retroviruses, as described (10, 22). For transduction, B cells isolated from C57 or Rosa26+/fl-STOP-fl-Ikkβca mice were stimulated with LPS for 24 h in the presence of nil or CID 1067700, as indicated, incubated with viral particles that were pre-mixed with 6 μg/ml DEAE-dextran at 25°C for 30 m (Sigma-Aldrich). After incubation at 37°C for 5 h with gentle mixing every hour, cells were centrifuged at 500 g for 1 h and then 1,000 g for 4 m. Transduced B cells were cultured in virus-free FBS-RPMI in the presence of LPS plus IL-4 for 96 h and then harvested for flow cytometry analysis of expression of GFP (indicating expression of exogenous genes) and IgG1. Rosa26+/fl-STOP-fl-Ikkβca B cells expressed IKKβCA (as well as the GFP from the same bi-cistronic transcript) from the Rosa26 locus upon expression of the Cre recombinase and, consequently, deletion of the “STOP” cassette. Dead (7–AAD+) cells were excluded from analysis. To enforce expression of IKKβCA in plasma cells pre-generated from B cells stimulated with LPS plus IL-4, TGF-β, anti–δ/dex and RA for 66 h, cells were transduced with pMIG or pMIG-Cre virus, as above, and harvested after 72 h to analyze by flow cytometry the expression of GFP (indicating transduced cells) and plasma cell proportion and viability. Clinical and pathological analysis of MRL/Faslpr/lpr mice Skin lesions, lymphadenopathy and urine protein contents were assessed weekly. Skin lesions were scored on a scale of 0 to 4, with 0 = none, 1 = mild (snout only), 2 = moderate (< 2 cm in snout, ears and back), and 3 = severe (> 2 cm in snout and ears). Lymphadenopathy, as indicated by the appearances of lumps, was scored on a scale of 0 to 4, with 0 = none; 1 = small (at one site), 2 = moderate (at two sites), 3 = large at three or more different sites, and 4 = extremely large (at more than three sites). It was further confirmed by the increase in size of brachial and inguinal lymph nodes when mice were sacrificed. Proteinuria was assessed and scored using semi-quantitative Albustix® strips (Bayer), which, despite giving a range of serum albumin levels for each scale (scale 0 for negative or trace, and 1 through 4), generated few false-positive results when the score was above 3, as observed in virtually all 17-week old MRL/Faslpr/lpr mice. Splenomegaly was assessed when mice were sacrificed by the spleen size. To assess kidney pathology, kidneys were fixed in Tissue-Tek® OCTTM compound (Sankura Finetek) on dry ice. Seven-μm sections, as prepared by a Cryostat (Leica®), were fixed in cold acetone and stained with FITC-labeled anti–IgG1/anti–IgG2a mAbs. Sections were mounted using ProLong® Gold with DAPI (Invitrogen) for confocal microscopic analysis. For periodic acid–Schiff (PAS) staining, kidneys were fixed in paraformaldehyde (3.6%) at RT for 72 h and, after washing twice with PBS, embedded in paraffin. Five-μm sections were prepared and processed with periodic acid–Schiff (PAS) stain. Glomerular change severity was graded based upon glomerular activity, including glomerular cell proliferation (particularly mesangial matrix expansion), leukocyte infiltration and cellular crescents. Mesangial matrix expansion was grades as follows: 0 = no increase (matrix occupied up to 10% of the glomerulus), 1 = mild (10 – 25%), 2 = moderate (25 – 50%), and 3 = marked (50 – 100%). Leukocyte infiltration is graded as: 1 = mild, 2 = moderate, 3 = extensive. The severity of interstitial mononuclear cell infiltration was based on the ratio of infiltrated areas over the entire section (the value of area was determined by the ImageJ® software), quantified as the average of three sections 200 μM apart, and graded as: 1 = mild, 2 = moderate, 3 = severe. ELISA, ELISPOT and ANA assays To determine titers of total IgM, IgG1, IgG2a and IgG2b, sera were first diluted 4 to 128-fold with PBS (pH 7.4) plus 0.05% (v/v) Tween-20 (PBST). Two-fold serially diluted samples and standards for each Ig isotypes were incubated in 96-well plates pre-treated with sodium carbonate/bicarbonate buffer (pH 9.6) and coated with pre-adsorbed goat anti–IgM or anti–IgG (to capture IgG1, IgG2a and IgG2b) Abs (all 1 mg/ml; Supplemental Table 1). After washing with PBST, captured Igs were detected with biotinylated anti–IgM, –IgG1, –IgG2a or –IgG2b Abs (Supplemental Table 1), followed by reaction with horseradish peroxidase (HRP)-labeled streptavidin (Sigma-Aldrich), development with o-phenylenediamine and measurement of absorbance at 492 nm. Ig concentrations were determined using Prism® (GraphPad) or Excel® (Microsoft). To analyze titers of antigen-specific antibodies (high-affinity NP-binding or anti–dsDNA Abs), sera were diluted 1,000-fold in PBST. Twofold serially diluted samples were incubated in a 96-well plate pre-blocked with BSA and coated with NP4-BSA (in average 4 NP molecules on one BSA molecule) or dsDNA (10 μg/ml sonicated herring DNA). Captured Igs were detected with biotinylated Ab to IgM, IgG1, IgG2a or IgG3. Data are relative values based on end-point dilution factors. For ELISPOT analysis of total, NP-binding and dsDNA-binding ASCs, Multi-Screen® filter plates (Millipore) were activated with 35% ethanol, washed with PBS and coated with anti–IgM, anti–IgG, NP4-BSA or dsDNA (all 5 μg/ml) in PBS. Single spleen or bone marrow cell suspensions were cultured at 50,000 cells/ml in FBS-RPMI supplemented with 50 μM β-mercaptoethanol at 37°C for 16 h. After supernatants were removed, plates were incubated with biotinylated goat anti–mouse IgM, –IgG1, –IgG2a or –IgG3 Ab, as indicated, for 2 h and, after washing, incubated with HRP-conjugated streptavidin. Plates were developed using the Vectastain AEC peroxidase substrate kit (Vector Laboratories). The stained area in each well was quantified using the CTL Immunospot software (Cellular Technology) and depicted as the percentage of total area of each well for ASC quantification. For semi-quantitative ANA assays of sera from MRL/Faslpr/lpr and C57/Sle1Sle2Sle3 mice, sera were serially diluted in PBS (from 1:40 to 1:160), incubated on antinuclear Ab substrate slides (HEp-2 cell-coated slides, MBL-BION) and detected with a 1:1 mixture of FITC-labeled anti–IgG1 and anti–IgG2a mAbs (Supplemental Table 1) following manufacturer’s instructions. Images were acquired with an Olympus CKX41 fluorescence microscope. Cytokine intracellular staining Spleen cells were cultured in RPMI-FBS and stimulated with phorbol 12-myristate 13-acetate (PMA, 20 ng/ml) plus ionomycin (1 μg/ml; both from BioLegend) for 4 h at 37°C in the presence of brefeldin A (BFA). After pelleting, cells were stained with anti–CD4 mAb and Fixable Viability Dye eFluo®450 (FVD eFluo®450) followed by incubation with the BD Cytofix/CytopermTM buffer at 4°C for 20 m. After washing twice with the BD Perm/WashTM buffer, cells were resuspended in Hank’s Buffered Salt Solution (HBSS) with 1% BSA and stored overnight at 4°C. Cells were then stained with anti–IFN-γ and anti–IL-17 mAbs conjugated to different fluorophores in Perm/WashTM buffer and analyzed by flow cytometry. Dead (FVD eFluo® 450+) cells were excluded. Myeloid cell differentiation and function Bone marrow cells (107) were cultured for 10 d in RPMI-FBS in the presence of conditioned media from L-929 cells that express macrophage colony-stimulating factor (M-CSF, which promotes differentiation into CD11b+ macrophages) or recombinant murine Flt3-ligand (which promotes differentiation into CD11c+ DCs, Peprotech), resulting in generation of over 90% of CD11b+ or 20% of CD11c+ cells. After stimulation with TLR9 ligand CpG ODN for 1 h, cells were collected for RNA extraction and transcript analysis. GST-RILP pull-down RILP is an effector protein of activated Rab7 (Rab7-GTP). The E. coli strain BL21 harboring GST or GST-RILP expressing vector, as previously described (23), was grown at 37°C to an O.D. of 0.6 before induced by isopropyl-1-thio-β-D-galactopyranoside (IPTG, 0.5 mM) at 30°C for 4 h to express GST or GST-RILP. After pelleting and washing with cold PBS, bacterial cells were resuspended in 5 ml of cold lysis buffer (25 mM Tris-HCl pH 7.4, 1 M NaCl, 0.5 mM EDTA, 1 mM dithiothreitol and 0.1% Triton X-100) supplemented with a protease inhibitor cocktail (Sigma) and sonicated. Lysates were cleared and, after 5 ml of cold lysis buffer was added, incubated with 300 μl of pre-equilibrated slurry (50% packed volume) of glutathione-Sepharose 4B beads (GE Healthcare) at RT for 30 m. After washing with lysis buffer, beads (30 μl) with immobilized GST or GST-RILP were resuspended as slurry for protein quantification by the Bradford assay and pre-equilibrated in pull-down buffer (20 mM HEPES, 100 mM NaCl, 5 mM MgCl2 and 1% Triton X-100 plus protease inhibitor cocktail). Beads were then incubated by rotating with lysates (300 μg) prepared from stimulated B cells in the pull-down buffer at 4°C overnight. After washing twice with cold pull-down buffer, bound proteins were eluted by incubation of beads in the SDS-PAGE sample buffer at 95°C for 10 m. Immobilized GST-RILP was analyzed by SDS-PAGE/immunoblotting using anti–GST mAb; Rab7-GTP was analyzed by immunoblotting using anti–Rab7 mAb. Purification of recombinant Rab7 and NMR spectroscopy analysis DNA sequence encoding Rab7 (human RAB7A amino acid residues 2 – 207) was synthesized using codon optimization for E.coli expression and cloned into the pET30a vector, which allows for expression of an N-terminal Strep-tag followed by a SUMO tag. After plasmid transformation, BL21(DE3) cells were grown at 37°C in minimum media until the culture OD600 reached 0.6. After the culture was transferred to 18°C, protein expression was induced by IPTG (1 mM) for 15 h. For protein purification, lysates were first subjected to streptactin affinity chromatography and then removal of the Strep-SUMO tag by digestion of SUMO protease at 4°C overnight, resulting in release of cleaved Rab7 (with an additional N-terminal Thr residue) into the supernatants. Trace amounts of cleaved tag were removed by a new round of strep-tactin affinity chromatography. Protein purity was > 90%. For NMR spectroscopy analysis of free RAB7A, RAB7A (0.3 mM) was exchanged into the buffer containing 20 mM NaPO4 (20 mM, pH 6.9), NaCl (100 mM) and TCEP (1 mM). with 10% D2O. 2D 1H-15N HSQC was acquired with 2048 and 128 complex points in the direct and indirect dimensions, respectively. For acquisition of the NMR spectrum of RAB7A in complex with CID 1067700, 2.5 μl of CID 1067700 stock solution (40 mM in DMSO) was added to 40 μl of RAB7A to yield final 1:8 protein:compound ratio, followed by NMR spectrum acquisition using the same parameters. Docking analysis All modeling studies were performed using the Schrodinger 2015-3 software suite and its graphical interface, Maestro. The crystal structure of the GTP-bound Rab7 (PDBID: 1T91) was used as the docking target for CID 1067700. The bound GTP molecule and all water molecules were removed from the structure prior to docking. Docking was performed with Glide using first standard precision protocol to identify all possible poses with favorable Glide scores. Chlamydia titration For monitoring live organism shedding from swab samples, vaginal/cervical swabs were taken at the time points, as indicated. Each swab was soaked in 0.5 ml of sucrose-phosphate-glutamic acid (SPG) and vortexed with glass beads to release chlamydial organisms into supernatants. IFUs were titrated on HeLa cell monolayers in duplicates. The infected cultures were processed for immunofluorescence assays. Briefly, inclusions were counted in five random fields per coverslip under a fluorescence microscope. For coverslips with less than one IFU per view field, IFUs on entire coverslips were counted. Coverslips showing obvious cytotoxicity of HeLa cells were excluded. The total number of IFUs was calculated based on the mean IFUs per view, the ratio of the view area to that of the well, the dilution factor and inoculation volumes. Flow cytometry, immunoblotting, cDNA synthesis and quantitative RT-PCR (qRT-PCR) These methods were as we previously described (7, 10, 22). Antibodies (Supplemental Table 1) and oligonucleotides (Supplemental Table 2) used had been validated to be specific. Flow cytometry data were analyzed using the FlowJo® software (Tree Star). For immunoblotting, signals were quantified by Image J (NIH). For qRT-PCR, the ΔΔCt method was used to determine levels of transcripts and data were normalized to levels of CD79B (human) or Cd79b (mouse), which encodes the BCR Igβ chain that is constitutively expressed in B cells and, to a lesser degree, plasma cells. Statistical analysis Most statistical analyses were performed by one-tailed type 1 (for pairwise comparison) or type 2 student t-test. Survival data were analyzed by the Mantel-Cox log-rank test. Chlamydia infection data were analyzed by the Wilcoxon rank sum test. P values less than 0.05 were considered significant. More Materials and Methods in Supplemental Materials Results Rab7 is highly expressed in human and mouse lupus B cells Rab7 is upregulated in normal B cells by CSR-inducing stimuli (10), prompting us to analyze its expression in B cells from SLE patients and lupus mice. Peripheral blood mononuclear cells (PBMCs) from SLE patients expressed higher levels of RAB7A and AICDA transcripts than healthy subjects (Fig. 1A). Likewise, B cells, including PNAhi B cells, from lupus-prone MRL/Faslpr/lpr and C57/Sle1Sle2Sle3 mice displayed elevated Rab7 and Aicda transcripts as compared to those from age-matched C57 counterparts (Fig. 1B, 1C). A similar difference was observed in Rab7 and AID protein levels in lymphoid organs (Fig. 1D). Thus, lupus B cells dysregulate Rab7 expression. Targeting of Rab7 by CID 1067700 inhibits NF-κB activation and AID induction in B cells In view of treating lupus-prone mice with Rab7 inhibitor CID 1067700, we first tested the ability of this small molecule to inhibit CSR in vitro. CID 1067700 treatment of mouse B cells stimulated by CD154 or LPS plus IL-4 impaired Rab7 activation, as shown by reduced Rab7-GTP levels in RILP pull-down assays but normal Rab7 expression (Fig. 2A, 2B). This led to reduced AID expression and CSR to IgG1, despite normal B cell proliferation and germline IH-CH transcription, both of which are required for CSR (Fig. 2B–2D). Consistent with the requirement of AID for CSR to all Ig isotypes, CID 1067700 inhibited induction of CSR to IgG, IgA and IgE in human and mouse B cells (Fig. 2E–2H). CID 1067700 binds Rab7 with a high affinity (EC50: 10-20 nM), but was also shown to bind several small GTPases with much lower affinity (i.e., with EC50 being at least 80 nM) and could affect functions of these GTPases in cell lines (16, 24). In our hands, it directly bound purified recombinant Rab7 (Fig. 3A), likely through two binding sites on the surface of Rab7, as suggested by computational docking of CID 1067700 onto the crystal structure of Rab7, with one site overlapping with the GTP binding site and the other located on the opposite face (Fig. 3B). In stimulated primary B cells, which upregulate Rab7 expression, CID 1067700 specifically targeted Rab7, as its inhibitory activity was abrogated when Rab7 was ablated in Igh+/Cγ1-creRab7fl/fl conditional knockout B cells (Fig. 3C) – these knockout B cells showed reduced CSR (10). Conversely, CSR in CID 1067700-treated B cells was rescued by enforced expression of Rab7, but not Rab2a, a putative off-target of CID 1067700 (Fig. 3D). It was also increased by AID, which could rescue CSR in Rab7 knockout B cells (10). Like Rab7 deficiency, inhibition of Rab7 activity by CID 1067700 resulted in defective canonical NF-κB activation and normal non-canonical NF-κB activation (Fig. 2B). Expression of IKKβCA, a constitutively active mutant of IKKβ that can lead to canonical NF-κB hyperactivation (19) restored CSR in CID 1067700-treated B cells (Fig. 3E), indicating that the major defect in these cells is the impairment of canonical NF-κB activation. Thus, specific Rab7 inhibition in B cells hampers NF-κB activation, AID expression and CSR induction without affecting B cell proliferation. CID 1067700 blunts pathogenic autoantibody responses in lupus mice The Rab7 upregulation in lupus B cells, together with the role of Rab7 in NF-κB activation, AID expression and CSR, all of which are also elevated in lupus B cells and implicated in lupus pathogenesis (25, 26), suggested that Rab7 inhibition would hamper NF-κB-dependent pathogenic autoantibody responses in vivo, e.g., in MRL/Faslpr/lpr mice. These mice developed malar rash and dorsal skin lesions, lymphadenopathy, splenomegaly and nephritis, leading to mortality as early as at 11-week of age and an average life-span of about 20 weeks, with more than half of mice moribund between 17- and 23-week of age (Fig. 4A, 4B). When treated with CID 1067700 for only 10 weeks (starting at 10-week, one week before appearance of the first dead mouse in the untreated cohort), 14 of 16 MRL/Faslpr/lpr mice survived past the treatment period and half of mice were alive at 52 weeks, compared to only one in the untreated cohort (Fig. 4A). Treated mice had normal body weight, rare skin lesions and reduced lymphadenopathy and splenomegaly at 17 weeks (Fig. 4B–4D). They had some interstitial infiltration by monocytes (likely myeloid cells and T cells), but were largely free of glomerulonephritis, showing little proteinuria and decreased “crescent” formation and mesangial matrix expansion in glomeruli (Fig. 4E, 4F and not shown). Lupus nephritis is tightly associated with and/or caused by deposition of immunocomplexes (ICs) that contain class-switched IgG autoantibodies in the kidney. IgG-IC deposition was reduced in MRL/Faslpr/lpr mice treated with CID 1067700 (Fig. 5A). Serum levels of IgG anti-nuclear antibodies (ANAs) were also decreased in treated MRL/Faslpr/lpr and C57/Sle1Sle2Sle3 mice (Fig. 5B). As shown by time-course analyses of autoantibodies that bound double-strand DNA (anti–dsDNA), the ratio of pathogenic IgG classes, e.g., IgG1, IgG2a and IgG2b, over the non-pathogenic IgM class (IgG/IgM, depicted as RIgG) remained low in treated mice despite variations of IgG and IgM titers in different mice in the same cohort (Fig. 5C and data not shown). So did RIgG for total IgG, in contrast to the steadily increased anti–dsDNA and total RIgG, until peaking, in untreated mice (Fig. 5C). Thus, inhibition of Rab7 suppresses IgG autoantibody responses and prevents development of disease symptoms in lupus mice, leading to significantly increased life-span. CID 1067700 targets B cells and specifically impairs the CSR machinery in vivo The reduction of RIgG suggested that the CSR process was inhibited in CID 1067700-treated MRL/Faslpr/lpr mice. Indeed, these mice showed unchanged number of B cells but significantly decreased IgG+ B cells, concomitant with a slightly increased proportion of un-switched IgM+ B cells (Fig. 6A). Decreased CSR, as also shown by reduced post-recombination Iμ-Cγ transcripts (the molecular indicators of completed CSR), was associated with lower expression of CSR machinery genes, such as Aicda and 14-3-3γ, which is important for the targeting of AID to IgH switch (S) regions and is induced in an NF-κB-dependent manner (22, 27, 28); Rab7 expression was also slightly reduced (Fig. 6B). Expression of the A20 (Tnfaip3) gene, which dampens NF-κB activation and controls autoimmunity (29), or germline Iμ-Cμ transcription, however, was not affected; neither was expression of Prdm1 (encoding Blimp-1), Xbp1, which is essential for the plasma cell secretion function, or genes (Vps34, LC3 and Becn1) implicated in autophagy, which regulates plasma cell differentiation/functions (30, 31). Treated B cells were normal in proliferation, CD21/CD35 expression, induction of the CD80 activation markers and expression of CD40 and MHC II, which are important for B cells to interact with CD4+ T helper cells (Fig. 6C), thereby emphasizing the inherent nature of the CSR machinery defect. Rab7 has been suggested to be expressed in myeloid cells, in addition to B cells (32), prompting us to analyze the impact of Rab7 inhibition on CD11b+ macrophages and CD11c+ dendritic cells (DCs). The proportions of these cells, their survival in vitro and induced expression of cytokines that could influence B cells and autoantibody responses, such as BAFF and type I interferon (IFNα and IFNβ), were not affected by CID 1067700 treatment in MRL/Faslpr/lpr mice, with the only exception of reduced Il1b expression in CD11c+ DCs (Fig. 7A–7C). Reflecting the low expression of Rab7 in T cells and a modest role of this molecule in T cell functions (33), CID 067700 treatment did not change the proportions of total CD4+ T cells and those producing IFN-γ, which is critical for CSR to IgG2a and important in systemic autoimmunity (34–36), in MRL/Faslpr/lpr mice or survival of CD4+ lupus T cells in vitro (Fig. 7C, 7D). This, together with the ability of CID 1067700-treated C57 mice to clear Chlamydia infection, which is dependent on T cells, but not B cells or plasma cells (37, 38), showed that this small molecule does not have a major impact on T cells (Fig. 7E). Thus, CID 1067700 selectively targets B cells and impairs the CSR machinery in lupus-prone mice without altering proliferation/activation of B cells. Rab7 deficiency or Rab7 inhibition reduces ASCs Consistent with the surge of IgG+ ASCs during lupus flare, most cells expressing the plasma cell marker CD138 in MRL/Faslpr/lpr mice with active lupus (e.g., at 17-week) were IgG+, as shown by intracellular staining (Fig. 8A). Upon Rab7 inhibition, IgG+ plasma cells were greatly decreased (due to defective CSR) with a concomitant increase in the proportion of IgM+ plasma cells. However, the number of ASCs that produced IgM autoantibodies (e.g., anti–dsDNA) remained unchanged (Fig. 8B). This together with the lower number of IgG1+ and IgG2a+ ASCs indicated an overall reduction in ASCs upon treatment with CID 1067700. This Rab7 inhibitor had similar effect on ASCs in C57 mice, as indicated by the reduced antigen-specific IgG1+ ASCs and unchanged IgM+ ASCs in the spleen of mice injected with a T-dependent (NP-CGG) or T-independent (NP-LPS) antigen, which resulted in virtual abrogation of circulating antigen-specific IgGs (Fig. 8C). Likewise, Rab7 knockout in B cells and their plasma cell progenies, as occurring in Igh+/Cγ1-creRab7fl/fl mice, reduced total and antigen-specific IgG1+ ASCs (our previous findings, (10)) with no increase in IgM+ ASCs (Fig. 8D). ASCs in the bone marrow, in which long-lived plasma cells take residence (39), were even more sensitive to Rab7 inhibition or knockout, as both IgG+ and IgM+ ASCs were decreased (Fig. 8C, 8D). Finally, IgG+ ASCs preformed in vivo were vulnerable to CID 1067700 treatment, as they failed to produce antibodies ex vivo (Fig. 8E). Thus, abrogation of Rab7 expression or inhibition of its activity in normal and lupus-prone mice affects ASC production/maintenance, thereby compounding the defect in CSR to suppress class-switched antibody and autoantibody responses. Rab7 inhibition impairs plasma cell survival Despite their impact on ASCs (consisting of plasmablasts and plasma cells), neither CID 1067700 nor Rab7 knockout affected in vitro generation of CD138hi cells upon induction of B cells by all tested stimuli, such as LPS plus IL-4, TGF-β, BCR crosslinking and retinoic acid (RA), which led to more than 70% of live cells being CD138hi (Fig. 9A and not shown). This suggested that Rab7 was not involved in plasma cell generation and prompted us to analyze the effect of CID 1067700 on plasma cell survival. In MRL/Faslpr/lpr mice, CID 1067700 treatment resulted in increased death and reduced number of CD138hi cells (Fig. 9B, 9C). Even residual live CD138hi cells expressed lower levels of Cxcr4, Il6r and Vla4, all of which encode surface receptors that mediate plasma cell survival – by contrast, expression of Bcma and Taci, which are important for APRIL-dependent survival, was not affected (Fig. 9D). Expression of intracellular factors important for plasma cell survival (such as Irf4, Mcl1, and Hdac11) as well as the Atg5 autophagy gene was also affected. Expression of Prdm1 or Xbp1, which are important to maintain the plasma cell secretory function but dispensable for their survival (40), however, was not affected. To further confirm that Rab7 inhibition directly affects plasma cell survival, we treated CD138hi cells generated in vitro with CID 1067700. These cells displayed high levels of early and late apoptosis, as compared to the much slower loss of viability in their untreated counterparts (Fig. 9E). Enforced NF-κB activation through IKKβCA expression prevented CD138hi cells from being killed by CID 1067700 (Fig. 9F), showing that Rab7 plays a role in the plasma cell survival in vivo and in vitro, in part by mediating NF-κB-activation. Discussion Stemming from our previous findings (10), data reported here have further outlined an important role of Rab7 in antibody and autoantibody responses, owing to its functions in modulating Aicda expression, B cell class-switching and plasma cell survival. In spite of the partial impairments of these processes by Rab7 inhibition or knockout, their combined outcome was the virtual abrogation of class-switched specific antibodies in normal mice and paucity of pathogenic autoantibodies in lupus-prone mice. As we showed, small molecule Rab7 inhibition hampered CSR induced by all primary stimuli, including the one (CD154) produced by T cells, which mediate many autoimmune conditions in part by dysregulating B cells, and a ligand (R-848) of TLR7, an endosomal TLR that strongly promotes lupus pathogenesis and does so in a B cell-intrinsic manner (41). Thus, Rab7, which is an endosome-tethered protein, participates in B lineage cell differentiation processes initiated by many immune receptors irrespective of their initial locations, e.g., CD40 and TLR4 on the surface and TLR7 in the endosome. Surface immune receptors, however, need to be internalized for Rab7 to mediate CSR and plasma cell survival, likely in a manner dependent on Rab7+ endosomes. As indicated by our results showing IKKβCA-mediated rescue of CSR and plasma cell survival in CID 1067700-treated cells, the B cell- and plasma cell-intrinsic roles of Rab7 are, at least in part, through activation of NF-κB, a transcription factor central to B lineage cell functions (42, 43). Rab7-dependent NF-κB activation, however, is dispensable for B cell development and differentiation into plasma cells, as suggested by unchanged numbers of CD19+ B cells in CID 1067700-treated mice in vivo and generation of plasma cells from CID 1067700-treated B cells or Rab7 knockout B cells in vitro. It would also be absent during early activation of naïve B cells upon CD40 or TLR engagement, as these cells express low levels of Rab7 and contain sparse intracellular membrane structures. Only after Rab7 upregulation, likely together with expansion of the intracellular membrane network, would Rab7 nucleate the assembly of putative “intracellular signalosomes” on different membrane types (e.g., endosomes in B cells and autophagosomes in plasma cells) – through mechanisms that are not yet clear – for sustained NF-κB activation. This would be required for efficient AID induction in CSR, which takes at least 48 h to unfold, and continuous expression of genes in plasma cells to maintain survival. By contrast, Rab7-independent early NF-κB activation would occur through different signalosomes, e.g., those on the plasma membrane in B cells with cell surface receptor engagement. It also plays a role in the Rab7 gene transcription, possibly through several κB sites in the promoter region (unpublished data). Rab7 is inherently the preferred target of CID 1067700, as shown by its much lower EC50 as compared to the few small GTPase off-targets of this compound (16). As suggested by our docking analyses, CID 1067700 could potentially bind at two distinct sites on the Rab7 surface. Existence of a candidate binding site that is different from the GTP-binding site (the site that also exists in potential off-targets of CID 1067700) would, at least in part, explain the Rab7-specific inhibitory activity of CID 1067700. This together with upregulated Rab7 expression in B cells (and likely in plasma cells), including in PNAhi germinal center B cells in immunized mice, would underpin the specific inhibition of Rab7 by CID 1067700, as more molecules would be available for targeting. Likewise, the dysregulated Rab7 expression would make lupus B cells preferred targets of CID 1067700. Such dysregulation may be the consequence of a putative positive-feedback loop involving NF-κB hyperactivation (25, 26). It could also be exacerbated by female hormones, as suggested by enhancement of Rab7 expression by estrogens (our unpublished data). This together with estrogen upregulation of AID expression through the HoxC4 homeodomain transcription factor would contribute to the female bias of autoantibody-mediated systemic autoimmunity (11, 44, 45). In the subset of human lupus B cells that displayed moderate Rab7 expression, as shown in our studies, NF-κB hyperactivation may be through alternative mechanisms, such as A20 downregulation (29). Rab7 inhibition reduced expression of several genes instrumental to plasma cell survival, such as Cxcr4, Irf4 and Mcl1 (40, 46, 47). Expression of CXCR4 (a G protein-coupled receptor) has been shown to be boosted by NF-κB, consistent with the identification of several κB sites in the Cxcr4 gene locus (48), consistent with a role of Rab7 in NF-κB activation and rescue of survival of CID 1067700-treated plasma cells with enforced expression of IKKβCA. The presence of several Irf4-binding sites in the Cxcr4 promoter (49) also suggests that Cxcr4 transcription is regulated by Irf4, whose expression would be mediated by Rab7 (shown here) and promoted by NF-κB (50). Expression of Mcl1 in plasma cells is in general lower than that in B cells (51), perhaps explaining higher sensitivity of plasma cells to death upon Rab7 inhibition. Rab7 deficiency or inhibition in mice may also impair the autophagy-dependent antibody secretion, which together with decreased plasma cell survival would lead to marked reduction in ASCs. Like anti–dsDNA-specific ASCs in the spleen, kidney resident plasma cells that secret pathogenic nephrophilic antibodies (52–54) may be reduced, leading to significantly reduced kidney damage. As a small molecule, CID 1067700 injected i. p. was “metabolized” in vivo and required weekly administration to maintain detectable levels in the circulation and lymphoid organs (our unpublished observations). Despite this, Rab7 inhibition by CID 1067700 could prevent development of lupus pathology in MRL/Faslpr/lpr mice and extend the lifespan by more than 32 weeks, after a treatment period of only 10 weeks, suggesting that long-lasting changes had occurred in treated B cells – treated plasma cells would die. These changes likely include alterations in the epigenome in lupus B cells with extended survival (due to the Fas/lpr mutation) as well as changes in the BCR repertoire and/or the memory autoreactive B cell compartment. Putative epigenetic changes might occur through downregulation of NF-κB-dependent expression of histone modifying enzymes and/or re-balance of exaggerated Rab7-dependent autophagy, which modulates the microRNA machinery (15, 55). B cell-intrinsic mechanisms may be further complemented by changes in regulatory immune elements, such as T regulatory cells and DCs (56), possibly including altered type-I IFN gene signatures in plasmacytoid DCs (pDCs), as short-term pDC ablation could also elicit long-term prevention of nephritis in the BXSB lupus mouse mode (57). Such DC changes, however, would be indirect, as CID 1067700 did not decrease cytokine production by DCs in vitro. High Rab7 expression levels in DCs, however, do suggest that Rab7 regulate certain DC functions, perhaps antigen/autoantigen presentation through autophagy induction (58) and MyD88 signaling, which mediates skin lesions (59). By contrast, Rab7 is largely dispensable for T cell survival and functions (e.g., in clearing primary Chlamydia infection, as shown here). Addressing specific roles of Rab7 in these and other immune compartments requires generation of different conditional knockout mice. In contrast to the non-discriminating B cell-depletion lupus therapeutics approaches, CID 1067700 or its future derivatives with improved pharmacodynamics and pharmacokinetics properties would maintain IgM+ B cells and protective IgMs. It is conceivable that a Rab7 inhibitor can be combined with anti–BAFF or anti–CD20 mAb towards better therapeutic effects (60–62). Such an inhibitor may also be combined with a histone deacetylase (HDAC) inhibitor (HDI) to abrogate plasma cells by affecting plasma cell survival and generation, respectively – synthetic and naturally occurring (e.g., butyrate, a metabolite of gut microbiota) HDIs blunt antibody and autoantibody responses by inhibiting CSR/SHM and B cell differentiation into plasma cells, but not plasma cell survival (3, 21). The translational implications of Rab7-dependent NF-κB activation extend beyond lupus. Rab7 may promote B cell lymphomagenesis mediated by NF-κB hyperactivation (63–65), as suggested by the frequent DNA insertions/deletions and chromosomal translocations in/around the human RAB7A locus on the chromosome 3 (3q21) in hematologic malignancies (66–68). It may also play a role in NF-κB-mediated survival of multiple myelomas (69), as it does in maintaining the survival of plasma cells. Addressing these possibilities would greatly expand our studies towards the understanding of the role of Rab7 in immune regulation. Supplementary Material 1 This work was supported by National Institutes of Health (NIH) grants AI 079705 and AI 105813 (to P. C.), AI 124172 (to Z. X.), AI 104476 (to D. N. I.) and AI 047997 (to G. Z.). P. C. was also partially supported by the Alliance for Lupus Research (ALR) Target Identification in Lupus Grant ALR 295955 and the Zachry Foundation Distinguished Chair, D. N. I. by a Voelcker Fund Young Investigator Award, H. Z. by an Arthritis National Research Foundation research grant and R. W. by the Xiangya School of Medicine, Central South University of China. We thank Crystal Lafleur for technical help, Tian Shen for help in plasma cell induction, Egest J. Pone and Christie-Lynn Mortales for ELISPOT, Tamara McRae for PAS kidney histology analysis, Dr. Dmytro Kovalskyy for docking analyses, Dr. Benjamin J. Daniel and Karla M. Gorena in the UTHSCSA Flow Core Facility for help with cell sorting, and the UTHSCSA NMR and Analytical Ultracentrifugation Core Facility (supported in part by the NIH P30 CA054174 to the Cancer Therapy and Research Center of UTHSCSA) for NMR analysis. We thank Dr. Aimee L. Edinger for the RILP-expressing construct, Dr. Nu Zhang for help with cytokine intracellular staining and Dr. Xiaodong Li for help with myeloid cell differentiation assays. Abbreviations used AID activation-induced cytidine deaminase ASC antibody-secreting cell CSR class switch DNA recombination Rab7 Ras-related in brain7 SLE systemic lupus erythematosus FIGURE 1 Rab7 is highly expressed in human and mouse lupus B cells. (A) qRT-PCR analysis of levels of RAB7A and AICDA transcripts in PBMCs isolated from lupus patients or healthy subjects (n = 9). Expression of RAB7B, which is unrelated to RAB7A and is not evolutionarily conserved, was comparable in these samples (data not shown). (B) qRT-PCR analysis of Rab7 and Aicda transcripts in spleen B cells isolated from 10-week old MRL/Faslpr/lpr mice and 36-week old C57/Sle1/Sle2/Sle3 mice. Data are expressed as ratios of values to those in B cells from age-matched C57 mice (mean and s.d. of data from three independent experiments). (C) qRT-PCR analysis of Rab7 and Aicda transcripts in sorted spleen CD19+PNAhi cells (>95% pure, which displayed higher Rab7 expression than CD19+PNAlo cells, not shown) from 10-week MRL/Faslpr/lpr mice and NP-CGG-immunized C57 mice. Representative of two independent experiments (mean and s.e.m. of triplicate samples). (D) Immunoblotting analysis of Rab7 and AID in spleen and lymph node cells isolated from 10-week old MRL/Faslpr/lpr and C57 mice as well as CH12 B cells. FIGURE 2 CID 1067700 inhibits Rab7 activity, NF-κB activation, AID expression and CSR in B cells. (A) GST-RILP pull-down analysis of Rab7-GTP (bottom panels) in B cells stimulated with LPS plus IL-4 for 48 h in the presence of nil or CID 1067700. Expression of total Rab7 was also analyzed (top panels). (B) Immunoblotting of Rab7, phosphorylated and total p65 in the canonical NF-κB pathway, p52 in the non-canonical NF-κB activation pathway, AID and β-actin in stimulated B cells treated with nil or CID 1067700. Numbers on the right side indicate non-normalized values of quantified signals. (C) qRT-PCR analysis of levels of IgH germline Iμ-Cμ and Iγ1-Cγ1 transcripts, Aicda, post-recombination Iμ-Cγ1 and circle Iγ1-Cμ transcript in B cells stimulated with CD154 or LPS plus IL-4 and treated with different doses of CID 1067700. Data are expressed as ratios of values in CID 1067700-treated B cells to those in untreated cells (mean and s.e.m. of data from triplicate samples). (D) Flow cytometry analysis of proliferation and CSR to IgG1 in CFSE-labeled B cells after stimulation in the presence of nil or CID 1067700 (top panels) and depiction of the proportion of switched IgG1+ cells in B cells that had completed each cell division (bottom panels). (E–H) CSR to different Ig isotypes in human or mouse B cells stimulated by different combinations of a T-dependent or T-independent primary CSR-inducing stimulus and a secondary inducing stimulus, as indicated, in the presence of nil or CID 1067700. (A, B, E–H), representative of three independent experiments. FIGURE 3 CID 1067700 inhibit CSR in B cells by targeting Rab7. (A) NMR spectroscopy analysis of direct physical interaction of CID 1067700 with Rab7. Spectra of free Rab7 and Rab7:CID 1067700 were represented by red and green signals, respectively, with overlapping signals shown in black. Chemical shift perturbations and broadening observed for NMR signals (non-overlapping signals) of multiple Rab7 residues are indicative of direct physical interaction. (B) Docking analysis of two candidate CID 1067700 binding sites on the opposite faces of Rab7 (left panel). The more favorable docking score (Glide score –5.5) was obtained for CID 1067700 binding at the GTP-binding site of Rab7 (lower left panel) and the second binding site (Glide score –2.7) located on the opposite face of Rab7 when CID 1067700 adopts a different conformation (lower right panel). The interaction interface within the GTP-binding site was slightly different from that predicted by others (16). (C) Flow cytometry analysis of CSR to IgG1 in B cells from Igh+/Cγ1-creRab7+/fl and Igh+/Cγ1-creRab7fl/fl littermates after stimulation with LPS plus IL-4 in the presence of nil or CID 1067700. Representative of three independent experiments. (D) CSR to IgG1 in B cells pre-stimulated with LPS in the presence of CID 1067700, transduced with pMIG or pMIG-Rab7 and then stimulated with LPS plus IL-4 for 72 h (left panels). The histogram (right panel) depicts CSR rescue by Rab7, Rab2a, a potential off-target of CID 1067700 with EC50 (170 nM) much higher than Rab7 (10-20 nM), or AID. Other potential off-targets (http://tinyurl.com/obgvd3v) are three small GTPases with EC50 comparable to Rab2a (i.e., H-Ras, 20-145 nM; Rac1, 80 nM; and Cdc42, 91-129 nM), much weaker targets (i.e., autophagy protein ATG4B, EC50 of 13 μM, and histone lysine methyltransferase G9a, EC50 of 39 μM), and growth factors/receptors (i.e., FGF22, GFER, VLA-4 and EGFR) that have not been independently verified as potential off-targets and, to our best knowledge, are not known to regulate CSR (mean and s.e.m. of three independent experiments). (E) CSR to IgG1 in B cells isolated from Rosa26+/fl-STOP-fl-Ikkβca mice and transduced with pMIG or pMIG-Cre (which encoded the Cre recombinase to delete the “STOP” cassette in the Rosa26 locus and, therefore, allow for expression of IKKβCA) and then stimulated with LPS plus IL-4 in the presence of nil or CID 1067700 (mean and s.e.m. of four experiments). FIGURE 4 Rab7 inhibition by CID 1067700 prevents disease development in lupus-prone mice. (A) Survival curve of 16 MRL/Faslpr/lpr mice treated with nil or CID 1067700. The survival of mice maintained in our facility was similar to that reported by The Jackson Laboratory and other groups. (B) Skin lesions in 26-week old nil-or CID 1067700-treated MRL/Faslpr/lpr mice. (C–F) Spleens and cervical lymph nodes (C), physiological metrics as indicated (D), indices of kidney damages (E) and PAS staining of kidney sections (F) in 17-week old MRL/Faslpr/lpr mice treated with nil or CID 1067700 (C and F, representative of three independent experiments; D and E, mean and s.d. of four pairs). FIGURE 5 Rab7 inhibition blocks generation of pathogenic autoantibodies. (A) IgG-IC formation in the kidney 17-week nil- or CID 1067700-treated MRL/Faslpr/lpr mice (representative of kidney sections in three independent experiments). (B) ANA levels in serum samples (diluted 40-fold) from MRL/Faslpr/lpr mice, as in (A), and 54-week old nil- or CID 1067700-treated C57/Sle1Sle2Sle3 mice. ANAs to different autoantigens, as shown by different patterns of fluorescence images at higher magnifications, were all reduced in CID 1067700-treated mice (representative of three independent experiments). More diluted serum samples, e.g., by 160-fold, from CID 1067700-treated mice showed virtually no signals (not shown). (C) Ratios of anti–dsDNA (top panels) and total (bottom panels) IgG1, IgG2a and IgG2b titers to titers of the IgM counterparts in nil- or CID 1067700-treated MRL/Faslpr/lpr mice at different ages, as indicated. Data were normalized to values in mice at the age of from 10-week (set as 1), right before the treatment started, and were depicted as RIgG1, RIgG2a and RIgG2b (mean and s.e.m. of four mice per group). IgG3 titers were generally low (not shown). FIGURE 6 Rab7 inhibition hampers CSR in lupus-prone mice. (A) Flow cytometry analysis of number of B cells (left panel) and proportion of IgM+, IgG1+ and IgG2a+ cells among B cells (right panels) in 17-week old nil- or CID 1067700-treated MRL/Faslpr/lpr mice (mean and s.d. of four pairs of mice) – the proportion of these B cells was increased due to the reduced splenomegaly (data not shown). Both nil- and CID 1067700-treated MRL/Faslpr/lpr mice had B lymphocytopenia, with average of 3.2 × 107 CD19+ B cells per spleen, as compared to about 5.5 × 107 B cells in age-matched C57 mice (data not shown). Moribund MRL/Faslpr/lpr mice were excluded from analyses due to their severe B lymphocytopenia. (B) Expression of different transcripts, as indicated, in CD19+ B cells sorted from MRL/Faslpr/lpr mice, as in (A). Data were depicted as the ratio of values in CID 1067700-treated mice to those in nil-treated mice (*, p < 0.05; **, p < 0.01). (C) Flow cytometry analysis of B cell expression of markers (left and middle panel sets), as indicated, and proliferation (right panel set) in MRL/Faslpr/lpr mice, as in (A). FIGURE 7 Rab7 inhibition does not affect myeloid cells or T cells. (A) Flow cytometry analysis of CD11b+ and CD11c+ cells in 17-week old nil- or CID 1067700-treated MRL/Faslpr/lpr mice. (B) Expression of cytokine-encoding genes, as indicated, in CD11b+ and CD11c+ cells generated from the bone marrow cells isolated from untreated 10-week old MRL/Faslpr/lpr mice and then stimulated by CpG ODN in vitro in the presence of nil or CID 1067700 (mean and s.d. of triplicate samples; *, p < 0.05). (C) Survival of CD11b+ and CD11c+ myeloid cells as well as CD4+ T cells isolated from untreated 10-week old MRL/Faslpr/lpr mice and cultured in vitro in the presence of nil or different doses of CID 1067700 for 24 h or 48 h (mean and s.d. of triplicate samples). (D) Flow cytometry analysis of proportion of CD4+ T cells and expression of IFN-γ in CD4+ T cells in nil- or CID 1067700-treated MRL/Faslpr/lpr mice, as in (A). Expression of IL-17 is low despite the important role of this cytokine in lupus (70). Consistent with reduced splenomegaly, the number of T cells was reduced, possibly as the secondary effect of reduced activity of autoreactive B cells. No CD19+ cells expressed IFN-γ or IL-17 (not shown). (E) Shedding of chlamydia in C57 mice treated with nil or CID 1067700 (mean and s.e.m. of 5 mice in each group). B cells are not required for the clearance of primary chlamydia infection. (A, C, D), representative of three independent experiments. FIGURE 8 Rab7 deficiency or inhibition impairs ASC production/functions in vivo and in vitro. (A) Levels of intracellular IgM, IgG1 and IgG2a in spleen CD138+ cells from 17-week old nil- or CID 1067700-treated MRL/Faslpr/lpr mice (representative of three independent experiments). (B) ELISPOT analysis of IgM+, IgG1+ and IgG2a+ ASCs in 17-week old nil- or CID 1067700-treated MRL/Faslpr/lpr mice (right panels, mean and s.e.m. of four pairs of mice). (C) ELISPOT analysis of IgM+ and IgG+ (IgG1 or IgG3, as indicated) NP-binding ASCs in the spleen and bone marrow, as well as titers of circulating NP-binding IgM and IgG1 or IgG3 Abs, in nil- or CID 1067700-treated C57 mice immunized with NP-CGG (top panels) or NP-LPS (bottom panels). (mean and s.e.m. of three pairs of mice). (D) ELISPOT analysis of IgM+ NP-binding and total ASCs in the spleen and bone marrow in Igh+/Cγ1-creRab7fl/fl mice and their Igh+/Cγ1-creRab7+/fl littermates immunized with NP-CGG (mean and s.e.m. of three pairs of mice). (E) ELISPOT analysis of IgG1+ ASCs isolated form the bone marrow of C57 mice and treated in vitro with nil or CID 1067700n for 24 h before incubation for 24 h in the presence of nil or CID 1067700, totaling 48 h treatment (mean and s.e.m. of three independent experiments). FIGURE 9 Rab7 deficiency or inhibition impairs the survival of plasma cells, but not their generation. (A) Generation of CD19−/loCD138hi plasma cells in vitro from Igh+/Cγ1-creRab7fl/fl B cells and their Igh+/Cγ1-creRab7+/fl B cell counterparts upon stimulation by LPS plus IL-4 or IL-4, TGF-β, anti–δ/dex and RA (left panels) as well as from C57 B cells undergoing same stimulation and treated with nil or CID 1067700 (right panels). (B) Flow cytometry analysis of total (TCR− CD19−/lo)CD138hi cells in 17-week old nil- or CID107700-treated MRL/Faslpr/lpr mice (top panels) and proportion of dead (7–AAD+) cells (bottom panels). The proportion of (TCR−CD19+CD138−) B cells was increased, but their number and viability were not changed (data not shown). Representative of three independent experiments. (C) Flow cytometry analysis of the number of live (TCR−CD19−/lo)CD138hi cells in MRL/Faslpr/lpr mice, as in (B, mean and s.d. of four pairs of mice). (D) Expression of different transcripts, as indicated, in live 7–AAD−CD138hi cells sorted from 17-week old nil- or CID 1067700-treated MRL/Faslpr/lpr mice. Like Cd35 and Cd44 (which do not promote plasma cell survival), Vla4 and Cxcr4 are also involved in plasma cell homing to the bone marrow. Expression of iNos, as suggested to promote plasma cell survival in normal mice, was not detectable. Decreased expression of Iμ-Cγ1 and Iμ-Cγ2a in plasma cells was expected, due to reduced CSR. Data were depicted as the ratio of values in CID 1067700-treated mice to those in nil-treated mice (mean and s.d. of four pairs of mice; *, p < 0.05). (E) Flow cytometry analysis of early (Annexin V+ 7–AAD−) and late (Annexin VHi 7–AAD+) apoptosis in pre-generated CD19−/loCD138hi plasma cells (after stimulation by LPS plus IL-4, IL-5, TGF-β, anti–δ/dex and RA for 66 h) after treatment with nil or CID 1067700 for 24 h, 48 h and 72 h (the histogram depicts the mean and s.e.m. of three independent experiments; death of residual CD19+ B cells in the same culture was not affected by CID 1067700). Flow cytometry data (top panels) are representative of three independent experiments. (F) Survival of CD19−/loCD138hi plasma cells pre-generated in the presence of pMIG-Cre retrovirus to express IKKβCA and then treated with nil or CID 1067700 for 72 h. 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PMC005xxxxxx/PMC5113289.txt
LICENSE: This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. 8902617 1394 J Mol Endocrinol J. Mol. Endocrinol. Journal of molecular endocrinology 0952-5041 1479-6813 26242202 5113289 10.1530/JME-15-0124 NIHMS828823 Article Endothelial glucocorticoid receptor promoter methylation according to dexamethasone sensitivity Mata-Greenwood Eugenia Jackson P Naomi Pearce William J Zhang Lubo Divisions of Pharmacology and Physiology, Department of Basic Sciences, School of Medicine, Center for Perinatal Biology, Medical Center, Loma Linda University, Room A572, 11234 Anderson Street, Loma Linda, CA 92350, USA Correspondence should be addressed to E Mata-Greenwood ematagreenwood@llu.edu 9 11 2016 04 8 2015 10 2015 17 11 2016 55 2 133146 This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. We have previously shown that in vitro sensitivity to dexamethasone (DEX) stimulation in human endothelial cells is positively regulated by the glucocorticoid receptor (NR3C1, GR). The present study determined the role of differential GR transcriptional regulation in glucocorticoid sensitivity. We studied 25 human umbilical vein endothelial cells (HUVECs) that had been previously characterized as DEX-sensitive (n = 15), or resistant (n = 10). Real-time PCR analysis of GR 5′UTR mRNA isoforms showed that all HUVECs expressed isoforms 1B, 1C, 1D, 1F, and 1H, and isoforms 1B and 1C were predominantly expressed. DEX-resistant cells expressed higher basal levels of the 5′UTR mRNA isoforms 1C and 1D, but lower levels of the 5′UTR mRNA isoform 1F than DEX-sensitive cells. DEX treatment significantly decreased GRα and GR-1C mRNA isoform expression in DEX-resistant cells only. Reporter luciferase assays indicated that differential GR mRNA isoform expression was not due to differential promoter usage between DEX-sensitive and DEX-resistant cells. Analysis of promoter methylation, however, showed that DEX-sensitive cells have higher methylation levels of promoter 1D and lower methylation levels of promoter 1F than DEX-resistant cells. Treatment with 5-aza-2-deoxycytidine abolished the differential 5′UTR mRNA isoform expression between DEX-sensitive and DEX-resistant cells. Finally, both GRα overexpression and 5-aza-2-deoxycytidine treatment eliminated the differences between sensitivity groups to DEX-mediated downregulation of endothelial nitric oxide synthase (NOS3), and upregulation of plasminogen activator inhibitor 1 (SERPINE1). In sum, human endothelial GR 5′UTR mRNA expression is regulated by promoter methylation with DEX-sensitive and DEX-resistant cells having different GR promoter methylation patterns. glucocorticoids endothelium methylation 5′UTR mRNA isoform Introduction Glucocorticoids are therapeutic agents used for reducing inflammation via targeting the glucocorticoid receptor (NR3C1, GR) of immune cells (Auphan et al. 1995, Barnes 1998). However, glucocorticoids also target the GR present in various other tissues, causing unwanted side effects. In the cardiovascular system, glucocorticoids induce short-term side effects that include hypertension, dyslipidemia and thrombosis. Chronic synthetic glucocorticoid-therapy has been associated with endothelial dysfunction and increased risk of cardiovascular events such as myocardial infarction (Yang & Zhang 2004, Walker 2007, Hadoke et al. 2009, Huang & Glass 2010, Kadmiel & Cidlowski 2013). These adverse events are mediated in part by glucocorticoid-dependent down-regulation of endothelial nitric oxide synthase (NOS3) and upregulation of plasminogen activator inhibitor 1 (SERPINE1) (Wallerath et al. 2004, Tamura et al. 2015). Of importance, human studies have revealed significant human variability in response to both endogenous (cortisol) and synthetic glucocorticoids (Ito et al. 2006, Kino 2007), but the mechanisms remain undetermined. Glucocorticoids mediate their biological effects by the ubiquitously expressed GR (Bamberger et al. 1996, Adcock et al. 2004, Heitzer et al. 2007). Alternative splicing produces 3′UTR mRNA isoforms GRα, GRβ and GRP. GRα protein is the biologically relevant isoform, capable of binding ligand that regulates transcription and stability of target genes. GRβ is localized in the nucleus and has a dominant negative effect on GRα through the formation of GRα/GRβ heterodimers. GRP has been reported to have both synergistic and antagonistic effects on GRα (Kassel & Herrlich 2007, Biddie et al. 2012). Previously, we have shown that human endothelial sensitivity to dexamethasone (DEX) varied according to the levels of GRα protein degradation (Mata-Greenwood et al. 2013). Human umbilical vein endothelial cells (HUVECs) that were resistant to in vitro stimulation by DEX had an increased expression of the E3 ubiquitin ligase gene BCL2-athanogene 1 (BAG1) and subsequent GR protein ubiquitination and proteasomal degradation. It was found that the basal protein levels of GRα correlated with the endothelial expression of key genes, such as NOS3 and SERPINE1 (Mata-Greenwood et al. 2013). However, the transcriptional regulation of GR expression in human endothelial cells and its role in endothelial glucocorticoid sensitivity have not been well defined, and warrant further exploration. GR mRNA expression is regulated by complex mechanisms that include transcriptional and epigenetic modification of GR promoters (Presul et al. 2007, Turner et al. 2010, Cao-Lei et al. 2011). The GR gene (NR3C1) contains at least nine 5′UTR first exons that are spliced to the common exon 2. The alternative first exons are divided into two promoter regions: a distal region located more than 30 kb upstream that contains exons 1A and 1I, and a proximal region located 5 kb upstream of the translation start site that contains exons 1B, 1C, 1D, 1E, 1F, 1H, and 1J. Each first exon is regulated by its own promoter that binds specific transcription factor complexes (Bockmuhl et al. 2011, Cao-Lei et al. 2011). Therefore, the transcription of the GR gene is regulated by complex promoter regions containing multiple transcription start sites. Furthermore, both proximal and distal GR promoters are embedded in a CpG island that is mostly methylation-free and therefore can be targeted for methylation. Recent human and rodent studies have shown tissue and disease specific expression of untranslated first exons, due in part to changes in GR promoter methylation (Turner et al. 2006, 2008, 2010, Bockmuhl et al. 2011). These studies have shown that the various GR promoters allow for tissue-specific mechanisms to control and adapt GR expression levels according to various developmental and pathophysiological stages. Previous studies have shown that rodent heart and aortic tissue express significant levels of GR transcripts (Presul et al. 2007, Xiong & Zhang 2013), but the transcriptional regulation of GR in specific cardiovascular cells (i.e., endothelial, smooth muscle, cardiomyocytes) remains unknown. Therefore, the main objective of the present study is to uncover the mechanisms that regulate the expression of GR mRNA isoforms in human endothelial cells that have been previously characterized as DEX-sensitive or DEX-resistant. We find that DNA methylation plays an important role in the fine-tuning determination of GR mRNA isoform expression in human endothelial cells. Our study provides novel insights into the upstream mechanisms that alter GR expression in the cardiovascular system and suggest that future use of epigenetic markers will aid in identifying glucocorticoid responsive individuals. Materials and methods Subjects and cell culture HUVECs isolated from 25 healthy term pregnancies were selected from a previous cohort study of 42 subjects (Mata-Greenwood et al. 2013) to further characterize the transcriptional regulation of GR in human endothelial cells. These HUVECs were previously characterized for endothelial cell purity and in vitro response to DEX (Mata-Greenwood et al. 2013). The study subject characteristics are summarized in Supplementary Table 1, see section on supplementary data given at the end of this article. The study was approved by the IRBs of the Loma Linda University and the University of California at San Diego. HUVECs were cultured using ECM media (ScienCell, Carlsbad, CA, USA). All assays were performed between passages 4 and 6. To study inter-individual differences in response to glucocorticoids, we stimulated confluent and quiescent HUVECs with DEX using DMSO as a solvent (final concentration of 0.05%). This synthetic glucocorticoid was chosen for its stability in the presence of cellular 11-β-dehydrogenase, and for its specificity for GRα binding with respect to other nuclear receptors, including the mineralocorticoid receptor (Wenting-van Wijk et al. 1999). To starve HUVECs, we used M199 (Sigma–Aldrich) supplemented with 0.95 mM HEPES, 0.1% BSA, 1% antibiotics and 1% fetal bovine serum (FBS). The acute monocytic leukemia cell line THP-1 from Sigma–Aldrich was used as a positive control as it is known to express all GR mRNA isoforms (Steer et al. 2000). THP-1 cells were grown in DMEM with 1% antibiotics and 10% FBS. RNA extraction and real-time PCR Total RNA was extracted with TriZOL-RNEasy kits (Invitrogen), quantified, and stored at −80 °C until analysis. The total RNA (1 µg) was reverse transcribed and real time PCR was performed for each sample in triplicate as previously described (Goyal et al. 2014). Taqman assays were obtained from Life Technologies for GR mRNA isoforms 1B (Hs01005211_m1), 1C (Hs01010775_m1), 1D (Hs03666144_m1) and the housekeeping gene 18S (Hs99999901_s1), and these were run according to the manufacturer’s recommendations using a Probe Quantitect PCR mix (Qiagen). Designed primers for SYBR green PCR analysis of the remaining GR mRNA isoforms and the housekeeping gene 18S, together with PCR conditions and accession numbers, are shown in Supplementary Table 2, see section on supplementary data given at the end of this article. SYBR green PCR was performed using Quantitect SYBR green PCR kit (Qiagen) using a 2.0 Lightcycler amplifier (Roche). PCR products were purified, sequenced, and used to obtain standard curves for each mRNA isoform. Extrapolation of unknowns from the standard curve was performed using Prism 3 (GraphPad Software, San Diego, CA, USA), predicting unknowns from the standard curve Ct values. Data is presented as fg mRNA/ng 18S. Alternatively, the percentages of each GR mRNA isoform were estimated for each subject as mRNA isoform/sum of all mRNA isoforms × 100. SDS–PAGE and immunoblotting Western blotting was performed as previously described (Mata-Greenwood et al. 2010). Briefly, protein extracts (30 µg) were prepared in a cold lysis buffer, heat denatured in a Laemmli buffer, separated on SDS-PAGE, and transferred to PVDF membranes. Membranes were blocked in 5% non-fat dried milk in 0.05% TBST for 1 h, and then probed in primary rabbit anti-GR (Santa Cruz Biotechnologies), monoclonal anti-BAG1 (Santa Cruz Biotechnologies), monoclonal anti-HSP90 (BD Biosciences, San Jose, CA, USA), and rabbit anti-FKBP51 (Stressmarq, Victoria, BC, Canada), diluted in blocking buffer (1 µg/ml) overnight at 4 °C. After three 10 min washes with TBST, the membranes were incubated with secondary antibodies that were diluted at 1:2000. Bound antibodies were visualized using the chemiluminscence substrate (ThermoFisher Scientific, Carlsbad, CA, USA). The membranes were then probed with monoclonal anti-β-Actin (Ambion, Austin, TX, USA). Data is presented as protein levels relative to β-Actin levels. Cloning of GR promoters GR promoters B, C, D, F, and H were cloned into the firefly luciferase-pGL3 reporter vectors (Promega), as previously described (Mata-Greenwood et al. 2010). GR promoter regions were selected to include putative essential DNA elements such as initiator (Inr) and downstream promoters (DPE). Briefly, 500 ng of HUVEC DNA (from specific donors) was used to amplify GR promoter regions using primers that contained specific restriction enzyme sites (Supplementary Table 3, see section on supplementary data given at the end of this article), followed by ligation into the basic luciferase pGL3 vector. The non-methylated GR promoter inserts were confirmed by DNA sequencing. Vector clones containing WT GR promoters were used. Cell transfection and luciferase assays Transfection of plasmid DNA was performed with the aid of HD Xtreme transfection reagent (Roche) as previously described (Mata-Greenwood et al. 2013). Briefly, confluent cells were transfected with the GR promoter/pGL3-luciferase constructs, using a 1:1 complex of DNA:Xtreme reagent according to the manufacturer’s protocol. TK-Renilla luciferase vector (Promega Corp.) was used as the internal control. The transfection was carried out at 37 °C for 6 h. The cells were allowed to recover in a complete culture medium for 18–20 h, and then treated with starvation media with or without DEX (0.2 and 1 µM) for another 24 h, before adding passive lysis. Firefly and Renilla luciferase activities were measured using a dual-reporter assay kit (Promega) according to the manufacturer’s protocol. Relative luciferase values were calculated as a ratio of firefly/renilla luciferase activities. Each treatment was tested in quadruplicates and averages per sample were used to calculate group averages and standard errors. Methyl-DNA immunoprecipitation Genomic DNA was isolated from confluent and quiescent HUVECs using the Wizard genomic DNA isolation kit (Promega). Methyl-DNA immunoprecipitation (MeDIP) was performed with the aid of a commercial kit according to the manufacturer’s protocol (Active Motif, Carlsbad, CA, USA). In brief, 20 µg of DNA was sheared into ~ 200–400 bp fragments and immunoprecipitated with a 5-methylcytosine-specific antibody at 4 °C overnight. Immunoprecipitated DNA was bound to magnetic beads, washed and eluted. Input (sheared DNA) and immunoprecipitated DNA (1 µl) was used to amplify specific promoter regions from the GR gene using SYBR green PCR, as previously described. MeDIP real-time PCR primers are shown in Supplementary Table 4, see section on supplementary data given at the end of this article. Promoter methylation levels were estimated as immunoprecipitated DNA/total (input) DNA × 100. Bisulfite-converted DNA sequencing To determine the methylation status of GR promoters, DNA samples were treated with bisulfite using the epiTect Bisulfite kit (Qiagen), according to the manufacturer’s instructions. Converted DNA was amplified using primers directed to bisulfite modified genomic DNA (Supplementary Table 4). Amplification conditions were as follows: 94 °C for 30 s, 40 °C for 30 s, and 72 °C for 40 sX40 cycles. Resulting amplicons were cloned into pCR4-TOPO sequencing vectors (Invitrogen) for automated fluorescent sequencing. Data were analyzed using the CLC Software, and clones showing <90% conversion or identified as clonal were not included in further analysis. The methylation levels for each subject were estimated as the methylated clones/#total clones sequenced × 100. A minimum of ten clones per amplicon were analyzed by sequencing. Averages and standard errors were then calculated for each sensitivity group. Overexpression of GRα Mammalian expressing vectors for the promoter-less full length GR-1Cα (NM_000176.2) were a gift from Dr John A. Cidlowski (NIEHS, Research Triangle, NC, USA). GR over-expression was achieved by transfecting log-phase proliferating HUVECs with 1 µg DNA/six well using the Xtreme transfection reagent as previously described. After 18 h of recovery, HUVECs were treated with DEX (1 µM) or not for an additional 24 h before analysis. Overexpression of GRα was confirmed by real-time PCR and immunoblotting. Global demethylation assays To induce global demethylation, we utilized a 5 µM dose of 5′-aza-2′-deoxycitidine (AZA) in 50% confluent cells. After 24 h of AZA treatment, cells were treated with both AZA and DEX (1 µM) or solvent for another 24 h before harvesting total RNA. DNA demethylation was confirmed by GR promoter D methylation levels of < 1%. Procoagulant activity assay The procoagulant activity of HUVECs was tested by a one-step recalcification time test, also known as the activated partial thromboplastin time (aPTT) as previously described (Mata-Greenwood et al. 2013). As discussed, 70% confluent HUVECs were transfected with GRα-expressing vectors, and 18 h after were treated with or without DEX (1 µM) for an additional 24 h. Cells were then washed, trypsinized, and resuspended in PBS at a concentration of one million cells per ml PBS. A 1:1 solution was prepared with cells and fresh plasma (collected from one single donor and anticoagulated with 3.8% sodium citrate, 1:9, v/v) and incubated for 180 s at 37 °C. After the addition of preheated CaCl2, the time to fibrin strand generation was recorded by a BCS XP hemostatic analyzer (Siemens, Munich, Germany). Statistical analysis Data are presented as means±s.e.m. Each individual variable was analyzed via ANOVA followed by post-hoc least significant difference (LSD) analysis to determine differences between sensitivity groups and between treatment groups. Homogeneity of variances was confirmed (P>0.05) using the Levene’s Test of Equality of Error Variance. For data sets with unequal variances (P<0.05), the data were log transformed and all further statistics were performed on the transformed data. For graphical presentation, the anti-logs of the mean log values were calculated and plotted. In all cases, statistical power was >0.08. A P value of <0.05 was regarded as significant. All statistical analysis was performed using SPSS, version 22. Results Differential GR mRNA isoform expression in HUVECs according to DEX-sensitivity We have previously characterized a small cohort of 42 HUVECs obtained from healthy pregnancies for DEX-sensitivity. DEX-sensitive HUVECs expressed significantly higher levels of GRα protein than DEX-resistant HUVECs (Mata-Greenwood et al. 2013). Analysis of study group characteristics indicated that the pre-pregnancy maternal BMI and average systolic blood pressure were significantly higher in DEX-sensitive HUVECs compared to those of DEX-resistant cells (Supplementary Table 1), but the remaining parameters were not significantly different. To further understand the transcriptional regulation of GR in endothelial cells, and the mechanisms leading to the differences in GR expression between DEX-sensitive and DEX-resistant HUVECs, we analyzed the expression of 5′UTR mRNA isoform transcripts in 25 HUVECs (15 DEX-sensitive and 10 DEX-resistant). HUVECs expressed GR proximal mRNA isoforms 1B, 1C, 1D, 1F, and 1H, but did not express the distal isoforms 1A and 1I, or the proximal isoforms 1E and 1J (Fig. 1A and B). DEX-resistant HUVECs expressed significantly higher basal, but similar DEX-stimulated, GR mRNA isoform 1C levels (Fig. 1B); and lower percentages of mRNA isoform 1F levels (Fig. 1C) than DEX-sensitive cells. DEX treatment significantly decreased the expression of mRNA isoform 1C in DEX-resistant cells only (Fig. 1B). The percentages of GR 5′UTR mRNA isoforms in all HUVECs were ~67% (1C), ~30% (1B), ~2% (1F), ~1% (1H), and ~0.2% (1D) (Fig. 1). DEX treatment did not significantly alter the percentages of GR 5′UTR mRNA isoforms in either DEX-sensitive or DEX-resistant cells (Fig. 1C). We also analyzed the expression profile of GR 3′UTR mRNA isoforms GRα, GRβ and GRP. GRα represented ~ 96% of all 3′UTR mRNA isoforms, followed by GRP (4%), and GRβ expression was slight (<0.0006%) in all HUVECs (Fig. 1E). DEX-resistant HUVECs expressed significantly higher basal levels of GRα than DEX-sensitive HUVECs (Fig. 1D) that correlate with higher basal levels of the predominant 5′UTR mRNA isoform 1C (Fig. 1B). Importantly, DEX treatment decreased the expression of GRα (Fig. 1D) and increased the percentage of GRP (Fig. 1E) in DEX-resistant cells only. Lastly, there were no significant differences in the levels of total GR mRNA (measured by exons 2–3) between the sensitivity groups. However, DEX downregulated total GR mRNA in DEX-resistant cells only (Fig. 1D). Role of GRα overexpression on its own transcriptional regulation and endothelial cell phenotype To clarify the role of differential GR 5′UTR mRNA isoform levels between sensitivity groups on endothelial phenotype, we overexpressed GRα in both DEX-sensitive and DEX-resistant HUVECs, using a promoter-less GR-1Cα-expressing vector. We hypothesized that GRα overexpression would increase sensitivity to DEX in any HUVEC tested. To validate our methods, we first showed our protocol significantly increased GR-1Cα mRNA levels by 31-fold and 20-fold, and GRα protein levels by 3.5-fold and 2.4-fold in DEX-sensitive and DEX-resistant cells respectively (Fig. 2A and B). DEX-treatment significantly decreased the levels of overexpressed GRα mRNA and protein in both sensitivity groups (Fig. 2A), suggesting DEX-dependent post-transcriptional and post-translational mechanisms of GR regulation (Pratt et al. 2006, Turner et al. 2010). However, our overexpression system had a smaller effect on GR protein levels (two- to fourfold increase) compared to GR mRNA (20- to 31-fold increase) levels that is most likely due to the reported GR protein degradation by the proteasome (Wallace et al. 2010, Mata-Greenwood et al. 2013). Of interest, overexpression of similar amount of GR-1Cα vectors yielded significantly lower levels of both GRα mRNA and protein in DEX-resistant cells compared to DEX-sensitive cells (Fig. 2B). This finding suggests that DEX-resistant cells have stronger negative autoregulatory mechanisms on GR expression compared to DEX-sensitive cells. We then investigated the role of increased expression of GRα in endothelial phenotype of both DEX-sensitive and DEX-resistant cells (Fig. 2C, D and E). We chose to study NOS3 and SERPINE1 expression, as these genes are key endothelial genes regulated by glucocorticoids, and their expression changes also regulate endothelial phenotype (Lou et al. 2001, Muzaffar et al. 2005, Kimura et al. 2009). GRα overexpression correlated with significant decreases in NOS3 (Fig. 2C) and increases in SERPINE1 (Fig. 2D) basal mRNA expression in both DEX-sensitive and DEX-resistant cells. Overexpression of GRα also increased the basal procoagulant activity of HUVECs as shown by the aPTT assay (Fig. 2E). However, there were significant differences between the sensitivity groups in response to DEX. DEX-treatment led to NOS3 down-regulation, SERPINE1 upregulation and aPTT increases in GRα-overexpressing DEX-sensitive cells, but not in GRα-overexpressing DEX-resistant cells (Fig. 2D and E). Therefore, overexpression of GR-1Cα alone did not correct the lack of response to DEX in resistant cells. However, GR-1Cα overexpression did alter basal endothelial phenotype in both sensitivity groups suggesting important non-ligand dependent effects of GR in human endothelial cells. We also investigated the effect of GR-1Cα over-expression on its own expression. We found that GR-1Cα overexpression (alone or in combination with DEX treatment) decreased the expression of GR mRNA isoform 1B in DEX-resistant cells, and that of isoform 1H in both sensitivity groups (Fig. 2F). GR-1Cα overexpression did not alter DEX effects on GR mRNA isoform expression (Fig. 2F). Finally, we investigated the expression of GR chaperones FKBP51, BAG1 and HSP90 in HUVECs overexpressing GRα. We found that resistant cells that overexpress GRα have significantly higher expression of the GRα inhibitor FKBP51 and higher levels of HSP90 than sensitive cells (Supplementary Figure 1, see section on supplementary data given at the end of this article), and could be a reason for the lack of DEX response in GRα overexpressing resistant cells. Therefore, differences in DEX-sensitivity in our HUVECs can also be accounted by differential regulation of GR chaperones. In summary, these results demonstrate that exogenous upregulation of GRα mRNA/protein levels can significantly alter both basal and glucocorticoid-stimulated endothelial phenotype in HUVECs, but does not eliminate the differences in GR expression and function regulation between the sensitivity groups. Correlation of GR 5′UTR mRNA isoform expression with promoter usage To further characterize the differences observed in GR mRNA isoform expression, we cloned five of the proximal TATA-less GR promoters to the pGL3 luciferase reporter vector to study promoter activity in HUVECs (Fig. 3A). Clones were sequenced and analyzed for putative internal elements (Inr), DPE, and transcription factor binding sites using the MattInspector software (Supplementary Figure 2, see section on supplementary data given at the end of this article). The consensus Inr element sequence (YYANWYY) located within the first 5 bp of the transcriptional starting site (+1) was found in promoter 1C only. The consensus TATA-less DPE elements (DPE=RGWYV) were found in promoters 1B and 1C, while partial DPEs were found in the remaining GR promoters (Supplementary Figure 2). Putative promoter elements for transcription factors were found for each promoter: those reported to be highly expressed in the cardiovascular system are shown in green. Luciferase assays revealed significant differences in GR promoter usage in all HUVECs, with promoter 1C having the highest activity (55%), followed by promoter 1B (30%), promoter 1D (10%), promoter 1F (8%), and promoter 1H (3%) (Fig. 3B). There were no significant differences in basal promoter usage between the sensitivity groups to account for the observed differences in GR 5′UTR mRNA isoforms 1C, 1D, and 1F (Fig. 1B). There were only small significant differences in DEX-stimulated promoter usage; sensitive cells responded to DEX with a slight increase in promoter 1B and 1D usage compared to DEX-resistant cells (Fig. 3B). DEX-treatment also significantly decreased promoter 1F usage in both DEX-sensitive and DEX-resistant cells, with non-significant decreases in promoter 1C usage in both groups as well (Fig. 3B). Therefore, our promoter assays suggest that the observed differences in GR mRNA isoforms 1C, 1D, and 1F between sensitivity groups (Fig. 1B and C) are not the result of differential transcriptional activation of GR promoters. We analyzed the correlation of promoter usage with 5′UTR mRNA isoform expression by plotting the average % mRNA levels with average % promoter usage in all HUVECs at basal, low DEX (0.2 µM) and high DEX (1 µM) dose (Fig. 3C). We found a significant positive correlation between these two parameters, with only promoter 1D usage being disproportionally higher than the expression of the 1D mRNA isoform (Fig. 3C), suggesting epigenetic regulation of promoter 1D. Role of promoter methylation in GR 5′UTR mRNA isoform expression Because our reporter assays failed to reveal transcriptional mechanisms that would account for the observed differences between DEX-sensitive and DEX-resistant cells in GRα expression regulation (particularly of mRNA isoforms 1C, 1D, and 1F), we hypothesized that there could be differential methylation patterns of GR promoters. We first studied promoter methylation levels by immunoprecipitation of 5-methylcytosine (Fig. 4A). As expected, promoters 1B and 1C showed very low methylation levels of <4 and <1.7% respectively (Fig. 4A). Promoter 1D showed the highest methylation levels of ~20%, followed by promoter 1F (~14%), and promoter 1H (~10%). There were significant differences in promoter methylation levels between DEX-sensitive and DEX-resistant HUVECs (Fig. 4A). DEX-resistant cells had significantly lower methylation levels of promoter 1D and higher methylation levels of promoter 1F, compared to DEX-sensitive cells (Fig. 4A). The basal promoter methylation levels (i.e. averages for all cells: sensitive and resistant) correlated inversely with the expression of GR 5′UTR mRNA isoforms, with promoter 1C having the lowest methylation levels and higher mRNA isoform 1C levels, and promoter 1D having the highest methylation levels together with lower mRNA isoform 1D expression levels (Fig. 4B). These results explain why the expression of the 5′UTR mRNA isoform 1D is lower than that of isoform 1F, although the cloned promoter 1D-driven luciferase activity was higher than that of promoter 1F (Figs 1B and 3B), as cloned promoter-vectors do not have any cytosine methylations. To confirm our MeDIP results, we then investigated the specific methylation sites in promoters 1D and 1F via bisulfite sequencing. Promoters 1D and 1F were chosen because they exhibited the highest methylation levels and because of differences in the expression of mRNA isoforms 1D and 1F between sensitivity groups. Bisulfite sequence analysis confirmed the differences observed in our MeDIP assays (Supplementary Figure 3, see section on supplementary data given at the end of this article and Fig. 4A). We found five methylation sites in promoter 1D with higher methylation percentages in DEX-sensitive cells than DEX-resistant cells (Supplementary Figure 3). DEX-resistant cells showed significant promoter 1F methylation of five different cytosines in comparison with none found in DEX-sensitive cells. In sum, bisulfite analysis confirmed that DEX-sensitive cells have higher methylation levels for promoter 1D but lower methylation levels for promoter 1F, compared to DEX-resistant cells. It is important to note that the MeDIP assay and bisulfite sequencing showed methylation levels for promoter 1F of ~7 and 0%, respectively, in DEX-sensitive cells. This discrepancy is likely due to the presence of other methylation sites further upstream or downstream from the selected DNA segment analyzed via bisulfite sequencing. Finally, we utilized AZA to induce global demethylation in order to study the role of GR promoter methylation on its own expression and function. Analysis of the GR 5′UTR mRNA isoform expression demonstrated that AZA treatment resulted in increased expression of all GR 5′UTR mRNA isoforms in DEX-sensitive cells, and in all isoforms except isoform 1D in DEX-resistant cells (Fig. 4C and D). Importantly, AZA treatment eliminated the differences in GR 5′UTR mRNA isoforms 1C, 1D and 1F expression between DEX-sensitive and DEX-resistant cells (Fig. 4C). Analysis of AZA-induced fold increases in GR mRNA expression further highlighted differences between sensitivity groups. AZA-treatment produced higher (fold of control) increases in the expression of GR mRNA isoforms 1B and 1D in DEX-sensitive cells compared to DEX resistant cells, and a higher fold increase of isoforms 1F and 1H in DEX-resistant cells compared to DEX sensitive cells, and these data correlated with GR promoter methylation levels (Fig. 4A and D). Consistent with the effect of AZA on GR expression, we found that AZA pretreatment increased the response to DEX in the resistant group in terms of NOS3 and SERPINE1 gene expression regulation, and thereby eliminated the differential response to DEX between the sensitivity groups (Fig. 4E and F). Of note, AZA treatment significantly increased the basal expression of SERPINE1 on all cells. This result is likely due to the effect of AZA on SERPINE1 promoter demethylation and basal transcriptional upregulation. However, we did not study the effect of AZA on the promoter methylation status of other genes. Therefore, AZA effects on in vitro DEX response could be mediated by demethylation of other genes that are differentially methylated in DEX-sensitive and DEX-resistant cells. In sum, we found significant differences in GR promoter methylation that result in differential GR 5′UTR mRNA isoform expression, and these differences further characterize DEX-sensitive and DEX-resistant HUVECs. Discussion We uncovered novel mechanisms of GR expression regulation in human endothelial cells that include differential expression of 5′UTR mRNA isoforms due to promoter methylation We have also found significant differences in GR promoter methylation and 5′UTR mRNA isoform expression according to DEX-sensitivity. The results of our studies on GR mRNA and protein regulation in HUVECs are summarized in Table 1. First, we have determined that the primary 5′UTR mRNA isoform present in human endothelial cells is isoform 1C, followed by isoform 1B, with smaller contributions from isoforms 1F, 1H, and 1D. Previous studies have shown similar dominance of expression of isoform 1C in tissues such as the liver, heart, kidney, and lung (Presul et al. 2007, Turner et al. 2008, 2010). Our promoter analysis suggests that the presence of putative Inr elements and DPE in promoter 1C leads to transcriptional dominance of mRNA isoform 1C compared to other isoforms. These DNA elements are known to recruit RNA polymerase complexes in TATA-less promoters (Butler & Kadonaga 2002, Yang et al. 2007, Juven-Gershon & Kadonaga 2010). Interestingly, mRNA isoforms 1J, 1D, 1H, and 1F have been reported to be highly expressed in non-vascular tissues such as the hippocampus and peripheral mononuclear cells (Turner et al. 2008, Cao-Lei et al. 2013). In our studies, these exons represent < 10% of all endothelial GR transcripts. Therefore, our data indicate that regulation of isoforms 1C and 1B expression, with smaller contributions from mRNA isoforms 1D, 1F and 1H, will have a higher impact on total GR mRNA expression. Previously we reported that increased in vitro DEX sensitivity of HUVECs correlated positively with GRα protein levels (Mata-Greenwood et al. 2013). DEX-sensitive HUVECs showed lower GRα protein turnover through the proteasome system, and this was partly due to lower expression of the E3 ubiquitin ligase BAG1. In the present study, we have found that increased GRα protein levels observed in DEX-sensitive, compared to DEX-resistant, cells are not the result of increased GRα mRNA levels, as previously hypothesized. However, we did observe significant differences in GRα mRNA isoform expression among DEX-sensitive and DEX-resistant HUVECs. Resistant cells, but not sensitive cells, responded to DEX treatment with a significant down-regulation of the main GR 5′UTR mRNA isoform 1C and 3′UTR mRNA isoform α (Table 1). Because glucocorticoids downregulate GRα mRNA expression (Petersen et al. 2004, Ramamoorthy & Cidlowski 2013), we now hypothesize that DEX-resistant cells show significant DEX-dependent downregulation of GR mRNA expression in addition to increased GR protein degradation via the proteasome. Our GRα overexpression data supports this hypothesis; DEX treated-resistant cells had lower levels of overexpressed GRα mRNA and protein than DEX-treated-sensitive cells. Therefore, DEX-resistance in endothelial cells could arise from a strong negative autoregulation that includes both mRNA and protein expression decreases. Another interesting result was that GRα overexpression did not increase in vitro response to DEX (measured as changes in NOS3, SERPINE1, and aPTT) in resistant cells (Table 1). Furthermore, GRα overexpression significantly altered basal endothelial phenotype (NOS3, SERPINE1, and aPTT levels) in both sensitivity groups with a greater effect shown in resistant cells. We currently speculate these data to be caused by differences in GR:chaperone interactions between sensitive and resistant cells. In support of this hypothesis, we found that GRα overexpression upregulated the expression of GR inhibitors BAG1 and FKBP51. Further studies on GR chaperones are therefore needed to fully understand the differential in vitro response to DEX in HUVECs. In summary, these data suggest that posttranslational regulation of GRα protein, such as GRα proteasomal degradation and GR:chaperone interactions, and not transcriptional mechanisms, are key factors in determining basal and DEX-stimulated levels of biologically active GR and, thereby, in the biological response to glucocorticoids (Table 1). Perhaps the most novel result of this study is the inverse association between GR 5′UTR mRNA isoform expression and GR promoter methylation together with the finding of significant differences in promoter methylation between DEX-sensitive and DEX-resistant cells (Table 1). This study is the first to report that methylation plays an important role in GR mRNA expression in endothelial cells. DEX-sensitive HUVECs showed significantly higher methylation of promoter 1D, but lower methylation of promoters 1F and 1H. Methylation levels of promoter 1D and 1F correlated inversely with the expression of their corresponding 5′UTR mRNA isoforms 1D and 1F. Of importance was the finding that AZA treatment abrogated the differences in GR 5′UTR mRNA isoform expression between sensitivity groups, thereby showing that methylation differences in GR promoters are a principal reason for the observed differences in GR 5′UTR mRNA isoforms expression between DEX-sensitive and DEX-resistant cells. Unexpectedly, AZA treatment increased the expression of GR mRNA isoforms 1B and 1C, even though their proximal promoters were highly unmethylated. We hypothesize that AZA demethylation of upstream sequences, such as promoter 1D or GR enhancers, increases the expression of mRNA isoforms 1B and 1C. Our hypothesis is in agreement with previous reports on YY1, a promoter 1D binding transcription factor, and the mediated transcriptional activation of isoform1B (Cao-Lei et al. 2011). To our knowledge, this study is the first to show that the expression of GR mRNA isoforms 1B and 1C is also regulated by methylation. Numerous studies have shown a significant role of promoter 1F methylation in brain tissue, and its correlation with psychiatric diseases (Moser et al. 2007, Alt et al. 2010, Labonte et al. 2014, Van der Knaap et al. 2014). In rats, maternal care has shown to decrease methylation levels of promoter 1–7 in brain and liver tissue (Szyf et al. 2005, Witzmann et al. 2012), while hypoxia and other stressors increase it (Xiong & Zhang 2013, Gonzalez-Rodriguez et al. 2014). Recent human studies on promoter 1F methylation in umbilical cord mononuclear cells revealed increased promoter 1F methylation in gestational infants exposed to maternal stressors (Filiberto et al. 2011, Drake et al. 2012, Sinclair et al. 2012, Hompes et al. 2013). This finding is of interest because our DEX-sensitive cells originated from mothers with significantly higher pre-pregnancy BMI than those from the DEX-resistant group. Therefore, we hypothesize that maternal weight could be an important factor (stressor) in determining fetal endothelial glucocorticoid sensitivity. Altogether, our data suggest that differential methylation of GR promoters have significance in regulating GR mRNA isoform expression and are associated with glucocorticoid sensitivity. Together, our findings show that GRα gene expression in human endothelial cells is highly complex and that GR promoter methylation patterns differ between DEX-sensitive and DEX-resistant HUVECs. Although these differences in GR promoter methylation and 5′UTR mRNA expression do not account for the differences observed in GRα protein expression, function, and further alterations of endothelial phenotype, we hypothesize that they could be exploited to develop epigenetic markers of vascular glucocorticoid sensitivity. Importantly, global demethylation studies with AZA eliminated the differences between sensitivity groups in the in vitro response to DEX, indicating an important role of methylation patterns in establishing HUVEC sensitivity to glucocorticoids. Future research into the mechanisms that lead to differential methylation of GR proximal promoters, and the potential role of maternal obesity in programming fetal endothelial glucocorticoid sensitivity, are warranted. Supplementary Material 01 We thank Dr John A Cidlowski (NIEHS) for providing the full length human GR-1Cα expressing vectors, Dr Fuxia Xiong for helping in the design of cloning primers, and Dr Donna Thorpe for helping with the statistical analysis. Funding The present study was supported by the AHA SDG award #0630297N to Dr E M-G and by the School of Medicine, Loma Linda University. Figure 1 Basal and DEX-stimulated expression of GR mRNA transcripts in DEX-sensitive (S) and DEX-resistant (R) HUVECs. (A) Structure of the human glucocorticoid receptor gene (NR3C1) that includes 9 exons 1 and 3 stop signals that result in both 5′UTR and 3′UTR mRNA isoforms. (B, C, D and E) Confluent and quiescent HUVECs were treated with solvent, DEX 0.2, and DEX1 µM for 24 h and GR mRNA isoforms were quantified by real-time PCR as described under methods. (B) Basal and DEX-stimulated expression levels of GR 5′UTR mRNA isoforms (1B, 1C, 1D, 1F, and 1H) expressed as fg GR isoform/ng 18S RNA. (C) Expression of GR 5′UTR mRNA isoforms as percent of total GR mRNA. (D) Basal and DEX-stimulated expression of GR 3′UTR mRNA isoforms (GRα, GRP and GRβ) as fg GR isoform/ng 18S RNA; (E) Expression of GR 3′UTR mRNA isoforms as percent of total GR mRNA. THP1 monocytoid cells were used as a positive control to verify that HUVECs do not express isoforms 1A, 1E, 1I and 1J. Bars represent the average±s.e.m. (n = 15 DEX-sensitive and 10 DEX-resistant). *P<0.05 DEX-treated vs untreated; #P<0.05 DEX-resistant cells vs DEX-sensitive cells. Figure 2 Role of GRα overexpression in endothelial phenotype, expression autoregulation, and response to DEX. HUVECs were transfected with a promoter-less GR-1Cα expressing vector, then treated for 24 h with or without DEX (1 µM). Total RNA was extracted, reverse-transcribed and quantified by real-time PCR. (A and B) GRα overexpression in HUVECs upregulated both mRNA (A) and protein (B) levels in both DEX-sensitive (n = 5) and DEX-resistant (n = 5) HUVECs. (C, D and E) Effect of GRα overexpression on NOS3 downregulation (C), SERPINE1 upregulation (D) and activated partial thromboplastin time, aPTT (E). (F) Effect of GRα overexpression on GR 5′UTR mRNA isoform levels. Bars represent the average±s.e.m. (n = 5 DEX-sensitive and 5 DEX-resistant). *P<0.05 DEX-treated vs untreated; #P<0.05 DEX-resistant vs DEX-sensitive cells; †P<0.05 basal vs GRα overexpression. Figure 3 Basal and DEX-stimulated transcriptional activity of proximal GR promoters. (A) Structure of the proximal CpG island of the human GR gene. (B and C) HUVECs (12 DEX-sensitive and 8 DEX-resistant) were transfected with GR promoter-luciferase vectors and then treated with solvent, DEX 0.2, or DEX 1 µM for 24 h. Promoter activity was estimated by the levels of firefly luciferase activity, normalized to Renilla luciferase activity and expressed in fold activity of the empty pGL3 firefly basic reporter vector. Transfections were performed in quadruples. (B) Basal and DEX-dependent GR promoter usage in HUVECs. (C) Linear regression analysis of promoter usage (percent luciferase activity) against 5′UTR mRNA isoform expression (percent isoform levels). Averages for all HUVECs for each treatment group (DEX 0, 0.2 and 1 µM) were used. Bars represent the average±s.e.m.. *P<0.05 DEX-treated vs untreated; #P<0.05 DEX-resistant cells vs DEX-sensitive cells. Figure 4 Role of GR promoter methylation on GR expression and response to DEX. (A) Methylation of proximal promoters as determined by immunoprecipitation of 5-methylcytosine in DEX-sensitive (S) and DEX-resistant (R) cells (n=8/group). Results are shown as average percentage methylation. (B) The correlation between basal HUVEC GR promoter methylation and GR 5′UTR mRNA isoform expression was determined by linear regression analysis. Each data point represents the average levels for each sensitivity group. Promoter methylation percentages are shown as Iog10 values. (C and D) Global demethylation was achieved with 48 h of AZA treatment, and the expression of GR 5′UTR mRNA isoform was determined by real-time PCR (n = 5/sensitivity group). Results are shown as fg GR isoform/ng 18S RNA (C), and fold expression of untreated cells (D). (E and F) HUVECs were treated with AZA as described for (C) and (D) in the presence or absence of DEX 1µM, and then analyzed for NOS3 (E) and SERPINE1 (F) mRNA expression by real-time PCR. Bars represent the average±s.e.m. *P<0.05 DEX-treated vs untreated; #P<0.05 DEX-resistant cells vs DEX-sensitive cells; †P<0.05 non-AZA vs AZA treatment. Table 1 Summary of major findings on GR expression regulation in HUVECs Figure 1: GR mRNA isoform levels Resistant cells have higher expression of GR isoforms 1C and 1D, and lower expression of isoform 1F than sensitive cells in basal conditions. Dexamethasone-treatment downregulated 5′UTR mRNA isoform 1C and 3′UTR mRNA isoform α in resistant cells only. Figure 2: Effect of GR-1Cα Overexpression GR-1Cα overexpression in resistant cells did not improve in vitro response to dexamethasone as determined by NOS3 downregulation, SERPINE1 upregulation, and decreases in aPTT. GR-1Cα overexpression further downregulated the expression of 5′UTR mRNA isoforms 1B (in resistant cells only) and 1H in both sensitivity groups. Figure 3: GR promoter activity There were no significant differences in basal GR promoter (unmethylated) activity between sensitive and resistant cells. Dexamethasone treatment decreased promoter 1F activity in both sensitivity groups, decreased promoter 1B activity in resistant cells only and increased promoter 1D activity in sensitive cells only. Promoter activity differences between sensitive and resistant cells did not correlate with differences in GR 5′UTR mRNA levels. Figure 4: GR promoter methylation and AZA treatment Sensitive cells have higher promoter 1D methylation levels and lower promoter 1F and 1H methylation levels compared to resistant cells. Promoter methylation levels correlated with GR 5′UTR mRNA levels. AZA treatment upregulated the expression of all GR mRNA isoforms except isoform 1D in resistant cells. AZA treatment improved in vitro dexamethasone response in resistant cells as determined by NOS3 downregulation and SERPINE1 upregulation. Supplementary data This is linked to the online version of the paper at http://dx.doi.org/10.1530/JME-15-0124. Declaration of interest The authors declare that there is no conflict of interest that could be perceived as prejudicing the impartiality of the research reported. 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PMC005xxxxxx/PMC5113727.txt
LICENSE: This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. 101302316 33345 Cell Host Microbe Cell Host Microbe Cell host & microbe 1931-3128 1934-6069 27693306 5113727 10.1016/j.chom.2016.09.002 NIHMS816601 Article Diverse intestinal bacteria contain putative zwitterionic capsular polysaccharides with anti-inflammatory properties Neff C. Preston 1* Rhodes Matthew E. 1* Arnolds Kathleen L. 1 Collins Colm B. 2 Donnelly Jody 1 Nusbacher Nichole 1 Jedlicka Paul 3 Schneider Jennifer M. 1 McCarter Martin D. 4 Shaffer Michael 1 Mazmanian Sarkis K. 5 Palmer Brent E. 1⌘ Lozupone Catherine A. 1⌘ 1 Department of Medicine, University of Colorado Anschutz Medical Campus, Aurora, CO 80045 USA 2 Department of Pediatrics, University of Colorado School of Medicine, Aurora, CO 80045 USA 3 Department of Pathology, University of Colorado Anschutz Medical Campus, Aurora, CO 80045 USA 4 Department of Surgery, University of Colorado Anschutz Medical Campus, Aurora, CO 80045 USA 5 Division of Biology & Biological Engineering, California Institute of Technology, Pasadena, CA 91125, USA ⌘ Corresponding Author: Lead Contact: Dr. Catherine Lozupone (Catherine.Lozupone@ucdenver.edu; Phone 303-724-7942; Fax 303-724-7212).; Dr. Brent Palmer (brent.palmer@ucdenver.edu; Phone 303-724-7203; Fax 303-724-7212) * Authors contributed equally 19 9 2016 29 9 2016 12 10 2016 12 10 2017 20 4 535547 This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. Summary Zwitterionic capsular polysaccharides (ZPS) are bacterial products that modulate T cells, including inducing anti-inflammatory IL-10-secreting T regulatory cells (Tregs). However, only a few diverse bacteria are known to modulate the host immune system via ZPS. We present a genomic screen for bacteria encoding ZPS molecules. We identify diverse host-associated bacteria, including commensals and pathogens with known anti-inflammatory properties, with the capacity to produce ZPSs. Human mononuclear cells stimulated with lysates from putative ZPS-producing bacteria induce significantly greater IL-10 production and higher proportions of Tregs than lysates from non ZPS-encoding relatives or a commensal strain of Bacteroides cellulosilyticus in which a putative ZPS biosynthetic operon was genetically disrupted. Similarly, wild-type B. cellulosilyticus DSM 14838, but not a close relative lacking a putative ZPS, attenuated experimental colitis in mice. Collectively, this screen identifies bacterial strains that may use ZPS to interact with the host as well as those with potential probiotic properties. eTOC Identifying anti-inflammatory host-associated bacteria can reveal strategies to combat inflammatory disease. Neff et al. conduct a genomic screen to identify bacteria with the capability to produce capsular zwitterionic polysaccharides (ZPS). These ZPS-producing bacteria induce increased levels of anti-inflammatory IL-10 and Tregs and prevent experimental colitis in mice. Introduction The trillions of microorganisms that colonize the human body (the microbiota) control many aspects of both innate and adaptive immune responses (Hooper and Macpherson 2010; Molloy, Bouladoux, and Belkaid 2012) and a healthy microbiota plays a crucial role in maintaining immune homeostasis. Accordingly, dysbiosis of the gut microbiota is associated with many diseases characterized by chronic gut inflammation, including Inflammatory Bowel Diseases (Kverka et al. 2011) and HIV infection (Lozupone et al. 2014). Host-associated bacteria that influence T cell populations are of key interest, since T cells play a central role in controlling host immune status. One key class of molecules known to influence T cell populations in the context of both health and disease are capsular zwitterionic polysaccharides (ZPS)(Surana and Kasper 2012). Unlike most naturally occurring polysaccharides composed of negatively charged sugar molecules, ZPSs contain positive and negative repeating charges and can activate CD4+ T cells in complex ways (Avci and Kasper 2010; Tzianabos et al. 1993). The alternating charges are crucial, as chemical modification eliminates the ability of ZPS to modulate immune responses (Tzianabos et al. 1993). Diverse bacteria produce immune-modulatory ZPSs, including SP1 of Streptococcus pneumonia (Velez et al. 2009), CP8 of Staphylococcus aureus (O’Riordan and Lee 2004) and O-chain antigen of Morganella morganii (Young et al. 2011). The best-studied ZPS is Polysaccharide A (PSA) of the intestinal bacterium Bacteroides fragilis NCTC 9343. Certain ZPSs are involved in disease, having the ability to induce abscess in a T cell dependent manner (Tzianabos et al. 1993). However, certain ZPSs also appear to play important and diverse roles in both maintaining and restoring intestinal immune homeostasis. For instance, studies in mice have shown that the ZPS of B. fragilis NCTC 9343 PSA, can drive a Th1-mediated response to help maintain Th1/Th2 balance in the gut (Mazmanian et al. 2005). PSA can also induce anti-inflammatory IL-10- secreting T regulatory cells (Tregs), to protect against both T-cell mediated and chemically induced colitis in mice (Mazmanian, Round, and Kasper 2008; Round and Mazmanian 2010). Finally, immune assays with human PBMC have shown that PSA can also induce CD4+ T cells with suppressive capacity in humans (Telesford et al. 2015; Kreisman and Cobb 2011). The bacteria known to modulate the host immune system using ZPS are limited, and include phylogenetically diverse organisms that make structurally similar ZPS. Specifically, B. fragilis NCTC 9343 and S. pneumoniae make similar ZPSs called PSA and SP1 respectively (Figure 1), in which the crucial positive charge is conferred by the same amino sugar, acetamido-amino-2,4,6-trideoxygalactose (AATGal). Most strains of B. fragilis contain an AATGal-ZPS but these vary in structure, with only ~25% of strains making PSA and with strain 638R making PSA2, a more structurally complex ZPS (Figure 1) that shares similar immunological properties to PSA and a biosynthesis locus on a homologous chromosomal region (Wang et al. 2000). The biological activities of varied ZPS from different bacterial strains are generally thought to be similar (Stephen, Groneck, and Kalka-Moll 2010), although the degree to which AATGal-ZPSs may vary in function is not well understood. As an example Sp1, PSA and PSA2 all induce abscess and SP1 and PSA both induce T cell activation in an APC dependent manner (Wang et al. 2000; Kalka-Moll et al. 2002). However, PSA and not SP1 induced CD4+39+FoxP3+ cells in a Dendritic Cell (DC)-dependent manner in stimulations with human cells derived from peripheral blood (Telesford et al. 2015), which has functional implications because CD39 expression was shown to be important for PSA-mediated protection against CNS inflammation in murine models (Wang et al. 2014). Further expansion of our knowledge of the diversity of ZPSs in nature may pave the way to discovery of ZPS with therapeutic potential. To further expand our knowledge of the breadth of AATGal-ZPSs and the bacteria that produce them, we screened complete and draft genomes for those containing orthologues to AATGal biosynthetic genes and for a subset of these genomes, characterized the gene content of Capsular Polysaccharide Biosynthesis (CPS) operons that contained them. Furthermore, we tested the immune-modulatory properties of AATGal-ZPS encoding bacteria using human blood and tissue assays and a mouse model of colitis. The availability of thousands of sequenced genomes from a continually increasing repertoire of cultured human gut inhabitants makes such genomic screens coupled with functional experiments a powerful approach for understanding the distribution of key biological properties across human gut bacteria. Results Genomic screen for bacteria that encode AATGal-ZPS molecules The PSA operon of B. fragilis NCTC 9343 had been previously cloned and sequenced (Coyne et al. 2001). This operon contains transcriptional regulators upaY and upaZ, which are conserved across CPS loci in the Bacteroides (Krinos et al. 2001; Xu et al. 2003), 4 glycosyl transferases (GT) and other key genes for CPS biosynthesis such as a flippase and polymerase (Figure 1). The key genes for the biosynthesis and attachment of the AATGal amino sugar that gives PSA its positive charges, and thus zwitterionic property, are wcfR, which encodes a protein that synthesizes AATGal and wcfS, which encodes a GT that transfers this amino sugar to the polysaccharide backbone, in an adjacent position to wcfR (Figure 1) (Coyne et al. 2001). Gene homologues to wcfR and wcfS downstream of upaY and upaZ transcriptional regulators, but not the other genes in the PSA operon, were conserved in almost all of 50 strains of B. fragilis tested, indicating that AATGal-ZPS but not canonical PSA are conserved across B. fragilis (Coyne et al. 2001). We predicted which other bacteria may produce AATGal-ZPS by first performing a BLAST search for B. fragilis NCTC 9343 wcfR gene homologues in protein coding genes from 8065 genomes. To define a similarity threshold at which the BLAST hits were potentially orthologous to wcfR and thus produce a functionally equivalent molecule, we considered the fact that B. fragilis NCTC 9343 has a wcfR gene homologue within its genome (BLAST e-value = 3e−48) that encodes a protein with a different function, the aminotransferase DegT (ref|wp_010992163). Plotting the e-value distribution of hits to B. fragilis wcfR produced a bimodal distribution, with the DegT in the lower distribution (Figure S1A). We hypothesized BLAST hits in the upper distribution (< 1e−90 in our search) may be orthologues to wcfR. We next determined whether wcfR orthologues had other essential elements of AATGal-ZPS nearby in the genome, including a homologue to the wcfS gene and the upaY and/or upaZ transcriptional regulators (using a threshold of e-value < 1e−5). Diverse taxa contain diverse putative AATGal-ZPS operons Of the 8065 genomes screened, 517 had BLAST hits to the B. fragilis wcfR gene with an e-value < 1e−90, including taxonomically diverse bacteria in the Bacteroidales, Erysipelotrichales, Clostridiales, and Bacillales orders (Figure 2). In at least 409 of these 517 genomes, wcfR homologues had a wcfS homologue adjacent or in very close proximity (within 3 genes). Most genomes from bacteria in the Bacteroidales order contained homologues to the upaY and/or upaZ transcriptional regulators upstream, but wcfR homologue containing bacteria from other bacteria lineages did not. Consistent with previous reports that B. fragilis and S. pneumoniae produce AATGal-ZPS with related genes (Coyne et al. 2001), among our predicted producers of AATGal-ZPS molecules were 217 strains of S. pneumoniae (Figures 1,2). Our screen also identified the PSA2 operon of B. fragilis 638R, which has a related but more complex structure compared to PSA, with five monosaccharides rather than four (Figure 1, S3)(Wang et al. 2000). Genomes usually only contained one AATGal-ZPS operon but in rare cases could contain multiple, including B. cellulosilyticus strains DSM 14838 and CL02T12C19 and B. fragilis strains HMW 615 and YCH46 (Figure S3, S4). Predicted producers of AATGal-ZPS were scattered throughout the 16S rRNA phylogenetic tree of the Bacteroides genus and phylogenetically interspersed with species that did not contain predicted AATGal-ZPS operons (Figure 3A), indicating a pattern of multiple gains and losses. A similar phylogenetically interspersed pattern was also observed for predicted AATGal-ZPS and non- AATGal-ZPS producers in the Erysipelotrichales (Figure 3B) and the Clostridiales (data not shown) lineages. For AATGal-ZPS encoding bacteria in the Bacteroidales order, we predicted the operon gene content based on the genes located between the upaY/upaZ transcriptional regulators and the wcfR/wcfS gene homologues and also using the Database of Prokaryotic Operons (Door2) application (Mao et al. 2009). To relate the operons to each other based on their gene content, we binned genes into families and clustered the operons that had similar collections of genes families. Interestingly, and consistent with previous reports (Coyne et al. 2001), only 4 of the 13 surveyed strains of B. fragilis had a canonical PSA operon, B. fragilis strain 638R had a unique operon consistent with its production of PSA2, and 6 strains shared an operon for a previously uncharacterized AATGal-ZPS (Figure S3). Consistent with PSA and PSA2 of B. fragilis having related but unique structures, the content of sugar biosynthesis and GT genes of the operons suggest that the AATGal-ZPSs in the Bacteroidales include variable polysaccharide backbones that generally have 4–5 sugar repeating subunits (Figure S2; Table S1). Establishing an AATGal-ZPS immune phenotype in human blood and tissue To establish assays in human blood for determining whether bacteria with putative AATGal-ZPS operons have anti-inflammatory properties, we first performed 3-day stimulations of peripheral blood mononuclear cells (PBMC) from healthy adults with lysate of wild-type (WT) B. fragilis NCTC 9343, and B. fragilis with the PSA operon knocked-out (B. fragilis ΔPSA). After three days of stimulation, the cell culture supernatant was subjected to IL-10 ELISA and the cell cultures to flow cytometry to assess immune cell populations (see methods). B. fragilis WT lysate induced significantly higher IL-10 levels (p<0.0001, Figure 4A) and lower levels of the inflammatory cytokines IL-6 and TNF-α (p=0.01, p=0.02, respectively, Figure S5A) than B. fragilis ΔPSA. We also used a 24 hour Intracellular Cytokine Staining (ICCS) assay to evaluate whether any IL-10 was being produced by CD4+ T cells in these mixed cell populations. WT B. fragilis stimulations produced a significantly higher fraction of CD4+ IL-10+ cells than B. fragilis ΔPSA (p=0.0015, Figure 4B) but the vast majority of these CD4+IL-10+ cells were CD25−FoxP3− (p<0.0001, Figure 4C). We also found a significant decrease in Treg induction by B. fragilis ΔPSA compared to WT when we used CD127 and CTLA4 as additional markers to FoxP3 and CD25 (Figures 4E). Consistent with reports that CD25 and FoxP3 alone are inadequate human Treg markers (Sakaguchi et al. 2010; Gavin et al. 2006), stimulations with WT B. fragilis did not result in a significantly greater proportion of CD4+CD25+FoxP3+ cells compared to B. fragilis ΔPSA (Figure 4D). To establish an assay for determining whether AATGal-ZPS containing bacteria can stimulate naïve T cells in an APC-dependent manner as has been previously described for B. fragilis PSA, we stimulated isolated CD14+ monocytes with bacterial lysates prior to being co-cultured with purified naïve T cells. Even though no memory or effector T cells were present, WT B. fragilis induced higher levels of IL-10 and Tregs compared to B. fragilis ΔPSA (p = 0.026, p = 0.021, Figure 4F and 4G). Since fewer cells were used for this assay (two hundred thousand naive T cells) compared to whole PBMC (two million total cells), lower levels of IL-10 were observed. Since immune cell subsets can behave differently depending on body compartment (Hu and Pasare, 2013), we also conducted assays using lamina propria mononuclear cells (LPMC) from resected gut tissue supplied to us following surgery (note that surgery was usually conducted to remove tumors. Sections of healthy tissue were used in the assays). WT B. fragilis induced more IL-10 and more CD25+FoxP3+CD127−CTLA-4+ Tregs than B. fragilis ΔPSA in LPMC (p = 0.0005, p=0.008 Figure 4H, and 4I, respectively). Taken together, our results show that an increased proportion of CD25+FoxP3+CD127−CTLA-4+ Tregs and increased IL-10 in supernatants from 3-day stimulations of PBMC and LPMC are both an indicator of PSA-like activity in bacteria. Assaying phylogenetically interspersed ZPS encoding and non-encoding bacteria for PSA-like immunomodulatory activity We selected 6 putative AATGal-ZPS-encoding and 7 non-encoding strains that were phylogenetically interspersed on a 16S rRNA tree of the Bacteroidales and Erysipelotrichales orders for immune assays (Figure 3). Using phylogenetically interspersed bacteria helps to reduce the effects of other genetic differences between strains that may be confounding. As an example, although any individual bacterial isolate will usually differ in many genes from even a very close phylogenetic relative, all of the putative ZPS-operon containing bacteria selected here would not be expected to share any genes to the exclusion of the phylogenetically interspersed non-ZPS encoding bacteria by chance. Finding anti-inflammatory properties established for PSA to be associated with our genomic predictions of AATGal ZPS-operon presence, would thus strongly implicate the ZPS-operons as an underlying reason. The selected bacterial strains also contained wcfR orthologues that were scattered throughout the wcfR tree (Figure 2), which allows us to test whether our selected e-value threshold is diagnostic of ZPS-like activity. Finally, they contained AATGal-ZPS operons with diverse gene content (Figure S2). Bacterial strains were grown to early stationary phase in liquid broth media, and a qPCR assay validated that the ZPS-encoding bacteria tested were expressing the wcfR gene under these growth conditions (Figure S1B). Stimulation of human PBMC with lysates of the predicted ZPS-producers elicited significantly higher median levels of IL-10 and CD25+FoxP3+CD127−CTLA-4+ Tregs in both the Bacteroidales and the Erysipelotrichales (Figure 5 A, B). Individual predicted ZPS-producing bacteria were also each compared to its closest assayed non ZPS-producing relative with a paired T-test and in almost all cases the predicted ZPS-producer induced significantly more IL-10 and Tregs, except for a couple of case that were borderline significant (Table 1). Our results for stimulations in LPMC were less clear. Stimulations with LPMC showed significantly greater median IL-10 production in ZPS-producers than non-producers in the Bacteroidales (p=0.039) but not in the Erysipelotrichales (p=0.21, Figure 5C). Median Treg stimulation was not significantly higher in ZPS-producers versus non in LPMC (Figure 5D). Paired T-tests between predicted ZPS-producing bacteria and their closest assayed non ZPS-producing relative were only sometimes significant (Table 1). However, the closest non-ZPS producing relatives of the ZPS-producers had typically only a 16S rRNA % ID of ~92% ID (Table 1), indicating that differences in other genes in the genomes may be obscuring the effects of the ZPS. When we compared B. cellulosilyticus and B. intestinalis, the most highly related strains with opposite designations, statistical significance was reached for IL-10 production and Treg stimulation in both PBMC (p=0.0026, p=0.047, Figures S6A and S6B, respectively) and LPMC (p=0.0019, p=0.028, Figures S6C and S6D, respectively). ZPS-knockout strains of Bacteroides cellulosilyticus To further confirm that the increased IL-10 and Treg levels in these bacteria were conferred by putative ZPS operons, we disrupted a wcfR gene in B. cellulosilyticus DSM 14838 via targeted insertional mutagenesis using the pKNOCK-bla-ermGb vector as described by (Alexeyev 1999). B. cellulosilyticus DSM 14838 has two putative AATGal-ZPS operons in its genome (Figure S2), one was encoded on Scaffold 5 (ZPS1) and one was encoded on Scaffold 9 (ZPS2). The operon encoding ZPS1 was simpler than the operon encoding ZPS2, and showed greater similarity in gene content to PSA, sharing homologues to the wcfQ and wcfP GTs and to the wzx3 flippase (Figure S4). Sequencing of the cDNA produced from mRNA of WT B. cellulosilyticus DSM 14838 grown to late log phase showed that both copies of the gene were expressed by the cell population. By PCR confirmation of both genomic DNA and mRNA, we confirmed that the wcfR gene of ZPS1 and not ZPS2 was disrupted. Stimulation of PBMC with B. cellulosilyticus ΔZPS1 resulted in the production of significantly less IL-10 and Tregs compared to WT bacteria (Figure 5E and 4F). As with B. fragilis and its PSA knockout counterpart, when isolated APCs were first stimulated with B. cellulosilyticus or B. cellulosilyticus ΔZPS1 and then co-cultured with purified naïve CD4+ T cells, the knockout strain induced less IL-10 and Tregs compared to wild type (Figure 5G and H), indicating that this AATGal-ZPS of B. cellulosilyticus can also induce Tregs from naïve T cells in an APC-mediated fashion. ZPS producing B. cellulosilyticus DSM 14838 protects against colitis in a TNBS model To further test whether our genomic screens for immune-modulatory ZPS operons are predictive of the anti-inflammatory effects described for B. fragilis PSA, we tested the effect of gavaging mice with the putative ZPS producer B. cellulosilyticus DSM 14838 in a Trinitrobenzenesulfonic acid (TNBS) induced colitis model. In two separate trials, female C57/Bl6 mice aged 8 – 12 weeks were gavaged with 5.0 × 108 cells of bacteria in 200 μL of culture media or culture media without bacteria, once a week for 3 weeks. On the day of the third treatment, mice were challenged with TNBS. Gavage of mice with B. cellulosilyticus led to significantly decreased weight loss induced by TNBS enema relative to vehicle control, measured by two-way repeated measures ANOVA (p = 0.014, Figure 6C). Vehicle-gavaged mice displayed a significant reduction in initial body weight by day 5 post-enema (95% ± 2.3; n = 6; p < 0.01) while those receiving B. cellulosilyticus were protected from weight loss and actually gained weight overall (102.3% ± 0.6; n = 6). In contrast, mice gavaged with B. intestinalis, a close relative of B. cellulosilyticus (97.4% identity over their aligned 16S rRNA genes) that does not encode a putative ZPS operon displayed no such protection from TNBS-induced weight loss. Gavage of mice with B. cellulosilyticus also led to decreased histological evidence of inflammation (Figure 6A) as assessed in blinded manner by a trained pathologist (Figure 6B). The vehicle group of TNBS treated animals displayed histological evidence of inflammation (2.28 ± 0.26) that was significantly higher than those receiving B. cellulosilyticus (1.40 ±0.27; p = 0.02), while those receiving B. intestinalis displayed worse inflammation than vehicle controls, though the difference was not statistically significant (3.30 ± 0.55; p = 0.051). The decrease in inflammation coincided with an increase in CD4+ FoxP3+ regulatory T cells in the colonic lamina propria of the vehicle group (5.3% ± 0.77; n = 4) compared to mice gavaged with B. cellulosilyticus (7.9% ± 0.82; n = 4; p = 0.04) (Figure 6D and E). In contrast those receiving B. intestinalis displayed no significant difference in Treg frequency from vehicle controls. DISCUSSION Here we show that we can predict bacteria with anti-inflammatory properties in in vitro assays in humans based on the presence of predicted AATGal-ZPS operons in their genomes. Furthermore, the one putative AATGal-ZPS producer tested, B. cellulosilyticus DSM 14838, showed a robust protection of colitis in mice, indicating that this bacterial strain has potential probiotic applications. B. cellulosilyticus appears to be a benign member of the Bacteroides, especially when compared to B. fragilis. It was originally isolated from healthy human feces for its ability to degrade cellulose (Robert et al. 2007) and is a gut symbiont that is notable for its extensive glycobiome (McNulty et al. 2013). Whether it is the 2 AATGal-ZPSs encoded by B. cellulosilyticus DSM 14838 that confers this anti-colitic property remains to be elucidated. The significant reduction of Treg and IL-10 in a B. cellulosilyticus strain in which one AATGal-ZPS had been genetically disrupted supports a role for this ZPS in anti-inflammatory properties of B. cellulosilyticus DSM 14838. A wide variety of bacteria from diverse phylogenetic lineages appear to produce AATGal-ZPSs that may modulate the immune system. We focused our analyses on bacteria within the Bacteroidales order and one isolate in the Erysipelotrichales order; Similar follow-up with a larger diversity of predicted AATGal-ZPS producing bacteria would also be useful for confirming the significance of our predictions. Our analysis of AATGal-ZPS operon gene content of bacteria in the Bacteroidales order suggests that we are identifying a diversity of ZPSs that includes PSA2 of B. fragilis strain 638R. Our immune assay results suggest that diverse AATGal-ZPS containing bacteria induce IL-10 and Tregs in stimulations of mixed immune cell populations from both PMBC and LPMC. Furthermore, assays with our B. cellulosilyticus ΔZPS1 strain indicates that for this putative AATGal-ZPS, Treg induction occurs at least in part via the APC-dependent stimulation of naïve T cells. Further work to more deeply define mechanisms of immune-modulation in these ZPSs and whether they differ between the various ZPS sub-types is needed, including experiments with AATGal-ZPSs purified from different bacteria, a greater diversity of genetic knock-out strains, human assays with more defined immune cell populations, and more validation in mouse models. Analysis of a wider diversity of AATGal-ZPSs may elucidate ones with therapeutic potential. Even for the best-studied AATGal-ZPS, PSA of B. fragilis, the mechanisms of immune-modulation, especially in humans, are far from being completely understood. Previous work establishing anti-inflammatory effects of B. fragilis/PSA in mice and humans have shown that PSA induces Foxp3+ Treg cells that express IL-10 upon antigen presentation on DCs (Round and Mazmanian, 2010)(Telesford et al. 2015), a result which we confirm here for both B. fragilis PSA and an AATGal-ZPS in B. cellulosilyticus DSM 14838. However, we also found that PSA induced IL-10 production by CD4+ T cells in mixed cell populations was mediated mostly by FoxP3- cells in humans, which is consistent with the results of Kreisman and Cobb despite considerable differences in assay design (Kreisman and Cobb 2011). It has also been shown previously that PSA can directly induce IL-10 from FoxP3−/CD4+ T cells via TLRs in mice (Round et al. 2011). The bacterial mediation of CD4+ T cell IL-10 production by Tr1 cells in humans is not unique to B. fragilis; the probiotic Bifidobacterium breve also induces colonic IL-10 producing Tr1 cells that do not express FoxP3 (Jeon et al. 2012). This work also evaluated the effects of PSA on immune cells in the gut compartment, and stimulations performed with mixed cell populations from LPMC from human gut tissues showed comparable results to those performed with PBMC when comparing B. fragilis to B. fragilis ΔPSA. This is an important finding since immune cells in different body compartments have the potential to respond very differently to environmental stimuli (Hu and Pasare 2013), and indicates that immune phenotypes in PBMC can be relevant to the gut compartment. However, for the broad comparison of predicted ZPS-producers to non ZPS-producers, the results for LPMC were not as strong as for PBMC with only increased IL-10 production in the Bacteroidales being modestly significant and no significant differences in Treg induction. The weaker phenotype in LPMC may be related to inherent challenges when working with these tissues. There was more variability in the responses across samples, which may be due to factors that are difficult to control for such as the presence of different bacterial populations already on the mucosal samples. Also, inherent differences in the bacteria that go beyond presence/absence of AATGal-ZPSs (e.g. production of other factors by these microbes that also influence immune phenotypes) may indicate why we had the power to observe a difference in B. fragilis versus knockout in LPMC but not in the broader comparisons of putative ZPS-producers versus non-producers. Further experiments with additional ZPS knock-out strains and purified ZPS will allow for a more robust analysis of whether diverse AATGal-ZPSs have an anti-inflammatory phenotype in human LPMC. Our techniques identify commensal bacteria already known to have anti-inflammatory properties Some AATGal-ZPS encoding bacteria have been shown to have anti-inflammatory properties in other studies. For instance, the crude lysate of P. distasonis, and particularly its membranous fraction, attenuated DSS-induced murine colitis while preventing increases in several pro-inflammatory cytokines and promoting significantly more CD4+CD25+FoxP3+ cells in mesenteric lymph nodes (Kverka et al. 2011). P. distasonis has also been previously shown to induce Tregs through a T cell receptor that was shared with B. uniformis, another species that we predict to produce an AATGal-ZPS (Lathrop et al. 2011). However, abolishment of function upon digestion with protease K indicated that this antigen is a protein and not a polysaccharide, signifying that P. distasonis and B. uniformis may share additional factors for stimulating Tregs. The predicted ZPS producers also included close relatives of 2 bacteria in a 17-strain consortium previously shown to induce Tregs in mice and protect against colitis and allergic diarrhea in mouse models (Atarashi et al. 2013) (Clostridium ramosum, and Clostridum 7_3_45FAA which is highly related to Clostridium symbiosum (Figure 2). Use of a cognate antigen-driven suppressor assay determined that specific bacterial antigens likely contributed to expansion of Tregs in this model (Atarashi et al. 2013). Our literature search also identified papers describing the convergence of surface structure properties of B. fragilis with distantly related ZPS-producers. For instance, Clostridium spiroforme, a predicted ZPS-producer in the Erysipelotrichales, had previously been reported to have a polysaccharide capsule similar to that of B. fragilis that mediates haemagglutination in both species (Baldassarri et al. 1989). Interestingly, the electron micrographs of C. spiroforme reported in (Baldassarri et al. 1989) show outer-membrane vesicles (OMVs) that are strikingly similar to those of B. fragilis (Shen et al. 2012) (Figure S7). OMVs of B. fragilis carry PSA and can induce immunomodulatory effects and prevent experimental colitis (Shen et al. 2012). Our techniques identify human pathogens The predicted producers of AATGal- ZPSs also include pathogenic bacteria, such as Clostridium botulinum (botulism), Clostridium perfringens (gas gangrene;bacteremias;wound infection), and Brachyspira hyodysenteriae (swine dysentery) and bacterial species that may opportunistically infect immunocompromised hosts such as C. ramosum (van der Vorm et al. 1999) and C. symbiosum (Elsayed and Zhang 2004). The presence of the AATGal-ZPS operon orthologues in pathogenic bacteria is not surprising given that ZPS producing bacteria including B. fragilis, S. pneumoniae, and S. aureus, often are commensal bacteria that can cause disease when they have escaped their normal habitats (Surana and Kasper 2012). B. fragilis is considered to be the most virulent of all of the Bacteroides species because of frequent isolation from a variety of clinical specimens including intra-abdominal abscess, blood, wound, perirectal, pelvic and other sites (Polk and Kasper 1977), and abscess formation requires PSA (Lindberg et al. 1982; Mazmanian and Kasper 2006; Onderdonk et al. 1977). S. aureus induces skin abscess in a manner that is also dependent on its ZPS (Weidenmaier, McLoughlin, and Lee 2010), and S. pneumoniae strains that produce Sp1 are the most common cause of bacterial pneumonia (Stephen, Groneck, and Kalka-Moll 2010). Although ZPSs can also in certain contexts be pro-inflammatory, e.g. as Th17 cell inducers (Mazmanian and Kasper 2006; Surana and Kasper 2012), Treg induction itself is known to be important for many pathogens as a mechanism for evasion of immune clearance and persistence in the host (Belkaid 2007; Mills 2004). Consistent with this notion, infection with putative ZPS-producer B. hyodysenteriae, which induces a severe colitis in pigs known as swine dysentery, induces a mucosal CD4+ T-cell response. This suggests that the induction of both pro-inflammatory and regulatory responses are important in the pathogenesis of this species (Hontecillas et al. 2005). CONCLUSIONS Taken together this work has established a greater diversity of AATGal-ZPSs and bacteria that carry them than has been previously appreciated. Much further study will be needed to understand how this expanded class of important immune-modulatory molecules mediate interactions with the host. EXPERIMENTAL PROCEDURES Putative ZPS operons were identified using a BLASTP search of the wcfR, wcfS, upaY, and upaZ genes of the PSA operon of B. fragilis NCTC 9343 against the entire collection of completed and draft genomes in the NCBI database on September of 2013. The proximity of wcfR, wcfS, upaY, and upaZ gene homologues on genomic contigs were determined using custom code. Operon gene membership was further defined using DOOR2 (Mao et al. 2014) and compared as detailed in the Supplemental Methods. Phylogenetic trees of the wcfR genes and the 16S rRNA genes from the surveyed bacteria were created as described in the Supplemental Methods. The bacterial isolates used in the immune assays were purchased from the ATCC or DSMZ and grown in rich media depending on their preferences as described in the Supplemental Methods. Bacteria were subjected to freeze/thaw or heat killing before being used in immune stimulations. Since immune stimulations with heat killed compared to freeze/thaw lysates resulted in no differences (data not shown), all reported stimulations were done with freeze/thaw lysates in order to avoid protein denaturing. The qPCR assays that were used to verify expression of wcfR in B. cellulosilyticus, B. fragilis WT, and B. uniformis are described in the Supplemental Methods and Figure S1B. The B. cellulosilyticusΔZPS1 strain was developed using the pKNOCK-bla-ermGb vector to disrupt wcfR via targeted insertional mutagenesis as previously described (Alexeyev 1999) and as detailed in the Supplemental Methods. To conduct the immune assays, human PBMCs were isolated by Ficol gradient centrifugation as previously described (Chain et al. 2013; Kassu et al. 2010; Neff et al. 2015) from the blood of 13 normal individuals. Informed consent was obtained and the study protocol was approved by the Colorado Multiple Institutional Review Board (COMIRB #14-1595). PBMCs were cultured with 10 μg freeze killed bacterial lysate for 3 days at 37°C. Six and 10-day stimulations were also performed and had similar results to those of 3-day stimulations (data not shown). Stimulations were performed in the presence of Streptomycin and Penicillin and in aerobic conditions and no bacterial growth was observed in the cell cultures. Unlike in the assays conducted by Kreisman and Cobb (Kreisman and Cobb 2011) in human PBMC, our stimulations were conducted in absence of exogenous IL-2; the IL-2 receptor CD25 is upregulated in the presence of IL-2, which could compromise our Treg staining. Cytokine secretion after 3-day stimulations with bacterial lysates was quantified in supernatant using ELISA Ready Set Go! (eBioscience), Tregs were enumerated using flow cytometry, and ICCS was used to determine IL-10+ cells, all as detailed in the Supplementary Methods. To determine whether induced IL-10 production and Tregs were due to restimulation of memory T cells, CD14+ monocytes were isolated by magnetic bead selection (Miltenyi Biotec), plated, stimulated with bacterial lysate for 4 hours and washed twice with PBS. Naïve T cells were negatively selected by magnetic beads (Miltenyi Biotec) and were added to the bacterial stimulated APCs. After three days supernatant was collected and subjected to IL-10 ELISA and cells were enumerated for Tregs. Intestinal lamina propria lymphocytes were isolated from resected gut tissue of jejunum, duodenum and colon, which were obtained from patients undergoing elective abdominal surgery. All patients signed a release to allow the unrestricted use of discarded tissues for research purposes and all protected patient information was de-identified to the laboratory investigators. The lamina propria lymphocytes were isolated from these tissues as detailed in the Supplemental methods. To test for protection in a murine TNBS colitis model, female C57/Bl6 mice aged 8 – 12 weeks were gavaged with bacteria or control PBS on days 0, 7, and 14 as described in the Supplemental Methods. Mice were cohoused prior to the intervention, and then housed in separate cages once the treatments began to prevent transmission of the introduced bacteria between mice. Mice were anesthetized, shaved and skin painted with 100μl of 1% TNBS in 100% EtOH on day 7 and received a rectal enema of 2.5% TNBS in 40% EtOH (5μl/g body weight) on day 14. Colonic tissue was prepared for histological assessment of disease as described in the Supplemental Materials or digested as previously described (Collins et al. 2013). CD4+CD25+FoxP3+ cells in colonic tissue were enumerated with flow cytometry as described in the Supplemental methods and statistical analysis was performed using GraphPad Prism. These experiments were approved by IACUC (B-104413(12)1E). Supplementary Material supplement Sources of Support We would like to thank Ashleigh Jones for her technical assistance with the mouse experiments. We would also like to express deep gratitude to Eric Martens for sharing with us the pKNOCK-bla-ermGb vector and for his guidance in conducting insertional transposon mutagenesis. This work was funded from R01 DK104047. Dr. Lozupone was also supported by K01 DK090285. Dr. Neff was supported by NIH T32 AI007405. Dr. Collins was supported by K01 DK099403. Figure 1 PSA operon of B. fragilis NCTC 9343 and chemical structures of B. fragilis NCTC 9343 PSA, B. fragilis 638R PSA2, and S. pneumoniae SP1. A. The PSA operon of B. fragilis and the conserved properties of B. fragilis AATGal-ZPS operons, as described by Coyne et al. (Coyne et al. 2001) B. Chemical structure of PSA of B. fragilis and related ZPSs. The shaded regions indicate the amino sugar AATGal that is synthesized by the wcfR gene and transferred by the wcfS gene to a polysaccharide backbone that varies in structure between these ZPSs. Genes shared across Bacteroidales AATGal-ZPSs, and examples of other AATGal-ZPS operons are shown in Figure S2, S3, and S4. Figure 2 A neighbor joining tree of BLAST hits to the wcfR gene of B. fragilis with an e-value <1e−90. Highly related sequences from different strains of the same species (or undesignated strains that are likely the same species) are collapsed into a wedge with the number of strains (genomes) within that wedge noted. Colors indicate the taxonomic order of the bacteria from which the wcfR sequence came. The wcfR genes of bacterial strains tested in immune assays are indicated with a star, showing that tested bacteria include those with wcfR homologues throughout this phylogeny. Figure S7 shows electron micrograph evidence of a convergence in surface structures in bacteria that are very distantly related phylogenetically but share highly similar wcfR gene homologues in their genomes. Figure 3 16S rRNA trees of all genomes that were screened in the orders Bacteroidales and Erysipelotrichales showing presence/absence of PSA-like operons. A. Strains surveyed in the Bacteroidales order and B. Strains surveyed in the Erysipelotrichales order. Species shown in red text had genes encoding both wcfR and wcfS and the genes were in adjacent or close positions within the operon. Those without a close homologue to wcfR are in black. Nodes in which all bacteria had the same color designation are collapsed into wedges with the number of strains noted in parentheses. The stars indicate predicted PSA-producing (in red) and non PSA-producing (in black) bacterial strains selected for immunologic testing. Figure 4 WT B. fragilis induces higher IL-10 production and proportion of Tregs compared to B. fragilis ΔPSA in human PBMC and LPMC. A. Levels of IL-10 in the supernatant of PBMC cultured with WT B. fragilis and B. fragilis ΔPSA for 3 days as determined by ELISA. B. Percent IL-10+ CD4+ T cells and C. CD4+IL-10+ T cells that are CD25+/−FoxP3+/− after one day stimulation with WT B. fragilis. D. Proportion of CD4+ T cells that are CD25+FoxP3+ in PBMC after 3 days of culture with WT B. fragilis or B. fragilis ΔPSA. E. Proportion CD4+ T cells that are CD25+FoxP3+CD127−CTLA4+ in PBMC after 3 days of culture with WT B. fragilis and B. fragilis ΔPSA. F. Levels of IL-10 in the supernatant and G. proportion of Tregs generated from purified naïve T cells mixed with bacteria stimulated purified CD14+ monocytes. H. Levels of IL-10 in the supernatant and I. proportion of CD4+ T cells that are CD25+FoxP3+CD127−CTLA4+ of LPMC after 3 days of culture with bacterial lysates. Statistical significance was calculated by paired T tests. Data for other cytokines (IL-6, TNF-α, IL-17, and IL-22) are in Figure S5A. Representative staining for CD25+FoxP3+CTLA4+CD127−Tregs in human PBMC and LPMC are in Figure S5B. Figure 5 (Left) Putative PSA producers in the Bacteroidales or Erysipelotrichales orders induce more IL-10 and Tregs compared to their non-PSA producing relatives in PBMC and LPMC. A. IL-10 levels and B. proportion of CD25+FoxP3+CTLA4+CD127−cells of CD4+ T cells in PBMC cultured with bacteria from the Bacteroidales (circles) or Erysipelotrichales order (squares) for 3 days. C. IL-10 levels and D. proportion CD25+FoxP3+CTLA4+CD127− cells of CD4+ T cells in LPMC cultured with bacteria from the Bacteroidales (circles) or Erysipelotrichales order (squares) for 3 days. Predicted PSA producers are in red and those that are not are in black. Statistical significance between medians of predicted and non-predicted PSA producers was calculated by nonparametric Mann-Whitney tests. (Right) WT B. cellulosilyticus induces higher IL-10 production and proportion of Tregs compared to a wcfR knockout in whole PBMC and purified naïve T cells. E. Levels of IL-10 and F. proportion CD4+ T cells that are CD25+FoxP3+CD127−CTLA4+ in PBMC after 3 days of culture with B. cellulosilyticus and B. cellulosilyticus ΔZPS1. G. Levels of IL-10 in the supernatant and H. proportion of Tregs generated from purified naïve T cells mixed with bacteria stimulated purified CD14+ monocytes. Statistical significance was calculated by paired T tests. Comparisons of stimulations with WT B. cellulosilyticus and the closely related B. intestinalis are in Figure S6. Figure 6 B. cellulosyliticus administration attenuates murine colitis in vivo. A. Representative micrographs of H&E stained colonic sections demonstrate that B. cellulosyliticus causes a decrease in intestinal inflammation relative to either vehicle controls or mice gavaged with B. intestinalis (black scale bar 200 μm). B. Histological inflammatory index scores show protection from inflammation in mice gavaged with B. cellulosilyticus relative to vehicle control or B. intestinalis. C. Weight loss curve data correlates with attenuated inflammation seen in histological scores. D. Representative contour plots showing expression of FoxP3+ T cells from the colonic lamina propria of each group, then enumerated E. * P < 0.05, ** P < 0.01. Table 1 Individual PSA-producing bacteria were compared with their closest non-PSA-producer relative for IL-10 and Treg induction in PBMC and LPMC. Statistical significance was calculated by paired T tests and the p-values for each comparison are noted in the table The 16S rRNA percent identity between pairs was calculated based on aligned sequenced in Arb (Kumar et al. 2005). PSA-producer Closest non PSA-producer 16S rRNA % Identity PBMC IL-10 PBMC Tregs LPMC IL-10 LPMC Tregs Bacteroides fragilis Bacteroides ovatus 94 0.007 0.041 0.304 0.025 Bacteroides cellulosilyticus Bacteroides intestinalis 97.4 0.003 0.047 0.002 0.028 Bacteroides uniformis Bacteroides stercoris 91.1 0.063 0.009 0.619 0.260 Bacteroides fluxus Bacteroides stercoris 93 0.015 0.034 0.184 0.495 Parabacteroides distasonis Prevotella stercorea 84.4 0.002 0.089 0.611 0.339 Clostridium spiroforme Catenibacterium mitsuoki 92.1 <0.0001 0.003 0.002 0.225 Highlights Genomic screen identifies bacteria with ability to produce zwitterionic polysaccharides. Predicted bacteria display anti-inflammatory immune modulation in human cell assays. Putative ZPS-producer Bacteroides cellulosilyticus protected mice from colitis. ZPS-producing bacteria may have therapeutic potential. This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final citable form. Please note that during the production process errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain. Author Contributions Conceptualization, C.A.L. and B.E.P.; Methodology, C.P.N., M.E.R., K.L.A., C.B.C, C.A.L., and B.E.P.; Software, M.E.R., M.S., and C.A.L.; Formal Analysis, C.P.N., M.E.R., K.L.A., C.B.C., B.E.P., and C.A.L.; Investigation, C.P.N., K.L.A., C.B.C., J.D., N.N., P.J., and J.M.S.; Resources, M.D.M. and S.K.M.; Data Curation, M.E.R., M.S., and C.P.N.; Writing – Original Draft, C.P.N., M.E.R., C.B.C., B.E.P., and C.A.L.; Writing – Review & Editing, K.L.A., M.S., S.K.M; Visualization, C.P.N., M.E.R., K.L.A., C.B.C., B.E.P., and C.A.L.; Supervision, B.E.P. and C.A.L., Project Administration, B.E.P. and C.A.L.; Funding Acquisition, C.A.L., B.E.P. and C.B.C. 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PMC005xxxxxx/PMC5113738.txt
LICENSE: This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. 9706581 34240 Curr Protoc Neurosci Curr Protoc Neurosci Current protocols in neuroscience 1934-8584 1934-8576 27696360 5113738 10.1002/cpns.16 NIHMS812620 Article Automatic dendritic spine quantification from confocal data with Neurolucida 360 Dickstein Dara L. 123 Dickstein Daniel R. 12 Janssen William G. M. 12 Hof Patrick R. 123 Glaser Jack 4 Rodriguez Alfredo 4 O’Connor Nate 4 Angstman Paul 4 Tappan Susan J. 4 1 Fishberg Department of Neuroscience, Icahn School of Medicine at Mount Sinai, New York, NY 10029, USA 2 Friedman Brain Institute, Icahn School of Medicine at Mount Sinai, New York, NY 10029, USA 3 Computational Neurobiology and Imaging Center, Icahn School of Medicine at Mount Sinai, New York, NY 10029, USA 4 MBF Bioscience, Williston, VT 05495, USA Corresponding author: Susan Tappan, susan@mbfbioscience.com 4 9 2016 3 10 2016 3 10 2016 03 10 2017 77 1.27.11.27.21 This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. Determining the density and morphology of dendritic spines is of high biological significance given the role of spines in synaptic plasticity and in neurodegenerative and neuropsychiatric disorders. Precise quantification of spines in three dimensions (3D) is essential for understanding the structural determinants of normal and pathological neuronal function. However, this quantification has been restricted to time- and labor-intensive methods such as electron microscopy and manual counting, which have limited throughput and are impractical for studies of large samples. While there have been some automated software packages that quantify spine number, they are limited in terms of their characterization of spine structure. This unit presents methods for objective dendritic spine morphometric analysis by providing image acquisition parameters needed to ensure optimal data series for proper spine detection, characterization, and quantification with Neurolucida 360. These protocols will be a valuable reference for scientists working towards quantifying and characterizing spines. dendritic spines neurons confocal microscopy automated quantification Introduction Because of their capacity for plasticity and their role as the location of excitatory synapses, accurately characterizing the structure of dendritic spines is of profound biological significance. Spine morphology determines the strength, stability and function of excitatory synaptic connections that subserve the neuronal networks underlying cognitive function. Developmental, aging-, and disease-related structural changes in neurons and dendritic spines, and their functional consequences, remain poorly understood. Therefore, there is value in imaging and quantifying specific spine populations, types, densities, and distribution along neuronal dendrites across brain regions or cortical layers. It is also important to assess entire neurons or dendritic trees as it permits to assess tree complexity and dendritic branching, both of which may be altered in disease states. Optimally both spines and neurons should be examined at high resolution, but frequently a compromise is necessary for throughput. The necessity to analyze data sets accurately, efficiently, and in true 3D has been a major bottleneck in deriving reliable relationships between altered neuronal function and changes in spine morphology. In this chapter, we provide protocols for both imaging and analysis scenarios, starting with imaging dendritic segments (Basic protocol 1), followed by the protocols for complete spine analysis (Basic protocol 2), and full neuron imaging and analysis (Basic protocol 3 and 4). BASIC PROTOCOL 1 TITLE: IMAGING OF FLUORESCENTLY LABELED DENDRITIC SEGMENTS High-resolution confocal microscopy is used to visualize spines on dendritic segments or complete neurons. Prior to performing microscopy, a number of labeling techniques can be employed which may include GFP-viral transfection, iontophoretic injection of a fluorescent dye (cell loading), DiOlistic labeling, or viral expression. We have routinely used iontophoretic injection of Lucifer Yellow in our laboratory; however, the Alexa Fluor dyes have also been used because of larger variety of choices (Boyan and Liu, 2014; Ding et al., 2009; Knafo et al., 2009a; Knafo et al., 2009b; Merino-Serrais et al., 2011; Wallace and Bear, 2004). For cell loading, it is imperative to fill a neuron sufficiently to the distal tips of all apical and basal dendrites or up to 10 minutes depending on the experimental conditions. It is also important not to overfill a neuron to avoid dye leaking out of the cell or dye-coupling with other neurons which can lead to multiple “ghost” neurons being filled. Once neurons are labeled with the fluorescent marker of choice, the tissue can be taken to the microscope. A confocal microscope with objective lenses that have a low numerical aperture for low resolution and a high numerical aperture for high resolution should be used. Imaging parameters for the confocal microscope should be selected for the particular fluorophore used, animal tissue, and confocal microscope. It is important to note that the same imaging parameters must be used for the entire study. Materials Charged or gelatin subbed glass slides (Fisherbrand Microscope slides; Fisher Scientific) Glass coverslips (number 1.5; Sigma-Aldrich, St. Louis,MO) Imaging spacers (SecureSeal, Electron Microscopy Sciences, Hatfield, PA) or nail polish to seal coverslips to the slide. VectaShield mounting medium (Vector Laboratories, Burlingame, CA), or any other preferred anti-fade fluorescence mounting media. Labeled tissue Confocal microscope equipped with low and high numerical aperture objective lenses. Immersion media; choose an immersion media that matches the specifications of the high NA objective that is on your system. Examples of immersion media and their refractive index (RI) are oil (RI = 1.53–1.54), glycerol (RI = 1.47) and water (RI = 1.34). This and the lens choice should also be based on what medium the sample is mounted in (aqueous, etc.) for optimal refractive index matching and aberration-reduced imaging. Setting up the confocal microscope Optimize the confocal laser scanning system for the particular fluorophore by matching the laser line to the excitation peak of the fluorophore (e.g., Argon 458 nm line for Lucifer Yellow). Match the dichroic beam-splitter in front of the laser to the laser used. Select an emission filter to maximize the amount of collected photons. We recommend a long-pass image filter unless multiple fluorophores are used or there is background photon emission due to autofluorescence. Choose appropriate image resolution (e.g., 512 × 512) and bit depth (16 or 8 bit). Most confocal microscopes can image with at least 12-bits. Filled neurons with large, bright soma and fine processes could benefit for more intensity resolution (assuming the sensor itself has the dynamic range). Taking high-resolution images of dendritic segments or sections of cells Sample the dendritic segment in an unbiased manner. Sampling should be random (for example, do not choose the best-looking spines). Choose a segment based on brain region, type of cells, and the type of inputs into the cell you wish to obtain. Measurements can be taken on entire neurons (see below), at specific distances from the soma, or by branch orders. In practice, it is best to choose segments that can be captured in a single field-of-view without exceeding the working distance of the highest resolution objective that will be used. In addition, we recommend avoiding bifurcations, sampling from primary dendrites (due to variation in spine density compared to higher order branches), and sampling the first and last 10% of the dendrite. If the neuron has been previously traced (using MBF Bioscience’s Neurolucida live on a wide-field microscope, or Neurolucida 360 on previously acquired images), use Neurolucida 360 Explorer to display the reconstructed trace with 3D Sholl rings placed at specific distances superimposed on the neuron (Figure 1A) to determine where to image along the dendritic arbor. Alternatively, Zen Zeiss software can be used to capture a low-resolution 3D image montage (e.g., with 10× objective) of the complete neuron and select the desired segments from this image by using the ruler tool and measuring at the desired distance, such as 50 or 100 µm from center of the soma, or desired branch order (Figure 1B). Note that this method selects branches on the basis of 2D alignment, instead of 3D distance. Image the dendritic segment. Regardless of how you choose to sample segment, locate the neuron at low magnification (10×). Once the segment of interest is located, switch to a high numerical aperture, high magnification objective (63× or 100×), locate the segment of interest again, and place it in the center of the field of view. We recommend imaging dendritic segments at high magnification (63× or 100× with an additional digital zoom) to obtain the fine structural detail of each spine. Set gain and offset to acquire the optimal image. It is very important to avoid saturated pixels. If the dendrite is saturated when imaging dendrites and spines, the size and shape may appear altered. This can lead to some spines (especially those above and below the dendrite) not being detected or not being properly characterized. Moreover, saturated pixels will result in incorrect deconvolution outcomes as described in the next section. Essentially, do not strive to get the perfect publication picture with minimized background noise. Instead, get an image with some background noise to facilitate successful post-processing deconvolution. Set the gain so that there are relatively few saturated pixels in the dendritic portion of the image and relatively zero-intensity pixels in the background of the image. A special color palette can be used on most microscopes to visualize saturated and zero intensity pixels in distinctive color (commonly red for saturated pixels and blue for pixels at zero; Figure 2). Select the averaging number, frame direction, and other parameters; they must be maintained throughout the entire experiment. We generally use a line or frame average of 4, and a pixel dwell time of approximately 6 µm per pixel. Reduced scanning speed produce cleaner images, which can lead to more accurate reconstructions. Select a pinhole size at “1 airy unit.” It is important to resist opening the pinhole to obtain a brighter signal with less noise. Resolution along the Z (or optical) axis decreases with increasing pinhole size. Set the X and Y parameters to 0.05 µm and the z-interval to 0.1 µm to allow the most accurate imaging (other laboratories may use different scaling to achieve a cubic voxel (Golden et al., 2013; Hao et al., 2006; Rocher et al., 2010)). We tend to spatially oversample in XYZ given the small size of spine heads and necks. Larger pixel sizes may miss these structures, and thus important information regarding the number of thin spines and length of neck will be underestimated. In addition, deconvolution can also benefit from the added information provided by oversampling. Set the RI correction value. This is an essential step to minimize the immersion RI mismatch of your sample to reduce the spherical aberration. The best-case scenario is immersion media RI = sample RI. Acquire the Z stack of the segment. Make sure to capture enough planes above and below the dendritic segment so that the entire segment for analysis is contained within the image stack. This will ensure complete resolution of the top and bottom of your sample and proper quantification and characterization of spine heads. A common practice is to acquire at least 0.5 µm above and below the sample. SUPPORT PROTOCOL TITLE: POST-PROCESSING DECONVOLUTION Deconvolution is a computational method that attempts to correct the optical distortion inherent in all light microscopic imaging systems (Holmes, 1992). This distortion, or point spread function (PSF), blurs all light passing through a microscope on its way to the detector and is heavily influenced by several system features, including the numerical aperture (NA) of the objective lens, and the refractive index of the objective lens immersion medium, specimen, and specimen mounting medium (Gibson and Lanni, 1992; Nasse and Woehl, 2010). Deconvolution of confocal image stacks results in images with an improved signal-to-noise characteristic and more easily resolved structures. Specifically, for dendritic spines, deconvolution allows better discretization of adjacent spines and well as more accurate measurements and classification (Rodriguez et al., 2008). Proper deconvolution is necessary for images with dendritic spines to reduce the optical Z-smearing of dendrites and spines in the ZY projection. Incomplete deconvolution can distort individual spines and cause problems when quantifying spine densities (as individual spines many not be discernible) and classifying spines into specific types (Rodriguez et al., 2008). Such errors can significantly impact the final data. Materials AutoQuant Image Deconvolution Software (Media Cybernetics; other software programs for deconvolution include those from Scientific Volume Imaging, Zeiss, FIJI, Matlab, etc., refer to their operating instructions for use). Minimal Computer Specification: 2.8 GHz Intel® quad-core 64-bit processor (Core i7 series) or better; RAM: 16 GB memory or higher; OS: Windows® 7 (64-bit); Graphics Card: 2 GB and OpenGL® 4.2 or higher (e.g., NVIDIA GeForce® GTX series, http://www.mediacy.com/index.aspx?page=AutoQuantX3_sys_req). Confocal images (check with the deconvolution software to ensure that native file formats from the microscope imaging software are compatible). Deconvolving images captured with a confocal microscope Open images in AutoQuant and make sure that they are correctly imported. If licensed deconvolution software is not available, one can deconvolve using some freeware software such as ImageJ (http://imagej.net/Parallel_Iterative_Deconvolution) Microscope settings (e.g., objective, N.A., voxel size) should be automatically imported. Ensure that these setting are correct and manually enter where necessary. Enter the emission wavelength. Save the output file as a 16-bit .tif file. Record the image scaling so that it can be entered into Neurolucida 360 for analysis. BASIC PROTOCOL 2 TITLE: DENDRITIC SPINE MODELING AND RECONSTRUCTION WITH NEUROLUCIDA 360 Morphometric analysis of image data containing dendritic branches with spines Neurolucida 360 from MBF Bioscience is a software platform for reconstructing neuronal morphology by tracing, editing, and visualizing image data from light microscopes in 3D. It is based, in part, on the laboratory version of NeuronStudio, originally developed at the Icahn School of Medicine at Mount Sinai by Susan Wearne and her colleagues (Rodriguez et al., 2003; Rodriguez et al., 2008; Rodriguez et al., 2006; Wearne et al., 2005). Key components and algorithms implemented in NeuronStudio for process and dendritic spine reconstruction have been further developed in Neurolucida 360. Built with three algorithms for user-guided and automatic tracing, Neurolucida 360 accurately models neurons visualized with multiple methodologies and imaging techniques. Further, when the algorithms are operated in user-guided mode, the researcher can switch algorithms on-the-fly to adjust for differing conditions along a single dendrite. Automatic dendritic spine detection models the protrusions from dendrites using a mesh to capture the surface and a 5-point segment to model the spine backbone. This results in a more accurate representation of the spine length and shape for better spine classification as well as a mechanism to modify the branch assignment when spines and branches are densely packed. The companion software for analytics, Neurolucida 360 Explorer, calculates a large number of metrics, including volume, length, plane angle, surface area, and includes a notation of whether the spine was classified and how it was classified (manual or automatic). Materials Neurolucida 360 v2.7 or later (MBF Bioscience). Neurolucida 360 Explorer Computer requirements: 2.8 GHz Intel® quad-core; RAM: 16 GB memory or higher (32 GB needed as image size increases); OS: Windows® 7, 8 or 10 (64-bit); Graphics Card: AMD Radeon series GPU with 2GB graphics memory or more (http://www.mbfbioscience.com/neurolucida360). ◦ Performance can vary quite drastically depending on changes in hardware (for example, solid state drives (SSDs) will speed up loading/saving quite dramatically) Image data with known scaling either embedded within the file, or written in your laboratory notebook. File formats accepted by Neurolucida 360 include: tiff, lsm (Zeiss), czi (Zeiss), oib/oif (Olympus), VSI (Olympus), lif (Leica), jpx, ids/ics (Nikon), bigTIFF (btf, ImageJ/FIJI). Protocol steps Refer to the video “Automatic dendritic spine modeling with Neurolucida 360” (DendriticSpines_with_Neurolucida360.mp4) for demonstration of this protocol. Load the image stack into Neurolucida 360 by dragging and dropping the file into the main window. Critically important: confirm the image scaling parameters and immersion media for proper scaling. Adjust the values if inaccurate, or provide values if image scaling is not embedded in the image (e.g., .tiff images). Zoom in to the region of interest using the mouse scroll wheel. Alternatively use the pivot point icon to center the image. Click the Tree icon and select the user-guided tracing mode. In the drop-down menu select the most suitable algorithm for the image data loaded. If desired, select the “pan to window center” checkbox to have the image re-center as you trace. Trace the backbone of the dendritic branch. Left-click to place the initial start point, move the mouse cursor along the branch to see the path (represented by open circles) and estimated thickness provided by the tracing algorithm. Click to have the algorithm trace between points (control+Z will undo the last point). The size of the open circles provides a preview of the thickness of the dendritic branch. Ensure that large spines do not over-influence the thickness by adjusting the path of the proposed trace. To end the trace, right-click (Figure 4). Record the tracing algorithm in the laboratory notebook, indicating which algorithm(s) was (were) used for tracing. Note: if automatic tracing is used, record all relevant parameters in addition to the tracing algorithm in the laboratory notebook. Once traced, inspect the tracing to ensure that the dendritic branch is accurately modeled for thickness in all 3 dimensions. Edit points as necessary (Figure 5). To edit, click the Edit button. Select the point mode to visualize the trace points of the branch. Each point can be moved individually by clicking the point with the left mouse button, or move points as a group (control+click to select multiple points) to adjust the position (control+Z to undo the last change). The dendritic diameter can be modified at each point by adjusting the thickness slider or by typing in a new value. Model dendritic spines. Click the Spine button to select the Spine detection mode. Detect all, and inspect the results. This will help parametrize the following settings (Figure 6): Outer range – this value defines the maximum distance from the dendritic surface that is used to search for spines. Minimum height – this value defines the minimum distance from the dendritic surface for a surface protrusion to be considered a spine. It helps prevent false positives due to surface irregularities. Reduce this value if the spine base is too large. Minimum count – this value is used to exclude individual objects that are too small to be considered a spine. This can be useful when trying to prevent image noise from being detected as spines. Alternative: Use Filter image noise, an image pre-processing filter that can be used with non-deconvolved images. Adjust parameters until the spine modeling algorithm detects the spines as desired. Alternatively, click a spine in the image to detect it. Alternatively, detect spines on a single branch of a complex dendritic arbor by selecting “use click to detect all spines on branch.” It is important to use the same parameters throughout the study; do not choose parameters arbitrarily since this will introduce bias and may affect the data and interpretation. Record the detection parameters in the laboratory notebook (Figure 6). Edit dendritic spines. Use the Edit mode to adjust the detection by splitting and merging spines. Each detected object is displayed in a different color. You may toggle the visibility of all reconstructed objects by using the +/− tool bar button. This allows you to see the underlying image data to determine if adjacent meshes need to be combined to make one spine, or if multiple spines are encompassed by one mesh that needs to be split (Figure 7). Advanced editing: When detecting spines on multiple branches, make sure to confirm that the spines are properly assigned to the correct branch. To view and change the branch assignment, select the Points button. The spine backbone is displayed as a series of 5 points. Move the point of attachment to the new branch by selecting and dragging it to the new location. The spine will be re-detected and assigned to the specified branch (Figure 8). Save the data file. Perform morphometric analyses. Open the data file in the Neurolucida 360 companion program, Neurolucida 360 Explorer. From Neurolucida 360 Explorer’s main menu, select Branched Structure Analyses from the Analysis menu. Click the Spines tab and select reports available with spines, spine details, and dendrites. The Dendrite Spine report includes the total number (and type, if classified), spine density per micrometer of dendritic length. The spine details report includes the many metrics, including total extent (the measure of the shortest-path distance from the dendritic surface to the furthest voxel of the spine) and spine backbone length (the length of the spine from the furthest included voxel along the backbone to the insertion onto the dendritic branch.), head diameter, head:neck ratio. Note: other analyses may be of interest, depending on your scientific question. ALTERNATE PROTOCOL 2 TITLE: SPINE CLASSIFICATION Accurate and effective dendritic spine classification remains a fundamental challenge for the neuroimaging research community. Dendritic spine morphology is thought to be crucial in synaptic plasticity and strength due to its compartmentalization of biochemical and electrical signals. A dendritic spine is a micron-sized protrusion, comprised of a spine head, where the excitatory synapse is located, and a spine neck that connects the spine to the dendritic shaft. Spines come in multiple shapes and sizes, with the more common subclasses being thin, mushroom and stubby (Harris et al., 1992; Jones and Powell, 1969; Nimchinsky et al., 2002; Peters and Kaiserman-Abramof, 1970; Spacek and Hartmann, 1983). Digital representation of spines using light microscopy has traditionally relied on manual counting from a computer screen and is prone to subjective errors. Despite the recent introduction of semi-automated tracing methods (e.g., NeuronStudio, Vaa3D, and Imaris), the problem of detecting and characterizing spine shapes automatically, in 3D, remains unsolved. Automatic classification with Neurolucida 360 greatly reduces human subjectivity and intra-operator variability. Dendritic spines from different brain areas, developmental stages, pathological conditions, or species may require different classification settings. Neurolucida 360 permits simple adjustment of the classification settings, however it is important that the classification settings are chosen on the basis of empirical research and remain unchanged throughout the study. After automatic detection with Neurolucida 360, dendritic spines can be automatically classified with a simple one-button operation into one of the following types: stubby, mushroom, thin, or filopodia (Figure 9). Alternate complex types (e.g., double-headed) can be assigned manually after detection. Each spine type is color-coded for easy visualization, and can be interactively re-classified to a different canonical or complex type. By default, spine classification is assigned according to parameters determined by Rodriguez et al. (2008), which were empirically determined for mouse hippocampal neurons as the consensus from multiple experienced researchers. Default settings for detection and classification should be considered starting points and not mandates. Both detection and parameters and classification settings will be influenced by imaging methodology as well as neuron characteristics (Benavides-Piccione et al., 2002; Harris et al., 1992; Nimchinsky et al., 2002; Rodriguez et al., 2008). Report quantification parameters in your manuscripts so that others can interpret, replicate, and build upon your work. When selecting parameters based on previously published peer-reviewed papers, note that papers that use manual spine measurements are typically measuring spine head sizes in the lateral XY dimension only, which may not be directly comparable to true 3D detection and measurement. Materials Neurolucida 360 v2.7 or later (MBF Bioscience) Neurolucida 360 Explorer (MBF Bioscience) Computer requirements: 2.8 GHz Intel® quad-core; RAM: 16 GB memory or higher (32 GB or more needed as image size increases); OS: Windows® 7, 8 or 10 (64-bit); Graphics Card: AMD Radeon series GPU with 2GB graphics memory or more (http://www.mbfbioscience.com/neurolucida360). ◦ Performance can vary drastically depending on changes in hardware (for example, solid state drives (SSDs) will dramatically speed up loading/saving image files). Data file from Neurolucida 360 with modeled dendritic spines. Protocol steps Step annotations If desired, classify the dendritic spines. Click the Classify button to instantaneously re-color the detected spines according to spine class. By default, the spines are colored red (thin), blue (mushroom), green (stubby), and yellow (filopodia) according to the metrics determined by Rodriquez et al., (2008). Alternatively: different metrics can be entered to define the spine classes according to values specific to the species or condition under study. Click Settings to enter the values appropriate for your experimental paradigm. Record the classification parameters in your laboratory notebook (Figure 10). Save the data file. Open the data file in Neurolucida 360 Explorer and select the spine details report from Branched Structure Analysis. Spine type and assigned type will be included in the spine details report. BASIC PROTOCOL 3 IMAGING COMPLETE NEURONS In some instances, complete neuronal reconstructions from high-resolution images (e.g., 1024×1024) are desired in order to analyze both neuronal complexity and spine density on entire neurons. Depending on the microscope and software capabilities, the entire neuron can be captured using an automated tiling function, with an appropriate amount of overlap between tiles (e.g., 10%), along with the Z-step distance. If there is no such tiling option, individual stacks need to be separately acquired at high resolution and magnification, and then stitched together using specific software programs such as Neurolucida 360 or Volume Integration and Alignment System (VIAS; http://research.mssm.edu/cnic/tools-vias.html). As in automated tiling performed by the acquisition software, there must be an appropriate amount of overlap (e.g., 10%) to accurately stitch the segments together as a post-acquisition operation. Find the neuron of interest on the microscope using the lowest magnification objective (e.g., 10×). An initial rapid image acquisition of the overall Z-depth and area is needed to set up for the high-resolution high magnification acquisition that follows this step. In order to determine both the area and maximum Z-depth using rapid acquisition methods, first set the system up as follows: change image resolution to a lowered value (e.g., 256×256), change pixel dwell time to its maximum speed (fastest pixel dwell time), and open the pinhole aperture to its maximum size (largest optical slice thickness). Using these conditions allows for rapid determination of the neurons area and Z-depth. Start image acquisition and adjust for gain/offset signal/background). Since the Airy Unit aperture setting is opened to its maximum, the image adjustments are used to optimize observation of the entire neurons. If the neurons dendritic branches extend beyond the field of view, change the digital magnification from Z=1 to Z=0.9. Continue this process until you have the entire neuron in the field of view (e.g., Z=0.8, etc). Start the Z-step function by clicking on the Z-stack window. Using the Z-step function, determine the upper and lower limits to include both the material, along with an additional Z buffer distance both above and below the tissue. It is important to capture all of the neurons terminal dendritic branches. Record both the Z-depth and the total area of the neuron. If needed, a low-resolution 3D capture can be taken at this time. Otherwise, set up for high-resolution full neuron capture. Do not move the XY position. Change to an oil-immersion objective (e.g., 63× oil/N.A. 1.4 or 100× oil/N.A. 1.4). Change the pinhole value to 1 Airy Unit and optimize for offset/gain. Set and optimize the parameters for high-resolution image capture, (e.g., 1024×1024 resolution, increased pixel dwell time, frame average of 2). Open the image information tab and record the x/y pixel resolution (e.g., 0.5×0.5×0.5 µm). Disengage the Z-step function, and open tiling by clicking open the tiling function window. Open the function and setup (if available) for on-line stitching. Determine the number of overlapping (8–10%) tiles needed to acquire the entire neuron using the area value from the low-resolution image. Engage the Z-step function. Using the Z-depth values from the low-resolution image, set the interval for voxel dimensions (e.g., 0.5×0.5×0.5 µm). Turn “online stitching” on. Set image overlap at 8–12% (Figure 11). Ensure both tiling and Z-stack functions are engaged, and that all image parameters are set. Image the neuron. Alternatively, image Z-stacks can be saved independently and stitched using off-line programs (Figure 12). BASIC PROTOCOL 4 (optional) TITLE: NEURON RECONSTRUCTION USING NEUROLUCIDA 360 Instructions for reconstructing the entire neuronal structure follow the basic protocol for reconstructing the single dendritic segment described previously, with a few additional steps to model the soma and confirm the origin of the trees at the base of the soma. Materials Neurolucida 360 v2.7 or later (MBF Bioscience) Computer requirements: 2.8 GHz Intel® quad-core; RAM: 16 GB memory or higher (32 GB or more needed as image size increases); OS: Windows® 7, 8 or 10 (64-bit); Graphics Card: AMD Radeon series GPU with 2GB graphics memory or more (http://www.mbfbioscience.com/neurolucida360). ◦ Performance can vary drastically depending on changes in hardware (for example, solid state drives (SSDs) will dramatically speed up loading/saving image files) Image data with known scaling either embedded within the file, or written in your laboratory notebook. File formats accepted by Neurolucida 360 include: tiff, lsm (Zeiss), czi (Zeiss), oib/oif (Olympus), VSI (Olympus), lif (Leica), jpx, ids/ics (Nikon), bigTIFF (btf, ImageJ/FIJI). The width, height, number of focal planes, and depth of each pixel all contribute to the size of image files. Compression algorithms reduce the impact of image dimensions on the storage system. Though compression has no direct impact on the memory required to navigate an image, a good rule of thumb we have found is to have two times the on-disk file size in available memory when using Neurolucida 360. Protocol steps Load the image stack into Neurolucida 360 by dragging and dropping the stack into the main window. Critically important: confirm the image scaling parameters and immersion media for proper scaling. Correct the values if inaccurate, or provide values if image scaling is not embedded in the image (e.g., tiff images). Zoom in to the region of interest using the mouse scroll wheel. Alternatively use the pivot point icon to center the image. To reconstruct the soma. Click the Soma button to enter the Soma mode. Adjust the circular cursor using Control+scroll wheel to create a discrete search region for the algorithm. Click the soma in the image to model it. If the soma is rendered as a cube, reduce the sensitivity, clear the soma, and re-detect. Trace the backbone of the dendritic branch. Click the Tree button. Select the user-guided tracing mode. In the drop-down menu, select the most suitable algorithm for the image data loaded. Select the “pan to window center” checkbox to have the image re-center as you trace. Click to place the initial start point, move the mouse cursor along the branch to see the path and estimated thickness provided by the tracing algorithm. Click to have the algorithm trace between points (control+Z will undo the last point). Ensure that large spines do not over-influence the thickness by adjusting the path of the proposed trace. To end the trace, right-click (Figure 4). Continue until all branches are traced. When desired, switch algorithms while tracing to match the algorithm to the image data presented. This will reduce the amount of editing needed. Directional kernels works well for punctuate label at distal branches, Rayburst Crawl and Voxel Scooping are helpful in areas of high complexity. Record the tracing algorithm in the laboratory notebook. Once traced, inspect the tracing to ensure that the dendritic branch is accurately modeled for thickness in all 3 dimensions. Edit points as necessary (Figure 5). Click the Edit button and select the point mode to visualize the trace points of the branch. You can move points individually by clicking a point with the left mouse button, or move points as a group (control+click to select multiple points) to adjust the position (control+Z to undo the last change). You can modify thickness at each point by using the thickness slider or typing in a new value. Confirm the origin of the dendritic trees. While it is important for branch analyses to have each tree begin at the soma, it is not required to trace in any particular direction. Return to the Edit panel and select the point mode to visualize the trace points of the branch. Draw a marquee around the soma small enough so that it does not contain full dendritic trees, but large enough to contain all the points closest to the soma. Once selected, the option to set all endings to “origins” becomes available only if some trees are initiated at a different location. Select the button to reset all trees to have their origin closest to the soma (Figure 13). Save the data file. Proceed to Basic Protocol 2 to model dendritic spines. COMMENTARY Background Information Dendritic spine morphology has become a central focus in research in the fields of learning and memory, aging, and neurodegenerative diseases (for review see (Dickstein et al., 2007; Dickstein et al., 2013; Hara et al., 2012) as well as other neuropsychiatric disorders such as autism (Durand et al., 2012; Hung et al., 2008; Hutsler and Zhang, 2010; Phillips and Pozzo-Miller, 2015), schizophrenia (Hayashi-Takagi et al., 2011; Ramos-Miguel et al., 2015), and addiction (Maze et al., 2010; Selvas et al., 2015) as they are an integral component of excitatory synapses. Excitatory synapses comprise the majority of connections in the central nervous system and play a vital role in learning, memory, and cognition. Abnormal development or regulation of these synapses has been implicated in many neurodevelopmental, psychiatric, and neurodegenerative disorders. Most excitatory synapses occur at specialized postsynaptic compartments known as dendritic spines, which are tiny protrusions from the dendrites of neurons (Carlisle and Kennedy, 2005; Ethell and Pasquale, 2005; Harris and Stevens, 1989; Nimchinsky et al., 2002). Based on their morphology, spines can be divided into “canonical” types (stubby, mushroom, thin) and complex types (cup-shaped, multi-headed or branched, and filopodia) (Ethell and Pasquale, 2005; Harris et al., 1992; Kasai et al., 2010; Nimchinsky et al., 2002). The variable structure of spines determines the strength, stability, and function of the synaptic connections that facilitate the neuronal networks in the brain. Understanding the dynamics of spine morphology will help researchers to address how the brain is able to process a continuous flow of sensory information and simultaneously store and consolidate memories, sometimes for a lifetime. However, precise quantification of spines parameters has been restricted to time and labor-intensive electron microscopy, which has limited throughput and is impractical for large-scale studies. Accordingly, there is growing interest in automating quantitative analysis of dendritic spine morphology at the light microscopic level. Traditionally, performing manual spine analysis has been, and in many situations still is, the approach of choice. This usually involves tracing dendrites and marking spines from confocal stacks as they appear in the XY plane with software packages such as Neurolucida (Brennan et al., 2009; Hao et al., 2006; Knafo et al., 2009a; Knafo et al., 2009b), Imaris (Vecellio et al., 2000), Metamorph (Wallace and Bear, 2004) and Arivis. Such counting is then followed by manual measurements of spine heads and necks using programs such as Photoshop (Hao et al., 2006). These methods, in addition to being very time-consuming, introduce much error based on observer bias and high inter-observer variability (Donohue and Ascoli, 2011). Moreover, underestimating the number of spines is a concern in these conditions since spines, which project on the Z plane of the dendrite, are often overlooked as they are obscured by the brighter dendritic shafts. Automatic algorithmic analysis of spine morphology at the light microscopic level provides for higher throughput by substantially increasing analysis speed, accuracy, and reproducibility compared to existing manual methods. In addition, it provides for observer independence and for quantitative analyses that are virtually impossible without automation (such as spine volume, surface, head diameter, neck diameter, etc.). NeuronStudio was our first semi-automated quantitative software based on the Rayburst Sampling algorithm. This software was used in multiple studies from our group and others on various animal models, such as mouse, rat and monkey, and in many brain areas including the prefrontal cortex, hippocampus, and nucleus accumbens (Bloss et al., 2011; Golden et al., 2013; Price et al., 2014; Radley et al., 2008; Rocher et al., 2010; Shansky et al., 2009; Steele et al., 2014). While programs such as Imaris (Bitplane), Amira, and NeuronStudio may make quantification easier, there remain issues regarding accuracy, in particular in defining the spine head volume and surface area (Donohue and Ascoli, 2011; Dumitriu et al., 2011). Here, we introduce a new computational approach for detection and shape analysis of dendritic spines that incorporate the algorithms of our previous software (NeuronStudio; http://research.mssm.edu/cnic/tools-ns.html) as well as numerous improvements to make the software more broadly usable. Neurolucida 360 can read multichannel, high-bit depth images, with file sizes that exceed 50 GB. The algorithms have been tested with various labeling techniques on neurons and spines from different mammalian species (mouse, rat, monkey) and brain regions. It is important to note that successful data acquisition always relies on the quality of the materials used, and of the labeling of the cells analyzed, independent of the software performance. It is essential that imaging be performed in optimal conditions, such as these detailed in this unit. We believe that the new quantitative software package, Neurolucida 360, provides the neuroscience research community with the ability to perform higher throughput automated 3D quantitative light microscopy spine analysis under standardized conditions to accelerate the characterization of dendritic spines with greater objectivity and reliability. Critical Parameters Insufficient labeling of cell – the saying “garbage in, garbage out” holds true here. The best imaging systems and most sophisticated algorithms cannot correct for inconsistent or improper methodology at the bench. Image scaling – For the most accurate estimates of quantitative measures (e.g., volume, extent, etc.) the correct image resolution and axial step size must be provided. Troubleshooting Problem Possible Cause Solution Poor images (low signal-to-noise) Poor/incomplete labeling of cells Only use tissue with strong fluorescent signal and complete arborization Z-smear Identified cell beyond working distance of objective Image only cells that lie within 80 µm of the tissue surface Low Z resolution Microscope type (e.g., confocal, spinning disk, 2 photon), pinhole size too large, objective is not sufficient to resolve the needed features Adjust imaging parameters to obtain the optimal image Dendrites appear distorted Air bubble in mounting media Remount the tissue Dendrite appears to be moving across the screen during confocal imaging Insufficient seal of coverslip If you used spacers when mounting the tissue, make sure there are enough spacers used for the thickness of the tissue. Each spacer is 120 µm If you used nail polish, either there is not enough to create a proper seal or it has not hardened enough. It is always best to wait a couple of days between mounting the tissue and imaging Make sure the objective does not compress the coverslip. This happens when the working distance is mismatched with the tissue Dendrite appears to be compressed while imaging The segment is too deep in the tissue (>80 µm) Image segments more parallel to the tissue section Dendrites appear to be flat once reconstructed Objective unable to fully adjust to the Z-step depth Image segments more parallel to the tissue section Software does not target the image Loading tiff images into Neurolucida 360 without correct scaling Correct size of voxels Dendrites appear beaded Poor perfusion/fixation leads to poorly loaded neurons Cells are not usable for analysis Cell loses fluores- cence intensity during imaging Poor perfusion/fixation leads to poorly loaded neurons Cells are not usable for analysis Overlapping den- dritic segments from adjacent cells/same cell in same imaging plane Certain techniques (e.g., viral expression using GFP, DiOlistic, cells loaded too closely) In certain cases this is unavoidable (e.g., GFP). If dendritic segments are separated in the Z-plane they can still be used. Anticipated Results After reconstruction in 3D with Neurolucida 360, a number of metrics are calculated. Using the companion software, Neurolucida 360 Explorer, spine analyses include number, total extent, plane angle, volume, surface area, contact area, XYZ coordinates, head diameter and length, neck length, head diameter to neck diameter ratio, as well as notations of attachment, type, and method for classification. Several analyses are also available for dendrites, including but not limited to: Sholl analysis, branch order, dendritic length, number of branch points, spine density, spine density by type, convex hull, polar histogram. These analyses can be exported directly to Microsoft Excel. The data file can also be exported in a format suitable for third-party 3D rendering software (e.g., Blender), or further utilized with programming software (such as MatLab) to perform additional computations. Time Considerations Image acquisition Acquisitions of dendritic segments or full neurons are the most time-consuming aspects of dendritic spine analysis. The time it takes to image dendritic segments can vary depending on the depth of the segment, the Z-step, scan time, and averaging. It is important to avoid shortcuts when acquiring confocal images to preserve the fine structural details of dendritic spines. Moreover, it is important to remain unbiased when choosing dendritic segments to image (e.g., avoid only imaging shallow dendritic segments to save time). The time to image a complete neuron will vary depending on the type of data to be collected from the cell. For dendritic spine density only, neurons can be imaged at a lower magnification. For more detailed information about spines (e.g., spine type, and estimates of surface area, volume, and neck length), higher magnifications are needed but this will increase the imaging duration as more image stacks need to be obtained and stitched together. A complete neuron at 100× can take up to 10 hours to image, depending on neuron size, complexity, and microscope configuration. Dendritic spine analysis Automatic dendritic spine analysis with Neurolucida 360 requires less than 1 minute for branch reconstruction. Parameterization of spine detection can take 3–10 minutes, with automatic detection occurring in less than 1 minute. Spine classification is instantaneous. Manual editing of branch and dendritic spines will vary depending on the complexity of the image data. For short dendritic segments similar to those described here, editing typically requires less than 5 minutes. Complete neuronal reconstruction The time required for automatic montaging of a complete neuron from discrete, overlapping image stacks will depend on the number of stacks. Typically, image montaging requires approximately 5 minutes with a powerful computer. Once the image has been stitched, the reconstruction of the entire neuronal structure will also depend on the complexity. Typically, user-guided reconstruction can take between 10 minutes and 3 hours. Supplementary Material supplemental video The development of Neurolucida 360 was funded by a NIMH Lab-to-Marketplace grant (R44 MH093011) to Paul J. Angstman and Patrick R. Hof. Videos were created by Pasang Sherpa. We appreciate the thoughtful edits by our colleague, Dr. Sandrine Dincki. Figure 1 Neuronal map for determining the dendritic segments to image. (A) 3D reconstruction of a CA1 pyramidal neuron with superimposed Sholl rings created in Neurolucida Explorer (MBF Bioscience). (B) Low magnification confocal image of a CA1 pyramidal neuron with superimposed concentric circles at measured distances from the center of the cell body using the Zeiss Zen 780 software. Note: the neurons in this figure are not the same. Figure 2 Example of optimally set gain and offset of dendritic segments Images were acquired on a Zeiss 780 laser scanning confocal microscope equipped with the Zen software. (A) Image demonstrates an open Zen operating window for high-resolution dendritic Z-stack imaging. Note the longitudinal dendritic segment with the presence of spines. Within this image, the gain (red) and offset (blue) are properly set to acquire the optimal finalized Z-stack image. The gain is set so there are virtually no saturated pixels (red) present prior to imaging. The offset (blue) appears somewhat mottled within a black background. This adjusted level of background noise is necessary to facilitate successful post-processing deconvolution. All other parameters (frame resolution, averaging number, frame direction, etc) are set prior to imaging. The standard ZEN operating window is open, along with some of the more advanced functions needed for high-resolution 3D imaging (e.g., Z-stacks, focus, etc). (B) A vertical dendritic representation with incorrect offset (blue) settings. While there is no over saturation of the gain (red), the offset (blue) is too high (not enough blue demonstrated). The effect on image reconstruction would be altered. Figure 3 Deconvolution of dendritic segments XY and ZY maximal projections of a typical image stack before (A) and after (B) deconvolution with AutoDeblur. Compared to the raw data (A), the deconvolved data exhibit good relative intensity equalization of spines and dendrites, and significantly reduced Z-axis “stretching” from optical smear, in the ZY projection (B). Adapted from (Rodriguez et al., 2008).XY and ZY maximal projections of a typical image stack before (A) and after (B) deconvolution with AutoDeblur. Compared to the raw data (A), the deconvolved data exhibit good relative intensity equalization of spines and dendrites, and significantly reduced Z-axis “stretching” from optical smear, in the ZY projection (B). (Adapted from (Rodriguez et al., 2008). Figure 4 Tracing the backbone of the dendritic segment Dendritic segment seen here is from a mouse pyramidal CA1 neuron filled with Lucifer Yellow. A cursor (red +) is moved along the dendritic segment to see the path and estimated thickness provided by the tracing algorithm. The open yellow circles provide a preview of dendritic branch thickness. It is important to confirm that large spines do not over-influence the thickness of the dendrite. Scale bar = 2 µm. Figure 5 Inspection of dendritic segment thickness (A) Neurolucida 360 showing inspection and correction of points (green) from the dendritic branch (yellow) that were drawn off center by the large spine (arrow). (B) To edit, view the branch in point mode, select the point, and move it to the correct, centered location on the dendritic branch. Scale bar = 0.5 µm. Figure 6 Merging dendritic spines Individual spine detections can be merged to create a single model for a dendritic spine. Inspecting the underlying image data (A) can show that a single spine was inaccurately modeled as two discrete objects (B). To correct, select each spine object in edit mode and select merge. The software remodels the spine to include all voxels previously split between the two objects as a single spine (C). Scale bar = 1 µm. Figure 7 Dendritic spine detection parameters The software has four detection parameters to set the conditions for modeling dendritic spines. The parameters, which will vary based on the imaging settings and experimental paradigm being tested, should be chosen based on empirical data, and remain constant during the study. Do not choose parameters arbitrarily since this will introduce bias and may affect the data and interpretation. Figure 8 Representation of dendritic spines in Neurolucida 360 The dendritic spine is modeled with a mesh to represent the surface and volume of the spine (A). The spine backbone (B) is represented with five points. The most distal point in the backbone indicates the furthest voxel from the dendritic surface, the centroid of the spine head (green) is the second point, and the last point represents where the spine connects with the dendrite. The shape of the dendritic spine is more accurately modeled, leading to better metrics and more complex spine classes. Spines can be re-assigned to nearby branches by dragging the last point from the original dendrite location to the desired location on the alternate branch. Figure 9 Spine classification using default parameters Dendritic spines are first modeled on the basis of a number of detection parameters, including distance from dendritic surface and apparent size. After detection, spines are colored to differentiate each modeled spine in close proximity (A). If desired, the detected spines can be classified using classification parameters as established by Rodriguez et al., 2008 (B) or through custom specifications. It is important that the same detection parameters and classification settings (if chosen) are used for all images in the experimental study. Scale bar = 2 µm. Figure 10 Setting spine classification parameters Different metrics can be entered to define the spine classes according to values specific to the species or condition under study. Parameters should not be changed during the study, and should be chosen on the basis of empirical evidence. Figure 11 Complete neuron image montage of a hippocampal pyramidal neuron acquired after whole-cell recording A single image was created using Neurolucida 360 to montage multiple 3D images of a mouse hippocampal pyramidal neuron labeled with biocytin. Multiple 2-channel z-series images were collected with a Zeiss LSM 710 confocal microscope, mounted on an AxioImager Z2, with a 20× Plan-apochromat objective, and a 25 mW multi-wavelength (458/488/514) argon laser and a 20 mW 561 nm diode DPSS laser (Alexa-549 displayed here). Dr. Piskorowski provided the image data from an experiment performed by Vincent Robert and Ludivine Therreau in accordance with European guidelines for the care and use of laboratory animals at the Université Paris Descartes. Note: this neuron was not imaged at a resolution high enough for concurrent spine analysis. Scale bar = 100 µm. Figure 12 Complete neuron reconstruction created with Neurolucida 360 Using Neurolucida 360, the pyramidal cell shown in Figure 11 was reconstructed using user-guided tracing and soma modeling. Scale bar = 100 µm. Figure 13 Setting the origin of branches as the closest point to the soma While it is important for branch analyses to have each tree begin at the soma, it is not required to trace in any particular direction. Confirm the root of each tree in edit mode, by drawing a marquee around the soma small enough so that it does not contain full dendritic trees, but large enough to contain all the points closest to the soma. Once selected, the option to set all endings to “origins” becomes available only if some trees are initiated at a different location. Select the button to reset all trees to have their origin closest to the soma. Significance Statement Understanding the role of dendritic spines is an important area of neuroscience research. We introduce a methodology for performing morphometric dendritic spine analysis from 3D confocal images of dendritic segments. The protocol describes the process of selecting segments for analysis, confocal image acquisition guidelines, deconvolution, and analysis with Neurolucida 360. Neurolucida 360 improves the reliability and accuracy of spine morphometrics while providing an objective means to rapidly analyze spines in 3D. Quantitative neuron and dendritic spine analyses could accelerate the understanding of the relationship between brain structure and function under physiological and pathological conditions and thereby improve the development of novel treatment strategies for complex CNS diseases. KEY REFERENCE Drs. Dickstein and Tappan hosted a webinar on this topic based on a previous version of Neurolucida 360. The recorded version of the webinar is available for viewing at this link: https://youtu.be/HczuQjeNcR4 INTERNET RESOURCES Software described in the protocol is available from the following companies. Free versions or free trials are available from each vendor. Zen Black image acquisition software (Zeiss) http://www.zeiss.com/microscopy/en_us/products/microscope-software/zen-lite.html AutoQuant image deconvolution software (Media Cybernetics) http://www.mediacy.com/index.aspx?page=AutoQuant Neurolucida 360 automated neuron reconstruction software (MBF Bioscience) http://www.mbfbioscience.com/neurolucida360 VIDEOS Automatic dendritic spine modeling with Neurolucida 360 (DendriticSpines_with_Neurolucida360.mp4) This video demonstrates all steps in Neurolucida 360 for modeling dendritic spines on dendritic segments from loading the image data to classification. LITERATURE CITED Benavides-Piccione R Ballesteros-Yanez I DeFelipe J Yuste R Cortical area and species differences in dendritic spine morphology J Neurocytol 2002 31 337 346 12815251 Bloss EB Janssen WG Ohm DT Yuk FJ Wadsworth S Saardi KM McEwen BS Morrison JH Evidence for reduced experience-dependent dendritic spine plasticity in the aging prefrontal cortex J Neurosci 2011 31 7831 7839 21613496 Boyan G Liu Y Dye coupling and immunostaining of astrocyte-like glia following intracellular injection of fluorochromes in brain slices of the grasshopper, Schistocerca gregaria Methods Mol Biol 2014 1082 99 113 24048929 Brennan AR Yuan P Dickstein DL Rocher AB Hof PR Manji H Arnsten AF Protein kinase C activity is associated with prefrontal cortical decline in aging Neurobiol Aging 2009 30 782 792 17919783 Carlisle HJ Kennedy MB Spine architecture and synaptic plasticity Trends Neurosci 2005 28 182 187 15808352 Dickstein DL Kabaso D Rocher AB Luebke JI Wearne SL Hof PR Changes in the structural complexity of the aged brain Aging Cell 2007 6 275 284 17465981 Dickstein DL Weaver CM Luebke JI Hof PR Dendritic spine changes associated with normal aging Neuroscience 2013 251 21 32 23069756 Ding JB Takasaki KT Sabatini BL Supraresolution imaging in brain slices using stimulated-emission depletion two-photon laser scanning microscopy Neuron 2009 63 429 437 19709626 Donohue DE Ascoli GA Automated reconstruction of neuronal morphology: an overview Brain Res Rev 2011 67 94 102 21118703 Dumitriu D Rodriguez A Morrison JH High-throughput, detailed, cell-specific neuroanatomy of dendritic spines using microinjection and confocal microscopy Nat Protoc 2011 6 1391 1411 21886104 Durand CM Perroy J Loll F Perrais D Fagni L Bourgeron T Montcouquiol M Sans N SHANK3 mutations identified in autism lead to modification of dendritic spine morphology via an actin-dependent mechanism Mol Psychiatry 2012 17 71 84 21606927 Ethell IM Pasquale EB Molecular mechanisms of dendritic spine development and remodeling Prog Neurobiol 2005 75 161 205 15882774 Gibson SF Lanni F Experimental test of an analytical model of aberration in an oil-immersion objective lens used in three-dimensional light microscopy J Opt Soc Am A 1992 9 154 166 1738047 Golden SA Christoffel DJ Heshmati M Hodes GE Magida J Davis K Cahill ME Dias C Ribeiro E Ables JL Kennedy PJ Robison AJ Gonzalez-Maeso J Neve RL Turecki G Ghose S Tamminga CA Russo SJ Epigenetic regulation of RAC1 induces synaptic remodeling in stress disorders and depression Nat Med 2013 19 337 344 23416703 Hao J Rapp PR Leffler AE Leffler SR Janssen WG Lou W McKay H Roberts JA Wearne SL Hof PR Morrison JH Estrogen alters spine number and morphology in prefrontal cortex of aged female rhesus monkeys J Neurosci 2006 26 2571 2578 16510735 Hara Y Rapp PR Morrison JH Neuronal and morphological bases of cognitive decline in aged rhesus monkeys Age (Dordr) 2012 34 1051 1073 21710198 Harris KM Jensen FE Tsao B Three-dimensional structure of dendritic spines and synapses in rat hippocampus (CA1) at postnatal day 15 and adult ages: implications for the maturation of synaptic physiology and long-term potentiation J Neurosci 1992 12 2685 2705 1613552 Harris KM Stevens JK Dendritic spines of CA 1 pyramidal cells in the rat hippocampus: serial electron microscopy with reference to their biophysical characteristics J Neurosci 1989 9 2982 2997 2769375 Hayashi-Takagi A Barker PB Sawa A Readdressing synaptic pruning theory for schizophrenia: Combination of brain imaging and cell biology Commun Integr Biol 2011 4 211 212 21655443 Holmes TJ Blind deconvolution of quantum-limited incoherent imagery: maximum-likelihood approach J Opt Soc Am A 1992 9 1052 1061 1634965 Hung AY Futai K Sala C Valtschanoff JG Ryu J Woodworth MA Kidd FL Sung CC Miyakawa T Bear MF Weinberg RJ Sheng M Smaller dendritic spines, weaker synaptic transmission, but enhanced spatial learning in mice lacking Shank1 J Neurosci 2008 28 1697 1708 18272690 Hutsler JJ Zhang H Increased dendritic spine densities on cortical projection neurons in autism spectrum disorders Brain Res 2010 1309 83 94 19896929 Jones EG Powell TP Morphological variations in the dendritic spines of the neocortex J Cell Sci 1969 5 509 529 5362339 Kasai H Fukuda M Watanabe S Hayashi-Takagi A Noguchi J Structural dynamics of dendritic spines in memory and cognition Trends Neurosci 2010 33 121 129 20138375 Knafo S Alonso-Nanclares L Gonzalez-Soriano J Merino-Serrais P Fernaud-Espinosa I Ferrer I DeFelipe J Widespread changes in dendritic spines in a model of Alzheimer's disease Cereb Cortex 2009a 19 586 592 18632740 Knafo S Venero C Merino-Serrais P Fernaud-Espinosa I Gonzalez-Soriano J Ferrer I Santpere G DeFelipe J Morphological alterations to neurons of the amygdala and impaired fear conditioning in a transgenic mouse model of Alzheimer's disease J Pathol 2009b 219 41 51 19449368 Maze I Covington HE 3rd Dietz DM LaPlant Q Renthal W Russo SJ Mechanic M Mouzon E Neve RL Haggarty SJ Ren Y Sampath SC Hurd YL Greengard P Tarakhovsky A Schaefer A Nestler EJ Essential role of the histone methyltransferase G9a in cocaine-induced plasticity Science 2010 327 213 216 20056891 Merino-Serrais P Knafo S Alonso-Nanclares L Fernaud-Espinosa I DeFelipe J Layer-specific alterations to CA1 dendritic spines in a mouse model of Alzheimer's disease Hippocampus 2011 21 1037 1044 20848609 Nasse MJ Woehl JC Realistic modeling of the illumination point spread function in confocal scanning optical microscopy J Opt Soc Am A Opt Image Sci Vis 2010 27 295 302 20126241 Nimchinsky EA Sabatini BL Svoboda K Structure and function of dendritic spines Annu Rev Physiol 2002 64 313 353 11826272 Peters A Kaiserman-Abramof IR The small pyramidal neuron of the rat cerebral cortex. The perikaryon, dendrites and spines Am J Anat 1970 127 321 355 4985058 Phillips M Pozzo-Miller L Dendritic spine dysgenesis in autism related disorders Neurosci Lett 2015 601 30 40 25578949 Price KA Varghese M Sowa A Yuk F Brautigam H Ehrlich ME Dickstein DL Altered synaptic structure in the hippocampus in a mouse model of Alzheimer's disease with soluble amyloid-beta oligomers and no plaque pathology Mol Neurodegener 2014 9 41 25312309 Radley JJ Rocher AB Rodriguez A Ehlenberger DB Dammann M McEwen BS Morrison JH Wearne SL Hof PR Repeated stress alters dendritic spine morphology in the rat medial prefrontal cortex J Comp Neurol 2008 507 1141 1150 18157834 Ramos-Miguel A Barr AM Honer WG Spines, synapses, and schizophrenia Biol Psychiatry 2015 78 741 743 26542741 Rocher AB Crimins JL Amatrudo JM Kinson MS Todd-Brown MA Lewis J Luebke JI Structural and functional changes in tau mutant mice neurons are not linked to the presence of NFTs Exp Neurol 2010 223 385 393 19665462 Rodriguez A Ehlenberger D Kelliher K Einstein M Henderson SC Morrison JH Hof PR Wearne SL Automated reconstruction of three-dimensional neuronal morphology from laser scanning microscopy images Methods 2003 30 94 105 12695107 Rodriguez A Ehlenberger DB Dickstein DL Hof PR Wearne SL Automated three-dimensional detection and shape classification of dendritic spines from fluorescence microscopy images PLoS One 2008 3 e1997 18431482 Rodriguez A Ehlenberger DB Hof PR Wearne SL Rayburst sampling, an algorithm for automated three-dimensional shape analysis from laser scanning microscopy images Nat Protoc 2006 1 2152 2161 17487207 Selvas A Coria SM Kastanauskaite A Fernaud-Espinosa I DeFelipe J Ambrosio E Miguens M Rat-strain dependent changes of dendritic and spine morphology in the hippocampus after cocaine self-administration Addict Biol 2015 Shansky RM Hamo C Hof PR McEwen BS Morrison JH Stress-induced dendritic remodeling in the prefrontal cortex is circuit specific Cereb Cortex 2009 19 2479 2484 19193712 Spacek J Hartmann M Three-dimensional analysis of dendritic spines. 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PMC005xxxxxx/PMC5113819.txt
LICENSE: This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. 101284307 33047 Nat Protoc Nat Protoc Nature protocols 1754-2189 1750-2799 27560173 5113819 10.1038/nprot.2016.098 NIHMS802696 Article Generating kidney organoids from human pluripotent stem cells Takasato Minoru 12 Er Pei X 12 Chiu Han S 2 Little Melissa H 123 1 Murdoch Childrens Research Institute, Flemington Rd, Parkville, Melbourne, Victoria 3052, Australia. 2 Institute for Molecular Bioscience, The University of Queensland, St Lucia, Queensland 4072, Australia. 3 Department of Paediatrics, The University of Melbourne, Parkville, Victoria 3010, Australia. Correspondence should be addressed to MT (minoru.takasato@mcri.edu.au) or MHL (melissa.little@mcri.edu.au). 15 7 2016 18 8 2016 9 2016 01 3 2017 11 9 16811692 This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. The human kidney develops from four progenitor populations; nephron progenitors, ureteric epithelial progenitors, renal interstitial progenitors and endothelial progenitors; resulting in the formation of maximally 2 million nephrons. Until recently, methods differentiating human pluripotent stem cells (hPSCs) into either nephron progenitor or ureteric epithelial progenitor had been reported, consequently forming only nephrons or collecting ducts, respectively. Here, we detail a protocol that simultaneously induces all four progenitors to generate kidney organoids within which segmented nephrons are connected to collecting ducts and surrounded by renal interstitial cells and an endothelial network. As evidence of functional maturity, proximal tubules within organoids display megalin-mediated and cubilin-mediated endocytosis, and respond to a nephrotoxicant to undergo apoptosis. This protocol consists of 7 days of monolayer culture for intermediate mesoderm induction followed by 18 days of three-dimensional culture to facilitate self-organising renogenic events leading to organoid formation. Personnel experienced in culturing hPSCs are required to conduct this protocol. Kidney organoid Human pluripotent stem cell Directed differentiation INTRODUCTION Directed differentiation of human pluripotent stem cells (hPSCs), including human embryonic stem cells (hESCs) and human induced pluripotent stem cells (hiPSCs), is one of the most promising approaches to recreate organs for regenerative medicine. As human embryonic stem cells represent the epiblast stage of embryogenesis1, such directed differentiation is undertaken in a stepwise manner designed to recapitulate the developmental process from the epiblast to a specific tissue cell type. This methodology works more efficiently than single-step based methods2 and has been widely used to successfully induce various human tissues such as hematopoietic, cardiac, lung, pancreatic, hepatic, intestinal, cerebral and renal endpoints3–9. While a variety of cell types can be induced in vitro via stepwise differentiation protocols, three-dimensional structures are further required to recreate complex multicellular and functional organs. Generation of such three-dimensional mini-organs, called organoids10, from hPSCs has been reported in recent years, including organoids of brain, optic cup, stomach, intestine and liver11–15. In this protocol, we describe the methodology we have recently published for generating kidney organoids from hPSCs16. This expands on the brief step-by step protocol describing kidney organoid generation we previously uploaded to Protocol Exchange17. Development of the protocol The stepwise differentiation of hPSCs to kidney begins with the induction of the primitive streak which is the progenitor population for both endoderm and mesoderm. While the anterior primitive streak gives rise to the endoderm, the posterior primitive streak has potential to develop into the mesoderm, including the axial, paraxial, intermediate and lateral plate mesoderm18,19. The intermediate mesoderm differentiates to the ureteric epithelium and the metanephric mesenchyme, which are two key kidney progenitor populations subsequently undergoing a reciprocal interaction to form the kidney20. The ureteric epithelium develops into the collecting duct of the kidney and the ureter connecting the kidney with the bladder21. The metanephric mesenchyme gives rise to the cap mesenchyme which has been shown via lineage tracing to differentiate into all other epithelial cell types of the nephrons22. In addition to these two progenitors, endothelial and renal interstitium progenitors also arise from the intermediate mesoderm although it is not yet clear if these are subsets of the metanephric mesenchyme or distinct outcomes from intermediate mesoderm23. Primitive streak induction The first stage of differentiation in this protocol is induction of the posterior primitive streak. As previously investigated24,25, the posterior primitive streak can be differentiated from mouse embryonic stem cells by activating BMP, Nodal and canonical WNT signaling in two-dimensional culture methods. This method can also be successfully applied to hPSCs26. At this stage, we also culture cells under a monolayer culture condition to control anteroposterior cell fate of the primitive streak more precisely than in embryoid bodies,.Cell-autonomous effects and cell-cell interactions promote spontaneous differentiation within embryoid bodies whereas specific conditions of growth factors, concentration, and timing can be chosen in monolayer culture to produce more robust and uniform differentiation to a specific lineage. We previously demonstrated that the posterior primitive streak was induced by canonical WNT signalling or the combination of high and low doses of BMP4 and Activin A, respectively, in 2 days. In contrast, high Activin A with low BMP4 concentrations differentiated hPSCs into the anterior primitive streak9. Intermediate mesoderm induction The second stage is differentiation of posterior primitive streak cells into the intermediate mesoderm. Our previous study showed that hESC-derived posterior primitive streak spontaneously gives rise to the lateral plate mesoderm under APEL medium culture conditions9. As the intermediate mesoderm develops medial to the lateral plate mesoderm during embryogenesis, it is necessary to control the medial nature of the differentiation process using exogenous factors. Thus, again, we keep a monolayer culture condition to control M-L cell fate. There are only a few morphogens that have been proven to regulate M-L patterning in trunk mesoderm. These are BMP4 and FGF9. BMP4 is expressed in the lateral plate mesoderm and promotes lateral plate mesoderm development, whereas noggin (NOG)-mediated antagonism of BMP signaling is required for paraxial mesoderm while a low concentration of BMP4 induces the intermediate mesoderm27. FGF9 is specifically expressed in the intermediate mesoderm from the caudal through to the rostral trunk region28 and effectively directs the differentiation of hPSC-derived primitive streak to the intermediate mesoderm9. In our protocol, FGF9 is sufficient to specify the intermediate mesoderm without using NOG (Fig. 1). Kidney organoid The kidney functions as a three-dimensional organ, hence the culture conditions for differentiation needs to switch from monolayer to three-dimensional for the cells to form intact renal structures. While continued 2D culture may be adequate to induce specific target cell types, as we have previously demonstated9, the process of aggregation provides an increased cell density and volume within which cells are able to positionally reorganise with respect to each other. We chose day 7 of differentiation to transfer cells from a culture plate onto a transwell filter as an aggregate grown at an air-media interface. Day 7 represents the stage of intermediate mesoderm which is considered to include not only progenitors of ureteric epithelium and metanephric mesenchyme but also progenitors of renal interstitium and endothelium23. This methodology of aggregation culture has been previously optimized for ex vivo culture of mouse embryonic kidneys20 and reaggregations of mouse embryonic kidney cells29. A proper three-dimensional environment allows this kidney progenitor mixture to undergo self-renogenesis to form a kidney organoid. Alternative methods for generating kidney tissues Several studies in which kidney progenitors were induced from hPSCs have been reported. Xia et al. generated CK8-positive ureteric bud progenitor-like cells from hiPSCs and showed that those cells could integrate into ureteric epithelium in a re-aggregate with mouse embryonic kidney cells30. Other studies differentiated monolayer hPSCs into SIX2-positive metanephric mesenchyme that developed to renal tubules31–33. Taguchi and colleagues carefully investigated the developmental process of the metanephric mesenchyme commitment in mice and used that knowledge to obtain metanephric mesenchyme cells from mouse ESCs and human iPSCs based on an embryoid body culture method34. Their protocol focused on inducing the posterior intermediate mesoderm in order to obtain only the metanephric mesenchyme without collecting duct, renal interstitial and endothelial cells. These induced metanephric mesenchyme cells could differentiate into not only renal tubules but also glomeruli by being combined with mouse dorsal spinal cord, a source of WNT signals known to induce nephrogenesis from the metanephric mesenchyme. Their follow-up study showed that these nephrons could become vascularized by incorporating host blood vessels when transplanted under a mouse renal capsule35. Morizane et al. optimized the differentiation protocol using monolayer hPSCs to maximally induce the metanephric mesenchyme with 90% efficiency36. Hence, similarly to the above protocol, this did not induce collecting ducts and other non-epithelial renal cell types. The induced metanephric mesenchyme cells were also able to develop into nephron structures including renal tubules and glomeruli when stimulated by canonical WNT signaling using CHIR99021, a WNT agonist. Generated renal tubules revealed cell death in response to nephrotoxicants, cisplatin and gentamicin. Freedman et al. employed an approach in which they started the differentiation from hPSC-derived epiblast spheroids by sandwiching hPSCs between two layers of dilute Matrigel37. Epiblast spheroids underwent epithelial-to-mesenchymal transition (EMT) to form a monolayer, followed by a mesenchymal-to-epithelial transition (MET) when reaggregated, resulting in the formation of renal tubules, glomeruli and endothelial cells. While all these studies exclusively induced either the ureteric epithelium or metanephric mesenchyme and their derivative cell types, our unique methodology generates both cell types at the same time9. In addition, our optimized protocol enables the generation of kidney organoids that contain not only the collecting duct and nephrons but also renal interstitium and an endothelial network16. Within the organoids, individual nephrons segment into distal tubules, early loops of Henle, proximal tubules and glomeruli containing podocytes that elaborate foot processes and can undergo vascularization. Such segmented nephrons are connected with collecting ducts and surrounded by renal interstitium and an endothelial network. This protocol is clearly distinguished from others, as all anticipated cell types are simultaneously developed in the organoids. Applications and limitations of the protocol The differentiation of hPSCs using this protocol recapitulates the developmental process of human kidney organogenesis. Therefore, this protocol can be used as a platform for a variety of studies such as understanding human development, modeling renal disease and nephrotoxic drug screening. For instance, we have used this protocol to investigate mediolateral (M-L) and anteroposterior (A-P) patterning during trunk mesoderm development9,16,38. Also, as kidney organoids contain all components of the kidney, kidney organoids can be used for studying development of each distinct cell type present within the human kidney. Kidney organoids can be also utilized to test renal tubular damage in response to nephrotoxic drugs. We have confirmed proximal tubule specific cell death in kidney organoids by adding 5-20 μM cisplatin to the culture medium for 2 days16. This demonstrated the presence of proximal tubules which are sufficiently mature to appropriately respond to cisplatin, presumably as a result of the presence of basolateral organic cation transporter 2 (OCT2) and copper transporter 1 (CTR1) that mediate uptake of cisplatin into these tubular cells39,40. Hence, kidney organoids should be of value for the screening of pharmaceuticals. Modeling genetic renal disease using kidney organoids is another useful application. Kidney organoids using iPSCs that are generated from readily accessible somatic cells (e.g. skin fibroblasts or leucocytes) from inherited kidney disease patients may recapitulate features of these renal disorders in vitro37. Such disorders include autosomal dominant / recessive polycystic kidney disease (PKD), medullary cystic kidney (MCKD), nephronophthisis (NPHP), Alport syndrome and Bartter syndrome41. However, considering the likely variability in forming kidney organoids between iPSC lines, it will be desirable to compare mutant iPSC to a proper isogenic control iPSC line. This can be done using genome-editing tools like CRISPR/Cas9 system to artificially generate a specific genetic mutation in an iPSC line37. It may be further ideal to correct the mutation in patient-derived iPSCs, again using CRISPR/Cas9 technology, in order to generate an isogenic control iPSC line. This will only be possible in instances where the underlying mutation has been identified. Despite significant possibilities, the protocol has limitations and is likely to benefit from further protocol improvements. Kidney organoids at day 18 in three-dimensional culture, while transcriptionally similar to the first trimester human kidney16, have not matured to the level of the adult kidney. As consistent with a previous study of Cadherin expression in the developing mouse kidney42,43, we showed that more mature proximal tubules in kidney organoids expressed ECAD16. Cultured human proximal tubule cells also express ECAD44, however, some reports suggest that terminally differentiated proximal tubules in adult human kidney reveal no or very low ECAD expression45. This protocol has not generated kidney organoids that reach an adult stage of maturation. This is evident by a lack of expression of some mature renal tubule markers and capillary loops do not form in most glomeruli. Hence, it is highly likely that organoid-culture conditions may require further optimization to reach maturation. This immaturity may be problematic when studying disease modelling because most aforementioned inherited kidney diseases develop after birth, some not until adulthood. Also, it is important to note that the kidney organoid is not a kidney in miniature form from the anatomical and functional point of view. The mature kidney filters the blood to form a urinary filtrate before reclaiming the majority of this fluid to finally produce 1 to 1.5 litres of urine a day. During this process, the kidney also removes nitrogenous and toxic wastes, regulates electrolytes, maintains acid–base balance and regulates blood pressure, both via selective tubular reabsorbtion, secretion and hormone production. To recapitulate such diverse functions would require hPSC-derived kidney organoids not only to be reasonably big and comprised of mature cell types, but also develop a vascular access and a single exit path for urine, both of which are currently missing in current kidney organoids. Experimental Design hPSC culture for differentiation This protocol can be applied to both hESC and hiPSC. We have successfully applied the method described here to both hESCs (HES-3, commercially available) and hiPSCs (CRL1502 clone C32) that were authenticated and tested for mycoplasma infection46. Cells were maintained on mouse embryonic fibroblast (MEF) feeder layer and passaged using TrypLE Select. However, before the differentiation began, cells were adapted to feeder-free conditions with MEF-conditioned medium and Matrigel-coated culture dishes. This is to eliminate MEFs from the differentiation culture to avoid any unknown influence of MEFs to the differentiation. The differentiation begins with hPSC density at approximately 40-50% confluency (step 24), which can be obtained by plating about 15,000 cells / cm2 the day before (step 23). This plating cell number depends on the cell cycle speed and recovery rate, hence, should be adjusted for each hPSC line/clone. Intermediate mesoderm induction Although the intermediate mesoderm is the common origin of all known kidney progenitors, different regions in the intermediate mesoderm along with A-P axis contribute to distinct types of kidney progenitor. The anterior intermediate mesoderm (GATA3+) gives rise to the ureteric epithelium and the posterior intermediate mesoderm (HOXD11+) develops into the metanephric mesenchyme34,47,48. In an embryo, A-P patterning in the intermediate mesoderm is associated with primitive streak cell migration in which cells migrate from caudal to rostral during which they are exposed to canonical WNTs, followed by FGF9 and RA38. Hence, earlier migrating cells, which are exposed to WNTs for a shorter period of time, give rise to the anterior intermediate mesoderm, whereas cells migrating late are exposed to WNTs for longer and form the posterior intermediate mesoderm. In the protocol, hPSCs are treated with GSK-3 inhibitor, CHIR99021 to induce canonical WNT signaling (Fig. 1). This differentiates hPSCs into the posterior primitive streak that expresses T and MIXL1 with minimum expression of SOX17, a marker of the anterior primitive streak9. CHIR99021 is added to hPSC culture for 3 to 4 days, which is an intermediate duration designed to induce both the anterior and the posterior intermediate mesoderm at the same time (Fig. 1). In this protocol, we employ a CHIR99021 Conversely, a shorter (less than 3 days) or longer (more than 4 days) phase of CHIR99021 results in the predominant induction of the anterior or posterior intermediate mesoderm, respectively. The medium period of CHIR99021 may vary depending on hPSC clones and lines to use, therefore it needs to be optimized not to obtain one-sided intermediate mesoderm population of either GATA3+ or HOXD11+ at day 7 of the differentiation16. As generally seen in human hPSC differentiation, each hPSC line or clone has its own propensity to develop into a certain cell fate easier than to the other lineages49 and we experienced in the initial step of the differentiation that distinct clones respond to CHIR99021 differently. To generate kidney organoids reproducibly, it is recommended to test the protocol once with distinct hES/iPSC lines or distinct hiPSC clones even when derived from the same individual, and choose the most responsive lines or clones to use thereafter. Hence, an optimal CHIR99021 concentration and differentiation time period may be required for each line. e.g. a range of 2-5 days of CHIR99021 period first, then concentrations between 6 to 10 μM CHIR99021 if necessary. Kidney organoid formation The kidney progenitor aggregate includes the ureteric epithelium and the metanephric mesenchyme, hence their reciprocal interaction spontaneously initiates nephrogenesis. However, to maximize nephron formation, the protocol stimulates the organoids with a high concentration CHIR99021 for 1 hour. After the CHIR99021 pulse, the organoids should be supplemented with FGF9 to maximize the development of nephrons. We found 5 additional days of FGF9 supplementation was sufficient to obtain maximal nephrogenesis. Subsequently, the organoids are cultured in growth factor-free APEL medium50 for further self-organization (Fig. 1). The resulting organoids are regarded as successful based upon the presence of appropriately segmented nephrons and surrounding stromal and endothelial cell populations. MATERIALS REAGENT Human embryonic stem cells. We have used HES-3 (Wicell Research Institute Inc, cat. no. ES03) ! CAUTION Experiments using hPSCs must conform to all relevant governmental and institutional regulations relating to human ethics, biosafety and genetic modification This work was approved by the MCRI Institutional Biosafety Committee (212-2014PC2).It is recommended to check regularly to ensure cells are chromosomally stable and are not infected with mycoplasma. Human induced pluripotent stem cells. We have used CRL1502 clone C32 (gifted from Dr. Ernst Wolvetang, The University of Queensland, Australia) ! CAUTION Experiments using hPSCs must conform to all relevant governmental and institutional regulations relating to human ethics, biosafety and genetic modification. This work was approved by the Royal Childrens Hospital human ethics committee (HREC/14/QRBW/34; HREC/15/QRCH/126) and the MCRI Institutional Biosafety Committee (212-2014PC2). It is recommended to check regularly to ensure cells are chromosomally stable and are not infected with mycoplasma. 2-Mercaptoethanol (55 mM) (Thermo Fisher Scientific, cat. no. 21985-023) Antibiotic-Antimycotic (Thermo Fisher Scientific, cat. no. 15240-062) bFGF (Merck, cat. no. GF003-AF) BSA (Sigma Aldrich, cat. no. A3311-10G) CHIR99021 (R&D, cat. no. 4423/10) DMEM high glucose (Thermo Fisher Scientific, cat. no. 11995-073) DMEM/F-12 (Thermo Fisher Scientific, cat. no. 11320-082) DMSO (Sigma Aldrich, cat. no. D5879) DTT, 100 mM (Promega, cat. no. P1171) Dulbecco's phosphate-buffered saline (DPBS) (Thermo Fisher Scientific, cat. no. 14190-144) FGF9 (R&D, cat. no. 273-F9-025) Foetal Bovine Serum (FBS) (Interpath Services, cat. no. SFBSF) Gelatin (Sigma Aldrich, cat. no. G9391) GlutaMAX Supplement (Thermo Fisher Scientific, cat. no. 35050-061) Glycerol (Sigma Aldrich, cat. no. G9012-500ML) Heparin (Sigma Aldrich, cat. no. H4784-250MG) hESC-qualified Matrigel, LDEV-Free (Corning, cat. no. 354277) Knockout Serum Replacement (Thermo Fisher Scientific, cat. no. 10828-028) Non-Essential Amino Acids (Thermo Fisher Scientific, cat. no. 11140-050) Penicillin/Streptomycin (Thermo Fisher Scientific, cat. no. 15070-063) Recombinant human serum albumin, 10% (wt/vol) (Novozymes, 230-005) STEMdiff APEL Medium (Stem Cell Technologies, cat. no. 5210) TrypLE Select (Thermo Fisher Scientific, cat. no. 12563-029) Trypsin EDTA, 0.05% (Thermo Fisher Scientific, cat. no. 25300-054) Paraformaldehyde (Sigma-Aldrich, cat. no. 158127) Triton X-100 (TritonX) (Sigma-Aldrich, cat. no. T9284-500ML) Donkey serum (Merck Millipore, cat. no. S30-100ML) DAPI (6-Diamidino-2-Phenylindole Dihydrochloride) (Thermo Fisher Scientific, cat. no. D1306) Appropriate antibodies to detect proteins of interest (see Table 1 for primary antibodies we have successfully used). EQUIPMENT 175 cm2 tissue culture flask (Nunc, cat. no. 159910) 25 cm2 tissue culture flask (Nunc, cat. no. 156367) 6-well transwell cell culture plate, 0.4 μm pore polyester membrane (Corning, cat no. 3450) Benchtop centrifuge (Thermo Scientific, Heraeus Pico 17) Biological safety cabinet (LAF Technologies, TOP-SAFE 1.2) CO2 incubators (Thermo Scientific, Heracell 150i) Conical tubes, 15 ml (Corning, cat. no. 352096) Conical tubes, 50 ml (Corning, cat. no. 352070) Freezing container (Nalgene, Mr. Frosty) Glass-Bottom Dish, 35mm (Mattek, cat. no. P35G-0-14-C) Inverted contrasting tissue culture microscope (Nikon, TS100) Laser confocal microscope (Zeiss, LSM780) Media storage bottle, 500 ml (Corning, cat. no. 430282) Pipetboy (Integra Biosciences, PIPETBOY pro) Pipettes (Gilson, P10, P200 and P1000 PIPETMAN Classic) Serological pipettes, 10 ml (Corning, cat. no. 357551) Stericup 0.22 μm filter unit (Merck Millipore, cat. no. SCGPU05RE) Sterile filter pipette tips (1000, 200, wide bore 200 and 10 μl; Molecular BioProducts, cat. nos. 3581, 3551, 3531 and 3501, respectively) Sterile microcentrifuge tube, 1.5 ml (Eppendorf, cat. no. 3810X) Swing-out rotor centrifuge (Eppendorf, Centrifuge 5702) Syringe-driven 0.22 μm filter unit (Merck Millipore, cat. no. SLMP025SS) Ultrapure water generation system (Sartorius, arium pro) Water bath, 37 °C (Thermoline, TWB-24D) REAGENT SETUP Matrigel-coated 25 cm2 tissue culture flask To prepare Matrigel-coated 25 cm2 tissue culture flask, add 30 μl of hESC-qualified Matrigel into a 15 ml tube containing 3 ml of chilled DMEM/F-12. Mix it well and transfer it into a 25 cm2 tissue culture flask. Keep the flask at room temperature, 15 to 25 °C, for at least 30 min to allow Matrigel to coat the surface. Use the flask within a day. CRITICAL STEP Handle Matrigel on ice as it solidifies when warmed over 16 °C. P200 pipette tips should be also pre-chilled before use. bFGF (10 μg ml−1) Centrifuge the tube briefly before opening. Reconstitute to 10 μg ml−1 in a filtered solution of 0.5% (wt/vol) BSA, 1 mM DTT and 10% (vol/vol) glycerol in DPBS. Aliquot it into appropriate amounts and store them at −80°C for up to 6 months. bFGF can be stored at 4 °C for up to 2 weeks once it is thawed. FGF9 (100 μg ml−1) Centrifuge the tube briefly before opening. Reconstitute to 100 μg/ml in filtered DPBS containing 0.1% (wt/vol) human serum albumin. Aliquot it into appropriate amounts and store them at −80°C for up to 6 months. FGF9 can be stored at 4 °C for up to 2 weeks once it is thawed. Heparin solution (1 mg ml−1) Reconstitute to 1 mg ml−1 in ultrapure water and filter sterilize it through a polyethersulfone (PES) 0.22 μm syringe-driven filter unit. Heparin solution can be stored at 4 °C for more than 12 months. CHIR99021 (10 mM) Centrifuge the tube briefly before opening. Reconstitute 10 mg of CHIR99021 into 2.149 ml of DMSO to make 10 mM stock. Aliquot it into appropriate amounts and store them at −20°C. Gelatin solution (0.1%, wt/vol) For 500 ml of 0.1% gelatin solution, dissolve 0.5 g of gelatin in 500 ml of ultrapure water or DPBS and autoclave it. The solution can be stored at 4 °C for up to 3 months. Mouse Embryonic Fibroblast (MEF) culture medium For preparing 500 ml of MEF culture medium, combine 442.5 ml of DMEM high glucose, 50 ml of foetal bovine serum, 5 ml of GlutaMAX-1 and 2.5 ml of Penicillin/Streptomycin. Filter sterilize the medium through a polyethersulfone (PES) 0.22 μm vacuum-driven filter unit and store it at 4 °C for up to 2 weeks. hESC medium For preparing 500 ml of hESC medium, combine 386.5 ml of DMEM/F-12, 100 ml of Knockout serum replacement, 5 ml of GlutaMAX-1, 5 ml of Non-Essential Amino Acids, 2.5 ml of Penicillin/Streptomycin and 1 ml of 2-Mercaptoethanol (55 mM). Filter sterilize media through a polyethersulfone (PES) 0.22 μm vacuum-driven filter unit and store it at 4 °C for up to 2 weeks. To ensure bFGF is fresh, only supplement the medium with 10 ng ml−1 bFGF just before use for hPSC maintenance. MEF-conditioned hESC medium Seed 1 × 107 mitotically inactivated MEFs onto a 175 cm2 tissue culture flask containing 40 ml of MEF culture medium. Next day, change the culture medium to 40 ml of hESC medium without bFGF. After overnight culture, collect the conditioned medium into a 500 ml bottle and store it at 4 °C. Feed MEFs again with 40 ml of fresh hESC medium. Repeat this cycle another 6 times to pool 280 ml of the conditioned medium in total. Filter sterilize the medium through a polyethersulfone (PES) 0.22 μm vacuum-driven filter unit and aliquot it into 50 ml tubes. Store tubes at −20°C for up to 6 months. MEF-conditioned hESC medium can be stored at 4 °C for up to 2 weeks once it is thawed. To ensure bFGF is fresh, only supplement the medium with 10 ng ml−1 bFGF just before use for hPSC maintenance. APEL medium Once a bottle of APEL (100 ml volume) is opened, add 0.5-1 ml of Antibiotic-Antimycotic and store it at 4 °C for up to 2 weeks. Frozen stock of human pluripotent stem cells (hPSCs) For expanding hPSCs before cryopreserving them, cells are cultured in hESC medium supplemented with 10 ng ml−1 bFGF on mitotically inactivated MEF feeder layer by a single-cell culture method in which cells are passaged using TrypLE Select, as described in procedure steps 1-9. Once hPSCs reach the desired number, harvest cells using TrypLE Select, centrifuge (×400g for 3 min) and resuspend them in 10% DMSO / 90% FBS. Split cell-suspension into cryo-vials for 1 ml per vial. Typically, hPSCs of 100% confluent in a 75 cm2 tissue culture flask are split into 9 cryo-vials, so that each cryo-vial contains 1.5-2.0 × 106 cells. Freeze vials in a freezing container at −80 °C overnight and subsequently store them in liquid nitrogen. CRITICAL We have experienced a huge variability in differentiation success rate between experiments when cells were obtained from a continuously maintained cell culture pool. To minimize this variation, hPSCs should be thawed one by one from a cryopreserved stock for each experiment. 2% (wt/vol) paraformaldehyde (100 ml) Add 2 g of PFA and 10 μl of 10 N NaOH to 80 ml of DPBS at 60 °C and mix it until the powder dissolves. Adjust the final volume up to 100 ml by adding DPBS. Aliquot it into appropriate amounts and store them at −20 °C for up to one month. ! CAUTION Paraformaldehyde is toxic and must be handled inside a fume hood with masks and goggles. Blocking buffer (50 ml) Dissolve 5 ml of donkey serum and 30 μl of TritonX in 45 ml of PBST. Aliquot it into appropriate amounts. Blocking buffer can be stored at −20 °C for up to one year. PROCEDURE MEF feeder seeding TIMING 2 h 1. Coat a 25 cm2 tissue culture flask with 3ml of 0.1% gelatin solution. Incubate the flask in a 37 °C CO2 incubator for 1h. 2. Prepare 10 ml of prewarmed MEF culture medium in a 15 ml conical tube. 3. Thaw a frozen vial of mitotically inactivated mouse embryonic fibroblasts (MEFs) in 37 °C water bath until a small ice pellet remains. Transfer MEFs into a 15 ml conical tube containing prewarmed MEF culture medium in a drop wise manner and centrifuge at ×400g for 3 min. 4. Remove supernatant and resuspend MEFs in MEF culture medium. Count cell number using a hemocytometer. Make cell-suspension of 3 × 105 cells in 5 ml of MEF culture medium. Remove gelatin and seed cells onto a gelatin coated 25 cm2 tissue culture flask to obtain the density at 12 × 103 cells / cm2 and incubate it overnight in a 37 °C CO2 incubator. Human PSC thawing TIMING 30 min 5. Prepare 10 ml of prewarmed hESC medium in a 15 ml conical tube. 6. Thaw a frozen vial of hPSC containing 1.5-2.0 × 106 cells in 37 °C water bath until a small ice pellet remains. Transfer hPSCs into a 15 ml conical tube containing prewarmed DMEM/F-12 in a drop wise manner and centrifuge at ×400g for 3 min. 7. Remove supernatant and resuspend cells in 5 ml of hESC medium supplemented with 10 ng ml−1 bFGF. 8. Remove MEF culture medium from the flask containing mitotically inactivated MEFs and plate above hPSCs suspension. Incubate it overnight in a 37 °C CO2 incubator. Growing hPSCs on MEF feeder layer TIMING 4-5 d 9. Change 5 ml of hESC medium supplemented with 10 ng ml−1 bFGF daily for 4-5 days. CRITICAL STEP For optimal results, cells should be approximately 80-100% confluent after 4-5 days culture. If cells do not reach this confluency, allow them to grow for another day. ? TROUBLESHOOTING Growing hPSCs on Matrigel TIMING 2 d 10. Prepare Matrigel-coated 25 cm2 tissue culture flask. 11. To passage hPSCs onto Matrigel, wash hPSCs on MEF feeder layer in 25 cm2 tissue culture flask with 3 ml DPBS twice. Aspirate DPBS. 12. Add 1 ml of TrypLE Select to cells and incubate the flask at 37 °C for 3 min. 13. Pipette 11 ml of DMEM/F-12 to cells, mix and ensure cells have lifted off from the plastic surface. CRITICAL STEP Pipette cells no more than twice as hPSCs are very sensitive. 14. Collect 4 ml of cell suspension in a 15 ml tube to obtain a 1:3 split ratio and centrifuge it at ×400g for 3 min. Alternatively, a 1:2 split ratio can be chosen to achieve 70-100 % confluency at step 17. 15. Remove supernatant and add 5 ml of MEF-conditioned hESC medium supplemented with 10 ng ml−1 bFGF to cells. Mix it gently. 16. Aspirate Matrigel-containing DMEM/F-12 from a prepared Matrigel-coated 25 cm2 tissue culture flask and seed cells from step 15. Culture them in a 37 °C CO2 incubator for 2 days with daily changing MEF-conditioned hESC medium supplemented with 10 ng ml−1 bFGF. Plating hPSCs for differentiation TIMING 1 h 17. Wash hPSCs on Matrigel in 25 cm2 tissue culture flask with 3 ml of DPBS twice. Aspirate DPBS. 18. Add 1 ml of TrypLE Select to cells and incubate at 37 °C for 3 min. 19. Pipette 10 ml of DMEM/F-12 to cells, mix and ensure cells have lifted off from the plastic surface. CRITICAL STEP Do not pipette cells more than twice as hPSCs are very sensitive. 20. Collect cell suspension into 15 ml tube. Count cell number using a hemocytometer. 21. Calculate cell suspension volume to achieve 375,000 cells. 22. Aliquot cells into a 15 ml tube. Centrifuge the tube at ×400g for 3 min. 23. Remove supernatant and resuspend cells in 4 ml of MEF-conditioned hESC medium supplemented with 10 ng ml−1 bFGF. Seed cells onto a prepared Matrigel-coated 25 cm2 tissue culture flask to obtain the density at 15 × 103 cells / cm2. Culture them overnight in a 37 °C CO2 incubator. Inducing the intermediate mesoderm TIMING 7 d 24. Aspirate MEF-conditioned hESC medium from the 25 cm2 tissue culture flask. CRITICAL STEP Cells should reach to 40-50% confluent on this day. If not, adjust cell number of plating at Step 21. 25. Add 4 ml of APEL medium containing 8 μM CHIR99021 to hPSCs. 26. Culture them in a 37 °C CO2 incubator for 2-5 days, refreshing APEL medium containing 8 μM CHIR99021 every 2 days. CRITICAL STEP Duration of CHIR99021 determines the ratio of collecting duct/nephron in the organoid. Shorter periods of CHIR99021 phase induce more anterior intermediate mesoderm whereas a longer periods results in the more posterior part. To obtain both compartments, 3 or 4 days of CHIR99021 is recommended. ? TROUBLESHOOTING 27. After CHIR99021 phase, change culture medium to 8 ml of APEL medium supplemented with 200 ng ml−1 FGF9 and 1 μg ml−1 Heparin. CRITICAL STEP A shortage of FGF9 concentration and/or media volume causes an inefficient induction of the intermediate mesoderm. 28. Culture them in a 37 °C CO2 incubator, refreshing medium every 2 days until day 7 of the differentiation counting step 24 as day 0 this includes both CHIR99021 phase and FGF9 phase Forming aggregates for developing kidney organoids TIMING 11-18 d 29. Aspirate the culturing medium and wash with 3 ml of DPBS. Aspirate DPBS. 30. Add 1 ml of trypsin EDTA (0.05%) to cells and incubate them at 37 °C for 3 min. 31. Monitor under the microscope to make sure all cells have lifted from the surface after 2 min. If the cells are still attached to the surface, gently pipette the cells with trypsin and place back into the incubator for further 1 min. 32. Transfer cell suspension to a 15 ml tube containing 9 ml of MEF culture medium to neutralize trypsin. Centrifuge the tube at ×400g for 3 min. 33. Aspirate the supernatant and resuspend the cells with 3 ml of APEL medium. 34. Take out 10 μl of cell suspension and perform a cell count with a hemocytometer. 35. Each organoid will have roughly 5 × 105 cells. Aliquot the required amount of cell suspension into a 1.5 ml microcentrifuge tube. Centrifuge the tube at ×400g for 2 min to make a cell pellet. 36. Aliquot 1.2 ml of APEL containing 5 μM CHIR99021 into a 6-well transwell cell culture plate. The transwell filter attaches on the surface of the medium. 37. Pick a pellet up by using a P1000 or P200 wide bore tip. ? TROUBLESHOOTING 38. Carefully place pellets onto the 6-well transwell filter with minimal APEL medium carry over. Incubate pellets at 37 °C for 1 h. 39. After 1 h incubation, remove the medium of APEL containing 5 μM CHIR99021, and use 1.2 ml of APEL medium supplemented with 200 ng ml−1 FGF9 and 1 μg ml−1 Heparin. 40. Culture pellets for 5 days, refreshing FGF9 and Heparin-containing APEL medium every two days. ? TROUBLESHOOTING 41. After 5 days, change the culture medium to APEL medium without FGF9 and Heparin supplemented. 42. Culture the organoids for further 6 to 13 days, refreshing APEL medium every two days. If you wish to proceed to whole mount immunofluorescence, proceed to the next section. Whole mount immunofluorescence TIMING 3 d 43. After 18 days of organoid culture, if desired, fix the pellets in the transwell cell culture plate with 2% (wt/vol) paraformaldehyde at 4 °C for 20 minutes. 44. Remove the paraformaldehyde and wash three times with DPBS. PAUSE POINT Once fixed and washed, organoids can be stored at 4 °C for several months before immunofluorescence staining. 45. Aliquot around 150 μl of blocking buffer (10% donkey serum / 0.3% TritonX / DPBS) into the MatTek Glass Bottom Dishes. 46. Carefully cut the organoids off the filter and submerge the filter into the blocking buffer. 47. Block the organoids at room temperature for 2-3 h, gently keep shaking the dish using a rocker during incubation. 48. Prepare primary antibodies of choice in blocking buffer (0.3% TritonX / 10% Donkey serum / DPBS) with appropriate dilutions (Table 1). 49. Aspirate the blocking buffer off the MatTek dish, and aliquot 150 μl of blocking buffer containing primary antibodies into the MatTek dish. 50. Incubate the organoids with primary antibody solution at 4 °C over-night. CRITICAL STEP Make sure the organoid is completely submerged into the solution. Preferably, gently keep shaking the dish using a rocker during incubation. 51. Aspirate the primary antibody solution off the dish and wash with PBTX (0.3% TritonX / DPBS) for 6 times, 10 minutes each with gentle shaking. 52. Prepare secondary antibodies (1:400 dilution) of choice in PBTX. 53. Aspirate PBTX off the MatTek dish, and aliquot 150 μl of PBTX containing secondary antibodies into the MatTek dish. 54. Incubate organoids in secondary antibody solution at 4 °C over-night. 55. Remove secondary antibody solution and incubate with DAPI (1:1000 dilution) in DPBS for 3 h. 56. Wash organoids with DPBS for 10 min, 3 times. 57. Image organoids using a laser confocal microscope. ? TROUBLESHOOTING Troubleshooting advice can be found in Table 2. TIMING Steps 1-4, MEF feeder seeding: 2 h (Begin 9 days before hPSC differentiation at step 24) Steps 5-8, Human PSC thawing: 30 min Step 9, Growing hPSCs on MEF feeder layer: 4-5 d Steps 10-16, Growing hPSCs on Matrigel: 2 d Steps 17-23, Plating hPSCs for differentiation: 1 h Steps 24-28, Inducing the intermediate mesoderm: 7 d (Day 0 to 7) Steps 29-42, Forming aggregates for developing kidney organoids: 11-18 d (Day 7 to 25) Steps 43-57, Whole mount immunofluorescence: 3 d ANTICIPATED RESULTS This protocol produces kidney organoids from hPSCs with a high success rate. Success is defined as organoids containing segmented nephrons comprised of collecting duct, renal interstitium and endothelium. We have successfully generated organoids from both human ES cell lines (HES-3) and human iPSC lines (CRL1502 clone C32) and a number of patient-derived iPSC lines derived in house (unpublished). In addition, there is little variation between organoids within an experiment16. When the differentiation starts with CHIR99021 (Fig. 1 day 0), hPSCs on Matrigel should retain pluripotency as indicated by expression of stem cell markers such as OCT4 and NANOG, and with the anticipated morphology of a big nucleus, although defined borders of colonies are typically not seen at this stage (Fig. 2a,b). After 2 days of CHIR99021 exposure, colonies break apart into single cells with the morphology of spiky, typically triangular, shape (Fig. 2c). This is evidence of the epithelial-tomesenchymal transition (EMT) expected of hPSCs differentiating into the primitive streak. Once the 3-4 days of CHIR99021 phase ends (Fig. 2d) and the culture medium contains FGF9, cells start growing rapidly to reach confluence by day 7 of differentiation. The surface of the cell-layer at day 7 typically looks ‘hilly’ due to the contrast between thin and thick cell-layers (Fig. 2e). Occasionally cells become balls by day 7, which indicates the initial CHIR99021 duration or CHIR99021 concentration should be slightly shortened or reduced for an optimal result. If immunofluorescence on this day shows predominant population of either GATA3 or HOXD11-positive cells, adjust days of CHIR99021 to obtain both populations (Fig. 3a)16. The size of pellets comprised of 5 × 105 cells is approximately 2 mm in diameter (Fig. 2f). This pellet initiates nephrogenesis with developing renal vesicles in 3 days under the three-dimensional culture (organoid culture) conditions. The presence of renal vesicles can be confirmed under a tissue culture microscope (Fig. 2g,h). In the case of a failure of nephrogenesis, organoids look like a pancake without formation of any complex structures. After 11 days of organoid culture, if the differentiation has worked properly, obvious formation of glomeruli as well as tubular structures can be observed (Fig. 2i,j). The resulting kidney organoid will grow up to 6 mm in diameter by 18 days of organoid culture (Fig. 1 day 25). To evaluate tissues in kidney organoids, whole mount immunofluorescence can be performed (steps 44-58). Within the organoid, a number of different kidney cell types are visible (Table 1), including collecting ducts marked by PAX2, GATA3 and ECAD staining (Fig. 3b), loops of Henle marked by UMOD staining (Fig. 3c), proximal tubules marked by LTL and cubilin (CUBN) staining (Fig. 3d), the podocyte of the glomerulus marked by WT1 and NPHS1 staining (Fig. 3f) and basement membrane in glomeruli marked by LAM (Fig. 3g arrowheads), early mesangial cells marked by PDGFRA staining (Fig. 3h), distal tubule marked by ECAD staining in the absence of co-staining with either LTL or GATA3 (Fig. 3f), medullary interstitium marked by MEIS1 alone and cortical interstitium marked by MEIS1 and FOXD1 staining51 (Fig. 3e) and an endothelial network marked by CD31 (PECAM), KDR and SOX17 staining (Fig. 3h,i). Endothelial networks tend to run in between nephrons and also on the surface of the organoid (Fig. 3j). 4-color staining using NPHS1, LTL, ECAD and GATA3 antibodies/lectin enables to identify segmented nephrons in the kidney organoid (Fig. 3k). Typically, bigger sized kidney organoids develop nephrons densely in the peripheral region and have renal interstitium and endothelial network to grow in the middle (Fig. 3l). ACKNOWLEDGMENTS We are grateful to F. Froemling for experimental support and EJ. Wolvetang for providing iPSC lines. This research was supported by National Health and Medical Research Council (NHMRC) of Australia (APP1041277), the Australian Research Council (Stem Cells Australia, SRI110001002) and Organovo Inc. MHL is an NHMRC Senior Principal Research Fellow. We also acknowledge the Australian Cancer Research Foundation’s (ACRF) Cancer Biology Imaging Facility at The University of Queensland. Figure 1 Schematic diagram of the timeline for generating kidney organoids from hPSCs The protocol is based upon a step-wise differentiation protocol with sequential changing of culture media. hPSCs are cultured in MEF-CM (MEF-conditioned hESC medium). Differentiation begins in APEL/CHIR99021 (APEL medium supplemented with 8 μM CHIR99021) followed by APEL/FGF9/Heparin (APEL medium supplemented with 200 ng ml−1 FGF9 and 1 μg ml−1 heparin) and all growth factors are withdrawn in the final step. A pulse of CHIR99021 (5 μM) stimulates nephrogenesis in the organoids. Figure 2 Bright field images of hPSCs differentiation to kidney organoids Bright field images of the cells during differentiation. a, hPSC colonies on MEF feeder layer at day −3, before transfer onto Matrigel. b, hPSCs on Matrigel at day 0 before adding CHIR99021 to the medium. c, hPSCs differentiated into the posterior primitive streak cells with CHIR99021 induction showed a triangular shaped cell morphology. d, Monolayer culture at day 4 of differentiation e, Cells at day 7 of differentiation. Ideally, cultures nearly reach confluence at this time and form distinct areas of thick and thin layers across the surface. f, At day 7 of differentiation, cells were trypsinized and centrifuged to form an aggregate. This panel represents an aggregate at 30 min after transfer to transwell filter. g,h, A whole kidney organoid at day 10 of differentiation (3 days in organoid culture). A black square indicates the field of the right panel (h), which shows the formation of small renal vesicles. i,j, A whole kidney organoid at day 25 of differentiation (18 days in organoid culture). A black square indicates the field of the right panel (j). If the differentiation has been successful, glomerular structures (gl) can be recognized under microscope. Scale bars, 200 μm (a-e), 1 mm (f,g,i), 100 μm (h,j). Figure 3 Immunological characterization of structures within kidney organoids a, Staining for anterior intermediate mesoderm cells (GATA3) and posterior intermediate mesoderm cells (HOXD11) on day 7 of the differentiation (Step 29). b-l, Whole mount immunostaining of kidney organoids (Step 57). b, Co-staining for markers of collecting ducts (PAX2, GATA3 and ECAD). c, Staining for loop of Henle (UMOD and ECAD). d, Staining for proximal tubule markers (LTL and CUBN) shows evidence of an apical brush border (CUBN). e, Staining for cortical interstitium (MEIS1 and FOXD1, a white arrowhead) and medullary interstitium (MEIS1 only). FOXD1 also marks podocytes (WT1). f, Evidence for the formation of segmenting nephrons showing staining for early podocytes (WT1 and NPHS1), distal tubules (ECAD) and intervening unstained segments at day 18 of differentiation. An involute cluster of podocyes can be seen at the end of a forming nephron (center). g, At day 25 of differentiation, maturing glomeruli develop glomerular basement membrane (LAM, blank arrowheads) in the middle of podocytes (NPHS1). h, Staining for early mesangial cells (PDGFRA) invaginating into podocytes (NPHS1). i, Staining for the endothelial network (CD31 and SOX17). j, Staining of a representative whole mount kidney organoid illustrating the endothelial network (CD31) and glomerular podocytes (NPHS1). Cell nuclei stained by DAPI are shown in the inset panel. k, An example of a small whole kidney organoid (< 3 mm). l, An example of a larger kidney organoid (> 4 mm) Scale bars, 50 μm (a-i), 1 mm (j-l). Table 1 Antibodies for tissue characterization Cell type Antigen Host Supplier Cat. no. Dilution Posterior IM HOXD11 Mouse Santa Cruz Biotechnology sc-192 1:300 Anterior IM and collecting duct GATA3 Goat R&D Systems AF2605 1:300 Renal tubules and collecting duct PAX2 Rabbit Zymed Laboratories 71-6000 1:300 Maturing proximal, tubule, distal tubule and collecting duct ECAD Mouse BD Biosciences 610181 1:300 Loop of Henle UMOD Rabbit Biomedical Technologies BT-590 1:300 Proximal tubule LTL Biotin-conjugated Vector Laboratories B-1325 1:300 Proximal tubule CUBN Rabbit Santa Cruz Biotechnology sc-20607 1:150 Podocyte WT1 Rabbit Santa Cruz Biotechnology sc-192 1:100 Podocyte NPHS1 Sheep R&D Systems AF4269 1:300 Endothelium CD31 Mouse BD Pharmingen 555444 1:300 Endothelium KDR Rabbit Cell Signaling Technology 2479 1:300 Endothelium SOX17 Goat R&D Systems AF1924 1:300 Early mesangium PDGFRA Mouse BD Pharmingen 556001 1:200 Basement membrane LAM Rabbit Sigma-Aldrich L9393 1:300 Renal interstitium MEIS1/2 Mouse Activemotif ATM39795 1:300 Podocyte and renal interstitium FOXD1 Goat Santa Cruz Biotechnology sc-47585 1:200 Table 2 Troubleshooting table Step Problem Possible reason Solution 9 Cells do not recover or grow slowly after thawing Unhealthy cells at cryopreservation. Cryopreserve healthy cells. Alternatively, Rho kinase inhibitor (Y-27632) can be supplemented to hESC medium at 10 μM for 24 h post thawing. 26 Cells come off the plastic during CHIR99021 phase Cell density is too low Plate more cells at Step 23. 37 Pellets break up during a transfer Not enough centrifuging Perform two sequential centrifugations of ×400g for 2 min. Rotate the tube180° before the second spin at Step 35. Up to four sequential centrifugations can be performed. 40 No nephrogenesis happens Damaged cells due to centrifuge If centrifugations are repeated multiple times at Step 37, reduce the number of times or duration. Intermediate mesoderm induction fails Confirm FGF9 activity is intact. Use freshly thawed FGF9. Use more than 0.32 ml of FGF9/Heparin/APEL medium per cm2 at Step 27. Differentiation fails Confirm if posterior intermediate mesoderm markers, HOXD11, are positive at step 29 (Fig. 3a). If they are negative, modify culture conditions for your cells; e.g. initial cell density at Step 23, CHIR99021 concentration or CHIR99021 duration at Step 25, 26. 3 key references 1. Takasato M, Er PX, Chiu HS, et al (2015) Kidney organoids from human iPS cells contain multiple lineages and model human nephrogenesis. Nature 526:564–8. doi: 10.1038/nature15695 2. Takasato M, Little MH (2015) The origin of the mammalian kidney: implications for recreating the kidney in vitro. Development 142:1937–1947. doi: 10.1242/dev.104802 3. Takasato M, Er PX, Becroft M, et al (2014) Directing human embryonic stem cell differentiation towards a renal lineage generates a self-organizing kidney. Nat Cell Biol 16:118–26. doi: 10.1038/ncb2894 Editorial summary This protocol describes stepwise differentiation of human pluripotent stem cells into 3D kidney organoids that contain segmented nephrons connected to collecting ducts, surrounded by renal interstitial cells and an endothelial network AUTHOR CONTRIBUTIONS MT and MHL wrote the manuscript. MT, PXE and HSC performed the experiments. COMPETING FINANCIAL INTERESTS The authors declare competing financial interests (see the HTML version of this article for details). MT and MHL are named inventors on a patent relating to this methodology. REFERENCES 1 Tesar PJ New cell lines from mouse epiblast share defining features with human embryonic stem cells Nature 2007 448 196 9 17597760 2 Takasato M Maier B Little MH Recreating kidney progenitors from pluripotent cells Pediatr. 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PMC005xxxxxx/PMC5113833.txt
LICENSE: This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. 2985117R 4816 J Immunol J. Immunol. Journal of immunology (Baltimore, Md. : 1950) 0022-1767 1550-6606 27798158 5113833 10.4049/jimmunol.1600836 NIHMS818721 Article Loss of neurokinin-1 receptor alters ocular surface homeostasis and promotes an early development of herpes stromal keratitis Gaddipati Subhash *§ Rao Pushpa § Jerome Andrew David § Burugula Bala Bharathi *§ Gerard Norma P ** Suvas Susmit *§¶# * Department of Ophthalmology, Wayne State University School of Medicine, Detroit, MI § Department of Anatomy & Cell Biology, Wayne State University School of Medicine, Detroit, MI ¶ Department of Immunology and Microbiology, Wayne State University School of Medicine, Detroit, MI ** Division of Respiratory Diseases, Boston’s Children hospital, Department of Medicine, Harvard Medical School, Boston, MA # Corresponding author: Dr. Susmit Suvas, 7223 Scott Hall, Departments of Ophthalmology, Anatomy & Cell Biology and Microbiology and Immunology, Wayne State University School of Medicine, Detroit, MI, Phone: 313-577-9820, Fax: 313-577-3125, ssuvas@med.wayne.edu 27 9 2016 17 10 2016 15 11 2016 15 11 2017 197 10 40214033 This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. Substance P neuropeptide and its receptor neurokinin-1 (NK1R) are reported to present on the ocular surface. In this study, mice lacking functional NK1R exhibited an excessive desquamation of apical corneal epithelial cells in association with an increased epithelial cell proliferation, increased epithelial cell density, but decreased epithelial cell size. The lack of NK1R also resulted in decreased density of corneal nerves, corneal epithelial dendritic cells, and a reduced volume of basal tears. Interestingly, massive accumulation of CD11c+CD11b+ conventional dendritic cells (cDCs) was noted in the bulbar conjunctiva and near the limbal area of corneas from NK1R−/− mice. After ocular HSV-1 infection, the number of cDCs and neutrophils infiltrating the infected corneas was significantly higher in NK1R−/− than C57BL/6J mice. This was associated with an increased viral load in infected corneas of NK1R−/− mice. As a result, the number of IFN-γ secreting virus specific CD4 T cells in the DLNs of NK1R−/− mice was much higher than infected C57BL/6J mice. An increased number of CD4 T cells and mature neutrophils (CD11b+Ly6ghigh) in the inflamed corneas of NK1R−/− mice was associated with an early development of severe HSK. Collectively, our results show that the altered corneal biology of uninfected NK1R−/− mice along with an enhanced immunological response after ocular HSV-1 infection cause an early development of HSK in NK1R−/− mice. Substance P inflammation cornea and herpes simplex virus-1 Introduction Neurokinin-1 receptor (NK1R) is the highest affinity receptor for substance P (SP), an eleven amino acid long neuropeptide (1, 2). NK1R is reported to express in corneal epithelial cells, and SP-NK1R interaction promotes the chemokine expression in primary cultures of human corneal epithelial cells (3, 4). Blocking of NK1R signaling, while using NK1R antagonists, is shown to ameliorate many pro-inflammatory conditions, including airway and ocular inflammation in animal models (5–8). Therefore, NK1R serves as a promising target to control chronic inflammation. Currently, NK1R antagonists are approved to prevent nausea and vomiting associated with cancer chemotherapy in clinics (9, 10). In addition to promoting inflammation, NK1R signaling is also reported to accelerate corneal epithelial wound healing in animal models (11, 12). However, the role of functional NK1R in regulating ocular surface homeostasis under steady-state condition is not known. Recurrent corneal HSV-1 infection can cause the development of herpes stromal keratitis (HSK), a chronic ocular inflammatory condition. If not controlled with steroids and anti-viral, HSK can cause the loss of vision. Mouse models have long been used to study the pathogenesis of HSK. Recently in a mouse model, we demonstrated that blocking NK1R signaling during the clinical period of the disease with spantide I (NK1R antagonist), ameliorated the severity of HSK (7). This suggested the pro-inflammatory nature of NK1R in an ongoing inflammatory condition However, it is not clear whether the lack of functional NK1R on the ocular surface under steady-state condition increases or decreases the susceptibility of eyes to develop HSK after corneal HSV-1 infection. To address the above question, we used mice lacking functional Nk1r gene (NK1R−/−) (13). Contrary to our expectation, an early development of severe HSK was noted in infected NK1R−/− mice when compared with infected C57BL/6J (B6) mice. While trying to understand the mechanism, we determined that in comparison to uninfected B6 mice, uninfected NK1R−/− mice exhibited excessive cell sloughing at the apical surface of the corneal epithelium in association with an increased epithelial cell proliferation, increased epithelial cell density, but decreased epithelial cell size. Additionally, a significant decrease in the number of resident corneal epithelial dendritic cells, but an increased accumulation of cDCs near limbal area was detected in naïve corneas of NK1R−/− mice than wild type B6 mice. Upon ocular HSV-1 infection, increased infiltration of cDCs and neutrophils was detected in the infected corneas from NK1R−/− mice. In addition, NK1R−/− mice corneas exhibited an increased viral titer at early time-points (days 2 and 4) post-infection. This was associated with an increased priming of virus specific IFN-γ secreting CD4 T cells in the DLNs of NK1R−/− mice. An increased number of CD4 T cells and mature neutrophils (CD11b+Ly6ghigh) in inflamed corneas of NK1R−/− mice was associated with an early development of severe HSK. Together, our results indicate the contribution of NK1R signaling in maintaining the homeostasis of the ocular surface under steady-state condition, and that the lack of functional NK1R increases the susceptibility of eyes to develop severe HSK upon ocular HSV-1 infection. Materials and Methods Mice and Ethics statement Eight to twelve week old male and female C57BL/6J mice were procured from the Jackson laboratory (Bar Harbor, ME). Breeding pairs of NK1R−/− mice were obtained from Dr. Norma P Gerard, and the mice were bred in an animal facility at Wayne State University School of Medicine (WSUSOM). Functional ablation of the NK1R gene in NK1R−/− mice was confirmed using tail biopsy and performing the PCR followed by electrophoresis (Supplementary Figure 1). Eight to twelve week old male and female B6 and NK1R−/− mice were used to carry out the experiments. All of the animals were housed in an Association for Assessment and Accreditation of Laboratory Animal Care (AAALAC) approved specific pathogen free animal facility at Wayne State University School of Medicine (WSUSOM). The Institutional Animal Care and Use Committee (IACUC) of Wayne State University approved all of the experimental protocols and procedures. In addition, all of the experimental procedures were in complete agreement with the Association for Research in Vision and Ophthalmology resolution on the use of animals in research. Corneal HSV-1 infection and viral titration A virulent HSV-1 RE Tumpey strain used in the current study was propagated on a monolayer of Vero cells (American Type Culture Collection, Manassas, VA; CCL81) as described previously (14). To carry out an ocular HSV-1 infection, mice were first anesthetized by intra-peritoneal injection of Ketamine (33mg/Kg bodyweight) + Xylazine (20mg/Kg bodyweight) in 0.2 mL PBS. The corneas were scarified with trephine (Fine Science Tools, Foster city, CA) while twisting three to four times over the corneal surface. 1×104 plaque forming unit (p.f.u) of HSV-1 virus was then topically applied with a pipette to the eye in 3μL of 1x PBS followed by a gentle massage of the eyelids. The HSV-1 load in infected corneas of C57BL/6J and NK1R−/− groups of mice was determined on day 2, 4 and 5 post-infection as described previously (14). The same infected eye was not used to measure the viral load at different days post-infection. After collecting the eye-swabs, mice were euthanized on the indicated time-points post-infection and the corneas were processed for flow cytometry analysis. Clinical Scoring of HSK The eyes were examined on different day post-infection, while using a hand-held slit lamp biomicroscope (Kowa, Nagoya, Japan), to determine the extent of corneal opacity and angiogenesis. A standard scale for corneal opacity, ranging from 0–5, was used as described earlier (14). The neovascularization (NV) of the cornea was determined by measuring the centripetal growth of newly formed blood vessels in each quadrant of the cornea as described earlier (14). Lymph nodes and corneal cell preparation for flow cytometry HSV-1 infected B6 and NK1R−/− mice were euthanized on day 7 post-infection. A single cell suspension of the draining lymph nodes (DLNs) from individual mouse was prepared as described earlier (14). The infected eyes from both groups of mice were enucleated and collected in ice-cold RPMI medium with antibiotics. Under a dissecting microscope, a radial incision was made at the limbal region, and the cornea was separated from the underlying lens, iris, ciliary body, and scleral tissue using curved fine forceps (Miltex surgical instruments, PA). The individual cornea was suspended in 250 μL of RPMI, and 20 μL of liberase TL (2.5 mg/mL) was added followed by incubation at 37°C for 45 minutes on a tissue disruptor. At the end of the incubation period, the samples were triturated using 3 mL syringe plungers and passed through a 70 μm cell strainer. This was followed by pelleting down the cells at 315× g for 8 minutes in a refrigerated centrifuge. Cell surface staining Cell surface staining was carried out as described earlier (14). Briefly, the single cell suspension obtained from the individual cornea and DLN was washed with FACS buffer, followed by blocking of Fc receptors and incubation with fluorochrome conjugated antibodies. The following antibodies were used for the cell surface staining: Percp-Cy5.5 conjugated- anti-CD4 (RM4-5), FITC conjugated anti-Gr1 (RB6-8C5), Percp-Cy5.5 conjugated anti-CD11b (M1/70), PE-Cy7 conjugated anti-Ly6g (1A8), PE conjugated IAb (AF6-120.1), and Alexa 647 conjugated anti-CD11c (N418). All of the antibodies were purchased from BD biosciences and BioLegend, San Diego, CA. At the end of the cell surface staining, samples were acquired using a LSR II flow cytometer, and the data was analyzed using the FlowJo software (Ashland, OR, USA. V8.8.7). Corneal FITC painting assay HSV-1 infected C57BL/6 and NK1R−/− mice were anesthetized with isoflurane on day 2 post-infection. A 1% FITC solution was prepared by dissolving FITC isomer 1 (Sigma F7250) in 1:1 (vol/vol) acetone: dibutyl phthalate solution. The corneas of infected mice were painted under anesthesia with 3 μl of FITC solution. After 16h, the DLNs were collected and a single cell suspension was prepared while using a collagenase type II (Gibco 17101-015) enzyme solution. Cells were stained for IAb, CD11b, and CD11c molecules and the samples were acquired on a LSRFortessa flow cytometer. The data was analyzed using the FlowJo software. Intracellular cytokine and nuclear Ki-67 staining Single cell suspension of the lymph nodes was stimulated with 3 MOI (multiplicity of infection) of UV inactivated HSV-1 as described earlier (14). At the end of incubation period, cell surface staining was carried out, followed by permeabilization of the cells with Cytofix/Cytoperm (BD biosciences). PE-conjugated anti-IFN-γ (XMG1.2) antibody was used to stain IFN-γ expressing CD4 T cells. The cells were washed in perm wash (BD Biosciences) buffer with the final washing given in FACS buffer. For nuclear Ki-67 staining, cells were stained using a PE mouse anti-human Ki-67 kit (BD Pharmingen) as per manufacturer instruction. Samples were then acquired on the LSR II flow cytometer and the data was analyzed using the FlowJo software. Mouse cytokine protein array analysis Cytokine and chemokine levels in HSV-1 infected corneal tissues from B6 and NK1R−/− mice were measured using a Mouse Cytokine Array Panel A kit (R&D systems, Minneapolis, MN). Corneas dissected from naïve or infected eyes (day 4 and day 9 post-infection) of B6 and NK1R−/− mice were transferred to 1x PBS with protease inhibitor cocktail (PIC) and kept at −80°C. Sonication of the corneas was performed at 50% amplitude with a cycle of 15 second pulse, followed by 1 minute of resting on ice. A total of six cycles were given to each cornea. The tissue lysates (sonicated samples) obtained were centrifuged at 4°C at 15,000 rpm for 10 minutes. The supernatant was collected and the amount of protein in each sample was estimated using a BCA protein assay kit (Thermo Scientific). A total of four corneas from each group was pooled to obtain a minimum of 200 μg of protein for cytokine and chemokine array analysis as per the manufacturer instructions. Positive signals on the membranes were quantified using Image Studio Lite Version 4.0. Corneal whole mount staining Mice were euthanized and their eyes were enucleated with a pair of forceps. The eyeballs were immediately fixed in 4% paraformaldehyde for 30 min at room temperature. The corneal tissue was separated with a bard-parker #21 blade under a dissection microscope. Tissues were flattened with 6–8 partial cuts from the limbal to central cornea and stored in 30% sucrose solution overnight at 4°C. The next day, the corneas were permeabilized using 0.1% EDTA-0.01% Hyaluronidase type IV-S solution at 37°C for 90 min, and immediately followed by blocking with a 3% bovine serum albumin-1% Triton X100 solution for 90 min at room temperature. The corneal tissues were incubated with a primary antibody at an appropriate dilution in a humidified chamber (Supplementary table 1) for 16 hours in a cold room (4°C). The next day, the tissues were washed four times with 0.3% Triton X100-PBS solution (10 min each wash). If the primary antibody was unconjugated, a secondary antibody was added at an appropriate dilution as stated in Supplementary table 1 followed by overnight incubation in a cold room. Prior to acquisition, the corneal tissue was mounted with vectashield medium containing DAPI (H1200, Vector Laboratories, Burlingame, CA, USA). Images were acquired using a Leica TCS SP8 confocal microscope. An Image J version 1.49b software was used to quantitate the CD11c+ cells in the corneal wholemount from both groups of mice. The Image J “multi-point” tool was used for manual counting of the corneal nerve leash and limbal nerve trunk branch points. Cochet and Bonnet Esthesiometry Corneal sensitivity was measured using Cochet and Bonnet Esthesiometer attached with 12/100 mm nylon thread. This test was performed at 23–25°C room temperature by touching the central cornea of B6 or NK1R−/− mice. Numerical values were derived from a conversion table provided by the manufacturer (Luneau SAS). Phenol red thread tear test To measure the tear levels in the eyes of unmanipulated B6 and NK1R−/− mice, pH indicator phenol red treated cotton threads were obtained from Zone-Quick (ZQ-1010, Showa Yakuhin Kako, Japan). The mice were restrained by holding the lose skin at base of the neck without touching the facial skin or whiskers. The eyes were tested for tear level by placing the tip of the cotton thread on the bulbar conjunctiva of the lateral canthus for 30 seconds. The picture of the threads was taken and tear absorption was measured using a 10 cm scale. Bromodeoxyuridine (BrdU) incorporation assay For BrdU labeling of the corneal epithelium, 8 to 12-week old B6 and NK1R−/− mice were given a single intra-peritoneal injection of BrdU (10 mg BrdU/mL saline; 0.2 mL/mouse). The mice were euthanized on the next day after 18 hours, and their eyes were collected to snap freeze in OCT media. Longitudinal sections were cut at an 8μm thickness, and mounted on positively charged slides (Thermo Shandon Limited, UK). The sections were air dried overnight at room temperature and fixed in 4% buffered paraformaldehyde for 15 min followed by 3 washings with 1x PBS. For antigen retrieval, sections were immersed in 2N HCl in a covered Coplin jar for 30 minutes at room temperature. The acid was neutralized with 0.1M Borate buffer (pH-9.0) for 5 minutes with two buffer changes. The slides were blocked with 3% BSA in 1X PBS and incubated with a primary antibody (Abcam, MA, USA, BU1/75, ab6326) at a 1:100 dilutions in blocking buffer for 18 hrs at 4°C. The next day, the slides were washed three times and incubated with Alexa-488 conjugated anti-Rat antibody (Molecular Probes) at a 1:200 dilutions overnight at 4°C. The slides were washed and mounted with vectashield medium containing DAPI prior to acquisition. Statistical Analysis Statistical analysis was carried out using the Graph Pad Prism software (San Diego, CA). All p values were calculated using an unpaired, two-tailed Student’s t test. P < 0.05 was considered statistically significant. The results are displayed as the mean. Results Ocular HSV-1 infection causes an early development of corneal opacity and angiogenesis in NK1R−/− mice Previously, we determined that blocking NK1R signaling in HSV-1 infected inflamed corneas, during clinical period of disease, ameliorated the severity of HSK in a B6 mouse model (7). In this study, we analyzed whether the lack of functional NK1R on the ocular surface, under steady-state condition, also reduces the severity of HSK upon ocular HSV-1 infection. The corneas from both groups of mice were infected with HSV-1 as described in the methods section. Unexpectedly, our results showed significantly increased corneal opacity and angiogenesis on day 9 and 11 post-infection in HSV-1 infected corneas from NK1R−/− mice in comparison to the infected group of B6 mice (Fig. 1A, C and D). The incidence of corneal opacity and angiogenesis was also much higher in NK1R−/− mice when analyzed on day 9 and 11 post-infection (Fig. 1B). By day 14 and 16 post-infection, the extent of corneal opacity and angiogenesis was similar in eyes from both groups of mice. Collectively, our results show an early development of severe HSK in NK1R−/− mice after ocular HSV-1 infection. Excessive sloughing of apical corneal epithelial (ACE) cells in unmanipulated NK1R−/− mice To determine the underlying mechanism for our unexpected results, we microscopically evaluated the corneal surface of the eyes from uninfected B6 and NK1R−/− mice. No phenotypic differences in the appearance of the eyes were noted when comparing B6 and NK1R−/− mice (Fig. 2A). However, hematoxylin and eosin staining of paraffin-embedded corneal sections from NK1R−/− mice showed a much thinner apical layer of the corneal epithelium with occasional delaminating superficial epithelial cells in comparison to the corneas from B6 mice (Fig. 2B). The laser scanning confocal microscopy of whole mount corneas from B6 and NK1R−/− mice demonstrated significantly increased number of desquamating ACE cells (denoted by the * sign) in knockout mice (Fig. 2D). Excessive cell sloughing at the corneal apical surface could possibly stimulate compensatory cell proliferation in the corneal epithelium. Therefore, we next evaluated the corneal epithelial cell proliferation between B6 and NK1R−/− mice. Short-term Bromodeoxyuridine (BrdU) incorporation assay showed a significant increase in labeling of basal corneal epithelial cells in NK1R−/− compared to B6 mice (Fig. 2E). In addition, a significant increase in the number of hematoxylin stained nuclei was determined in the corneal epithelium of NK1R−/− than B6 mice (Fig. 2C). Increased epithelial cell density, but decreased epithelial cell size was also evident in the whole mount corneas from NK1R−/− mice (Fig. 2F). Together, our results demonstrated an excessive exfoliation and increased mitotic index of corneal epithelial cells in NK1R−/− mice. Loss of NK1R reduces the density of corneal epithelial DCs, but dramatically increases the number of cDCs in the bulbar conjunctiva and near the limbal area of uninfected cornea The normal corneal epithelium is populated with resident CD11c+ DCs, which are in close association with surrounding epithelial cells. The resident corneal DCs have been shown to promote the re-epithelialization of corneal wounds (15). An alteration in the homeostasis of the corneal epithelium might affect the homeostasis of corneal DCs. Therefore, we next compared the density of corneal DCs by carrying out the immunofluorescence staining of CD11c+ cells in the corneal whole mounts from unmanipulated B6 and NK1R−/− mice. As is shown in Fig. 3A, the resident corneal epithelial DCs present in the peripheral and central areas of the corneas from NK1R−/− mice were almost half in number when compared to DCs in the corneas from B6 mice. However, a more than two-fold increase in the number of CD11c+ cells stained with anti-CD11c (clone N418) antibody was evident in the bulbar conjunctiva and limbal region of the corneas from NK1R−/− mice when compared to the limbal area of the corneas from B6 mice (Fig. 3B and supplementary Figure 2). The majority of CD11c+ cells near the limbal area was also co-stained with CD11b molecule (Fig. 3C). Moreover, z-scans of the corneal wholemount near the limbal area showed that CD11b+CD11c+ cells were localized in both the corneal epithelium and anterior stroma, whereas CD11b+CD11c− macrophages were deep seated in the stroma of the corneas from both groups of mice (Supplementary movie S1). Together, our results showed an altered homeostasis of corneal resident epithelial DCs along with an increased accumulation of conventional dendritic cell type near the limbal area of the corneas from unmanipulated NK1R−/− mice. Reduced epithelial nerve density, stromal nerve trunk branching and basal level of tears in the corneas from NK1R−/− mice The corneal epithelium is a highly innervated tissue and the corneal nerves are reported in close association with corneal epithelial cells and dendritic cells (16, 17). We next ascertained whether the altered homeostasis of corneal epithelial and dendritic cells influences the density of corneal nerves. The corneal whole mount staining for class III β-tubulin, using Tuj-1 antibody, showed a significant decrease in the number of corneal subbasal nerve leashes in the peripheral region of the corneas from NK1R−/− mice (Fig. 4A). Additionally, the number of corneal stromal nerve trunk branch points near the limbal area was also significantly more reduced in NK1R−/− than B6 mice (Fig. 4A). The corneal nerve density was similar in the central corneal region when comparing both groups of mice (data not shown). Moreover, no significant differences (p>0.05) in corneal sensation were determined in the central corneal region of the eyes from both groups of mice, while using the Cochet-Bonnet Esthesiometer (Fig. 4B). Lastly, the phenol red thread tear test was carried out to evaluate the volume of unstimulated tears in the eyes from NK1R−/− and B6 mice. Our results showed a significant decrease (p<0.0001) in the volume of unstimulated tears measured in the eyes of NK1R−/− than B6 mice (Fig. 4C). Increased viral load in the corneas of NK1R−/− mice The intact apical surface of the corneal epithelium provides resistance to the establishment of HSV-1 infection in the mouse model. Our results clearly showed that in NK1R−/− mice, the apical layer of the corneal epithelium is much thinner and has more desquamating ACE cells. Therefore, viral load of HSV-1 on the corneal surface was compared at different time-points post-infection between B6 and NK1R−/− mice as described in the methods. Our results showed a moderate, but statistically significant increase in viral load in the corneas of NK1R−/− mice when compared with B6 mice on day 2 and 4 post-infection (Figure 5). No significant difference in viral load was determined between both groups of mice on day 5 post-infection. Pre-clinical and clinical phase of HSK document a differential level of cytokine/chemokines in infected corneas of NK1R−/− and B6 mice Development of HSK in a mouse model is categorized into a pre-clinical and a clinical phase of disease as reported earlier (18). During the pre-clinical phase (day 1 through 6 post-infection), active viral replication is reported with minimal corneal opacity and angiogenesis whereas, in the clinical stage of the disease (day 7 though 18 post-infection) severe corneal opacity and angiogenesis develop in response to chronic immunoinflammatory reactions in the inflamed corneas. We ascertained whether the presence or absence of functional NK1R affect the level of cytokines/chemokines in HSV-1 infected corneas during the pre-clinical and clinical phase of HSK. Infected corneas obtained from both groups of mice on day 4 (pre-clinical) and day 9 (clinical phase) post-infection were sonicated as described in the method section. Uninfected corneas from both groups of mice were also processed to determine the basal level of cytokines/chemokines. The amount of cytokines in the corneal lysates from both groups of mice was measured using a Mouse Cytokine Array assay kit as per the manufacturer’s instructions. Our results demonstrated that infected corneal lysates from NK1R−/− mice exhibited a marked increase in the amounts of neutrophil attracting chemokines CXCL1 (KC), CXCL2 (MIP-2) and CCL2 (MCP-1) in comparison to infected B6 mice, when measured on day 4 post-infection (Fig. 6). We also noted an increased amount of IL-1 receptor antagonist (IL-1Ra) in infected corneas of NK1R−/− than B6 mice on day 4 post-infection. On the other hand, during the clinical phase of HSK (day 9 post-infection), reduced levels of a number of cytokines/chemokines including the tissue inhibitor of metalloproteinase (TIMP-1), CCL2, and interleukin-1 receptor antagonist (IL-1ra) was measured in the corneal lysates of NK1R−/− than B6 mice (Fig. 6). No difference in the amounts of TIMP-1, CCL2, and IL-1ra protein was seen in uninfected corneal lysates from both groups of mice. Increased number of cDCs and neutrophils in infected corneas of NK1R−/− mice at an early time point after corneal HSV-1 infection In light of our observation demonstrating the massive accumulation of cDCs near the corneal limbal area of unmanipulated NK1R−/− mice (Fig. 3), we investigated the influx of cDCs in the peripheral, paracentral, and central region of HSV-1 infected corneas of B6 and NK1R−/− mice at an early time-point post-infection. As is shown in the corneal whole mount staining of CD11c+ cells, NK1R−/− mice exhibited an increased influx of CD11c+ cells in all three regions of infected corneas as stated above on day 2 post-infection (Fig. 7A). Moreover, the flow cytometry analysis of HSV-1 infected corneas on day 2 post-infection showed that almost all of CD11c+ cells co-expressed CD11b molecule, suggesting their cDCs phenotype (Fig. 7B). Our results also showed an increased influx of neutrophils in infected corneas of NK1R−/− than B6 mice on day 2 and 4 post-infection (Fig. 7C). Collectively, an increased immune cell influx was detected in infected corneas of NK1R−/− mice at early time-points post-infection. Increased numbers of CD11c+ dendritic cells observed in the DLNs of infected NK1R−/− mice did not migrate from the infected corneas The infiltrating DCs can pick up the viral antigens and migrate to the draining lymph nodes (DLNs) to prime virus specific T cells (19). Therefore, we next ascertained the number of CD11c+ cells in DLNs of HSV-1 infected B6 and NK1R−/− mice at early time-points post-infection. Our results showed a significant increase in the absolute number of CD11c+ cells in the DLNs of NK1R−/− than B6 mice on day 3 post ocular infection (Fig. 8A). No significant difference in the basal number of CD11c+ DCs was determined in the DLNs from both groups of uninfected mice. To address whether increased numbers of CD11c+ dendritic cells measured in the DLNs of infected NK1R−/− mice are the result of more CD11c+ cells migrating from the infected cornea to the DLN, we carried out FITC-painting of the infected corneas from both groups of mice. FITC painting of virus infected corneas was carried out on day 2 post-infection, and 16h later the number of IA-b highCD11C+CD11b+FITC+ cells were quantitated in the DLNs isolated from both groups of mice (Fig. 8B). Unexpectedly, our results showed a lesser number of FITC+CD11b+CD11c+ cells in the DLNs of NK1R−/− than C57BL/6 mice, when measured on day 3 post-infection. Taken together, our results showed that the increased number of CD11c+ DCs noted in the DLNs of infected NK1R−/− mice is not the outcome of an increased migration of cDCs from the infected corneas to DLNs. Increased expansion of CD4 T cells and IFN-γ secreting virus specific CD4 T cells in NK1R−/− mice Our results showed an increased viral load in infected corneas of NK1R−/− mice. Therefore, we next ascertained whether this results in an increased priming of CD4 T cells in the DLNs of NK1R−/− mice. The proliferation of CD4 T cells in the DLNs of infected B6 and NK1R−/− mice was compared by measuring the expression of Ki-67 nuclear antigen on day 3 and 5 post-infection using a flow cytometer. A significant increase in the proliferation of CD4 T cells in the DLNs of NK1R−/− mice was noted on day 3, but not on day 5 post-infection (Fig. 9A). To address HSV-1 antigen-specificity of CD4 T cells in the DLNs of infected B6 and NK1R−/− mice, a single cell suspension of the DLNs from both groups of infected mice was prepared on day 7 post-infection. As described in the methods section, the single cell suspension from both groups of mice was stimulated with UV-inactivated HSV-1 followed by intracellular cytokine staining to determine the number of IFN-γ secreting CD4 T cells. As is shown in Fig. 9B, about a two-fold increase in the number of IFN-γ secreting virus-specific CD4 T cell was detected in the DLNs of infected NK1R−/− mice, when compared to infected B6 mice. Increased influx of CD4 T cells and neutrophils into the inflamed corneas of infected NK1R−/− mice CD4 T cells and neutrophils play a pivotal role in the development of HSK (20, 21). Therefore, we next ascertained the influx of CD4 T cells in inflamed corneas of HSV-1 infected NK1R−/− and B6 mice. Single cell suspensions of individual corneas obtained from B6 and NK1R−/− mice on day 11 and 17 post-infection were stained for CD4 T cells, and the samples were acquired on a BD flow cytometer. Our results showed an increased frequency and absolute number of CD4 T cells in infected corneas of NK1R−/− mice on day 11 and 17 post-infection (Fig. 8). Similarly, an increased frequency and absolute number of CD11bhighLy6Ghigh mature neutrophils were seen in inflamed corneas of NK1R−/− mice on day 11 post-infection (Fig. 10). Discussion Our results clearly demonstrate an altered homeostasis of naive uninfected corneas in NK1R−/− mice. This involves lesser tear volume, reduced nerve density, reduced numbers of resident corneal epithelial DCs, increased accumulation of cDCs near the corneal limbal area, and an excessive exfoliation of apical corneal epithelial cells. As a result of this, the corneas of NK1R−/− mice are more susceptible to HSV-1 infection, as is evident from an increased viral load measured in the infected corneas at early time-points post-infection. An increased viral load was associated with the generation of an increased number of viral antigen specific CD4 T cells (as measured with intracellular cytokine assay) in NK1R−/− mice. Collectively, an altered corneal biology of uninfected NK1R−/− mice along with an enhanced immunological response after ocular HSV-1 infection cause an early development of HSK in NK1R−/− mice as depicted in the schematic of Figure 11. Our results showed an excessive exfoliation of apical corneal epithelial (ACE) cells in uninfected NK1R−/− mice. The exfoliation of ACE cells is regulated by tight junction proteins and adherens junction proteins. The ACE cells at the apical surface form tight junctions (TJs) and serve as a barrier to protect the ocular surface from microbial infections (22, 23). In addition, the adherens junction (AJ) proteins in the corneal epithelium are involved in stabilization of cell-cell adhesion (24). Thus, degradation, improper localization or reduced expression of membrane bound tight junction or adherens junction proteins in the corneal epithelium may increase the rate of exfoliation of ACE cells. NK1R signaling has been shown to enhance the expression of E-cadherin adhesion and ZO-1 tight junction protein in cultured human corneal epithelial cells (25, 26). This suggest that the lack of functional NK1R could cause a reduced expression or an improper localization of E-cadherin AJ and ZO-1 tight junction proteins in the corneal epithelium resulting in an excessive exfoliation of ACE cells, as determined in uninfected NK1R−/− mice. To maintain corneal epithelium homeostasis, excessive loss of ACE cells should be compensated by hyper-proliferation of basal epithelial cells, as determined in the corneas from NK1R−/− mice (Fig. 2). Additionally, rapid exfoliation of ACE cells may also impact the innervation of corneal nerves, as the latter has been reported to form complex structures with ACE cells (16). Due to the excessive loss of ACE cells, the ends of nerve fibers innervating the corneal epithelium may not make an intimate association with superficial corneal epithelial cells, and thereby retract from the corneal epithelium. Furthermore, the retraction of nerves fibers from the selective places in the corneal epithelium may also reduce the branching of stromal nerve trunks as depicted in our results. Afferent sensory nerves in the cornea are reported to play an important role in regulating tear secretion from the lacrimal gland through a neural reflex arc, which originates from the ocular surface (27). The reduced innervation of the corneas, as determined in NK1R−/− mice, might affect the neural reflex arc, and thereby reduce the secretion from the lacrimal gland, resulting in a lesser volume of basal tears as measured in the eyes of NK1R−/− mice. In addition, excessive exfoliation of ACE cells may also compromise tear film retention on the corneal surface, and promote corneal desiccation. This may also increase the severity of HSK upon ocular HSV-1 infection. In fact, a strong correlation between corneal desiccation, decreased density of corneal nerves, and pathogenesis of HSK are reported in human and mouse models of HSK (28–30). It is widely accepted that the corneal epithelium is populated with CD11c+ dendritic cells with long dendritic processes, which cover a significant area of the non-inflamed cornea (31). These DCs and their dendritic processes are in close association with corneal epithelial cells (15). However, the nature of the interaction between epithelial cells and resident DCs under steady state condition in corneal epithelium is not clear. In normal skin, E-cadherin adhesion protein mediate the interaction between epidermal keratinocytes and Langerhans cells (LCs), and this interaction is required for the retention of LCs in the skin (32). An aberrant expression of E-cadherin in human papillomavirus infected cervical tissue was associated with a significant reduction in Langerhans cells (33). Considering the role of SP-NK1R interaction in regulating the expression of E-cadherin in corneal epithelial cells (26), the lack of functional NK1R on the ocular surface may cause an aberrant expression of E-cadherin in the corneal epithelium, resulting in a decrease in the number of corneal epithelial DCs as noted in NK1R−/− mice. Moreover, signaling through NK1R has also been shown to promote the survival of bone-marrow derived DCs (34). Thus, the lack of NK1R on the ocular surface may result in the apoptosis of corneal epithelial resident DCs, and thereby decrease their number as determined in corneas of NK1R−/− mice. The massive accumulation of cDCs noted in the bulbar conjunctiva and near the corneal limbal area of NK1R−/− mice could be due to persistent low-grade inflammation in the conjunctival tissue of these mice. In support, we observed an increased number of Gr1+ and NKp46+ cells near the corneal limbal area of uninfected NK1R−/− than B6 mice (data not shown). Moreover, an increased vasodilation of feeder vessels was detected near the limbal area of NK1R−/− mice when compared with B6 mouse normal corneas (Supplementary Figure 3). Vasodilation of blood vessels along with an enhanced expression of selectins on vascular endothelial cells are reported to cause an increased infiltration of leukocytes from the peripheral blood into the skin tissue (35). At present, the possible cause of an increased vasodilation, as depicted in the feeder blood vessels near the corneal limbal area of NK1R−/− mice, is not clear. However, we suspect that it may be due to conjunctival inflammation in NK1R−/− mice. We are currently investigating this possibility. The severity of HSK in a mouse model is largely determined by viral load and the number of effector CD4 T cells and neutrophils in infected corneas. Increased viral load noted in NK1R−/− mice is possibly the outcome of two events. First, the easiness in establishing the primary HSV-1 infection, as the apical surface of NK1R−/− mice is disrupted due to excessive exfoliation of ACE cells. An increased viral load was associated with an increased influx of neutrophils as shown in our results on day 2 and day 4 post-infection (Figure 7). A recent study showed that infiltrating neutrophils in HSV-1 infected corneas can facilitate HSV-1 replication and dissemination (36). Thus, increased neutrophils in NK1R−/− mice may play a role in increasing the viral load at early time-points post-infection. The possible cause of an increased influx of neutrophils is the higher amounts of neutrophil attracting chemokines (CCL-2, CXCL1 and CXCL2) measured in infected corneas of NK1R−/− mice. An increased viral load may cause an increased generation of effector CD4 T cells as noted in the DLNs of NK1R−/− mice. A recent study showed that CD4 T cell priming in DLNs of HSV-1 infected mice could be due to the drainage of soluble viral antigens from infected corneas or the migration of cornea-infiltrating DCs loaded with viral antigens to the DLNs (19). Our results showed an increased number of cDCs in infected corneas and the DLNs of NK1R−/− than B6 mice. However, the results obtained from the corneal FITC-painting assay, to determine DC trafficking to DLNs, showed a lesser number of corneal cDCs migrating to the DLNs in NK1R−/− mice. DC migration is dependent upon their maturation (37), and NK1R signaling is reported to promote the maturation of DCs (38). The lack of functional NK1R on DCs in NK1R−/− mice may affect their maturation, and thereby reduce their migration from infected corneas to DLNs. Thus, the increased priming of CD4 T cells detected in DLNs of NK1R−/− mice is possibly the outcome of the drainage of soluble viral antigens from infected corneas. Together, our findings characterized a novel role of NK1R in maintaining the homeostasis of the ocular surface under a steady state condition. Moreover, the lack of NK1R increases the susceptibility of the eyes to ocular HSV-1 infection resulting in an increased incidence and early development of HSK. Several NK1R antagonists are in clinical trials for non-ocular conditions, including alcoholism and psychiatric conditions. It would be of interest to determine whether long-term treatment of NK1R antagonists, given for non-ocular conditions, increases the incidence of HSK or other microbe-induced ocular pathologies. Supplementary Material 1 We would like to thank Drs. Frank Giblin and Shravan Chintala for providing access to Zeiss Axio Imager Z2 fluorescence microscope facility. Many thanks to Ronald P. Barrett for help with SP8 confocal microscope. Funding Sources Supported by National Eye Institute Grant EY022417 awarded to Dr. Suvas, Core vision grant EY004068 awarded to Dr. Hazlett and Research to Prevent Blindness (RPB) grant awarded to Dr. Juzych. Figure 1 Lack of NK1R promotes an early development of HSK (A) Representative slit lamp pictures of B6, NK1R−/− mice eyes on day 11 post-ocular HSV-1 infection. (B) Frequency of eyes with severe opacity in both groups of mice. (C and D) Scatter plots showing corneal opacity and angiogenesis grading on day 9, 11, 14 and 16-post ocular infection. Data shown is the representative of three independent experiments (n = 5–10 mice per group). p values were calculated using two-tail student’s t-test (****p<0.0001, **p<0.01, *p<0.05 significant and ns p>0.05 non-significant). Figure 2 Lack of NK1R causes an excessive sloughing of apical corneal epithelial cells (A) Slit lamp bio-microscope images of naïve WT (top) and NK1R−/− (lower) showing corneal surface. (B) Representative H & E stained corneal tissue sections (8μ thick) from both groups at 20X magnification, boxed area shows the higher magnified view of that region. Apical corneal epithelial cell sloughing from the ocular surface of NK1R−/− mice indicated by arrow heads. Scale bar-60 μm. (C) Graphical representation for the number of epithelial cells quantified from H&E stained corneal sections of B6 and NK1R−/− mice. (D) Whole mount naïve corneas stained for ZO-1 (green) in B6 and NK1R−/− mice. Asterisks and scatter plot denote empty space resulting from the desquamation of ACE cells in outermost layer of the corneal epithelium. Scale bar-50 μm. (E) Representative corneal sections stained with anti BrdU Ab after 18 hours of BrdU pulsing in WT and NK1R−/− mice (BrdU positive cells indicated by arrows). Scale bar-50 μm. (F) Whole mount naïve corneas stained with E-cadherin (green) and counterstained with DAPI to demonstrate an increased epithelial cell density but decreased epithelial cell size at wing cell zone in NK1R−/− mouse cornea. Scale bar-25 μm. Images are representative of two independent experiments (n = 3–6 corneas per group). p values were calculated using two-tail student’s t-test (****p<0.0001, **p<0.01 significant). Figure 3 Lack of NK1R changes the homeostasis of corneal epithelial and limbal dendritic cells (A) Whole mount (montage images with 10X) corneas of naïve B6 and NK1R−/− mice stained with FITC conjugated anti-CD11c antibody (HL3 Clone). Scatter plot shows the total number of CD11c positive cells/each cornea from both the groups. (B) Low magnified limbal region of WT and NK1R−/− whole mount corneas stained with FITC conjugated anti-CD11c antibody (N418 clone, 5X). Dotted line denotes the limbal region. Scale bar-200 μm. Scatter plot shows the total number of CD11c positive cells at limbus/cornea from both the groups. (C) Co-localization of CD11c (N418) (Green) and CD11b (Red) in the limbal region of NK1R−/− mice corneal whole mounts. Nucleus was stained with DAPI (Blue) (20X). Scale bar-50 μm. Data shown is the representative of three independent experiments (n = 3–4 corneas per group). Cj-Conjunctiva, C Cornea-Central cornea. p values were calculated using two-tail student’s t-test. (**p<0.01 and *p<0.05 significant). Figure 4 Lack of NK1R reduces the corneal nerve density and basal levels of unstimulated tears (A) Confocal images of Tuj1 stained whole mount corneas from uninfected B6 and NK1R−/− mice. Images are montages images acquired with 20X objective lens. Scatter plots denote number of nerve leashes (bunches) and limbal stromal nerve trunk branch points from both groups of mice (n = 4 corneas per group). (B) Measurement of corneal sensitivity with Cochet and Bonnet Esthesiometer. (C) Image of phenol red threads used for measuring the tear quantity in B6 (top) and NK1R−/− (bottom) mice. The extent of color change from the thread edge denotes the abundance of tears. Scatter plot represents the volume (in mm) of tear absorption by phenol red coated cotton thread from both the groups. Data shown is the representative of two independent experiments (n= 10 corneas per group). p values were calculated using two-tail student’s t-test. (****p<0.0001, **p<0.01 and ns p>0.05). Figure 5 Increased viral load in corneas of NK1R−/− mice The viral load in individual corneas from both groups of mice was measured as plaque forming unit (p.f.u.) on day 2, 4, and 5 post-ocular infections. Each circle represents an individual eye from HSV-1 infected mice. Data shown is the sum of two independent experiments (n = 8–10 corneas per group). p values were calculated using two-tail student’s t-test. (*p<0.05 significant and p>0.05 non-significant). Figure 6 Differential amount of cytokine and chemokines in infected corneas of NK1R−/− and B6 mice during pre-clinical and clinical phase of HSK The cytokine and chemokine array blots of the corneal lysates prepared from uninfected, and HSV-1 infected corneas of B6 and NK1R−/− mice on day 4, and day 9 post-ocular infection. Bar diagram denote quantitation of the molecules involved in regulating the pathogenesis of HSK. A mouse cytokine array layout is provided to read the protein array blot images. Four corneal samples were pooled to carry out the assay. n = 8 corneas per group. Figure 7 Increased influx of cDCs and mature neutrophils in HSV-1 infected corneas of NK1R−/− than B6 mice (A) Corneal whole mounts stained with FITC conjugated anti-CD11c (clone N418) antibody from B6 and NK1R−/− mice on day 2 post-ocular HSV-1 infection. More magnified limbal, paracentral and central corneal images for both groups are included (n = 3–4 corneas per group). (B) Representative FACS plots denote that majority of infiltrating CD11c+ cells co-expressed CD11b molecule (n = 5 corneas per group). Graphs show frequency and absolute number of CD11b+CD11c+ cells in infected corneas on day 2 post-infection. (C) Representative FACS plots showing influx of leukocytes (CD45+) and neutrophils (CD11b+Ly6G+) in HSV-1 infected corneas on day 2 and 4 post-infection from both groups of mice. Graphs demonstrate the frequency and absolute number of leukocytes and neutrophils in infected corneas (n = 6 corneas per group). Data shown is the representative of two independent experiments. p values were calculated using two-tail student’s t-test. (*p<0.05, **p<0.01, ***p<0.001 significant and p>0.05 non-significant). Figure 8 Increased number of CD11c+ dendritic cells in the DLNs of HSV-1 infected NK1R−/− mice did not migrate from the infected corneas (A) FACS plots demonstrating the frequencies of CD11c+Gr1-ve DCs in naïve DLNs, and the DLNs obtained on day 3 post-infection, from both groups of mice. Bar diagrams denote the absolute number of DCs (n = 4–5 mice per group). (B) FACS plots showing the frequency of FITC+ DCs in the DLNs of infected mice, from both groups, on day 3 post-infection. The infected corneas of B6 and NK1R−/− mice were FITC-painted on day 2 post-infection and 16h later, the DLNs were removed. Bar diagrams show frequency and absolute number of FITC+ DCs in the DLNs of B6 and NK1R−/− mice on day 3 post-infection (n = 6 mice per group). Data shown is the representative of two independent experiments. (*p<0.05, **p<0.01, ****p<0.0001 significant and p>0.05 non-significant). Figure 9 Increased expansion and Th1 differentiation of CD4 T cells in DLNs of HSV-1 infected NK1R−/− mice (A) Representative FACS plots are showing the frequencies of Ki67 expressing CD4 T cells in the DLN of B6 and NK1R−/− mice on day 3 post-ocular HSV-1 infection. Scatter plots show frequency and absolute number of CD4+ Ki67+ cells in DLNs of uninfected and HSV-1 infected mice from both groups on day 3 and 5 post-infection (n = 3–6 mice group). (B) Representative FACS plots are denoting IFN-γ producing CD4 T cells after ex-vivo re-stimulation of lymph node cells from both groups of mice with UV inactivated HSV-1 on Day 7 post-infection. Scatter plots demonstrate frequency and absolute number of IFN-γ producing CD4 T cells from both groups of mice (n = 9–10 mice per group). p values were calculated using two-tail student’s t-test. (****<0.0001, *p<0.05 significant and p>0.05 non-significant) Figure 10 Increased influx of CD4 T cells and mature neutrophils (CD11bhighGr1high) in infected corneas of NK1R−/− mice (A) Representative FACS plots of CD4 T cells in infected corneas from both groups of mice on day 11 and 17 post-infection. Bar diagrams demonstrate the frequencies and absolute number of CD4 T cells in individual corneal tissue from both groups on day 11 and day 17 post-infection. Data shown is the representative of two independent experiments (n = 5–7 corneas per group). (B) Representative FACS plots of CD11bhighGr1high granulocytes in inflamed corneas on day 17 post-infection from both groups of mice. Bar diagrams denote frequency and absolute number of CD11bhigh cells in infected corneas from both the groups of mice on day 17 post-infection. (n = 7 corneas per group). p values were calculated using two-tail student’s t-test. (***p<0.001, **p<0.01, and *p<0.05 significant). Figure 11 Schematic of events in uninfected and HSV-1 infected corneas of NK1R−/− mice to cause an early development of HSK Cells in the apical layer of the corneal epithelium of uninfected NK1R−/− mice slough off prematurely due to an abnormal localization or expression of junctional complex proteins. This leads to an increased basal epithelial mitotic index, reduced corneal nerve density, and reduced volume of tears. Lack of NK1R survival signal is the most likely cause of the reduced number of resident corneal CD11c+ cells noted in NK1R−/− mice. Increased CD11b+CD11c+ cells found near the limbal area of uninfected NK1R−/− mice is possibly the outcome of low-grade inflammation developed due to lesser volume of tears. Altered ocular surface in NK1R−/− mice ease the establishment of corneal HSV-1 infection, and an increased influx of neutrophils in infected cornea further facilitate HSV-1 replication. Increased amount of viral antigens drained to the DLNs cause an increased expansion of HSV-1 specific effector CD4 T cells, which migrate to the infected cornea to cause an extensive tissue damage. 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PMC005xxxxxx/PMC5114002.txt
LICENSE: This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. 101633964 42657 Austin J Pulm Respir Med Austin journal of pulmonary and respiratory medicine 27868109 5114002 NIHMS798832 Article Air Pollution and Lung Function Loss: The Importance of Metabolic Syndrome Zhang L 12 Crowley G 1 Haider SH 1 Zedan M 1 Kwon S 1 Nolan A 134* 1 Department of Medicine, Division of Pulmonary, Critical Care and Sleep Medicine, New York University, USA 2 Department of Respiratory Medicine, PLA, Army General Hospital, China 3 Department of Environmental Medicine, New York University, USA 4 Bureau of Health Services and Office of Medical Affairs, Fire Department of New York, USA * Corresponding author: Anna Nolan, Division of Pulmonary, Critical Care and Sleep, NYU School of Medicine, New Bellevue, 7N Room 24462 1st Avenue, New York, NY 10016, USA 30 6 2016 17 6 2016 2016 17 11 2016 3 2 1043This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. Air pollution: an international issue A multinational study spanning over 20 years showed that approximately 5.5 million deaths were attributed to airpollution [1]. Even brief ambient Particulate Matter (PM) exposure significantly decreases FEV1 [2–6]. Development of airway injury following PM exposure is a major health concern worldwide and is associated with an increased risk for hospital admission due to respiratory and vascular diseases [7]. Furthermore, a reduction of pollutants has the potential to save five million lives per year [8]. Both diseases place tremendous burden on the world’s health resources. The costs and challenges of remedying the pollution burden may have a more profound effect on developing countries. As a pulmonologist in Beijing, pollution has always been a significant contributor to the disease burden of my patients. My experience in the Division of Pulmonary and Critical Care at New York University has raised my awareness about the relevance of air pollution and associated diseases. This brief overview will serve to highlight the challenges faced in dealing with this international issue of pollution and Metabolic Syndrome (MetSyn) which are both significant contributors to loss of lung function. Air pollution in China In 2010, approximately 1.2 million deaths may have been secondary to the negative health effects of ambient PM exposure. These deaths represent a 33% increase when compared to data published in 1990 [9]. In 2013, Beijing had a “haze event;” some estimates indicate PM2.5 levels reached a monthly average above 170 μg/m3, peaking at 677μg/m3. This haze event may have been responsible for an estimated 690 deaths, 5470 hospitalizations for respiratory illness, and an increase in hospitalizations for cardiovascular disease [10]. In my hometown of Beijing, the pollution remains severe. These high levels of PM originate from a number of sources; the burning of fossil fuels and biomass are significant contributors [11]. PM2.5 includes products of combustion and is considered on a mass basis to be more toxic due to its hazardous components which stay airborne longer and can more readily reach the lung [12,13]. Epidemiologic studies have associated PM2.5 pollution with adverse health effects, linking PM2.5 exposure to the development of vascular and pulmonary diseases [14–23]. PM exposure causes systemic inflammation and chronic lung disease Airflow obstruction from PM and smoke exposure is a heterogeneous process. PM exposure causes systemic inflammation, endothelial dysfunction, and subsequent end-organ damage [24–26]. The development of obstructive airways disease from PM induced inflammation is poorly understood [27]. In addition to the aforementioned short term effects of PM exposure, long-term exposure also impairs lung function [17,28–31]. A 3.4% change in forced vital capacity per 10 μg/m3 change in concentration of PM10 has been reported [28]. The group that I am working with has focused on the exposure that occurred after the destruction of the World Trade Center (WTC) complex on 9/11/2001. Similarly, many firefighters, rescue workers, and lower Manhattan residents who were exposed to WTC-PM and other toxins also experience a loss of lung function [32,33]. However, we know there to be heterogeneity in the development of lung disease even after a high intensity exposure; therefore, we and other investigators have tried to identify other cofactors such as MetSyn that contribute to disease development. MetSyn, the collection of risk factors including hypertension, dyslipidemia, insulin resistance, and abdominal obesity, is a key cofactor that, according to 2012 estimates, affects at least 34% of Americans [34–36]. Previous cross-sectional studies have suggested associations between impaired lung function and MetSyn [37–41]. Longitudinal assessment showed that lower baseline FEV1 was an independent predictor of development of MetSyn [42]. In New York City 2014, the average value of PM2.5 was 8.48 μg/m3 and the PM10 24-hour maximum concentration was 46.25 μg/m3. While these levels are well below what is found in my native city of Beijing, there may still be room for improvement. Nearly half of COPD patients exhibit MetSyn [43]. In air pollution studies, long-term PM exposure and coexisting MetSyn increase systemic inflammation [34]. In the WTC exposed FDNY cohort, dyslipidemia (defined as an elevated triglycerides and low high-density lipoprotein) was significantly predictive of developing a FEV1 less than the lower limit of normal [24]. The systemic inflammatory effects of lipids and subsequent end-organ effects are of great interest. In light of these findings, our work has focused on the effects of lipids and inflammation in the development of PM-induced lung injury. The Chinese economy has undergone significant growth in recent years. The lifestyle and dietary choices of the Chinese population have similarly undergone changes that have led to the estimated prevalence of obesity in the Chinese adult population to be 30% [44]. Childhood obesity (BMI≥ 95th percentile) is rising in China (from 1.2% to 10% for boys age 7–18 and from 1.1% to 5.2% for girls age 7–18 between 1985 and 2000, in Beijing) [45,46]. Unhealthy eating habits, however, are not the only factors contributing to the rise in obesity. As discussed in more detail in previous sections of this paper, PM exposure has been linked to a number of adverse health effects [14–23]. Recently, ambient levels of Beijing PM have been shown to induce systemic inflammation and metabolic dysfunction in an exposed rat population, resulting in significantly increased body weight (when compared to a population exposed to filtered air) [44]. If these findings are found to be generalizable to the human population, it would indicate ambient Beijing PM has led to metabolic dysfunction in the people of Beijing. The adverse effects from this exposure coupled with an increase in unhealthy lifestyle choices of a city-dwelling population would be a probable explanation of the high prevalence of MetSyn in China which has been cited to be as high as 21.3%, with urban populations being more likely to exhibit MetSyn (compared to rural populations, OR=1.27) [47]. Metabolic biomarkers of obstructive airway disease not only have prognostic utility, they can direct future research into mechanisms producing airflow obstruction and fuel future work into their downstream effects. Multiple biomarkers have been identified and studied in clinical trials [48]. Our studies have focused on the well-phenotyped World Trade Center (WTC)-exposed Fire Department of New York (FDNY) cohort. In this population, we have observed classic lipid and non-lipid vascular risk factors predict abnormal lung function in the WTC-PM exposed cohort [24,49–51]. This data fits into a larger set of studies demonstrating an increased risk of patients with dyslipidemia for developing COPD due to air pollution and smoking [52]. The mechanism of bioactive lipid induced pulmonary inflammation is poorly understood but is an area of significant interest [53,54]. Biologically active lipid metabolites may identify plausible pathways of disease that could be pharmacological targets. Given the high prevalence of metabolic syndrome in my home country of China and throughout the world, establishing a mechanistic link between lipid mediators of MetSyn and lung injury is crucially important. The adverse impact on quality of life and sizable cost of WTC-lung disease are both public health concerns. Validating metabolic contributors of PM associated lung disease in the Chinese population is necessary. Future work will focus on the metabolomics of these PM exposed populations. 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Chinatown, New York Allergy Asthma Proc 2009 30 605 611 19772715 34 Chen JC Schwartz J Metabolic syndrome and inflammatory responses to long-term particulate air pollutants Environ Health Perspect 2008 116 612 617 18470293 35 Grundy SM Cleeman JI Daniels SR Donato KA Eckel RH Franklin BA Diagnosis and management of the metabolic syndrome: an American Heart Association/National Heart, Lung, and Blood Institute Scientific Statement Circulation 2005 112 2735 2752 16157765 36 Aguilar M Bhuket T Torres S Liu B Wong RJ Prevalence of the metabolic syndrome in the United States, 2003–2012 JAMA 2015 313 1973 1974 25988468 37 Lazarus R Sparrow D Weiss ST Baseline ventilatory function predicts the development of higher levels of fasting insulin and fasting insulin resistance index: the Normative Aging Study Eur Respir J 1998 12 641 645 9762793 38 Lawlor DA Ebrahim S Smith GD Associations of measures of lung function with insulin resistance and Type 2 diabetes: findings from the British Women’s Heart and Health Study Diabetologia 2004 47 195 203 14704837 39 Lin WY Yao CA Wang HC Huang KC Impaired lung function is associated with obesity and metabolic syndrome in adults Obesity (Silver Spring) 2006 14 1654 1661 17030977 40 Fimognari FL Pasqualetti P Moro L Franco A Piccirillo G Pastorelli R The association between metabolic syndrome and restrictive ventilatory dysfunction in older persons J Gerontol A Biol Sci Med Sci 2007 62 760 765 17634324 41 Leone N Courbon D Thomas F Bean K Jégo B Leynaert B Lung Function Impairment and Metabolic Syndrome: The Critical Role of Abdominal Obesity American Journal of Respiratory and Critical Care Medicine 2009 179 509 516 19136371 42 Hsiao FC Wu CZ Su SC Sun MT Hsieh CH Hung YJ Baseline forced expiratory volume in the first second as an independent predictor of development of the metabolic syndrome Metabolism 2010 59 848 853 20006363 43 Watz H Waschki B Kirsten A Müller KC Kretschmar G Meyer T The metabolic syndrome in patients with chronic bronchitis and COPD: frequency and associated consequences for systemic inflammation and physical inactivity Chest 2009 136 1039 1046 19542257 44 Wei Y Zhang JJ Li Z Gow A Chung KF Hu M Chronic exposure to air pollution particles increases the risk of obesity and metabolic syndrome: findings from a natural experiment in Beijing FASEB J 2016 30 2115 2122 26891735 45 Ji CY Report on childhood obesity in China (1)–body mass index reference for screening overweight and obesity in Chinese school-age children Biomed Environ Sci 2005 18 390 400 16544521 46 Ji CY The prevalence of childhood overweight/obesity and the epidemic changes in 1985–2000 for Chinese school-age children and adolescents Obes Rev 2008 9 Suppl 1 78 81 18307704 47 Xi B He D Hu Y Zhou D Prevalence of metabolic syndrome and its influencing factors among the Chinese adults: the China Health and Nutrition Survey in 2009 Prev Med 2013 57 867 871 24103567 48 Barnes PJ The cytokine network in asthma and chronic obstructive pulmonary disease J Clin Invest 2008 118 3546 3556 18982161 49 Nolan A Naveed B Comfort AL Ferrier N Hall CB Kwon S Inflammatory biomarkers predict airflow obstruction after exposure to World Trade Center dust Chest 2012 142 412 418 21998260 50 Weiden MD Naveed B Kwon S Cho SJ Comfort AL Prezant DJ Cardiovascular biomarkers predict susceptibility to lung injury in World Trade Center dust-exposed firefighters Eur Respir J 2013 41 1023 1030 22903969 51 Tsukiji J Cho SJ Echevarria GC Kwon S Joseph P Schenck EJ Lysophosphatidic acid and apolipoprotein A1 predict increased risk of developing World Trade Center-lung injury: a nested case-control study Biomarkers 2014 19 159 165 24548082 52 Tiengo A Fadini GP Avogaro A The metabolic syndrome, diabetes and lung dysfunction Diabetes Metab 2008 34 447 454 18829364 53 Bowler RP Jacobson S Cruickshank C Hughes GJ Siska C Ory DS Plasma sphingolipids associated with chronic obstructive pulmonary disease phenotypes Am J Respir Crit Care Med 2015 191 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PMC005xxxxxx/PMC5114019.txt
LICENSE: This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. 2984819R 7707 Tetrahedron Lett Tetrahedron Lett. Tetrahedron letters 0040-4039 27867229 5114019 10.1016/j.tetlet.2012.03.073 NIHMS798100 Article Eucalyptals D and E, new cytotoxic phloroglucinols from the fruits of Eucalyptus globulus and assignment of absolute configuration Wang Ji ab†‡ Zhai Wen-Zhu ab†‡ Zou Yike c§ Zhu Jing-Jing a† Xiong Juan b‡ Zhao Yun a† Yang Guo-Xun b‡ Fan Hui a† Hamann Mark T. c§ Xia Gang a† Hu Jin-Feng ab*†‡ a Department of Natural Products for Chemical Genetic Research, Key Laboratory of Brain Functional Genomics, Ministry of Education, East China Normal University, No. 3663 North Zhongshan Rd., Shanghai 200062, PR China b Department of Natural Products Chemistry, School of Pharmacy, Fudan University, No. 826 Zhangheng Rd., Shanghai 201203, PR China c Department of Pharmacognosy, School of Pharmacy, The University of Mississippi, University, MS 38677, USA * Corresponding author. Tel./fax: +86 21 51980172. fhu@brain.ecnu.edu.cn, jfhu@fudan.edu.cn (J.-F. Hu) † Responsible for phytochemistry work. ‡ Responsible for cytotoxic assay. § Responsible for ECD calculation. 28 6 2016 25 3 2012 23 5 2012 17 11 2016 53 21 26542658 This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. Two new phloroglucinols, named eucalyptals D (1) and E (2), along with a related known compound (euglobal-In-3, 3) were isolated from the fruits of Eucalyptus globulus. Their structures were established on the basis of extensive spectroscopic studies, revealing that they share a common 3,5-diformyl-isopentyl phloroglucinol unit, but each is instead coupled to a different sesquiterpenoid skeleton (aromadendrene in 1, cadinene in 2, and a spirosesquiterpene in 3). Compound 1 possessed an unusual seven-membered D ring with an ether bridge between C-2 of the aromadendrene moiety and C-2′ of the aromatic unit. The absolute configuration of the isolates was defined by the comparison of experimental and calculated electronic circular dichroism (ECD) spectra. Compounds 1–3 exhibited significant in vitro cytotoxicities against a few human cancer cell lines (Huh-7, Jurkat, BGC-823, and KE-97) using the CellTiter-Glo™ luminescent cell viability assay method. Eucalyptus globulus Myrtaceae Phloroglucinols Eucalyptals Cytotoxicities Introduction The phloroglucinol-terpene adducts are a class of secondary metabolites with interesting bioactive structures unique to plants in the family Myrtaceae, especially Eucalyptus species.1–3 The blue gum plant Eucalyptus globulus Labill was autochthonous to Australia.4 It was recorded that this plant was first introduced to China in late 1890s.5 Now it is widely cultivated in southern and south-western China, especially in Yunnan and Jiangxi provinces. The dried mature fruits, earned a common Chinese name ‘Yi-Kou-Zhong’, have been used as an herbal medicine for the treatment of influenza, inflammation, and eczema.6 The fruits have been documented to yield cytotoxic 3,5-diformyl-isopentyl phloroglucinol-coupled sesquiterpenes.7,8 In an ongoing project towards the discovery of new antitumor agents from natural products,9,10 two (1,2) new and one (3) related known phloroglucinol-coupled sesquiterpenes (Fig. 1) were isolated from ‘Yi-Kou-Zhong’ collected from the noted Jing-gang Mountain. We herein report the characterization of the new compounds and their cytotoxic effects against four human cancer cell lines (Huh-7 hepatocarcinoma, Jurkat T cell lymphoblast, BGC-823 and KE-97 gastric carcinoma). Results and discussion Air-dried and powdered fruits of E. globulus were extracted with 95% ethanol at room temperature (rt), and the extract was concentrated in vacuo. The crude extract was suspended in H2O and then exhaustively extracted with EtOAc. Our phytochemical reinvestigation on the EtOAc fraction gave rise to three 3,5-diformyl-isopentyl phloroglucinol-coupled sesquiterpenes (1: 3.4 mg, 2: 1.7 mg, 3: 4.2 mg). The isolation was indeed guided by observing the typical signals of the formyl protons in the 1H NMR spectrum. Comparison of the spectroscopic data and physical properties with those reported in the literature, compound 3 was identified as euglobal-In-3, a phloroglucinol possessing an unusual spirosesquiterpene skeleton previously isolated from the leaves of Eucalyptus incrassate.11 The absolute configuration of 3 was deduced herein by means of the electronic circular dichroism (ECD) calculation for the first time (see below). Eucalyptal D (1)12 was obtained as a pale yellow gum. The molecular formula of 1 was determined to be C28H36O5 based on a prominent molecular ion peak at m/z 452.2562 [M]+ in its HR-EIMS. The IR and UV data of compound 1 were in good agreement with those of euglobal-In-3 (3),11 indicating that 1 also has a similarly substituted phloroglucinol moiety. The 1H NMR spectral data (in CDCl3, Table 1) of 1 showed two D2O-exchangable hydrogen-bonded phenolic hydroxyls [δ 13.35 (1H, s, 4′-OH), 13.22 (1H, s, 6′-OH)], two aldehyde protons [δ 10.09 (1H, s, H-7′), 10.20 (1H, s, H-8′)], one oxymethine [δ 5.36 (1H, br d, J = 4.5 Hz, H-2)], a methine proton [δ 3.19 (1H, br d, J = 11.0 Hz, H-9′)] adjacent to the aromatic ring and isobutyl side chain, four singlet methyls [δ 1.60 (vinylic Me-14), 1.18 (Me-15), 1.06 (Me-12), 0.99 (Me-13)], two doublet methyls [δ 0.95 (3H, d, J = 6.3 Hz, Me-13′), 0.77 (3H, d, J = 6.6 Hz, Me-12′)], and two typical methine protons resonating at δ 0.68 (1H, dd, J = 11.3, 9.9 Hz, H-6) and 0.49 (1H, ddd, J = 9.9, 9.5, 6.3 Hz, H-7) attributed to a gem-dimethyl cyclopropane ring. 13C and DEPT NMR spectra of 1 exhibited twenty-eight signals classified as six sp3 methyl, four sp3 methylene, six sp3 (one oxygenated at δ 86.5) and two sp2 (δ 193.3, 192.1) methine, two sp3, and eight sp2 (δ 169.5, 168.3, 167.2, 138.0, 135.5, 115.9, 108.2, 104.6) quaternary carbons (Table 1). These results demonstrated that 1 was a phloroglucinol-coupled sesquiterpene, and the 3,5-diformyl-isopentyl phloroglucinol unit of which was secured by 2D NMR experiments. An obvious isobutyl spin system was found in the COSY spectrum. In the HMBC spectrum, methine proton H-9′ was correlated with C-l′, C-2′, C-6′, and C-11′, while formyl proton H-7′ was correlated with C-2′, C-3′, and H-8′ was correlated with C-5′ and C-6′ (Fig. 2). Two separated spin systems of –OCHCH2– (H-2 and H2-3) and – CHCHCHCH2CH2– (H-5, H-6, H-7, H2-8, andH2-9) were found for the sesquiterpene unit in the COSY spectrum of 1. One bond proton–carbon connectivities and the long range proton–carbon couplings in this unit were then ascertained by HSQC and HMBC NMR experiments (Fig. 2), which led to the determination of an aromadendrene-type sesquiterpene moiety involving a 5-membered ring (A), 7-membered ring (B), and 3-membered ring (C). The molecular formula of 1 accounted for eleven degrees of unsaturation. Apart from six double-bond equivalents in the 3,5-diformyl-isopentyl phloroglucinol unit, and the tricyclic sesquiterpene unit bearing an unambiguous double-bond (olefinic carbons resonating at δ 138.0 and 135.5), the remaining one degree of unsaturation must be an additional ring connecting between the two units. The linkage positions could be thereafter easily elucidated by a key HMBC correlation between the oxymethine proton H-2 at δ 5.36 and C-2′ at δ 168.3. Meanwhile, H-9′ at δ 3.19 was further correlated with C-3 (δ 39.9), and C-15 (δ 22.4), H-5 at δ 2.08 (1H, d, J = 11.5 Hz) was correlated with C-9′ at δ 43.0 in the HMBC NMR spectrum. In fact, similar phloroglucinol–aromadendrene coupled compounds (e.g. macrocarpals A and B, euglobal V) were previously obtained from the fruits and leaves of E. globulus.8,13–16 However, such a seven-membered D ring constructed with an ether bridge between C-2 of the tricyclic aromadendrene moiety and C-2′ of the aromatic E ring in compound 1 has never been encountered. The relative stereochemistry of 1 was determined by the analysis of the proton coupling constants (Table 1) and the NOE correlations in the NOESY NMR spectrum (Fig. 3). A large coupling constant (11.5 Hz) between H-5 and H-6 indicated that both H-5 and H-6 took opposite axial positions. Clear NOE correlations were observed between H-5 and Me-12 at δ 1.06, between H-5 and H-9′, between H-6 at δ 0.68 and H-7 at δ 0.49, between H-6 and Me-15 at δ 1.18, between Me-15 and H-3a at δ 1.53, between H-3b at δ 2.32 and H2-10′ at δ 1.42/1.30, as well as between H2-3 and H-2. These data revealed that H-2, H-6, H-7, Me-15, and the isobutyl group adopted the same orientation, whereas H-5, H-9′ and the cyclopropane ring assumed the same orientation as depicted in Fig. 1. Eucalyptal E (2)12 was also obtained as a pale yellow gum. The molecular weight of 2 and its chemical formula of C28H38O7 were deduced from its HR-EIMS, which resulted in an [M-H2O]+ ion peak at m/z 468.2516. The IR and UV data of 2 closely resembled those of compounds 1 and 3,11 indicating that 2 also has a substituted phloroglucinol moiety. The 1H and 13C NMR data (Table 1) of 2 showed general features similar to those of compound 4 (eucalyptal B, Fig. 1), a known 3,5-diformyl-isopentyl phloroglucinol-coupled cadinene previously also isolated from the fruits of E. globulus in 2007.7 The 1H NMR spectral data of 2 exhibited two D2O-exchangable phenolic hydroxyls [δ 13.35 (1H, s, 4′-OH), 13.38 (1H, s, 6′-OH)], two aldehyde protons [δ 10.06 (1H, s, H-7′), 10.17 (1H, s, H-8′)], an olefinic proton resonating at δ 5.62 (1H, brs, H-2), one oxymethine [δ 4.55 (1H, d, J = 10.0 Hz, H-5α)], a methine proton [δ 2.66 (1H, t, J = 5.6 Hz, H-9′)] adjacent to the aromatic ring and isobutyl side chain, four tertiary methyl groups with singlets at δ 1.26 (3H, Me-12), 1.30 (3H, Me-13), 1.28 (3H, Me-14), and 0.88 (3H, Me-15), and two secondary methyl doublets at δ 0.95 (3H, d, J = 6.5 Hz, Me-12′) and 0.97 (3H, d, J = 6.5 Hz). Similar to 1, the 13C NMR and DEPT NMR spectra of 2 also gave 28 signals [six sp3 methyl, four sp3 methylene, five sp3 (one oxygenated at δ 77.3) and three sp2 (δ 191.7×2, 115.4) methine, three sp3 (two oxygenated at δ 74.9 and 70.4) and seven sp2 (δ 169.3, 167.9, 162.2, 138.5, 107.0, 104.0, 103.4) quaternary carbons] (Table 1). The obvious difference between 2 and 4 was in the cadinene moiety. A tertiary methyl group (geminal to a carbon bearing an oxygen) at δ 1.28 (3H, Me-14) was present in 2, instead of the Δ10(14) exomethylene group in 4.7 Moreover, a trisubstituted double bond at C-1 was present in 2. These structural features were confirmed by 2D NMR experiments, and the planar structure of 2 was determined. The relative stereochemistry of 2 was determined by a combination of analysis of the proton coupling constants (Table 1) and the NOE correlations in the NOESY NMR spectrum (Fig. 3). In the proposed structure of 2, a large coupling constant (10.0 Hz) between H-5 at δ 4.55 and H-6 at δ 2.62 indicated that both H-5 and H-6 took opposite axial positions. Clear NOE correlations were observed between H-5 and Me-12 at δ 1.26, between H-5 and H-3a at δ 2.51, between H-6 and H-7 at δ 2.01, between H-6 and Me-15 at δ 0.88, between Me-15 and H-3b at δ 2.05, between Me-15 and H-9′ at δ 2.66, as well as between Hax-9 at δ 1.83 (br d, J = 16.1, 11.3 Hz) and Me-14 at δ 1.28, but not between Me-14 and H-6 (otherwise they should have a strong NOE correlation). The above data mentioned that H-5, the 2-hydroxyisopropyl group at C-7, Me-14, and the isobutyl group at C-9′ took the same orientation, whereas H-6, H-7, 10-OH, Me-15, and H-9′ adopted the same orientation as illustrated in Figure 1. The overall absolute configuration of phloroglucinol-coupled sesquiterpenes has never been determined. To our knowledge, the absolute configuration at C-9′ of macrocarpals H, I, and J was once determined by a computational chemical method involving Monte Carlo (MC) and semiempirical molecular orbital calculations.17 The absolute stereochemistry at C-10 of a derivative of macrocarpals A and C was established by chemical transformation and modified Mosher’s method; however, the absolute configuration of entire structure of the macrocarpals A and C was still unknown.14 To date, the calculated experimental electronic circular dichroism (ECD) spectral data have been successfully utilized to determine the absolute configuration of complex naturally occurring compounds (e.g. sorbiterrin A,18 psiguadials,19 and discorhabdins20). To further determine the absolute configuration of compounds 1–3, a computational approach was applied, and the simulated ECD curves were then overlaid with the experimental CD spectra for comparison. Briefly, conformational analyses were carried out by the Amber force field method followed by the PM6 semi-empirical method in tandem to acquire pre-optimized structures. As a result, a group of low energy conformations of compounds 1–3 were generated. Each low energy conformation was further optimized by the density functional theory (DFT) method at the B3LYP/6-31g(d,p) level in the gas phase and applying the Polarizable Continuum Model (PCM) solvation model, respectively, and the optimized geometries were then followed by excited state calculations using the time-dependent density functional theory (TDDFT) method at the same theoretical level. Resulting from the simulated ECD curves overlaid with the experimental CD spectra of each compound (Fig. 4) (see Supplementary data), the absolute configuration of compounds 1–3 was thus finally assigned as (2R, 4R, 5R, 6R, 7R, 9′S)-eucalyptal D (1), (4R, 5S, 6R, 7R, 10R, 9′S)-eucalyptal E (2), and (1S, 4R, 5S, 10R, 9′S)-euglobal-In-3 (3), respectively. From a structural point of view, the above three isolates (1–3) have a common 3,5-diformyl-isopentyl phloroglucinol unit, but each is instead coupled to a different sesquiterpenoid framework. With regard to their biosynthetic pathway, these phloroglucinol-sesquiterpene adducts (1–3) are thought to be derived biogenetically from a phloroglucinol precursor (a) and a bicyclogermacrene (b) (Fig. 5). In fact, biogenetic pathways have been previously proposed for phloroglucinol-coupled aromadendrenes (e.g. macrocarpals A–C,14) cadinenes (e.g. eucalyptals A–C,7) and spirosesquiterpenes (e.g. euglobal-In-211) obtained from the plant E. globulus. Since compound 1 contained an unusual seven-membered D ring with an ether bridge between C-2 of the aromadendrene moiety and C-2′ of the aromatic unit, a possible biosynthetic pathway is therefore highlighted in Fig. 5. The key step is producing a stable intermediate (c) possessing an allyl cation with a p–π conjugated effect, followed by a carbocation-induced cyclization under acidic condition to form such a seven-membered D ring in compound 1. The cytotoxicities of compounds 1–3 against human BGC-823 and KE-97 gastric, Huh-7 hepatocarcinoma, and Jurkat T lymphoma cancer cell lines were tested by the CellTiter-Glo™ luminescent cell viability assay method.10 The results were summarized in Table 2. Supplementary Material 2 The work was supported by an NSFC Grant (No. 90713040), STCSM Grants (Nos. 06DZ19002, 07DZ22006, 11DZ1921203), and the Fundamental Research Funds for the Central Universities (No. 78210102). The ECD calculation was carried out in MH’s group, to whom the computational resources were provided by the Mississippi Center for Supercomputing Research (MCSR), the United States of America. Figure 1 The structures of phloroglucinol-coupled sesquiterpenes 1–4. Figure 2 Key COSY ( ) and HMBC (H→C) correlations of 1. Figure 3 Observed key NOE (H H) correlations of 1 and 2. Figure 4 Simulated ECD spectra of 1–3 (after Boltzmann averaging) compared with the experimental CD spectra. Figure 5 Hypothetical biosynthetic pathway of 1. Table 1 1H and 13C NMR data of 1 and 2 (in CDCl3, δ in ppm, J in Hz) No. 1a 2b δ H δ C δ H δ C 1 138.0 138.5 2 5.36 (br d, 4.5) 86.5 5.62 (br s) 115.4 3 1.53 (dd, 14.2, 4.5, H-3a) 2.32 (br d, 14.2, H-3b) 39.9 2.51 (br d, 18.0, H-3a) 2.05 (dd, 18.0, 4.3, H-3b) 34.6 4 43.7 43.1 5 2.08 (d, 11.5) 47.1 4.55 (d, 10.0) 77.3 6 0.68 (dd, 11.5, 9.9) 32.4 2.62 (br d, 10.0) 43.5 7 0.49 (ddd, 10.0, 9.9, 5.3) 24.9 2.01 (m) 29.6 8 1.41 (overlapped, H-8a) 1.58 (overlapped, H-8b) 21.3 2.23 (m) 1.65 (overlapped) 25.1 9 2.14 (overlapped, H-9a) 2.04 (overlapped, H-9b) 36.4 1.83 (br dd, 16.0, 10.5, Hax) 1.66 (overlapped, Heq) 31.1 10 135.5 70.4 11 18.6 74.9 12 1.06 (s, 3H) 15.6 1.26 (s, 3H) 30.0 13 0.99 (s, 3H) 28.1 1.30 (s, 3H) 29.6 14 1.60 (s, 3H) 22.0 1.28 (s, 3H) 22.3 15 1.18 (s, 3H) 22.4 0.88 (s, 3H) 20.9 1′ 115.9 107.0 2′ 168.3 162.2 3′ 108.2 104.0 4′ 167.2 167.9 5′ 104.6 103.4 6′ 169.5 169.3 7′ 10.09 (s) 193.3 10.06 (s) 191.7 8′ 10.20 (s) 192.1 10.17 (s) 191.7 9′ 3.19 (br d, 11.0) 43.0 2.66 (t, 5.6) 36.3 10′ 1.30 (overlapped, H-a) 1.42 (overlapped, H-b) 41.7 1.13 (m) 1.38 (m) 43.5 11′ 1.11 (m) 25.8 1.70 (m, overlapped) 27.6 12′ 0.95 (d, 6.3) 21.4 0.95 (d, 6.5) 23.0 13′ 0.77 (d, 6.6) 24.5 0.97 (d, 6.5) 23.1 4′-OH 13.35 (s) 13.35 (s) 6′-OH 13.22 (s) 13.38 (s) a Recorded at 500 and 125 MHz for 1H and 13C, respectively. b Recorded at 400 and 100 MHz for 1H and 13C, respectively. Table 2 Cytotoxicities of compounds 1–3 Compound IC50 (μM, mean ± SEM, n = 4) KE-97 Jurkat BGC-823 Huh-7 1 5.20 ± 1.16 7.16 ± 2.84 6.65 ± 1.36 11.73 ± 1.81 2 7.22 ± 2.06 10.71 ± 4.21 10.16 ± 0.89 24.57 ± 4.45 3 4.63 ± 0.86 10.50 ± 3.25 14.27 ± 0.78 10.77 ± 3.55 STa 0.13 ± 0.01 0.14 ± 0.03 0.17 ± 0.02 0.23 ± 0.08 a Staurosporine (ST): Positive control. Supplementary data Supplementary data (NMR, HR-EIMS, CD/UV curves, and experimental/calculated electronic circular dichroism (ECD) spectra of compounds 1–3) associated with this article can be found, in the online version, at http://dx.doi.org/10.1016/j.tetlet.2012.03.073. References and notes 1 Eyles A Davies NW Mohammed C J Chem Ecol 2003 29 881 898 12775149 2 Eschler BM Pass DM Willis R Foley WJ Biochem Syst Ecol 2000 28 813 824 10913843 3 Bharate SB Singh IP Bioorg Med Chem Lett 2011 21 4310 4315 21665468 4 Kawabata T Hasegawa T Nojiri Y Uchida C Tsubata T Kato H Takano F Ohta T Heterocycles 2011 83 631 636 5 Editorial Commission of China Flora Flora of China 53 Science Press Beijing 1984 28 6 Jiangsu New Medical College Dictionary of Chinese Materia Medica Shanghai Scientific & Technical Publishing House Shanghai 1985 1793 7 Yin S Xue JJ Fan CQ Miao ZH Ding J Yue JM Org Lett 2007 9 5549 5552 18020353 8 Yang XW Guo QM Wang Y Xu W Tian L Tian XJ Bioorg Med Chem Lett 2007 17 1107 1111 17118653 9 Li XW Weng L Gao X Zhao Y Pang F Liu JH Zhang HF Hu JF Bioorg Med Chem Lett 2011 21 366 372 21109433 10 Wu SB Bao QY Wang WX Zhao Y Xia G Zhao Z Zeng HQ Hu JF Planta Med 2011 77 922 928 21243584 11 Takasaki M Konoshima T Kozuka M Haruna M Ito K Nat Med 1997 51 486 490 12 The new phloroglucinol–sesquiterpene adducts 1 and 2 were named eucalyptals D and E, respectively. The trivial name was sequentially derived from the work of Yue and co-workers (Ref.7 herein). Eucalyptal D (1): Pale yellow gum; [α]D22 104.7 (c 0.34, CHCl3); UV (CH3OH) λmax (log ε) nm: 274 (4.38). IR (KBr) νmax (cm−1): 3424 (br), 2924, 1633, 1601, 1448, 1384, 1173, 1021; For 1H, 13C NMR data, see Table 1; EI-MS: m/z 452 [M]+; HR EI-MS: m/z 452.2562 [M]+ (C28H36O5; calcd 452.2563, Δ = −0.2 ppm). Eucalyptal E (2): Pale yellow gum; [α]D22 −135.3 (c 0.17, CHCl3); UV (CH3OH) λmax (log ε) nm: 276 (4.52). IR (KBr) νmax (cm−1): 3444 (br), 2925, 1632, 1445, 1384, 1045; For 1H, 13C NMR data, see Table 1; EI-MS: m/z 468 ([M-H2O]+); HR EI-MS: m/z 468.2516 [M–H2O]+ (C28H36O6; calcd 468.2512, Δ = 0.9 ppm). 13 Osawa K Yasuda H J Nat Prod 1996 59 823 827 8864235 14 Nishizawa M Emura M Kan Y Yamada H Ogawa K Hamanaka N Tetrahedron Lett 1992 33 2983 2986 15 Takasaki M Konoshima T Fujitani K Yoshida S Nishimura H Tokuda H Nishino H Iwashima A Kozuka M Chem Pharm Bull 1990 38 2737 2739 1963812 16 Amano T Komiya T Hori M Goto M J Chromatogr 1981 208 347 355 17 Osawa K Yasuda H Morita H Takeya K Itokawa H Chem Pharm Bull 1997 45 1216 1217 18 Chen L Zhu TJ Ding YQ Khan IA Gu QQ Li DH Tetrahedron Lett 2012 53 325 328 19 Shao M Wang Y Liu Z Zhang DM Cao HH Jiang RW Fan CL Zhang XQ Chen HR Yao XS Ye WC Org Lett 2010 12 5040 5043 20929258 20 Hu JF Fan H Xiong J Wu SB Chem Rev 2011 111 5465 5491 21688850
PMC005xxxxxx/PMC5114023.txt
LICENSE: This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. 0042124 4284 Int J Cancer Int. J. Cancer International journal of cancer 0020-7136 1097-0215 27038352 5114023 10.1002/ijc.30117 NIHMS828607 Article The association of soy food consumption with the risk of subtype of breast cancers defined by hormone receptor and HER2 status Baglia Michelle L Zheng Wei Li Honglan Yang Gong Gao Jing Gao Yu-Tang Shu Xiao-Ou Division of Epidemiology, Department of Medicine, Vanderbilt-Ingram Cancer Center, Vanderbilt University School of Medicine, Nashville, TN, 37203 (MLB, WZ, GY, XOS); Department of Epidemiology, Shanghai Cancer Institute, Shanghai, People’s Republic of China, 200032 (HL, JG, YTG) Corresponding author: Xiao-Ou Shu, M.D., Ph.D., Vanderbilt Epidemiology Center, Vanderbilt University Medical Center, 2525 West End Avenue, Suite 600 (IMPH), Nashville, TN 37203-1738, Phone: 615-936-0713, Fax: 615-936-8291, xiao-ou.shu@vanderbilt.edu 10 11 2016 05 5 2016 15 8 2016 15 8 2017 139 4 742748 This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. Soy-food intake has previously been associated with reduced breast cancer risk. Epidemiological evidence for subgroups of breast cancer, particularly by menopausal and hormone receptor status, is less consistent. To evaluate the role of hormone receptor and menopausal status on the association between soy-food intake and breast cancer risk, we measured usual soy-food intake in adolescence and adulthood via food frequency questionnaire in 70,578 Chinese women, aged 40-70 years, recruited to the Shanghai Women’s Health Study (1996-2000). After a median follow-up of 13.2 years (range:0.01-15.0), 1,034 incident breast cancer cases were identified. Using Cox models, we found that adult soy intake was inversely associated with breast cancer risk (hazard ratio-HR) for fifth versus first quintile soy protein intake=0.78; 95% confidence interval (CI):0.63-0.97). The association was predominantly seen in premenopausal women (HR=0.46; 95% CI:0.29-0.74). Analyses further stratified by hormone receptor status showed that adult soy intake was associated with significantly decreased risk of ER+/PR+ breast cancer in postmenopausal women (HR=0.72; 95% CI:0.53-0.96) and decreased risk of ER−/PR− breast cancer in premenopausal women (HR=0.46; 95% CI:0.22-0.97). The soy association did not vary by HER2 status. Furthermore, we found that high soy intake during adulthood and adolescence was associated with reduced premenopausal breast cancer risk (HR=0.53; 95% CI:0.32-0.88; comparing third versus first tertile) while high adulthood soy intake was associated with postmenopausal breast cancer only when adolescent intake was low (HR=0.63; 95% CI:0.43-0.91). Our study suggests that hormonal status, menopausal status, and time window of exposure are important factors influencing the soy-breast cancer association. soy breast cancer adolescence menopausal status hormone receptor status INTRODUCTION Breast cancer is the leading cancer in women worldwide 1. Low rates of breast cancer among women in Asian countries and its rapid increase following emigration to western cultures has led to lifestyle factors, particularly dietary factors, being postulated as an explanation for this pattern 2-4. Epidemiological studies have shown that soy food consumption may decrease the risk of breast cancer and these data were summarized in several recent meta-analyses/systematic reviews 5-8. However, the conclusions from these studies are mixed with one suggesting that the association may be limited to premenopausal women 5, one reporting a stronger effect in postmenopausal women 6, and two concluding no modifying effect of menopausal status 7, 8. The majority of previous studies investigating the association between soy food intake and breast cancer risk have been case-control studies which are subject to recall and selection biases. The few reports from cohort studies have also been inconsistent9, 10,11 and were limited by small numbers of breast cancer cases 9, 11 or did not include all sources of commonly consumed soy foods 11. Isoflavones, which have a chemical structure similar to 17β-estradiol, are the most abundant phytoestrogen in soy food and have been shown to compete with endogenous estrogen to bind estrogen receptors 12. Isoflavones have weak estrogenic potency and endogenous estrogen level may affect their action; isoflavones exert estrogenic-like effects in estrogen-deprived environments and anti-estrogenic effects when endogenous estrogen levels are high 13. Experimental studies have suggested that soy may be protective against hormone-related cancers14. Breast cancer is a heterogeneous disease and biological differences in subtypes depending on the expression of receptors, such as estrogen receptor (ER), progesterone receptor (PR), and human epidermal growth factor receptor-2 (HER2) have been well recognized. Several risk factors for subtypes of breast cancer also differ; compared to receptor-negative tumors, ER+/PR+ tumors are more strongly associated with some reproductive factors, such as parity, timing of births, and age at menopause 15, 16. Due to the ability of isoflavones to bind estrogen receptors, the association between soy intake and breast cancer risk may vary by hormone receptor status of the tumor, though few studies have assessed this association 8, 14. Of the 8 case-control studies we found in the literature that considered hormone receptor status as a potential effect modifier, 3 reported that the protective association between soy and breast cancer was consistent across all subtypes of ER/PR tumors 17-19. Two studies found a greater reduction in risk in those with ER+ tumors compared to ER− tumors 20 or ER+/PR+ tumors compared to other ER/PR status 21, while another study found reduced risk for ER+/PR+ and ER−/PR− tumors but not mixed subtypes 22. One study only observed a decreased risk of ER+/PR+ breast cancer with high adolescent intake 23. To our knowledge, only one study evaluated the association by HER2 status, and it reported null results for all types, i.e. ER+, HER2−, and ER+/PR+/HER2-tumors 24. We only identified one prospective study that investigated soy intake and breast cancer risk by ER and/or PR status of tumors and reported no effect modification among postmenopausal women25. This study, however, was limited by small sample size and did not report the results for premenopausal women by hormone receptor status25. We have previously reported the association of adolescent and adult intake of soy with breast cancer risk in the Shanghai Women’s Health Study (SWHS).10 In the present study, we updated the association between soy food intake and breast cancer risk with a longer follow-up time and provided new information on the association by ER, PR, and HER2 status of the breast cancer. MATERIALS AND METHODS Study Population This study utilized the resources generated from the population-based Shanghai Women’s Health Study (SWHS) for which the methodology has been previously described 26, 27. Briefly, 74,942 women aged 40 to 70 years were recruited to the study from seven urban communities in Shanghai, China between 1996 and 2000, with a participation rate of nearly 93%. Information on demographic and lifestyle factors, as well as participant characteristics including reproductive factors, menstrual history, and medical history, was collected using structured questionnaires through in-person interviews by trained interviewers. Using a standard protocol, anthropomorphic measures, including height, weight, and waist and hip circumferences, were taken at the baseline interview. Self-reported weight information was collected at the 3rd and 4th follow-up interviews. Clinical information and tumor characteristics, including hormone receptor status (ER, PR, and HER2), were extracted from medical charts. Written, informed consent was obtained from all participants and the institutional review boards at all participating institutions approved the study. Ascertainment of Breast Cancer Cases Active surveys were conducted every 2-3 years in the SWHS to collect information on occurrence of cancer and other chronic diseases with the following response rates: 1st in-person follow-up, 99.8%; second, 98.7%; third, 96.7%, and fourth, 92%. Annual record linkage to the population-based Shanghai Cancer Registry was used to identify cancer cases. Women with a first cancer diagnosis of breast cancer (ICD-9 code 174) were defined as cases for this study 28. Cancer diagnosis was verified through in-person visits and review of medical charts obtained from the diagnostic hospital. Dietary Assessment Habitual dietary intake was measured using a validated food frequency questionnaire (FFQ) at baseline and 2-3 years later at the 1st follow-up interview; the latter was completed by 92% of cohort members who were alive at the time of the 1st follow-up. The FFQ used in this study was a comprehensive dietary assessment and was designed to measure the consumption of soy foods commonly consumed in Shanghai, including soymilk, tofu, fresh soy beans, and other soy foods 27. Estimated energy and nutrient intakes, including soy and isoflavones, were calculated by summing products of food intake amount multiplying the nutrient content of the specific food item based on the Chinese Food Composition Tables 2002 29. Statistical Analysis Women were excluded for the present study if they reported a previous cancer diagnosis at baseline (n=1,598), extreme baseline total energy intakes (<500 or ≥3500 kcal/day, n=125), or prior or current hormone replacement therapy (HRT) use (n=2,585) resulting in a total sample size of 70,578 women. Adult habitual dietary intake of soy food was assessed from the baseline and 1st follow-up surveys. Analyses performed used two methods for estimating adult soy intake: (1) the soy protein and soy isoflavone intake based on the baseline survey data only and (2) an average soy protein and isoflavone intake calculated by averaging the soy intake levels from the baseline and 1st follow-up surveys. The latter method was not used for women who developed cancer, diabetes, myocardial infarction, or stroke between the baseline and follow-up surveys because the diagnosis of these conditions may have modified some women’s dietary habits. For these women, the baseline soy measure was used for all analyses of adult intake. Adolescent soy intake was assessed at the baseline interview; women were asked to report their intake of commonly consumed soy foods between the ages of 13 and 15. Baseline variables were evaluated for their association with breast cancer and soy protein intake using generalized linear models for continuous variables and chi-square tests for categorical variables. Soy intake was analyzed using quintiles when sample size allowed, where the lowest quintile served as the reference group, in order to assess the pattern of association with a greater range of intake. Using Cox proportional hazards regression models, the hazard ratios (HR) and 95% confidence intervals (CI) for the association between soy intake and breast cancer risk were estimated. We used age as the time scale for the analyses, where age at enrollment was defined as the entry time and age at diagnosis or censoring was defined as the exit time. Censoring was defined as date of death, last date of follow-up, or the latest date of record linkage. The covariates included in the model were age at enrollment, body mass index (BMI), age at first live birth, physical activity (yes/no), education, family history of breast cancer, season of recruitment, total energy intake, and menopausal status. Menopausal status, which was updated at follow-up interviews, was treated as a time-varying covariate in the analyses. Menopausal status was further evaluated as an effect modifier by stratifying results by menopausal status. Categorical soy intake variables were treated as ordinal variables to evaluate the linear trend. Further analyses stratified by hormonal receptor status were performed. For these analyses, soy intake variables were categorized into tertiles of intake for analysis in each stratified group. The joint effect of average adult and adolescent soy protein intake was evaluated using tertiles of intake. These results were additionally stratified by menopausal status. Results from analyses on soy protein and soy isoflavones were very similar, therefore only the former is included in the tables (see supplemental tables 2 and 3 for soy isoflavone analyses). All statistical analyses were performed using SAS version 9.3 (SAS Institute, Cary, NC). RESULTS Over a median follow-up time of 13.2 years, 1,034 incident breast cancer cases were identified. The average (standard deviation) age at diagnosis was 59.6 (9.3) years. Consistent with the literature on the established risk factors for breast cancer 30 and our previous study,10 breast cancer cases were more likely to have a higher education, higher income, younger age at menarche, older age at menopause, longer total years of menstruation, older age at first live birth, fewer number of live births, and higher BMI compared to non-cases (Supplemental Table 1). Women in the highest quintile of soy protein (median intake 16.4 grams per day) were more likely to have a higher education, to exercise regularly, to be older at menopause onset, to be younger at age of first live birth, to have a family history of breast cancer, to have a higher BMI, to have a higher waist-to-hip ratio, and to consume more overall calories as well as more meats and vegetables. These factors were included in the analysis as covariates. The rate of cigarette smoking was very low in this cohort and was not related to breast cancer risk. Additionally, soy food intake was not related to weight change during the follow-up period. Table 1 shows the association between averaged adult and adolescent soy protein intake and breast cancer risk overall and by menopausal status at diagnosis. These updated results are similar to those previously published.10 Overall, soy protein was associated with a modest decrease in risk of breast cancer. Compared to the lowest quintile of soy intake, the highest quintile of averaged soy protein intake during adulthood was associated with reduced breast cancer risk (HR=0.78; 95% confidence interval (CI): 0.63, 0.97; Ptrend=0.007); the association was predominantly seen in premenopausal women (HR=0.46; 95% CI: 0.29, 0.74; Ptrend=0.004). No significant association was observed among postmenopausal women. Additionally adjusting for adolescent soy intake did not materially change the observed associations (data not shown). Analyses based on baseline soy intake information showed very similar results (data not shown). Adolescent soy intake was not significantly associated with breast cancer risk among premenopausal women; although the HR for the fifth quintile compared to the first quintile was in the direction of reduced risk (HR=0.69; 95% CI: 0.45, 1.04; Ptrend=0.08). No association between adolescent soy intake and postmenopausal breast cancer risk was observed. When stratified by hormone receptor status, HRs for high adult soy intake were below 1.0 for most subtypes, though only one reached statistical significance (Table 2). Compared to women in the lowest tertile of adult average soy protein intake, there was a significantly decreased risk of ER+/PR+ breast cancer among all women (HR=0.75; 95% CI: 0.58, 0.98; Ptrend=0.03), and the association was only significant in postmenopausal women (HR=0.72; 95% CI: 0.53, 0.96; Ptrend=0.02). A significantly decreased risk of ER−/PR− breast cancer was observed for premenopausal women (HR=0.46; 95% CI: 0.22, 0.97; Ptrend=0.04) in the highest tertile of soy intake. Analyses using baseline adult soy intake showed very similar results (data not shown). HRs associated with higher adult soy intake for HER2+ and HER2− breast cancer were both below 1.0 but none of the point estimates were statistically significant. Among premenopausal women, only high soy protein intake in both adulthood and adolescence was significantly associated with the risk (HR=0.53; 95% CI: 0.32, 0.88) (Table 3). Among postmenopausal women, high soy protein intake during adulthood was associated with a significantly decreased risk of breast only when adolescent intake was low (HR=0.63; 95% CI: 0.43, 0.91). High adolescent intake alone or high adult and adolescent intake was not significantly associated with the risk among postmenopausal women. None of the tests for multiplicative interaction between adult and adolescent soy intake reached statistical significance. Among breast cancer patients, those who had high soy food intake during both adolescence and adulthood had a later age of cancer diagnosis (mean age=61.3, SD=8.2) than cases who had low level soy food intake during both periods (mean age=57.5, SD=9.1) (p=0.0001). High consumption during adulthood alone (mean age=59.6, SD=8.5) and during adolescence alone (median age=61.7, SD=11.0) were also related to delayed age at cancer diagnosis. DISCUSSION In this population-based cohort study, we found a decreased risk of breast cancer with high soy food intake among all women, particularly in premenopausal women, consistent with several previous reports, 5, 31, 32 including our own previous study.10 We found that the significant association with ER+/PR+ breast cancer was mainly seen among postmenopausal women, while the association with ER−/PR− breast cancer was predominantly confined to premenopausal women. Furthermore, among premenopausal women, high soy intake during both adult and adolescent periods was associated with the biggest reduction in risk; however, among postmenopausal women, high adult soy intake was only associated with a decreased risk of breast cancer when adolescent intake was low. We did not observe the soy and breast cancer risk association to vary by HER2 status. These results suggest that both adult and adolescent soy food intake may be associated with a reduction in risk of breast cancer, and that this association may vary by menopausal status and ER/PR status. Several systematic reviews and meta-analyses have been conducted to summarize the literature on the association between soy intake and breast cancer risks 5-8. One meta-analysis, which included 12 case-control studies and 6 cohort or nested case-control studies, concluded that the association was strongest in premenopausal women; however, many of the included studies were not designed to assess the association between breast cancer and soy intake and the studies differed in the level of control for confounding 5. Another meta-analysis restricted to prospective studies observed the strongest association in postmenopausal women; however, the studies included were highly heterogeneous which resulted in difficult interpretations of the results 6. A more recent meta-analysis additionally considered the region and type of study conducted and found an association between soy intake and breast cancer risk in Asian countries, but not Western countries, and found no modifying effect of menopausal status; however, there was heterogeneity among the included studies and varying dietary intake measures 7. In our study we observed that the association between soy intake and reduced breast cancer risk was predominantly seen in premenopausal women. This finding is supported by studies that have shown that genistein, an isoflavone found in soy foods, inhibits growth of breast cancer cells in culture when endogenous estrogen levels are high33. None of the meta-analyses evaluated the potential modifying effect of hormone receptor status although this has been evaluated in a few previous studies with inconsistent findings. The majority of the previous studies were case-control studies and had several limitations, such as including a small number of breast cancer cases available for analysis 18, 20, low soy intake in the population studied 17, 20, 23, 25, lack of a comprehensive soy intake assessment 18, 24, or recall bias 17-24. The large sample size in our study allowed for analyses stratified by both ER/PR status and menopausal status. Our findings that soy intake may be associated with a reduction in risk of different breast cancer subtypes in premenopausal and postmenopausal women offers a potential explanation for the inconsistent findings of previous studies. Soy food is a rich source of isoflavones, which are structurally similar to estrogens; studies have shown that isoflavones compete with endogenous estrogen for the estrogen receptor making it biologically plausible that isoflavones protect against breast cancer development 12. Other anti-cancer properties of soy food, such as anti-angiogenic effects, anti-proliferative effects, antioxidative DNA topoisomerase I and II inhibition, as well as tyrosine kinases, and proteases effects 12, 14, may also explain the inverse association between isoflavones and breast cancer risk, particularly for estrogen receptor negative breast cancer. The reduced risk of breast cancer associated with soy intake has primarily been observed in Asian populations, with studies in Western populations generally showing no association,6 which is likely due to the lower level of soy food consumption as the soy intake levels in Asian populations are considerably higher than that of Western populations. On the other hand, several studies have also suggested that early or lifetime soy exposure may explain this discrepancy 10, 34, 35. In our study, we found only adolescent and adult soy intake in conjunction were significantly associated with reduced breast cancer risk among premenopausal women, suggesting a relatively long period of exposure may be required for soy food consumption to exert its protective effect. Although our finding that only high adult soy food intake alone was associated with postmenopausal breast cancer risk appears to be contradictory to the long-term exposure hypothesis at first glance, it is likely that soyfood, like most cancer preventive agents, would only be able to prevent some but not all breast cancer in women. Under the long-term exposure hypothesis, these “soy responsive” breast cancers would be prevented when women had sufficient exposure, e.g., high adolescent plus high adulthood exposure for pre-menopausal women, and high adulthood exposure for postmenopausal women. Because “soy responsive” breast cancer would have been already prevented during the pre-menopausal period for women with both high adolescent and adulthood soyfood intake, no additional benefit would be observed among post-menopausal women. This may also explain the null association observed in western populations as soy food consumption has only become popular in recent years. It is noteworthy that we found that soy food consumption during adolescence and adulthood were both related to late age at cancer diagnosis among breast cancer patients. This observation adds to the evidence supporting a causal association between soy food intake and breast cancer risk. More research is warranted to understand the underlying biological mechanisms. Diets high in soy food may be associated with healthier dietary and lifestyle behaviors. These dietary and other associated lifestyle factors which are associated with soy intake and breast cancer risk, could contribute to the observed inverse association seen in our population. We have carefully adjusted for a wide range of dietary and other lifestyle variables in our study although residual confounding can’t be completely ruled out. Additional adjustment for dietary pattern in our study did not change the study results. For some subgroup analyses, particularly those by HER2 status and mixed ER/PR status, the statistical power of the study was low. We had to analyze the data using tertile categorization which prevented us from investigating more extreme soy food intake in these specific groups of women. Additionally, some measurement errors, with the ER, PR, and HER2 status information obtained from multiple hospitals and a long lag time for recalling adolescent soy food intake, may have biased our results towards the null. The strengths of our study include its prospective design, large sample size, and low lost to follow-up rate. Adult soy intake was assessed using a validated, culturally appropriate FFQ designed to capture usual soy intake in our population. Multiple dietary assessments (at baseline and at the 1st follow-up survey) improved our soy intake measurement. In conclusion, we found that soy food intake was inversely associated with breast cancer risk, particularly in premenopausal women. The association between soy food intake and breast cancer risk may be modified by menopausal status and hormone receptor status. Supplementary Material Supplementary Material ACKNOWLEDGEMENTS The authors wish to thank the participants and research staff of the Shanghai Women’s Health Study for their contribution to the study. Funding: This work was supported by the United States National Institutes of Health (R37 CA070867). Michelle Baglia is funded by a CTSA TL1 fellowship. Abbreviations ER estrogen receptor PR progesterone receptor HER2 human epidermal growth factor-2 BMI body mass index Table 1 Adult and Adolescent Soy Protein Intake and Breast Cancer Risk By Menopausal Status Soy Protein Intake Level (RRa,b (95%CI)) Quintile 1 Quintile 2 Quintile 3 Quintile 4 Quintile 5 Ptrend ADULT INTAKE (median(g/day)) 3.5 6.0 8.2 10.9 16.0 Overall 1.00 (reference) 1.01 (0.83, 1.22) 1.00 (0.82, 1.21) 0.87 (0.71, 1.06) 0.78 (0.63, 0.97) 0.007 N(cases) 212 222 222 196 182 Premenopausalc (N(cases)=273) 1.00 (reference) 0.97 (0.69, 1.36) 0.86 (0.60, 1.24) 0.98 (0.68, 1.42) 0.46 (0.29, 0.74) 0.004 N(cases) 68 65 54 59 27 Postmenopausalc (N(cases)=761) 1.00 (reference) 1.03 (0.82, 1.30) 1.06 (0.84, 1.33) 0.83 (0.65, 1.06) 0.90 (0.71, 1.16) 0.15 N(cases) 144 157 168 137 155 ADOLESCENT INTAKE (median(g/day)) 1.8 3.9 6.2 9.2 15.6 Overall 1.00 (reference) 1.04 (0.86, 1.26) 1.12 (0.92, 1.35) 1.04 (0.86, 1.26) 0.95 (0.77, 1.16) 0.43 N(cases) 198 213 226 212 185 Premenopausalc 1.00 (reference) 0.77 (0.54, 1.11) 0.96 (0.68, 1.36) 0.74 (0.51, 1.07) 0.69 (0.45, 1.04) 0.08 N(cases) 63 55 69 51 35 Postmenopausalc 1.00 (reference) 1.17 (0.93, 1.47) 1.19 (0.94, 1.49) 1.18 (0.94, 1.49) 1.06 (0.84, 1.34) 1.00 N(cases) 135 158 157 161 150 a Cox proportional hazards models adjusted for age, body mass index, age at first live birth, physical activity, education, family history of breast cancer, season of recruitment, and menopause (time-varying) were used for analyses b Adult intakes additionally adjusted for total energy intake and juvenile intakes adjusted for total juvenile rice intake c Stratified based on menopausal status at breast cancer diagnosis Table 2 Adult and Adolescent Soy Protein Intake and Breast Cancer Risk By Menopausal Status and Receptor Status Adult Soy Protein Intake Level (RRa,b (95%CI)) Adolescent Soy Protein Intake Level (RRa,b (95%CI)) Tertile 1 Tertile 2 Tertile 3 Tertile 1 Tertile 2 Tertile 3 median=4.5g/day median=8.2g/day median=13.5g/day P trend median=2.6g/day median=6.2g/day median=12.5g/day P trend OVERALL ER+ (N(cases)=550) 1.00 (ref) 0.96 (0.78, 1.18) 0.86 (0.68, 1.07) 0.16 1.00 (ref) 1.28 (1.04, 1.57) 1.09 (0.87, 1.35) 0.76 ER− (N(cases)=288) 1.00 (ref) 1.25 (0.95, 1.66) 0.87 (0.63, 1.21) 0.32 1.00 (ref) 1.13 (0.86, 1.49) 0.98 (0.73, 1.32) 0.77 ER+/PR+ (N(cases)=409) 1.00 (ref) 0.91 (0.72, 1.15) 0.75 (0.58, 0.98) 0.03 1.00 (ref) 1.32 (1.03, 1.68) 1.16 (0.90, 1.48) 0.46 ER−/PR− (N(cases)=246) 1.00 (ref) 1.20 (0.89, 1.62) 0.83 (0.59, 1.18) 0.25 1.00 (ref) 1.12 (0.82, 1.52) 1.12 (0.82, 1.54) 0.52 ER+/PR− (N(cases)=124) 1.00 (ref) 1.18 (0.75, 1.85) 1.27 (0.78, 2.05) 0.35 1.00 (ref) 1.05 (0.69, 1.59) 0.81 (0.51, 1.28) 0.32 HER2+ (N(cases)=158) 1.00 (ref) 1.04 (0.72, 1.51) 0.79 (0.51, 1.21) 0.26 1.00 (ref) 1.23 (0.85, 1.77) 0.79 (0.52, 1.19) 0.17 HER2− (N(cases)=434) 1.00 (ref) 0.92 (0.73, 1.16) 0.83 (0.65, 1.07) 0.15 1.00 (ref) 1.11 (0.88, 1.40) 1.13 (0.89, 1.43) 0.37 PREMENOPAUSAL ER+ (N(cases)=135) 1.00 (ref) 1.00 (0.66, 1.50) 0.91 (0.57, 1.44) 0.67 1.00 (ref) 1.10 (0.74, 1.63) 0.86 (0.55, 1.35) 0.46 ER− (N(cases)=88) 1.00 (ref) 0.91 (0.56, 1.46) 0.60 (0.33, 1.11) 0.11 1.00 (ref) 1.31 (0.81, 2.11) 0.77 (0.43, 1.39) 0.30 ER+/PR+ (N(cases)=103) 1.00 (ref) 0.92 (0.58, 1.48) 0.91 (0.54, 1.52) 0.72 1.00 (ref) 1.01 (0.64, 1.61) 1.01 (0.62, 1.66) 0.97 ER−/PR− (N(cases)=68) 1.00 (ref) 0.85 (0.50, 1.44) 0.46 (0.22, 0.97) 0.04 1.00 (ref) 1.30 (0.73, 2.30) 1.09 (0.58, 2.05) 0.89 ER+/PR− (N(cases)=30) 1.00 (ref) 1.32 (0.56, 3.12) 1.04 (0.38, 2.83) 0.97 1.00 (ref) 1.48 (0.68, 3.25) 0.33 (0.09, 1.21) 0.08 HER2+ (N(cases)=49) 1.00 (ref) 1.07 (0.56, 2.05) 0.73 (0.33, 1.61) 0.44 1.00 (ref) 1.43 (0.75, 2.72) 0.64 (0.28, 1.47) 0.22 HER2− (N(cases)=122) 1.00 (ref) 0.90 (0.58, 1.38) 0.93 (0.58, 1.51) 0.78 1.00 (ref) 0.84 (0.55, 1.27) 0.84 (0.54, 1.32) 0.49 POSTMENOPAUSAL ER+ (N(cases)=415) 1.00 (ref) 0.95 (0.75, 1.21) 0.84 (0.65, 1.09) 0.19 1.00 (ref) 1.35 (1.06, 1.72) 1.16 (0.90, 1.49) 0.48 ER− (N(cases)=200) 1.00 (ref) 1.52 (1.07, 2.15) 1.05 (0.71, 1.57) 0.90 1.00 (ref) 1.05 (0.75, 1.48) 1.06 (0.75, 1.50) 0.76 ER+/PR+ (N(cases)=306) 1.00 (ref) 0.90 (0.69, 1.19) 0.72 (0.53, 0.96) 0.02 1.00 (ref) 1.45 (1.09, 1.92) 1.21 (0.90, 1.62) 0.44 ER−/PR− (N(cases)=178) 1.00 (ref) 1.44 (1.00, 2.08) 1.04 (0.69, 1.58) 0.91 1.00 (ref) 1.05 (0.73, 1.51) 1.13 (0.78, 1.62) 0.52 ER+/PR− (N(cases)=94) 1.00 (ref) 1.14 (0.66, 1.94) 1.35 (0.78, 2.33) 0.28 1.00 (ref) 0.90 (0.55, 1.48) 0.94 (0.57, 1.54) 0.84 HER2+ (N(cases)=109) 1.00 (ref) 1.02 (0.65, 1.61) 0.81 (0.49, 1.36) 0.40 1.00 (ref) 1.12 (0.72, 1.75) 0.83 (0.51, 1.34) 0.37 HER2− (N(cases)=312) 1.00 (ref) 0.94 (0.71, 1.23) 0.80 (0.60, 1.08) 0.14 1.00 (ref) 1.26 (0.95, 1.66) 1.26 (0.95, 1.68) 0.15 a Cox proportional hazards models adjusted for age, body mass index, age at first live birth, physical activity, education, family history of breast cancer, season of recruitment, and menopause (time-varying) were used for analyses b Adult intakes additionally adjusted for total energy intake and juvenile intakes adjusted for total juvenile rice intake c Stratified based on menopausal status at breast cancer diagnosis Table 3 Joint Effect of Adult and Adolescent Soy Protein Intake on Breast Cancer Risk Adult Average Soy Protein Intake (RRa (95%CI)) Juvenile Soy Protein Intake ≤6.32 6.33-10.43 ≥10.44 Premenopausalb (N(cases)=273)    ≤4.24 1.00 (reference) 0.62 (0.38, 1.00) 0.56 (0.31, 1.02)    4.25-8.61 0.86 (0.58, 1.28) 0.86 (0.57, 1.29) 0.78 (0.49, 1.25)    ≥8.62 0.56 (0.31, 1.00) 0.80 (0.51, 1.26) 0.53 (0.32, 0.88) Postmenopausalb (N(cases)=761)    ≤4.24 1.00 (reference) 0.96 (0.72, 1.29) 0.63 (0.43, 0.91)    4.25-8.61 1.07 (0.81, 1.43) 1.08 (0.82, 1.43) 0.94 (0.69, 1.26)    ≥8.62 0.94 (0.67, 1.32) 1.01 (0.76, 1.35) 0.98 (0.74, 1.29) a Cox proportional hazards models adjusted for age, body mass index, age at first live birth, physical activity, education, family history of breast cancer, season of recruitment, total adult energy, total juvenile rice intake, and menopause (time-varying) were used for analyses b Stratified based on menopausal status at breast cancer diagnosis Novelty and Impact: Epidemiological evidence is inconsistent and limited with regard to whether the soyfood and breast cancer risk association differ by hormone receptors and HER2 status. In a large cohort study, we found that soyfood intake was associated with both ER/PR positive and negative breast cancer risk but the association differed by menopausal status. No modification by HER2 status was observed. These results suggest that soyfood may influence breast cancer risk via multiple mechanisms. The authors have no conflicts of interest to disclose. WZ, XOS and YTG designed research, MLB analyzed data, MLB and XOS wrote the paper, WZ and GY provided critical review, HL, JG, and GY supervised field operation and cancer confirmation, MLB and XOS had primary responsibility for final content. All authors read and approved the final manuscript. REFERENCES 1 Ferlay J Shin HR Bray F Forman D Mathers C Parkin DM Estimates of worldwide burden of cancer in 2008: GLOBOCAN 2008 Int J Cancer 2010 127 2893 917 21351269 2 Parkin DM Muir CS Cancer Incidence in Five Continents. Comparability and quality of data IARC scientific publications 1992 45 173 1284606 3 Ziegler RG Hoover RN Pike MC Hildesheim A Nomura AM West DW Wu-Williams AH Kolonel LN Horn-Ross PL Rosenthal JF Hyer MB Migration patterns and breast cancer risk in Asian-American women J Natl Cancer Inst 1993 85 1819 27 8230262 4 Wu AH Ziegler RG Horn-Ross PL Nomura AM West DW Kolonel LN Rosenthal JF Hoover RN Pike MC Tofu and risk of breast cancer in Asian-Americans Cancer Epidemiol Biomarkers Prev 1996 5 901 6 8922298 5 Trock BJ Hilakivi-Clarke L Clarke R Meta-analysis of soy intake and breast cancer risk J Natl Cancer Inst 2006 98 459 71 16595782 6 Dong JY Qin LQ Soy isoflavones consumption and risk of breast cancer incidence or recurrence: a meta-analysis of prospective studies Breast Cancer Res Treat 2011 125 315 23 21113655 7 Chen M Rao Y Zheng Y Wei S Li Y Guo T Yin P Association between soy isoflavone intake and breast cancer risk for pre- and post-menopausal women: a meta-analysis of epidemiological studies PLoS One 2014 9 e89288 24586662 8 Fritz H Seely D Flower G Skidmore B Fernandes R Vadeboncoeur S Kennedy D Cooley K Wong R Sagar S Sabri E Fergusson D Soy, red clover, and isoflavones and breast cancer: a systematic review PLoS One 2013 8 e81968 24312387 9 Yamamoto S Sobue T Kobayashi M Sasaki S Tsugane S Soy, isoflavones, and breast cancer risk in Japan J Natl Cancer Inst 2003 95 906 13 12813174 10 Lee SA Shu XO Li H Yang G Cai H Wen W Ji BT Gao J Gao YT Zheng W Adolescent and adult soy food intake and breast cancer risk: results from the Shanghai Women’s Health Study Am J Clin Nutr 2009 89 1920 6 19403632 11 Nishio K Niwa Y Toyoshima H Tamakoshi K Kondo T Yatsuya H Yamamoto A Suzuki S Tokudome S Lin Y Wakai K Hamajima N Consumption of soy foods and the risk of breast cancer: findings from the Japan Collaborative Cohort (JACC) Study Cancer Causes Control 2007 18 801 8 17619154 12 Adlercreutz H Mazur W Phyto-oestrogens and Western diseases Annals of medicine 1997 29 95 120 9187225 13 Taylor CK Levy RM Elliott JC Burnett BP The effect of genistein aglycone on cancer and cancer risk: a review of in vitro, preclinical, and clinical studies Nutrition reviews 2009 67 398 415 19566600 14 Messina M McCaskill-Stevens W Lampe JW Addressing the soy and breast cancer relationship: review, commentary, and workshop proceedings J Natl Cancer Inst 2006 98 1275 84 16985246 15 Colditz GA Rosner BA Chen WY Holmes MD Hankinson SE Risk factors for breast cancer according to estrogen and progesterone receptor status J Natl Cancer Inst 2004 96 218 28 14759989 16 Huang WY Newman B Millikan RC Schell MJ Hulka BS Moorman PG Hormone-related factors and risk of breast cancer in relation to estrogen receptor and progesterone receptor status Am J Epidemiol 2000 151 703 14 10752798 17 Zhang C Ho SC Lin F Cheng S Fu J Chen Y Soy product and isoflavone intake and breast cancer risk defined by hormone receptor status Cancer science 2010 101 501 7 19860847 18 Cho YA Kim J Park KS Lim SY Shin A Sung MK Ro J Effect of dietary soy intake on breast cancer risk according to menopause and hormone receptor status Eur J Clin Nutr 2010 64 924 32 20571498 19 Iwasaki M Hamada GS Nishimoto IN Netto MM Motola J Jr. Laginha FM Kasuga Y Yokoyama S Onuma H Nishimura H Kusama R Kobayashi M Dietary isoflavone intake and breast cancer risk in case-control studies in Japanese, Japanese Brazilians, and non-Japanese Brazilians Breast Cancer Res Treat 2009 116 401 11 18777206 20 Touillaud MS Pillow PC Jakovljevic J Bondy ML Singletary SE Li D Chang S Effect of dietary intake of phytoestrogens on estrogen receptor status in premenopausal women with breast cancer Nutrition and cancer 2005 51 162 9 15860438 21 Dai Q Shu XO Jin F Potter JD Kushi LH Teas J Gao YT Zheng W Population-based case-control study of soyfood intake and breast cancer risk in Shanghai British journal of cancer 2001 85 372 8 11487268 22 Zhang M Yang H Holman CD Dietary intake of isoflavones and breast cancer risk by estrogen and progesterone receptor status Breast Cancer Res Treat 2009 118 553 63 19252980 23 Anderson LN Cotterchio M Boucher BA Kreiger N Phytoestrogen intake from foods, during adolescence and adulthood, and risk of breast cancer by estrogen and progesterone receptor tumor subgroup among Ontario women Int J Cancer 2013 132 1683 92 22907507 24 Suzuki T Matsuo K Tsunoda N Hirose K Hiraki A Kawase T Yamashita T Iwata H Tanaka H Tajima K Effect of soybean on breast cancer according to receptor status: a case-control study in Japan Int J Cancer 2008 123 1674 80 18623079 25 Wu AH Koh WP Wang R Lee HP Yu MC Soy intake and breast cancer risk in Singapore Chinese Health Study British journal of cancer 2008 99 196 200 18594543 26 Zheng W Chow WH Yang G Jin F Rothman N Blair A Li HL Wen W Ji BT Li Q Shu XO Gao YT The Shanghai Women’s Health Study: rationale, study design, and baseline characteristics Am J Epidemiol 2005 162 1123 31 16236996 27 Shu XO Yang G Jin F Liu D Kushi L Wen W Gao YT Zheng W Validity and reproducibility of the food frequency questionnaire used in the Shanghai Women’s Health Study Eur J Clin Nutr 2004 58 17 23 14679362 28 International Classification of Diseases, 9th revision National Center for Health Statistics 2008 29 Yang Y Wang GY Pan XC Chinese Food Composition Tables 2002 Beijing University Medical Press 2002 30 McPherson K Steel CM Dixon JM ABC of breast diseases. Breast cancer-epidemiology, risk factors, and genetics BMJ 2000 321 624 8 10977847 31 Lee HP Gourley L Duffy SW Esteve J Lee J Day NE Risk factors for breast cancer by age and menopausal status: a case-control study in Singapore Cancer Causes Control 1992 3 313 22 1617118 32 Hirose K Tajima K Hamajima N Inoue M Takezaki T Kuroishi T Yoshida M Tokudome S A large-scale, hospital-based case-control study of risk factors of breast cancer according to menopausal status Japanese journal of cancer research : Gann 1995 86 146 54 7730137 33 Lamartiniere CA Protection against breast cancer with genistein: a component of soy Am J Clin Nutr 2000 71 1705S 7S discussion 8S-9S 10837323 34 Wu AH Wan P Hankin J Tseng CC Yu MC Pike MC Adolescent and adult soy intake and risk of breast cancer in Asian-Americans Carcinogenesis 2002 23 1491 6 12189192 35 Shu XO Jin F Dai Q Wen W Potter JD Kushi LH Ruan Z Gao YT Zheng W Soyfood intake during adolescence and subsequent risk of breast cancer among Chinese women Cancer Epidemiol Biomarkers Prev 2001 10 483 8 11352858
PMC005xxxxxx/PMC5114024.txt
LICENSE: This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. 2984170R 7706 Tetrahedron Tetrahedron Tetrahedron 0040-4020 27867228 5114024 10.1016/j.tet.2012.04.025 NIHMS798098 Article Simplexolides A–E and plakorfuran A, six butyrate derived polyketides from the marine sponge Plakortis simplex Liu Xiang-Fang ab Shen Yang b* Yang Fan ac Hamann Mark T. c Jiao Wei-Hua a Zhang Hong-Jun a Chen Wan-Sheng a Lin Hou-Wen a* a Laboratory of Marine Drugs, Department of Pharmacy, Changzheng Hospital, Second Military Medical University, Shanghai 200003, People's Republic of China b Department of Pharmacy, Shanghai Children's Hospital, Shanghai Jiao Tong University, 1400 West Beijing Road, Shanghai 200040, People's Republic of China c Department of Pharmacognosy and the National Center for Natural Products Research (NCNPR), School of Pharmacy, The University of Mississippi, University, MS 38677, USA * Corresponding authors. Tel.: +86 21 62792098 (Y.S.); tel./fax: +86 21 65585154 (H.-W.L.); shenyang@medmail.com.cn (Y. Shen), franklin67@126.com (H.-W. Lin) 28 6 2016 14 4 2012 17 6 2012 17 11 2016 68 24 46354640 This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. Six new polyketides, simplexolides A–E (1–5) and a furan ester, plakorfuran A (6), together with four known furanylidenic methyl esters (7–10) were isolated from the marine sponge Plakortis simplex. Compounds 1–5 feature a tetrahydrofuran ring opened seco-plakortone skeleton. These new structures, including relative configurations, were determined on the basis of extensive analysis of spectroscopic data. The absolute configurations of 1–6 were established by the modified Mosher's method, and the CD exciton chirality method. However, configurations of the remote stereocenters at C-8 in compounds 1–5 were not determined. Antifungal, cytotoxicity, antileismanial, and antimalarial activities of these poly-ketides were evaluated. Plakortis simplex Simplexolide Mosher's method Antifungal Cytotoxicity Antimalarial Absolute configuration 1. Introduction Sponges of the genera Plakortis and Plakinastrella have been widely investigated for their biologically active polyketides.1–8 Apart from a large number of cyclic peroxides they also contain a group of γ-lactones, including bicyclic peroxylactones (plakortolides),9,10 bicyclic furanolactones (plakortones),8,11 N-alkylated lactones (amphiasterins),12 α,β-unsaturated lactones (butenolides),13 and some seco derivatives (seco-plakortolides).8 Plakortones A–F, featuring bicyclic furanolactones, are a class of ethyl branched (butyrate derived) polyketides from the genus Plakortis. They show interesting biological activities that have been the focus of extensive chemical and pharmaceutical studies. Plakortones A–D are cardiac sacroplasmic reticulum Ca2+-pumping ATPase activators, being active at micromolar concentrations;11 plakortones B–F exhibited moderate cytotoxicity against the murine fibro sarcoma cell line WEHI 164;14 plakortone G, a closely related analogof the γ-lactone isolated by Stierle and Faulkner,15 without a tetrahydrofuran moiety, showed antimalarial activity against both the D6 and W2 clones of Plasmodium falciparum.16 The absolute configurations of these plakortones were not confirmed during the initial isolation. The total syntheses of plakortones B, D, and E helped to establish their absolute configurations later.17–19 However, the absolute configurations of the other four plakortones A, C, F, and G still remain unknown. Recently, plakortones L, N, and P were isolated from the sponge of Plakinastrella clathrata.8 They have bicyclic furanolactone fragments like plakortones A–F, but with methyl rather than ethyl substituents. During the course of our continuing search for new drug leads from marine sponges collected off the Xisha Islands in the South China Sea, besides the previously reported two unusual polyketides simplextones A and B,20 we have recently isolated and identified six new polyketides, simplexolides A–E (1–5) and plakorfuran A (6), together with four known furanylidenic methyl esters (2Z,6R,8R,9E) [3-ethyl-5-(2-ethyl-hex-3-enyl)-6-ethyl-5H-furan-2-ylidene]-acetic acid methyl ester (7),15 methyl (2Z,6R,8S)-4,6-diethyl-3,6-epoxy-8-methyldeca-2,4-dienoate (8),21 methyl (2Z,6R,8S)-3,6-epoxy-4,6,8-triethyldodeca-2,4-dienoate (9),21 and (2Z,6R,8R,9E)[3-ethyl-5-(2-ethyl-hex-3-enyl)-6-methyl-5H-furan-2-ylidene]-acetic acid methyl ester (10)22 from the marine sponge Plakortis simplex. The primary difference between compounds 1–5 and the previously isolated plakortones A–F from Plakortis spp. is the opening of the tetrahydrofuran ring in 1–5. Herein, we describe the isolation, structure elucidation, and initial biological evaluation of compounds 1–6. 2. Results and discussion A sample of the sponge P. simplex, collected off the Xisha Islands in the South China Sea, was exhaustively extracted with MeOH. The extract was suspended in water and successively extracted with n-hexane, CH2Cl2, EtOAc, and n-BuOH. The CH2Cl2-soluble extract was subjected to repeated column chromatography followed by reversed-phase preparative HPLC to afford compounds 1–10 as colorless oils. The molecular formula of compound 1 was assigned as C17H30O3 by its HRESIMS (m/z 305.2094, [M+Na]+) and NMR data (Tables 1 and 2), displaying three degrees of unsaturation. The IR absorptions indicated the presence of hydroxyl (3451 cm−1), double bond (1655 cm−1), and ester carbonyl (1763 cm−1) groups. Analysis of the 1H NMR data (Table 1) and HSQC spectrum revealed the presence of four methyls, seven methylenes, two sp3 methines, one of which was oxygenated, one sp2 methine, one oxygenated sp3 quaternary carbon, and two sp2 quaternary carbons. By interpretation of 1H–1H COSY correlations, it was possible to establish five partial structures of consecutive proton systems: H-2/H-3, H-7/H-8/Me-17, H-11/Me-12, H-13/Me-14, and H-15/Me-16 (Fig. 1). The HMBC correlations from Me-14 (δH 1.01) to C-4 (δC 93.3), from H-13a (δH 1.64) to C-3 (δC 72.4) and C-5 (δC 120.1), and from H-3 (δH 4.22) to C-1 (δC 174.9) indicated the attachment of an ethyl group at C-4. Moreover, the HMBC correlations from Me-16 (δH 1.03) to C-6 (δC 93.3) and from H-15 (δH 2.13) to C-5 (δC 120.1), C-6 (δC 148.6), and C-7 (δC 44.9) demonstrated the linkage of C-5, C-7, and C-15 via C-6. The HMBC correlations from Me-17 (δH 0.85) to C-9 (δC 36.5), from H-9a (δH 1.11) to C-11 (δC 22.9), and from Me-12 (δH 0.89) to C-10 (δC 29.2) defined the structure of the C-1 to C-12 portion of the molecule. The C-1 ester carbonyl was confirmed to form a γ-butyrolactone with the oxygenated C-4, which was severely downfield shifted at δC 93.3, to consume the remaining one degree of unsaturation. The relative configuration of 1 was established on the basis of NOESY data (Fig. 1). The crucial NOE correlations between H-3 (δH 4.22) and H-13a (δH 1.64) suggested that these protons were oriented on the same face of the γ-butyrolactone moiety. The E-geometry of the Δ5,6 double bond was deduced from a NOESY correlation between H-5 (δH 5.09) and H-7a (δH 1.87). The absolute configuration of C-3 was determined by applying the modified Mosher's method to the secondary hydroxyl group.23,24 Compound 1 was reacted with (R)-(−)- and (S)-(+)- α -methoxy- α -tri-fluoromethylphenylacetic acid (MTPA) chlorides to give MTPA esters 1a and 1b, respectively. A consistent distribution of positive and negative Δδ values around C-3 allowed the assignment of S-configuration for C-3 (Fig. 2). On the basis of the previously determined relative configuration, a 3S,4S configuration was assigned to simplexolide A (1). However, configuration of the remote stereocenter at C-8 was not determined. Simplexolide B (2) was clearly an isomer of compound 1 on the basis of the identical molecular formula of C17H30O3 obtained by HRESIMS (m/z 305.2095 [M+Na]+). Comparison of the NMR data between 2 and 1 (Table 1) suggested that they had the same planar structures except for the configuration of the double bond at C-5–C-6, which was assigned as Z geometry on the basis of a NOESY correlation between H-5 and H-15 (Fig. 1). The NOE correlation between H-3 and H-5 indicated the same orientation of these two protons. The absolute configuration at C-3 was determined to be S by the modified Mosher's method (Fig. 2), implying that 1 and 2 were epimeric at C-4. On the basis of above-mentioned analysis, a 3S,4R configuration was assigned to simplexolide B (2). The molecular formula of compound 3 was established as C18H32O3 on the basis of HRESIMS (m/z 319.2247, [M+Na]+) and NMR data. The 1H and 13C NMR data indicated that 3 is a homolog of 2. The 1H NMR spectrum of 3 was almost identical to that of 2 except that a methyl group was replaced by an ethyl group at C-8 (Table 2). The geometry of the Δ5,6 double bond was assigned as E based on the NOESY correlation between H-5 and H-7. The crucial NOE correlation between H-3 and H-5 indicated that the relative configuration was assumed to be the same as 2. The CD spectrum of 3 displayed a positive Cotton effect at 196 nm, which was similar to that of 2 (Fig. 3), suggesting that the absolute configuration of 3 was the same as that of 2. Thus, a 3S,4R configuration was assigned to simplexolide C (3). Compound 4 exhibited a quasi-molecular ion peak at m/z 319.2251 ([M+Na]+, calcd 319.2249), consistent with the molecular formula of C18H32O3. The 1H and 13C NMR data of 4 (Tables 1 and 2) were similar to those of 3. The geometry of the double bond at C-5 was assigned as Z, supported by the NOE correlation between H-5 and H-15. The CD spectrum of 4 revealed a pronounced positive Cotton effect with maxima observed at 196 nm (Fig. 3), and this closely matched the CD spectrum of 3. Therefore, the absolute configuration of simplexolide D (4) was assigned to be 3S,4R, consistent with those of 3. The positive HRESIMS spectrum of simplexolide E (5) exhibited a pseudomolecular ion peak at m/z 305.2091 [M+Na]+, consistent with the molecular formula of C17H30O3, implying three degrees of unsaturation. Analysis of its NMR spectroscopic data revealed nearly identical structural features to those of 2, except for the geometry of the double bond at C-5, which was assigned as E on the basis of an NOE correlation between H-5 and H-7. The CD spectra of 5 showed a positive Cotton effect at 196 nm (Fig. 3), similar to that of 2, suggesting that the absolute configuration of 5 was 3S,4R. The HRESIMS of compound 6 exhibited a pseudomolecular ion peak at m/z 345.2040 [M+Na]+ and established a molecular formula of C19H30O4, indicating five degrees of unsaturation. The 13C NMR (Table 2) displayed 19 carbon signals, which were identified by the assistance of the DEPT spectrum as 5 methyls, 5 methylenes, 3 sp2 methines, 1 oxygenated sp3 methine, and 5 quaternary carbons. The carbon resonances at δC 84.0 (C-6) and 171.4 (C-3) are identical as those for a furano α,β-unsaturated ester.14,15 Furthermore, an ester carbonyl was recognized as being present in 6 from its 13C NMR signal at C 166.8 (qC, C-1) and strong IR absorptions at 1752 cm−1. By interpretation of COSY correlations (Fig. 1), it was possible to establish the proton connections between H-15 and H-16, H-17 and H-18, H-9 and H-10, H-13 and H-14, and between H-11 and H-12. The connectivities of these partial structures were further established by the HMBC correlations (Fig. 1). The conjunction of C-10 and C-11 was elucidated on the basis of the HMBC correlation from H3-12 to C-10. Moreover, the HMBC correlations from H3-18 and H-10 to C-8 indicated the attachment between C-9 and C-17 via C-8. The HMBC correlations observed from H3-16 to C-6, and from H-15 and H-17 to C-7 indicated the connection of C-8 and C-15 through C-6 and C-7. The HMBC correlations of H3-19/C-1, H3-14 and H-2/C-4, H-5/C-3 and C-13, and H-15/C-5 further confirmed the existence of an unsaturated furan ester. With this assignment secured, the final oxymethine at C-10 had to be substituted with a hydroxyl group to satisfy the molecular formula. Finally, the E-geometry of the Δ8,9 double bond was deduced from a NOESY correlation between H-7 and H-9. The crucial NOE correlation between H-2 and H-13 indicated that the geometry of the Δ2,3 double bond is assumed to be Z (Fig. 1). This completed the assignment of the planar structure of plakorfuran A (6). The absolute configuration at C-10 was determined to be R by applying a modified Mosher's ester method to the secondary hydroxyl group (Fig. 2). The absolute configuration at C-6 was determined by applying the CD exciton chirality method.25 The CD spectrum of 6 revealed a negative Cotton effect at λmax 285 nm (Δε −5.49) and a positive Cotton effect at λmax 205 nm (Δε 5.85) due to the transition interaction between two different chromophores of the unsaturated furan ester and the Δ8,9 double bond (Fig. 4), indicating a negative chirality for 6, thus concluding the absolute configuration as 6R,10R. Simplexolides A–E (1–5) feature a previously unknown tetrahydrofuran opened plakortone skeleton. A possible biogenetic pathway is proposed as shown in Scheme 1. Acetate, propionate, and butyrate units are required to assemble the polyketide skeleton.26 The double bond at Δ3,4 is oxidized to an epoxide. With acyl carrier protein (ACP) domain releasing, the carboxylic acid cyclizes onto the opening epoxide togenerate a γ-lactone with the insertion of a hydroxyl.27 In this lactonization step, a pair of stereoisomers are formed at C-4 due to the nucleophilic attack of the hydroperoxy group onto C-4 of the epoxide group from both of the side. Compounds 1, 2, and 5–10 were tested for antifungal, cytotoxicity, antileismanial, and antimalarial activities (Table 3). Compounds 2, 5, and 7–10 showed weak to moderate antifungal activity against the fungi Cryptococcus neoformans. The cytotoxic activity of compounds 1 and 2 against five human cancer cell lines, HCT-116 (colon cancer), HeLa (cervical cancer), SW480 (colon cancer), QGY-7703 (hepatocarcinoma), and A549 (lung carcinoma) was also assayed. The results showed that compound 1 exhibited much stronger cytotoxicity against the five cancer cell lines, which was due to the stereochemistry influenced. Compounds 2 and 10 showed moderate antileismanial activity againt Leishmania donovani, while compounds 7–9 were a little weaker, and compounds 1, 5 and 6 were inactive. Furthermore, the antimalarial activity against chloroquine sensitive (D6, Sierra Leone) and resistant (W2, Indo China) strains of P. falciparum was tested. In this assay, only compound 10 displayed antimalarial activity against D6 and W2 with IC50 values of 2.0 and 2.0 μg/mL, respectively, and both with SI [IC50(fibroblast)/IC50(parasite)] of 2.4, while the other compounds were inactive. 3. Experimental section 3.1. General experimental procedures Optical rotations were determined with a Perkin–Elmer 341 polarimeter equipped with a 1 mm cell. The CD spectra were obtained with a JASCO J-715 spectropolarimeter. IR spectra were recorded on a Bruker Vector 22 spectrometer using KBr pellets. The NMR experiments were conducted on Bruker AVANCE-600 and Bruker AMX-500 MHz instruments in CDCl3 with TMS as an internal standard. HRESIMS and ESIMS were obtained on a Q-Tof micro YA019 mass spectrometer. Reversed-phase HPLC was performed using Sunfire C18 (5 μm) and YMC-Pack Pro C18 RS (5 μm) columns with a Waters 1525/2998 liquid chromatograph. Column chromatography (CC) was carried out on silica gel 60 (200–300 mesh; Yantai, China), and Sephadex LH-20 (Pharmacia). TLC was carried out using HSGF 254 plates and visualized by spraying with anisaldehyde/H2SO4 reagent. Samples were weighed on a Shushi analytical balance. 3.2. Animal material The sponge specimen was collected around Yongxing Island and seven connected islets in the South China Sea in June 2007, and were identified by Prof. Jin-He Li (Institute of Oceanology, Chinese Academy of Sciences, China). A voucher sample (No. B-3) was deposited in the Laboratory of Marine Drugs, Department of Pharmacy, Changzheng Hospital, Second Military Medical University, China. 3.3. Extraction and isolation The air-dried and powdered sponge (2.0 kg, dry weight) was extracted with MeOH, and the crude extract was concentrated under reduced pressure at 45 °C to yield 500 g of residue. The residue was then extracted successively with n-hexane, CH2Cl2, EtOAc, and n-BuOH. The CH2Cl2 extract (41 g) was separated by vacuum liquid chromatography (VLC) on silica gel using CH2Cl2/MeOH as the eluent to give three fractions (Fr. A–C). The lower polarity part fraction A (CH2Cl2/MeOH 25:1) was subjected to VLC eluting with petroleum ether/EtOAc (PE) to give four subfractions (Fr. A1–A4). Fraction A3 was purified by reversed-phase preparative HPLC (Sunfire C18, 5 μm, 10×250 mm) to yield 31.7 mg of compound 1 (CH3OH/H2O 95:5, 2.0 mL/min, UV detection at 210 nm, tR=17.0 min), 22.1 mg of compound 6 (CH3CN/H2O 50:50, 2.0 mL/min, UV detection at 282 nm, tR=17.2 min), a mixture of compounds 3 and 4 (CH3CN/H2O 70:30, 2.0 mL/min, UV detection at 200 nm, tR=29.0 min), and a mixture of compounds 2 and 5 (CH3CN/H2O 70:30, 2.0 mL/min, UV detection at 200 nm, tR=24.4 min). The mixture of compounds 3 and 4 and the mixture of compounds 2 and 5 were further purified by reversed-phase preparative HPLC (YMC-Pack Pro C18 RS, 5 μm, 10×250 mm) to yield 21.3 mg of compound 3 (CH3CN/H2O 85:15, 2.0 mL/min, UV detection at 200 nm, tR=18.4 min), 1.8 mg of compound 5 (CH3CN/H2O 85:15, 2.0 mL/min, UV detection at 200 nm tR=17.4 min), 8.2 mg of compound 2 (CH3CN/H2O 85:15, 2.0 mL/min, UV detection at 200 nm, tR=66.9 min), and 52.1 mg of compound 5 (H3CN/H2O 85:15, 2.0 mL/min, UV detection at 200 nm, tR=62.6 min). Similarly, the four known compounds 7 (22.0 mg), 8 (15.1 mg), 9 (8.3 mg), and 10 (2.2 mg) were obtained from fraction A1. 3.3.1. Simplexolide A(1) Colorless oil; [α]D23+1 (c 0.215, MeOH); 1R (KBr) νmax 3451, 2960, 2927, 2873, 1763, 1655, 1464, 1412, 1378, 1343, 1290, 1248, 1210, 1182, 1119, 1103, 1090, 1071, 1014, 980, 958, 926, 885, 800 cm−1; 1H NMR (CDCl3, 600 MHz) and 13C NMR (CDCl3,150 MHz) data, see Tables 1 and 2; HRESIMS m/z 305.2094 [M+Na]+ (calcd for C17H30O3Na, 305.2093). CD spectrum (c 1.1 mg/mL, CH3CN), 193 nm (Δε -0.65), 222 nm (Δε 0.84). 3.3.2. Simplexolide B (2) Colorless oil; [α]D23+2 (c 0.120, MeOH); IR (KBr) νmax 3439, 2962, 2930, 2874, 1758, 1655, 1460, 1400, 1379, 1341, 1280, 1250, 1208, 1165, 1111, 1063, 1023, 972, 954, 916, 879, 799 cm−1; 1H NMR (CDCl3, 500 MHz) and 13C NMR (CDCl3, 125 MHz) data, see Tables 1 and 2; HRESIMS m/z 305.2095 [M+Na]+ (calcd for C17H30O3Na, 305.2093). CD spectrum (c 0.5 mg/mL, CH3CN), 196 nm (Δε+5.16). 3.3.3. Simplexolide C (3) Colorless oil; [α]D23−9 (c 0.090, MeOH); IR (KBr) νmax 3444, 2962, 2928, 2874, 1758, 1655, 1464, 1399, 1379, 1341, 1287, 1251, 1203, 1164, 1113, 1099, 1022, 975, 951, 915, 879, 800 cm−1; 1H NMR (CDCl3, 500 MHz) and 13C NMR (CDCl3, 125 MHz) data, see Tables 1 and 2; HRESIMS m/z 319.2247 [M+Na]+ (calcd for C18H32O3Na, 319.2249). CD spectrum (c 0.5 mg/mL, CH3CN), 196 nm (Δε +3.43). 3.3.4. Simplexolide D (4) Colorless oil; [α]D23+14 (c 0.130, MeOH); IR (KBr) νmax 3448, 2962, 2930, 2874, 1759, 1655, 1460, 1400, 1379, 1340, 1280, 1250, 1205, 1163, 1111, 1036, 1024, 975, 955, 914, 798cm−1; 1H NMR (CDCl3, 500 MHz) and 13C NMR (CDCl3, 125 MHz) data, see Tables 1 and 2; HRESIMS m/z 319.2251 [M+Na]+ (calcd for C18H32O3Na, 319.2249). CD spectrum (c 0.9 mg/mL, CH3CN), 196 nm (Δε +3.99). 3.3.5. Simplexolide E (5) Colorless oil; [α]D23−18 (c 0.170, MeOH); IR (KBr) νmax 3446, 2961, 2927, 2874, 1758, 1655, 1465, 1400, 1379, 1342, 1288, 1252, 1202, 1166, 1112, 1063, 1021, 974, 951, 916, 879, 800 cm−1; 1H NMR (CDCl3, 500 MHz) and 13C NMR (CDCl3, 125 MHz) data, see Tables 1 and 2; HRESIMS m/z 305.2091 [M+Na]+ (calcd for C17H30O3Na, 305.2093). CD spectrum (c 0.7 mg/mL, CH3CN), 196 nm (Δε + 2.57). 3.3.6. Plakorfuran A (6) Colorless oil; [α]D23−96 (c 0.085, MeOH); 1H NMR(CDCl3, 500 MHz) and 13C NMR(CDCl3,125 MHz) data, see Tables 1 and 2; HRESIMS m/z 345.2040 [M+Na]+ (C19H30O4Na, calcd 345.2042). CD spectrum (c 0.85 mg/mL, CH3CN), 205 nm ((Δε 5.85), 239 nm ((Δε 1.70), 285 nm ((Δε −5.49). 3.4. Preparation of MTPA esters 1a and 1b Simplexolide A (1; 1.0 mg and 0.8 mg, respectively) was reacted with R-(−)- or S-(+)-MTPACl (15 μL) in freshly distilled dry pyridine (500 μL) and stirred under N2 at room temperature for 18 h, respectively, and the solvent was removed in vacuo. The products were purified by mini-column chromatography on silica gel (200 mesh, petroleum ether/EtOAc, 1:1) to afford S-(−)- and R-(+)-MTPA esters 1a and 1b, respectively. 3.5. Preparation of MTPA esters 2a and 2b Simplexolide C (3; 1 mg each) was similarly processed to give S-(−)- and R-(+)-MTPA esters 3a and 3b, respectively. 3.6. Preparation of MTPA esters 6a and 6b Plakorfuran A (6; 1 mg each) was similarly processed to give S-(−)- and R-(+)-MTPA esters 6a and 6b, respectively. 3.7. Biological tests Antifungal assay against C. neoformans was performed as described by Ikhlas A. Khan et al.28 Amphotericin B was used as the positive control. Cytotoxicity was determined against human cancer cell lines HCT-116 (colon cancer), HeLa (cervical cancer), SW480 (colon cancer), QGY-7703 (hepatocarcinoma), and A549 (lung carcinoma) using the MTT assay method. Camptothecin was used as the positive control. The experimental details of this assay were carried out according to a previously described procedure.29 Antimalarial activity was determined in vitro against chloroquine sensitive (D6, Sierra Leone) and resistant (W2, Indo China) strains of P. falciparum by measuring plasmodial LDH activity.30 Chloroquine was used as the positive control. In vitro antileishmanial activity was tested on a culture of L. donovani promastigotes. In a 96-well microplate assay, test compounds were diluted to an appropriate concentration and added to the Leishmania promastigotes culture (2×106 cell/mL). The plates were incubated at 26 °C for 72 h and growth of Leishmania promastigotes was determined by Alamar blue assay.31 Pentamidine and Amphotericin B were used as the standard antileishmanial agents. The growth inhibition curve was used to compute the IC50 value for each compound. Supplementary Material 2 This work was supported by the National Natural Science Foundation of China (No. 81072573), the Major Program of Modernization of Chinese Medicine (STCSM, 09dZ1975800), the NIH, NIAID, Division of AIDS (No. AI 27094), and the USDA Agricultural Research Service Specific Cooperative Agreement (No. 58-6408-2-0009). The authors thank Dr. Melissa R. Jacob and Ms. Marsha A. Wright for antifungal assay assistance, and Dr. Shabana Khan for antimalarial assay assistance. Fig. 1 COSY ( ), key HMBC (→), and selected NOE ( ) correlations of 1,2, and 6. Fig. 2 ΔδS–R values (ppm) for the MTPA derivatives of 1, 2, and 6 in CDCl3. Fig. 3 CD curves of compounds 2–5. Fig. 4 Experimental CD spectrum of 6. Bold lines denote the electric transition dipole of the chromophores for 6. Scheme 1 Plausible biogenetic pathway for simplexolides A–E (1–5). Table 1 1H NMR data of compounds 1–6 in CDCl3 No. 1a 2b 3b 4b 5b 6b 2 2.59, dd (18.0, 1.2) 2.42, d (17.5) 2.43, d (17.5) 2.42, d (17.5) 2.46, d (17.5) 4.80, s 2.85, dd (18.0, 6.0) 2.80, dd (17.5, 5.5) 2.83, dd (17.5, 5.5) 2.82, dd (17.5, 5.5) 2.83, dd (17.5, 5.5) 3 4.22, d (5.4) 4.30, d (5.0) 4.32, t (4.0) 4.34, t (4.0) 4.31, d (5.5) 5 5.09, s 5.14, s 5.04 s 5.15 s 5.03, s 6.22, s 7 1.87, dd (13.8, 8.4) 2.11, dd (14.0, 9.5) 1.95, m 2.15, dd (14.5, 7.5) 1.70, dd (13.5, 9.0) 2.53 d (14.0) 2.17, m 2.21, dd (13.5, 7.0) 2.23, dd (14.5, 7.5) 2.13, dd (13.5, 5.5) 2.36 d (14.0) 8 1.62, m 1.65, m 1.21, m 1.45, m 1.58, m 9 1.11, m 1.14, m 1.41, m 1.17, m 1.10, m 5.17, d (9.0) 1.23, m 1.28, m 1.27, m 1.27, m 10 1.32, m 1.30, m 1.23, m 1.28, m 1.27, m 4.24, dt (9.0, 6.5) 11 1.30, m 1.27, m 1.24, m 1.28, m 1.27, m 1.55, m 1.39, m 12 0.89, t (7.2) 0.90, t (7.5) 0.84, t (7.5) 0.99, t (7.5) 0.89, t (7.5) 0.86, t (7.5) 13 1.64, dq (7.2, 7.2) 1.89, m 1.88, m 1.92, m 1.89, dq (15.0, 7.5) 2.15, m 1.72, dq (7.2, 7.2) 1.99, m 2.02, m 2.02, m 2.03, dq (15.0, 7.5) 14 1.01, t (7.2) 0.95, t (7.5) 0.99, t (7.5) 0.98, t (7.5) 1.01, t (7.5) 1.15, t (7.5) 15 2.13, m 2.04, m 2.10, dq (7.5, 7.5) 2.03, m 2.03, dq (14.0, 7.0) 1.88, m 2.27, dq (7.5, 7.5) 2.33, dq (14.0, 7.0) 1.76, m 16 1.03, t (7.2) 0.99, t (7.5) 1.00, t (7.5) 1.00, t (7.5) 0.98, t (7.5) 0.81, t (7.5) 17 0.85. d (6.6) 0.84. d (6.5) 1.25, m 1.20, m 0.81. d (6.5) 2.09, m 18 0.89, t (7.5) 0.85, t (7.5) 0.97, t (7.5) 19 3.68, s a Recorded at 600 MHz. b Recorded at 500 MHz. Table 2 13 C NMR data of compounds 1–6 in CDCl3 No. 1a 2b 3b 4b 5b 6b 1 174.9 qC 175.7 qC 175.1 qC 175.0 qC 175.6 qC 166.8 qC 2 37.6 CH2 38.8 CH2 38.8 CH2 38.8 CH2 38.9 CH2 84.0 CH 3 72.4 CH 74.4 CH 74.6 CH 74.6 CH 74.5 CH 171.4 qC 4 93.3 qC 92.8 qC 92.3 qC 92.2 qC 92.7 qC 140.3 qC 5 120.1 CH 123.4 CH 124.0 CH 123.5 CH 124.0 CH 139.4 CH 6 148.6 qC 147.3 qC 147.3 qC 147.7 qC 147.0 qC 97.4 qC 7 44.9 CH2 37.5 CH2 41.4 CH2 35.1 CH2 44.7 CH2 43.6 CH2 8 30.8 CH 30.6 CH 32.6 CH 37.0 CH 30.9 CH 139.0 qC 9 36.5 CH2 37.1 CH2 36.8 CH2 33.1 CH2 36.8 CH2 132.9 CH 10 29.2CH2 29.2 CH2 28.8 CH2 29.2 CH2 29.3 CH2 69.6 CH 11 22.9 CH2 22.9 CH2 23.1 CH2 23.1 CH2 23.0 CH2 30.4 CH2 12 14.0 CH3 14.1 CH3 14.1 CH3 14.1 CH3 14.1 CH3 9.7 CH3 13 31.8 CH2 27.4 CH2 27.2 CH2 27.4 CH2 27.1 CH2 18.5 CH2 14 8.1 CH3 8.3 CH3 8.4 CH3 8.4 CH3 8.4 CH3 12.1 CH3 15 23.9 CH2 29.8 CH2 23.4 CH2 30.0 CH2 23.5 CH2 30.9 CH2 16 12.9 CH3 13.0 CH3 12.8 CH3 13.1 CH3 12.8 CH3 8.1 CH3 17 19.6 CH3 19.1 CH3 25.5 CH2 26.1 CH2 19.5 CH3 24.5 CH2 18 10.6 CH3 11.6 CH3 13.6 CH3 19 50.6 CH3 a Recorded at 150 MHz. b Recorded at 125 MHz. Table 3 Biological activities of 1, 2 and 5–10 Compound Antifungal IC50 (μg/ml)/MIC (μg/ml) Cytotoxicity IC50 (μg/ml) Antileismanial IC50 (μg/ml) Antimalarial IC50 (μg/ml) HCT-116 HeLa SW480 QGY-7703 A549 D6 W2 1 – 9.23 27.43 17.08 26.53 16.79 >40 >50 >50 2 10.49/20 4.34 6.51 11.28 17.98 10.77 13.82 >50 >50 5 3.66 >50 – – – – >40 >50 >50 6 – >50 – – – – >40 >50 >50 7 20.00 – – – – – 38.56 >50 >50 8 15.30 – – – – – 31.24 >50 >50 9 20.00 – – – – – 20.20 >50 >50 10 11.72 – – – – – 7.11 2.0 2.0 Amphotericin B 0.317 – – – – – 0.34 – – Camptothecin – 3.22 2.43 8.26 1.41 0.81 – – – Pentamidine – – – – – – 1.62 – – Chloroquine – – – – – – – 0.06 0.83 Supplementary data: Supplementary data associated with this article can be found in the online version, at doi:10.1016/j.tet.2012.04.025. These data include MOL files and InChiKeys of the most important compounds described in this article. References and notes 1 Higgs MD Faulkner DJ J Org Chem 1978 43 3454 3457 2 Braekman JC Daloze D De Groote S Fernandes JB Van Soest RWM J Nat Prod 1998 61 1038 1042 9722495 3 Hu JF Gao HF Kelly M Hamann MT Tetrahedron 2001 57 9379 9383 4 Kossuga MH Nascimento AM Reimao JQ Tempone AG Taniwaki NN Veloso K Ferreira AG Cavalcanti BC Pessoa C Moraes MO Mayer AMS Hajdu E Berlinck RGS J Nat Prod 2008 71 334 339 18177008 5 Feng Y Davis RA Sykes M Avery VM Camp D Quinn RJ J Nat Prod 2010 73 716 719 20235550 6 Rahm F Hayes P Kitching W Heterocycles 2004 64 523 575 7 Qureshi A Salva J Harper MK Faulkner DJ J Nat Prod 1998 61 1539 1542 9868160 8 Yong KWL De Voss JJ Hooper JNA Garson MJ J Nat Prod 2011 74 194 207 21261297 9 Rudi A Afanii R Gravalos LG Aknin M Gaydou E Vacelet J Kashman Y J Nat Prod 2003 66 682 685 12762807 10 Perry TL Dickerson A Khan AA Kondru RK Beratan DN Wipf P Kelly M Hamann MT Tetrahedron 2001 57 1483 1487 11 Patil AD Freyer AJ Bean MF Carte BK Westley JW Johnson RK Lahouratate P Tetrahedron 1996 52 377 394 12 Zampella A Giannini C Debitus C D'Auria MV Tetrahedron 2001 57 257 263 13 De Guzman FS Schmitz FJ J Nat Prod 1990 53 926 931 14 Cafieri F Fattorusso E Taglialatela-Scafati O Ianaro A Tetrahedron 1999 55 13831 13840 15 Stierle DB Faulkner DJ J Org Chem 1980 45 3396 3401 16 Gochfeld DJ Hamann MT J Nat Prod 2001 64 1477 1479 11720540 17 Xie XG Wu XW Lee HK Peng XS Wong HN Chem —Eur J 2010 16 6933 6941 20432418 18 Hayes PY Kitching W J Am Chem Soc 2002 124 9718 9719 12175225 19 Akiyama M Isoda Y Nishimoto M Narazaki M Oka H Kuboki A Ohira S Tetrahedron Lett 2006 47 2287 2290 20 Liu XF Song YL Zhang HJ Yang F Yu HB Jiao WH Piao SJ Chen WS Lin HW Org Lett 2011 13 3154 3157 21604759 21 Compagnone RS Pina IC Rangel HR Dagger F Suarez AI Venkata Rami Reddy M John Faulkner D Tetrahedron 1998 54 3057 3068 22 Epifanio R Pinheiro L Alves N J Braz Chem Soc 2005 16 1367 1371 23 Ohtani I Kusumi T Kashman Y Kakisawa H J Am Chem Soc 1991 113 4092 4096 24 Hoye TR Jeffrey CS Shao F Nat Protoc 2007 2 2451 2458 17947986 25 Cai G Bozhkova N Odingo J Berova N Nakanishi K J Am Chem Soc 1993 115 7192 7198 26 Huang XH van Soest R Roberge M Andersen R J Org Lett 2003 6 75 78 27 Richard GB Mary JG James S J Chem Soc, Chem Commun 1980 1165 1167 28 Ma G Khan SI Jacob MR Tekwani BL Li Z Pasco DS Walker LA Khan IA Antimicrob Agents Chemother 2004 48 4450 4452 15504880 29 Carmichael J De Graff WG Gazdar AF Minna JD Mitchell JB Cancer Res 1987 47 936 942 3802100 30 Muhammad I Bedir E Khan SI Tekwani BL Khan IA Takamatsu S Pelletier J Walker LA J Nat Prod 2004 67 772 777 15165136 31 Mikus J Steverding D Parasitol Int 2000 48 265 269 11227767
PMC005xxxxxx/PMC5114165.txt
LICENSE: This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. 101282001 33781 Brain Struct Funct Brain Struct Funct Brain structure & function 1863-2653 1863-2661 26983815 5114165 10.1007/s00429-016-1208-y NIHMS770542 Article Exposure to a diet high in fat attenuates dendritic spine density in the medial prefrontal cortex Dingess Paige M. 2 Darling Rebecca A. 2 Dolence E. Kurt 1 Culver Bruce W. 1 Brown Travis E. 12* 1 School of Pharmacy, University of Wyoming, Laramie, WY 82071 2 Neuroscience Program, University of Wyoming, Laramie, WY 82071 * To whom correspondence should be addressed: Travis E. Brown, PhD, University of Wyoming, 1000 E. University Ave., Dept. 3375, Laramie, WY 82071, Phone: 307-766-6129, Fax: 307-766-2953, tbrown53@uwyo.edu 2 11 2016 17 3 2016 3 2017 01 3 2018 222 2 10771085 This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. A key factor in the development of obesity is the overconsumption of food calorically high in fat. Overconsumption of food high in fat not only promotes weight gain but elicits changes in reward processing. No studies to date have examined whether consumption of a high-fat (HF) diet alters structural plasticity in brain areas critical for reward processing, which may account for persistent changes in behavior and psychological function by reorganizing synaptic connectivity. To test whether dietary fat may induce structural plasticity we placed rats on one of three dietary conditions: ad libitum standard chow (SC), ad libitum 60% HF (HF-AL), or calorically matched 60% HF (HF-CM) for 3 weeks and then quantified dendritic spine density and type on basal and apical dendrites of pyramidal cells in layer V of the medial prefrontal cortex (mPFC) and medium spiny neurons (MSNs) of the nucleus accumbens. Our results demonstrate a significant reduction in the density of thin spines on the apical and basal segments of dendrites within the infralimbic, but not prelimbic, mPFC. high-fat prefrontal cortex plasticity dendritic spines Introduction At present, more than one third of the U.S. adult population is classified as obese, making obesity a substantial and relevant health concern [1]. Obesity contributes to and/or exacerbates a host of health problems, including heart disease [2], diabetes [2], stroke [3] and certain types of cancers [4], all of which could be mitigated by reducing the prevalence of obesity [5]. The development of obesity is likely a consequence of diverse factors that broadly include genetics [6], lifestyle [7] inactivity [8], pregnancy [9], unhealthy diet [10], socioeconomic status [11], and environmental influences [12]. Although there are numerous causes contributing to the obesity epidemic what is ubiquitous among most theories is that excessive consumption of foods calorically high in fat results in weight gain and obesity [13]. A hallmark of obesity is continued unhealthy eating behaviors despite knowledge of negative social and physiological consequences [14]. It has been hypothesized that exposure to dietary high-fat (HF) results in a decrease in natural reward sensitivity and therefore contributes to compensatory hedonic overeating behaviors (i.e., eating in the absence of an energetic demand) [15, 16]. In the rodent model, overconsumption of diets high in fat has consistently and efficiently been shown to induce obesity and induce a number of neurobiological changes within the mesolimbic dopamine reward system [17, 18]. For example, obese rats have a reduction in striatal dopamine D2 receptors (D2Rs) and knockdown of D2Rs potentiates compulsive food seeking to HF food, suggesting a deficit in brain reward processing [19]. Additionally, rats fed a diet consisting of Crisco, cheddar cheese and peanut butter for 15 weeks have lower extracellular dopamine (DA) levels within the nucleus accumbens (NAc) compared to standard chow fed animals [20]. Consistent with adaptations in reward processing, rats susceptible to diet-induced obesity are more prone to food-cue triggered motivation and show increased sensitivity to cocaine, suggesting basal differences in the function of the mesolimbic circuits [21, 22]. In addition to rodent studies, clinical research has shown evidence of dysregulated D2R signaling within obese human populations. Specifically, Wang et al., (2001) showed that striatal D2R availability is attenuated in obese individuals and that this decrease is negatively correlated with body mass index (BMI) [23]. It has also been demonstrated that the down regulation of striatal D2Rs in morbidly obese patients is linked with a decrease in brain glucose metabolism, a measure of brain function, within the prefrontal cortex (PFC) [24]. As demonstrated, previous reports of reward circuit modulation have focused on changes in dopaminergic plasticity, particularly in regards to DA and D2R levels but little is known about the structural plasticity that may underlie those changes. One way to examine structural change is to quantify dendritic spine density and spine type. Dendritic spines are considered to be the primary postsynaptic structures where excitatory synaptic inputs, primarily glutamatergic, are integrated [25]. Activity within the PFC is shaped by several factors. Dopamine in particular has been implicated in mediating primary PFC cognitive functions, including memory and reward [26], and the interaction between DA and glutamate has been studied as a major mechanism underlying neuronal excitability [27, 28] and may subserve plasticity. The influence of DA on glutamate function in the cortex is partially dependent upon what DA receptor is expressed on the neuron [29]. In the PFC, it has been demonstrated that D2 and D1 receptors decrease and increase pyramidal cell excitability, respectively [30]. Despite the well-established relationship between DA and glutamate and the relatively large amount of literature examining DA plasticity in obesity, very little research has aimed to elucidate changes in excitatory transmission. Functionally, increases in dendritic spine density and shape are hypothesized to be the direct result of long-term potentiation (LTP) [31, 32], particularly on dendritic segments where spine density is already low [33], and can shrink in size following long-term depression (LTD) [34]. As such, changes in spine density and shape are thought to reflect synaptic activity and neuronal remodeling. Dendritic spine plasticity has been extensively studied in response to pathological and non-pathological paradigms. For example, postmortem studies in human patients diagnosed with mental retardation [35] or schizophrenia [36] show a marked decrease in spine density in the CA1 region of the hippocampus and on pyramidal neurons of the PFC, respectively. Alternatively, an increase in spine density has been observed in the rat hippocampal dentate gyrus following consolidation of water maze training, a spatial learning task [37]. Within the reward circuit, an increase in spine density has been demonstrated in NAc shell (NAc-Sh) and mPFC following exposure to the psychostimulants amphetamine and cocaine [38]. Stress too has been reported to have a positive effect on spine density in the NAc-Sh, prelimbic PFC (PL-PFC) and orbitofrontal cortex (OFC) [39]. In contrast, morphine [40] and sucrose [41] elicit the opposite effect on spine density within the NAc-Sh and OFC, respectively. The aim of our study was to examine whether exposure to dietary HF would induce changes in dendritic spine density within the PFC and NAc similarly to other appetitive stimuli. Rats were maintained on either ad libitum standard chow (SC), ad libitum 60% HF (HF-AL) or 60% HF calorically matched (HF-CM) diets for 3 weeks. Following 3 weeks of feeding on SC, HF-CM, or HF-AL diets, dendritic spine density and type were analyzed within the PL-PFC, infralimbic prefrontal cortex (IL-PFC), the NAc-Sh and NAc core (NAc-C) using DiI staining to visualize the spines. Methods Animals Eighteen adult (PND 60) male Sprague-Dawley rats obtained from our breeding colony and housed in clear plastic cages in a temperature-controlled room with a 12:12-h light-dark cycle with lights on at 0700 were utilized for experimental procedures. Rats were 285-397 g at the beginning of the experiment. All experimental procedures and protocols for animal studies were approved by the University of Wyoming Institutional Animal Care and Use Committee in accordance with international guidelines on the ethical use of animals. Maintenance diets Rats were exposed to one of three dietary conditions in their home cages for three weeks: standard chow (SC, n=6), 60% high-fat (HF-AL, n=6), or 60% calorically-matched high-fat (HF-CM, n=6). The nutritional content of the SC diet included ∼29% protein, ∼58% carbohydrate, and ∼13% fat by kilocalorie with a total fuel value of 3.36 kcal/g (Laboratory Rodent Diet 5001, St. Louis, MO). The nutritional content of the HF diet included ∼20% protein, ∼20% carbohydrate, and ∼60% fat by kilocalorie with a gross fuel value of 5.24 kcal/g (Research Diets, New Brunswick, NJ). Animals in the HF-CM group were also fed the 60% HF diet but were food restricted such that their daily caloric intake, and therefore weight gain, did not significantly differ from the SC controls at the time of sacrifice (Figure 1B, Table 1). Each day, food consumption was measured and averaged for each dietary condition. The total amount of food consumed by the SC group was then multiplied by the caloric value of the diet (3.36 kcal/g) in order to obtain an average caloric intake. The average caloric intake was then divided by the caloric value of the HF diet (5.24 kcal/g) to estimate the amount of food to be given to the HF-CM group. This method ensured that the caloric intake of both the SC and HF-CM groups were the same. To validate that this procedure produced similar weight gain in the SC and HF-SM groups, all animals were weighed every other day. Furthermore, following sacrifice, epididymal fat was dissected and weighed as a proxy for overall fat composition. This gonadal fat deposit is among the largest adipose deposits in the rat and is therefore often used in diet studies to determine whether the dietary manipulation induced fat accumulation, in addition to changes in body weight [42]. Quantification of dendritic spine density After dietary exposure, rats were euthanized via cardiac perfusion (200 mL, 0.9% saline followed by 300 mL, 1.5% paraformaldehyde (in 0.1M phosphate buffer (PBS)). After washing in PBS, brains were coronally sectioned into 200 μm slices with a Leica VT1200S vibratome (Leica, Buffalo Grove, IL) and briefly collected in PBS. Slices were fixed in 4% paraformaldehyde in PBS for 20 minutes, incubated with Vybrant-DiI cell-labeling solution (1:200, Invitrogen, USA) for 1 hour at room temperature and placed in PBS at 4°C for 48 hours to allow dye diffusion within membranes. Finally, slices were mounted on glass slides with Vectashield (Vector, Burlingame, CA) and imaged using a Zeiss confocal microscope. For cortical pyramidal cells, dendritic spines were quantified on the terminal tips of third or fourth order basal dendrites and second or third order apical dendrites in layer V of the PL-PLC and IL-PFC. For medium spiny neurons, spines on third order or greater terminal tips were quantified in the NAc-Sh and NAc-C [43]. In all regions of interest, visible spines located within the terminal 10 μm were manually counted using 40 × magnification. In addition to total density, spine type was also analyzed following parameters previously described [44]. Briefly, spines were identified as thin type if the ratio of head diameter to neck diameter was greater than 1.1 and maximum head diameter was less than 0.4 μm. Spines were identified as mushroom type if the ratio of head to neck diameter was greater than 1.1 and the maximum head diameter was greater than 0.4 μm. Spines with a head to neck ratio of less than 1.1 were classified as stubby and those that bifurcated above the connection between spine and dendrite were classified as cup shaped. Filopodium were identified as long, thin protrusions lacking a head. Within each animal 4-8 dendrites were selected from distinct cells for analysis in each brain region and counts from these dendrites were then averaged. Dendrites were only selected if staining of the cell was complete enough that the branch order and differentiation of spine types could be determined. In total, 32-40 dendrites were analyzed per group for each brain region. Slides were coded so that the person responsible for cell selection and analysis was blind to the experimental condition. Statistical analyses were performed by averaging dendritic spine counts across animals per brain region. Group differences were assessed using two-way ANOVA and any post hoc comparisons were completed with Tukey's multiple comparisons test (p<0.05). Results To determine whether dietary manipulation may alter structural plasticity within the reward circuitry of the brain we quantified changes in dendritic spine density within the PFC and NAc, brain regions known to play a vital role in reward processing [45, 46]. There was a significant dietary effect on weight gain (F(2, 15) = 14.40, p<0.01), a significant day effect (F(10, 150) = 352, p<0.01), and significant dietary and day interaction (F(20, 150) = 9.50, p<0.01). Post-hoc analysis revealed that rats in the HF-AL group showed significant weight gain compared to HF-CM and SC fed rats days 9-21 (Figure 1B). In addition to gaining significant weight, rats maintained on the ad libitum high-fat diet showed a significant increase in estimated body fat composition measured by the ratio of epididymal fat to body weight (SC: 1.18 ± 0.09, HF-CM: 1.6 ± 0.08, HF-AL: 2.49 ± 0.25, Figure 1C). Basal and apical spine density was quantified from pyramidal cells within the PFC-PL and the PFC-IL regions of the prefrontal cortex (Figures 2-3, Table 2) and spines were quantified from medium spiny neurons (MSNs) in the shell and core of the NAc (Figure 4, Table 2). To our surprise the dietary exposure had no significant effect on the total spine density or spine type of MSNs within the NAc-C (Table 2). There was also no dietary effect on the spine density or spine type of pyramidal cells within the PL-PFC (Table 2). However, there was a significant dietary effect within the IL-PFC on the total spine density for both apical and basal dendrites (Apical: SC: 11.43 ± 0.09, HF-CM: 9.89 ± 0.16, HF-AL: 9.91 ± 0.22; F(2, 10) =57.34, p<0.01; Basal: SC: 12.00 ± 0.16, HF-CM: 10.08 ± 0.12, HF-AL: 10.05 ± 0.14, F(2, 10) = 74.22, p<0.01). An analysis of the spine type revealed that this reduction was due largely to an attenuation of thin spines in the IL-PFC. There was a significant dietary and spine type interaction (F(8, 150) = 14.82, p<0.01). Post-hoc analysis revealed that rats in both the HF-AL and HF-CM groups showed a significant attenuation in thin spines (Apical: SC: 7.24 ± 0.20, HF-CM: 5.39 ± 0.19, HF-AL: 5.50 ± 0.09; Basal: SC: 7.37 ± 0.25, HF-CM: 5.33 ± 0.28, HF-AL: 5.64 ± 0.11, Figure 3B). Interestingly, we also observed an increase in stubby type spines on apical dendrites in the HF-CM group compared to SC (SC: 1.16 ± 0.14, HF-CM: 1.69 ± 0.14) and a decrease in mushroom type spines on apical dendrites in the HF-CM group compared to SC (SC: 2.75 ± 0.14, HF-CM: 2.28 ± 0.12). Discussion Our study looked to expand upon previous research that has shown neurobiological changes as a result of exposure to dietary HF. To the best of our knowledge, no laboratories have examined whether dietary HF induces changes in dendritic spine density within the reward circuit. In the present study, rats exposed to dietary HF independent of weight gain had attenuation in spine density on both apical and basal dendrites of the IL-PFC compared to SC controls (Figure 3). This reduction in spine density can be mostly attributed to a loss of thin spines. This is not surprising given that thin spines are the most numerous comparatively and form and disappear more rapidly in the context of varying levels of synaptic activity, suggesting that they are more susceptible to plasticity [47]. Thin spines have been widely characterized under a multitude of circumstances. For example, a loss of thin spines has been observed in the monkey prefrontal cortex following aging [48] while an increase of thin spines in this region has been demonstrated subsequent of seven days forced abstinence from cocaine self-administration in rats [49]. The loss of thin spines in response to HF exposure may underlie previous reports that HF consumption impairs learning and memory, evidenced by performance on both hippocampal and frontal-dependent tasks [50]. While there were also significant changes between SC and HF-CM groups in mushroom and stubby spines in the IL-PFC, it is unlikely a dietary effect since the HF-AL group did not also show this trend. It is however possible that this finding may be attributed to food restriction given the nature of the feeding regimen in the HF-CM group, but future studies are required to elucidate this. It is further hypothesized that a lack of change in spine type or density in the nucleus accumbens may be due to a lack of ability to discriminate between D1 and D2 dopamine receptor-containing neurons, given their differential change in spine density following treatments such as withdrawal from cocaine [51]. Quantification of spine density is a common approach used to examine experience-induced modifications to synaptic organization [35] [36] [37]. Although it is an indirect measure, providing information about changes to the postsynaptic cell exclusively, electron microscopy (EM) studies have demonstrated that changes in spine density correlate with sites of synaptic contact [52, 53]. Specifically, time-lapse two-photon imaging studies within the hippocampus shows an increased spine density following induction of long-term potentiation (LTP), a phenomenon known to increase synaptic strength [25]. Similarly, following long-term depression (LTD), or loss of synaptic efficacy, shrinkage in spine size is observed [34] suggesting that changes in spine dynamics is correlated with synaptic activity, or lack thereof. To examine a potential neurobiological consequence of the HF diet, we quantified dendritic spine density in the PFC (IL and PL) and NAc (core and shell), key reward areas long characterized as being involved in reward seeking and reward reinforcement, respectively [38, 54, 55]. The PL-PFC has been known to initiate reward-seeking, as found in cocaine studies demonstrating that inhibition of this region blocks several forms of reinstated drug seeking [56-58]. The significance of the IL-PFC is presently less established but is suggested to play an opposing role in reward related behavior. Specifically, it has been demonstrated that the IL-PFC is responsible for the inhibition of cocaine seeking in extinguished rats, as measured by an increase in cocaine reinstatement following inactivation of this region [59]. Similarly, inactivation of the IL-PFC immediately following extinction impairs the maintenance of consolidation of extinction after cocaine self-administration [60]. The above findings suggest that while the PL-PFC facilitates reward seeking, the IL-PFC is an integral component of inhibitory control [61]. Our results demonstrate that exposure to HF decreases dendritic spine density and type in the IL-PFC within both the HF-AL and HF-CM groups compared to SC controls, while no differences between groups were observed in the PL-PFC or NAc. This is the first report of morphological changes following exposure to a HF diet. Given the proposed role of the IL-PFC in inhibitory control of drug reward seeking, we hypothesize that the decrease in spine density may underlie challenges in dieting behavior after exposure to fatty foods. This finding is supported by other reports of hypofunctionality in the PFC, notably the decrease in glucose metabolism in obese patients [14]. Future studies will expand upon these findings to study the downstream consequence of altering excitatory input and output from the IL-PFC in controlling feeding behaviors. The authors would like to thank Dr. Zhaojie Zhang, the director of the Neuroscience microscopy facility at the University of Wyoming, for his help and guidance imaging the spine data. We would also like to thank Kevin Schlidt and Morgan Deters for their assistance with animal care. We are also grateful for the support contributed by NIGMS grant P30 GM103398, and the College of Health Sciences Seed Grant from the University of Wyoming. Fig 1 Ad Libitum exposure to a high-fat diet for 3 weeks increases weight gain and body-fat composition (A) Experimental timeline. (B) Percent weight gain throughout dietary exposure. (C) Body-fat composition measured as the ratio of epididymal fat to body weight. Values represent the mean ± S.E.M. * indicates significant increase in HF-AL from SC and HF-CM fed rats. Fig 2 Exposure to a high-fat diet for 3 weeks has no effect on spine density within the prelimbic region of the prefrontal cortex (A) Representative prelimbic PFC apical (bottom) and basal (top) DiI-stained dendrites from each dietary condition. (B) Quantification of spine type from the basal (left) and apical (right) dendrites of pyramidal cells in the PL-PFC. Values represent the mean ± S.E.M. Fig 3 Exposure to a high-fat diet for 3 weeks decreases spine density within the infralimbic prefrontal cortex (A) Representative IL-PFC apical (bottom) and basal (top) DiI-stained dendrites from each dietary condition. (B) Quantification of spine type from the basal (left) and apical (right) dendrites of pyramidal cells in the IL-PFC. Values represent the mean ± S.E.M. Fig 4 Exposure to a high-fat diet for 3 weeks has no effect on spine density within the nucleus accumbens (A) Representative nucleus accumbens core (top) and shell (bottom) DiI-stained dendrites from each dietary condition. (B) Quantification of spine type from medium spiny neurons of the core (left) and shell (right). Values represent the mean ± S.E.M Table 1 Dietary compositions and percent weight gain for rats exposed to SC, HF-AL, and HF-CM dietary conditions for 3 weeks % Calories % Weight Δ Protein Carbohydrates Fat 3 wk Standard Chow 28.5 58.0 13.5 124.1 ± 0.96 High-Fat Calorically Matched 20.0 20.0 60.0 124.4 ± 2.16 High-Fat Ad Libitum 20.0 20.0 60.0 139.7 ± 3.65* * indicates significant weight gain from SC and HF-CM fed rats. Values represent the mean ± S.E.M Table 2 Summary of dendritic spine quantification A Prelimbic PFC Basal Apical SC HF-CM HF-AL SC HF-CM HF-AL Filopodium 0.27 ± 0.11 0.29 ± 0.09 0.23 ± 0.09 Filopodium 0.28 ± 0.08 0.36 ± 0.09 0.22 ± 0.08 Thin 7.30 ± 0.13 7.32 ± 0.10 7.29 ± 0.16 Thin 7.21 ± 0.12 7.06 ± 0.20 7.27 ± 0.16 Stubby 1.74 ± 0.08 1.56 ± 0.15 1.79 ± 0.10 Stubby 1.40 ± 0.03 1.68 ± 0.16 1.60 ± 0.06 Mushroom 2.54 ± 0.14 2.64 ± 0.16 2.59 ± 0.14 Mushroom 2.53 ± 0.15 2.44 ± 0.11 2.43 ± 0.14 Cup Shaped 0.22 ± 0.06 0.16 ± 0.04 0.16 ± 0.03 Cup Shaped 0.19 ± 0.05 0.08 ± 0.03 0.09 ± 0.04 Total 12.07 ± 0.19 12.01 ± 0.22 12.07 ± 0.23 Total 11.62 ± 0.24 11.61 ± 0.24 11.62 ± 0.11 B Infralimbic PFC Basal Apical SC HF-CM HF-AL SC HF-CM HF-AL Filopodium 0.54 ± 0.12 0.40 ± 0.12 0.31 ± 0.08 Filopodium 0.31 ± 0.12 0.39 ± 0.07 0.28 ± 0.05 Thin 7.37 ± 0.25 5.33 ± 0 28 * 5.64 ± 0.11 * Thin 7.24 ± 0.20 5.39 ± 0.19 * 5.50 ± 0.09 * Stubby 1.67 ± 0.13 1.58 ± 0.12 1.45 ± 0.07 Stubby 1.16 ± 0.14 1.69 ±0.14 $ 1.50 ± 0.20 Mushroom 2.20 ± 0.33 2.57 ± 0.10 2.48 ± 0.07 Mushroom 2.75 ± 0.14 2.28 ± 0.12 # 2.56 ± 0.19 Cup Shaped 0.24 ± 0.07 0.21 ± 0.06 0.16 ± 0.04 Cup Shaped 0.05 ± 0.03 0.14 ± 0.05 0.09 ± 0.04 Total 12.01 ± 0.16 10.08 ± 0.12 10.05 ± .14 Total 11.43 ± 0.09 9.89 ± 0.16 9.91 ± 0.22 C Nucleus Accumbens Core Shell SC HF-CM HF-AL SC HF-CM HF-AL Filopodium 0.41 ± 0.05 0.37 ± 0.12 0.23 ± 0.02 Filopodium 0.32 ± 0.09 0.30 ± 0.12 0.24 ± 0.08 Thin 9.45 ± 0.16 9.41 ± 0.25 9.4 ± 0.07 Thin 9.44 ± 0.13 9.36 ± 0.10 9.37 ± 0.17 Stubby 1.68 ± 0.06 1.91 ± 0.09 1.91 ± 0.15 Stubby 1.53 ± 0.14 1.67 ± 0.23 1.72 ± 0.09 Mushroom 2.67 ± 0.06 2.60 ± 0.08 2.55 ± 0.19 Mushroom 2.65 ± 0.12 2.52 ± 0.11 2.53 ± 0.19 Cup Shaped 0.29 ± 0.04 0.13 ± 0.05 0.19 ± 0.05 Cup Shaped 0.15 ± 0.07 0.16 ± 0.11 0.12 ± 0.05 Total 14.50 ± 0.08 14.42 ± 0.21 14.41 ± 0.24 Total 14.08 ± 0.18 13.99 ± 0.20 13.96 ± 0.23 * indicates significant decrease in HF-AL and HF-CM from SC fed rats. $ indicates significant increase in HF-CM from SC fed rats. # indicates significant decrease in HF-CM from SC fed rats. 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PMC005xxxxxx/PMC5114175.txt
LICENSE: This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. 0370121 6712 Prog Neurobiol Prog. Neurobiol. Progress in neurobiology 0301-0082 1873-5118 26721620 5114175 10.1016/j.pneurobio.2015.12.002 NIHMS757198 Article Challenges in the development of therapeutics for narcolepsy Black Sarah Wurts a Yamanaka Akihiro b Kilduff Thomas S. a* a Center for Neuroscience, Biosciences Division, SRI International, Menlo Park, CA 94025, USA b Research Institute of Environmental Medicine, Nagoya University, Nagoya 464-8601, Japan * Corresponding author at: Center for Neuroscience, Biosciences Division, SRI International, 333 Ravenswood Avenue, Menlo Park, CA 94025, USA. Tel.: +1 650 859 5509. thomas.kilduff@sri.com (T.S. Kilduff). 3 11 2016 23 12 2015 5 2017 01 5 2018 152 89113 This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. Narcolepsy is a neurological disorder that afflicts 1 in 2000 individuals and is characterized by excessive daytime sleepiness and cataplexy—a sudden loss of muscle tone triggered by positive emotions. Features of narcolepsy include dysregulation of arousal state boundaries as well as autonomic and metabolic disturbances. Disruption of neurotransmission through the hypocretin/orexin (Hcrt) system, usually by degeneration of the HCRT-producing neurons in the posterior hypothalamus, results in narcolepsy. The cause of Hcrt neurodegeneration is unknown but thought to be related to autoimmune processes. Current treatments for narcolepsy are symptomatic, including wake-promoting therapeutics that increase presynaptic dopamine release and anticataplectic agents that activate monoaminergic neurotransmission. Sodium oxybate is the only medication approved by the US Food and Drug Administration that alleviates both sleep/wake disturbances and cataplexy. Development of therapeutics for narcolepsy has been challenged by historical misunderstanding of the disease, its many disparate symptoms and, until recently, its unknown etiology. Animal models have been essential to elucidating the neuropathology underlying narcolepsy. These models have also aided understanding the neurobiology of the Hcrt system, mechanisms of cataplexy, and the pharmacology of narcolepsy medications. Transgenic rodent models will be critical in the development of novel therapeutics for the treatment of narcolepsy, particularly efforts directed to overcome challenges in the development of hypocretin replacement therapy. Narcolepsy Cataplexy Orexin Hypocretin Neurodegeneration Animal models 1. Overview of narcolepsy 1.1. History The neurological disorder narcolepsy began with descriptions of patients who experienced attacks of muscle weakness with retained consciousness after excitation (Westphal, 1877) and the frequent, urgent need to sleep (Gélineau, 1880; Schenck et al., 2007). The term “narcolepsy” (literally “seized by somnolence”) was coined by Gelineau and was described over one hundred years ago as a syndrome with many disparate features that seemed to defy reconciliation with a unified mechanism of etiology. Overwhelming sleepiness, emotionally-triggered muscle paralysis, onset of sleep attacks possibly associated with head trauma, sleep attacks during physical activity, nighttime sleeplessness, hallucinations, mental sluggishness and obesity were all described in these early reports. The attacks of paralysis were considered distinct from epilepsy because they were not accompanied by loss of consciousness, sensation was maintained, and neither tonic convulsions nor clonic movement were observed. These episodes were first characterized by Löwenfeld (Löwenfeld, 1902) but eventually termed “cataplexy” (literally “struck down as if stupefied”) by Henneberg and Adie in the early 20th century (Guilleminault et al., 2007) to refer to sudden, emotionally-triggered bilateral loss of muscle tone. 1.2. Clinical features 1.2.1. The narcolepsy tetrad The symptoms of narcolepsy were first organized into the classic tetrad to aid diagnosis (Yoss and Daly, 1957) and include: Excessive daytime sleepiness (EDS): sudden or persistent need to sleep during the day, independent of the amount or quality of previous nighttime sleep; cataplexy: sudden loss of muscle tone, usually triggered by positive, rather than negative, emotional stimuli (Anic-Labat et al., 1999); hypnogogic hallucinations: unreal, vivid auditory or visual perceptions at sleep onset; sleep paralysis: temporary inability to move while falling asleep or awakening. Of these symptoms, only cataplexy is unique to narcolepsy—the others can occur in people without narcolepsy, for example, in instances of severe sleep deprivation (Guilleminault and Cao, 2011). In addition, not all of these symptoms are present in all narcoleptic individuals. Cataplexy, while pathognomonic of narcolepsy, only occurs in 60–70% of narcoleptic patients (Bassetti and Aldrich, 1996) and, consequently, a distinction is made between diagnosis of narcoleptic patients with and without cataplexy (see Section 1.2.2). Beyond the classic tetrad, other features are now well acknowledged to contribute to the symptomatology of narcolepsy. Many of these features have been discovered through advances in basic sleep research over the last 50 years. 1.2.2. Non-tetrad symptoms: arousal state instability The discovery of rapid eye movement (REM) sleep as a distinct sleep state characterized by activated EEG, muscle atonia, bursts of eye movements, and vivid dreaming (Aserinsky and Kleitman, 1953; Dement and Kleitman, 1957; Jouvet et al., 1959) heralded a new understanding of the narcolepsy syndrome. Subsequent research revealed that patients with narcolepsy entered REM sleep sooner than the typical 90 min interval after sleep onset that is observed in non-narcoleptic controls (Rechtschaffen et al., 1963). Because these sleep-onset REM periods (SOREMPs) persisted during daytime naps (Dement et al., 1966), narcolepsy came to be viewed as a disorder of REM sleep timing. Intrusions of inappropriately timed dream imagery and muscle atonia of REM sleep were also thought to underlie the hypnogogic hallucinations and sleep paralysis experienced by patients with narcolepsy. Cataplexy came to be viewed as an initiation of REM sleep atonia during wakefulness—a hypothesis corroborated by the finding that only patients who experienced cataplexy also exhibited SOREMPs (Dement et al., 1966). These observations led to the implementation of the Multiple Sleep Latency Test (MSLT) to detect SOREMPs, and to objectively measure daytime sleepiness as an aid in the diagnosis of narcolepsy (Mitler et al., 1979; Richardson et al., 1978). In the MSLT, patients are provided a series of 4–6 nap opportunities at 2 h intervals that begin 2 h after the onset of wakefulness following a night of standard polysomnography. During the nap opportunities, mean sleep latency within 8 min and REM onset within 15 min (a SOREMP) in at least 2 naps was considered pathologic (Mathis and Hess, 2007). Recently, the diagnostic criteria for narcolepsy have changed such that a SOREMP during polysomnographic monitoring on the night prior to the MSLT can count as one of the two or more SOREMPS required for diagnosis (Eichler, 2014). Thus, three of the tetrad symptoms (cataplexy, hypnogogic hallucinations and sleep paralysis) appeared to be linked to a REM sleep abnormality in narcolepsy, but EDS did not fit this paradigm. As the timing of sleep and wakefulness across the 24 h day/night cycle became recognized as due to interaction between the circadian timekeeping system and a sleep homeostatic mechanism (Borbely et al., 1984; Daan et al., 1984; Edgar et al., 1993), the pathological sleepiness in narcolepsy was also examined in these terms. Patients with narcolepsy not only have difficulty staying awake during the day, they also sleep poorly at night (Roth et al., 2013). Could the EDS of narcolepsy be a compensatory response to lost night time sleep? Slow wave activity during NREM sleep (EEG spectral power in the 0.75–4.5 Hz frequency band), an index of homeostatic sleep drive, was shown in narcoleptics to increase after experimentally-induced sleep deprivation and to decrease during recovery sleep, which revealed that homeostatic regulation was operative (Tafti et al., 1992). Despite shorter latencies from bedtime to sleep onset, patients with narcolepsy indicate that they experience insomnia more frequently than controls (Parkes et al., 1998). These self-reports have been supported by objective polysomnography in which frequent nocturnal awakenings and reduced REM sleep latency are thought to contribute to fragmented nighttime sleep in narcolepsy (Harsh et al., 2000). Despite the large sample size in this study, however, the relationship between disrupted nighttime sleep and sleepiness the following day was found to be weak and thus does not explain the EDS of narcolepsy (Harsh et al., 2000). In addition, the defined, but attenuated, distribution of sleep, wake, and sleepiness across the 24 h day/night cycle in patients with narcolepsy has been interpreted to indicate an intact circadian timekeeping system (Broughton et al., 1988; Dantz et al., 1994). Thus, neither dysfunctional sleep homeostatic mechanisms nor abnormal circa-dian processes fully explain the pattern of fragmented arousal states. The observations that SOREMPs, the extent of nocturnal awakening, and EDS strongly correlate with cataplexy (Harsh et al., 2000) foreshadowed the current view that narcolepsy is best described as a disorder of arousal state instability. It has now been firmly established that the loss of arousal state boundary control, first described by Broughton et al. (1986), arises from the loss of the hypothalamic neuropeptide hypocretin-1 (HCRT1), also known as orexin (see Section 2.2 and Section 2.4). The 3rd Edition of the International Classification of Sleep Disorders, (Eichler, 2014) formalized the distinction of narcolepsy with loss of HCRT1 (which usually presents with cataplexy) as “narcolepsy type 1”, and without HCRT1 loss or cataplexy as “narcolepsy type 2.” Narcolepsy type 1 was intended to capture patients who clearly have insufficient HCRT1 levels but may not yet manifest cataplexy, since a third of patients with low HCRT1 do not develop cataplexy until ~15 years after the onset of EDS (Andlauer et al., 2012). Classification of narcolepsy type 1 requires EDS, a positive score on the MSLT, and either cataplexy or, if cataplexy is absent, a low concentration of cerebrospinal fluid (CSF) HCRT1 (<110 pg/ml, if using a standard reference) that is 1/3 of normal levels (Baumann et al., 2014). Narcolepsy type 2 also requires EDS and a positive score on the MSLT, and is diagnosed based on exclusion of narcolepsy type 1 and differentiation from hypersomnia by the presence of sleep paralysis and hallucinations. A SOREMP on polysomnography the night preceding the MSLT may substitute for one of the ≥2 SOREMPs on the MSLT that is typically required for the diagnosis of narcolepsy type 1 and type 2. These new diagnostic criteria and the classification of narcolepsy types underscore the move away from classic tetrad symptomatology to a more refined understanding based on the etiology of the disease. 1.2.3. Metabolic and autonomic abnormalities A renewed interest in the metabolic abnormalities noted anecdotally in narcoleptic patients resulted from the discovery of the role of HCRT loss in narcolepsy (see Section 2.2 and Section 2.4) and identification of the concomitant role of HCRT in energy homeostasis (Funato et al., 2009; Hara et al., 2001; Yamanaka et al., 2003). Narcolepsy has consistently found to be associated with obesity or increased body mass index (BMI) that does not appear to be secondary to daytime inactivity from EDS or medication (Chabas et al., 2007; Dahmen et al., 2001; Heier et al., 2011; Kok et al., 2003; Nishino et al., 2001; Poli et al., 2009; Schuld et al., 2002). Although the obesity has been clearly linked to low cerebrospinal fluid (CSF) HCRT1 levels (Heier et al., 2011; Nishino et al., 2001; Poli et al., 2009) and abdominal fat deposits (Kok et al., 2003; Poli et al., 2009), the cause of the BMI increase in narcolepsy has been challenging to parse. Binge eating, irresistible food cravings, and sleep-related eating disorder have been reported in approximately a quarter of narcoleptic patients (Fortuyn et al., 2008; Palaia et al., 2011), but this population also has reduced daily caloric intake compared to healthy controls (Chabas et al., 2007; Lammers et al., 1996). Like other overweight people, patients with narcolepsy who are obese tend to have lower resting metabolic rates (Chabas et al., 2007). The higher prevalence of eating disorders and the specificity of reduced basal metabolism to narcolepsy has been challenged in studies that employed BMI-matched controls, and have led to the hypotheses that obesity in narcolepsy could be due to changes in BMI set point or to reduced sympathetic tone (Dahmen et al., 2008, 2009; Fronczek et al., 2008a). Early reports of reduced leptin, a hormone that signals energy deficiency (Kok et al., 2002; Nishino et al., 2001; Schuld et al., 2000) or impaired glucose metabolism as in type 2 diabetes mellitus (Honda et al., 1986) have not been corroborated by studies of narcolepsy patients that have employed more rigorous methodology (Beitinger et al., 2012; Donjacour et al., 2014, 2013; Ohayon, 2013). However, a recent study of narcolepsy type 1 patients sampled close to disease onset found a positive correlation between CSF leptin levels and BMI; subjects with long disease duration and low CSF HCRT1 levels had higher leptin levels and BMI (Kornum et al., 2015). Surprisingly, patients with narcolepsy have been shown to be more sensitive to insulin in peripheral tissues (Donjacour et al., 2014). Autonomic disturbances in narcolepsy have been reported, but still remain poorly understood. Whether the autonomic changes are directly due to the loss of HCRTs or are secondary to the ensuing sleep/wake fragmentation has been difficult to ascertain, particularly because Hcrt neurons influence both sympathetic and parasympathetic outflows (Plazzi et al., 2011; van den Pol, 1999). Some studies have indicated reduced sympathetic tone in narcolepsy, as revealed by attenuated cardiovascular reflexes (Sachs and Kaijser, 1982) or increased variability in heart rate and blood pressure (Fronczek et al., 2008a). Other studies in which heart rate variability was measured in patients with narcolepsy have demonstrated normal reduction in sympathetic outflow during sleep, but reduced parasympathetic tone during wakefulness (Ferini-Strambi et al., 1997) or enhanced sympathetic activity during orthostatic stress (Grimaldi et al., 2010b). Baseline heart rate has also been reported to be elevated in narcolepsy (Grimaldi et al., 2012; Sorensen et al., 2013). The normal responses of increased heart rate in relation to arousals from sleep and decreased blood pressure during sleep have been shown to be blunted in narcolepsy with cataplexy (Dauvilliers et al., 2012; Grimaldi et al., 2012), particularly in those patients with low or absent HCRT1, even compared to narcolepsy patients with normal HCRT1 levels (Sorensen et al., 2013). Together, these results support the hypothesis that HCRT insufficiency, concomitant with altered sleep architecture, leads to increased sympathetic activation. However, this hypothesis appears to be refuted by a recent study in which a correlation was found between HCRT1 level, heart rate and resting muscle sympathetic nerve activity as measured by direct microneurographic monitoring (Donadio et al., 2014). Perhaps these opposing results could be explained by the possibility that autonomic changes near disease onset differ from autonomic responses that develop over time to compensate for the initial changes, as has been hypothesized for thermoregulatory changes in narcolepsy (Black et al., 2013). There is also evidence for altered temperature regulation in both human narcoleptics and animal models. Although a circadian rhythm of core body temperature (Tb) was clearly evident in human narcoleptics (Grimaldi et al., 2010a), nighttime Tb levels were elevated relative to controls (Mosko et al., 1983; Pollak and Wagner, 1994). Whether this is a cause or a consequence of disrupted nocturnal sleep in narcoleptics was unclear. Human narcoleptics also have a larger distal-to-proximal skin temperature gradient during wakefulness and, when asleep, maintain elevated distal skin temperature whereas proximal skin temperature increases to normal levels (Fronczek et al., 2006). Proximal skin warming in narcoleptic patients significantly suppressed nocturnal wakefulness and enhanced slow wave sleep whereas distal skin warming disrupted nocturnal sleep (Fronczek et al., 2008b). These observations are consistent with the concept that the Hcrt system is a key determinant of overall energy expenditure and, thus, body weight regulation. The normal decline in Tb at sleep onset is also blunted in Hcrt-deficient mice; these mice also have normal Tb levels during wakefulness despite exhibiting less locomotor activity (Mochizuki et al., 2006). Similar results were also observed in orexin/ataxin-3 mice in which Hcrt neurons are chronically lost after birth (Black et al., 2013). In this study, the number of remaining Hcrt neurons in the transgenic mice positively correlated with the Tb change from wakefulness to NREM and REM sleep. Together, these results imply a role for the Hcrt system in either activation of heat loss mechanisms or, alternatively, loss of the HCRTs may result in compensatory elevated activity in other thermogenic systems. In contrast to chronic HCRT deficiency, acute disruption of Hcrt signaling with the dual HCRT receptor antagonist almorexant decreased Tb in wild type mice. These observations led to the hypothesis that at the onset of narcolepsy, early disruption of Hcrt signaling may reduce thermogenesis; then as more Hcrt neurons are lost, the ensuing hypothermia may activate compensatory heat conservation mechanisms (Black et al., 2013). Hypocretin neurons directly innervate the rostral raphe pallidus, site of sympathetic premotor neurons that innervate brown adipose tissue (BAT), thereby providing a neural pathway for elevating thermogenesis (Tupone et al., 2011). Hypocretin-deficient mice also exhibit impaired BAT differentiation (Sellayah et al., 2011). Hypocretin deficiency in narcolepsy could thus both increase the risk of obesity and the metabolic syndrome (Poli et al., 2009), while augmented activity in this system could contribute to a lean phenotype (Funato et al., 2009). 1.3. Prevalence and risk factors Narcolepsy occurs in North America and Europe with a prevalence of 0.03–0.05% (Ohayon et al., 2002; Silber et al., 2002). Geographic differences clearly occur; in Japan, the prevalence may be as high as 0.18% (Honda, 1979; Tashiro et al., 1992) whereas cases are rarely reported in Israel (Lavie and Peled, 1987). As of 2002, the incidence rate was determined to be 1.37/100,000 new cases per year (Silber et al., 2002) with a bimodal distribution of age of onset with peaks at about 15 and 35 years of age (Dauvilliers et al., 2001). The proportion of narcolepsy cases in epidemiology studies that could be classified as narcolepsy type 1 or type 2 is currently unknown (Baumann et al., 2014). The average time to diagnosis from symptom onset (usually EDS appears first) has usually been reported to take longer than 10 years, but the time lag may diminish with improved awareness of the disorder (Thorpy and Krieger, 2014). Diagnostic delay is longer in women than men and is associated with higher body mass index (Luca et al., 2013). A retrospective study indicated that about half of narcoleptic patients report symptom onset prior to 15 years of age and, in China, 70% had onset before age 10 (Han et al., 2011). The delay in diagnosis is greatly reduced when disease onset is in childhood (Nevsimalova, 2009) or when cataplexy presents as the first symptom or with high frequency (Luca et al., 2013). Only 1–2% of first degree relatives share narcolepsy diagnoses, which represents a 10–40× increased risk factor compared to the general population (Mignot, 1998). Monozygotic twins that have narcolepsy with cataplexy are only 25–30% concordant for the disorder (Mignot, 1997). While this evidence supports a role for environmental factors to contribute to narcolepsy onset, genetic predisposition is clearly important. Risk factors for narcolepsy can be found in genes that encode the major histocompatibility complex proteins, also known as human leukocyte antigen (HLA) genes. Narcolepsy is highly associated with HLA class II polymorphisms in the closely linked loci DQB1*06:02 and DQA1*01:02 that together form the DQ0602 heterodimer (Juji et al., 1984; Matsuki et al., 1992; Mignot et al., 1994a). Almost all narcolepsy with cataplexy patients (82–99%) are carriers of DQB1*06:02 while only 12–38% of non-narcoleptic individuals carry this allele (Mignot et al., 1997, 2001). Full length exome sequencing (Tafti et al., 2014) has indicated the DQB1*0602 allele is not mutated in narcolepsy and, thus, is only a susceptibility factor in the disorder. The susceptibility risk for narcolepsy is two-fold in individuals that are homozygous for DQB1*06:02 compared to heterozygous carriers (Pelin et al., 1998). The largest genome-wide association study to date estimated a 251-fold increased risk for narcolepsy in DQB1*0602 carriers and identified 4 protective DQB1 alleles (Tafti et al., 2014). A much smaller, but significant, predisposing effect of HLA-DPB1*05:01 in narcolepsy has recently been found in Asians (Ollila et al., 2015). The HLA genes encode molecules that present antigen fragments to the T-cell receptor in order to direct an immune response to a specific antigen. Other predisposing factors for narcolepsy are associations with a polymorphism in the T-cell receptor alpha and beta genes, whose products recognize antigens presented by HLA molecules, and Cathepsin H, which processes antigens for presentation (Faraco et al., 2013; Hallmayer et al., 2009; Han et al., 2013a). The purinergic receptor subtype P2Y11, which is expressed in cytotoxic lymphocytes and in the brain, has also been shown to be associated with narcolepsy (Kornum et al., 2011b). The tight linkage between narcolepsy and HLA subtypes and other genes involved in autoimmunity such as TNFSF4, IL10RB-INFAR1, and P2YR11/DNMT1 (Faraco et al., 2013; Han et al., 2013a) strongly suggests an autoimmune basis for narcolepsy (Arango et al., 2015; Kornum et al., 2011a) (see Section 2.6). 1.4. Comorbidities The range of symptoms in narcolepsy, including arousal state instability and cataplexy, along with other metabolic and autonomic features of the disease that are not yet fully understood, can make it difficult to understand where the entity of narcolepsy ends and where comorbidities begin. For example, night time sleep disturbance in narcolepsy, while a consequence of arousal state instability due to HCRT deficiency (see Section 2.4), can also be caused by comorbidities thought to reflect motor instability such as restless legs syndrome, REM sleep without atonia, or REM sleep behavior disorder (Frauscher et al., 2013; Plazzi et al., 2010). Comorbidities were recognized by Legrand in one of the earliest descriptions of narcolepsy: “Encephalic congestion cardiac deficiency, gastric troubles or hepatic derangements, and such diseases as gout, diabetes, and rheumatism are some of its associations” (Legrand, 1888). Investigation into the comorbidities of narcolepsy began primarily with concerns for differential diagnosis or genetic associations, particularly with diabetes, depression, sleep apnea or parasomnias (Baker et al., 1986; Broughton et al., 1983; Honda et al., 1986; Mayer and Meier-Ewert, 1993). As the metabolic and autonomic abnormalities in narcolepsy began to be uncovered, concern was raised that patients with narcolepsy might be at a greater risk for serious, chronic conditions such as diabetes or cardiovascular disease. Recently, a well-controlled, prospective epidemiological study was undertaken to determine the odds ratios of medical and psychiatric disorders associated with narcolepsy in the United States (Ohayon, 2013). According to this study, digestive diseases, upper respiratory tract diseases, heart disease, hypercholesterolemia, and hypertension represented an increased risk in narcolepsy. Neither diabetes nor the metabolic syndrome was more prevalent in narcoleptic participants compared to age-, gender- and BMI-matched controls from the general population. Among the psychiatric conditions that present with a greater risk in narcolepsy, mood disorders were present in 19.2% of people with narcolepsy and primarily began after narcolepsy onset. Panic disorder, simple phobia, agoraphobia, generalized anxiety disorder, and posttraumatic stress disorder also were found to occur at an increased frequency in narcolepsy. These phobias and anxiety disorders began after narcolepsy onset in most cases. Participants with narcolepsy were not at greater risk than the general population for alcohol dependency. Psychotic disorders were not assessed in this study because there was no case in the matched general population sample. However, schizophrenia and other psychotic disorders have been noted to begin in children after the onset of narcolepsy (Canellas et al., 2014). The consequences of these medical and psychiatric comorbidities in narcolepsy may, at least in part, underlie the 1.5-fold increase in mortality observed in narcolepsy (Jennum et al., 2013; Ohayon et al., 2014). 2. Hypocretin/Orexin and disease mechanism 2.1. Narcoleptic dogs Narcolepsy has been described in other mammals including several breeds of dogs (dachshunds, poodles, Labrador retrievers and Doberman pinschers) (Mitler et al., 1976), horses (Dreifuss and Flynn, 1984; Lunn et al., 1993; Sweeney et al., 1983) and Brahman bulls (Strain et al., 1984). Although the mode of inheritance in small breed dogs is complex as it is in humans, large breed dogs such as Doberman pinschers and Labrador retrievers provide a simplified genetic system in which the mutation in the canine narcolepsy (canarc-1) gene is transmitted as an autosomal recessive trait with full penetrance (Foutz et al., 1979). Narcolepsy is also genetically transmitted in at least one breed of horse (Ludvikova et al., 2012). The existence of a genetic animal model of narcolepsy in dogs greatly facilitated research as it enabled the creation of a breeding colony to allow experimental pharmacological (Babcock et al., 1976; Delashaw et al., 1979; Mignot et al., 1988a,b; Mitler et al., 1976; Nishino and Mignot, 1997; Nishino et al., 1989), neurochemical (Faull et al., 1982, 1986; Mefford et al., 1983; Miller et al., 1990) and neurotransmitter receptor (Boehme et al., 1984; Bowersox et al., 1987, 1986; Kilduff et al., 1986; Mignot et al., 1988a,b) studies of narcolepsy to be conducted for the first time. The Food-elicited Cataplexy Test (FECT) was devised to enable quantitative assessment of cataplexy for pharmacological studies (Babcock et al., 1976; Mitler et al., 1976) and proved to be a useful tool for the assessment of drugs that ameliorated or exacerbated cataplexy (Nishino and Mignot, 1997). The general conclusion from these studies was that narcolepsy-cataplexy was likely a result of an imbalance between the monoaminergic and cholinergic systems resulting from monoaminergic hypoactivity and cholinergic hypersensitivity in the pons (Baker and Dement, 1985; Boehme et al., 1984; Mefford et al., 1983). Subsequent studies demonstrated that: (1) the activation of presynaptic adrenergic transmission likely underlies the anticaplectic activity of antidepressants (Mignot et al., 1993; Nishino et al., 1993), (2) the wake-promoting effects of the stimulants amphetamine and modafinil are mediated by presynaptic activation of dopamine (DA) neurotransmission (Mignot et al., 1994b) and (3) mesolimbic dopaminergic hypoactivity (Reid et al., 1996) and basal forebrain cholinergic hypersensitivity (Nishino et al., 1995) occur in narcolepsy. Although cataplexy, the pathognomonic symptom of narcolepsy, was unequivocally present in dogs, documentation of the occurrence of excessive sleepiness in these mutant animals was controversial and difficult to establish a species that can apparently sleep ad libitum in most domestic and laboratory situations (Kaitin et al., 1986a,b; Kushida et al., 1985; Lucas et al., 1979; Mitler and Dement, 1977). In contrast to the ease of evaluating cataplexy using the FECT, the labor-intensive nature of scoring of sleep/wake states based on EEG and EMG recordings limited the number of sleep pharmacology studies that were undertaken in narcoleptic dogs (Shelton et al., 1995). In contrast to human narcolepsy, early studies established that the canarc-1 mutation was not associated with the dog equivalent of the HLA system (Dean et al., 1989; Motoyama et al., 1989). Identification of the genetic basis of autosomal recessive mutation in dogs in an era before genome sequencing existed was a challenging task, necessitating the creation of a canine genomic bacterial artificial chromosome (BAC) library (Li et al., 1999). Using this BAC library, canarc-1 was ultimately identified as a deletion mutation in the gene encoding Hcrt receptor 2 (Hcrtr2) (Lin et al., 1999) as described below. 2.2. Dual discovery of hypocretins and orexins HCRT1 and HCRT2 are hypothalamic neuropeptides derived from a single precursor molecule (prepro-HCRT) by proteolytic processing (de Lecea et al., 1998; Sakurai et al., 1998). Although the HCRTs were formally described early in 1998 (de Lecea et al., 1998), subtraction cloning of the Hcrt gene from mouse and rat hypothalamus, localization of the cell bodies expressing the HCRT peptides, and description of their efferent projections was first reported at the 1997 Society for Neuroscience meeting (Peyron et al., 1997; Sutcliffe et al., 1997). Because the cell bodies expressing this gene were restricted to an area of the hypothalamus centered around the perifornical nucleus (PFH) and because of a weak homology to the gut peptide secretin, these molecules were called “hypocretins.” Just 6 weeks after the description of the HCRTs, these neuropeptides were independently reported by another group of investigators as ligands binding to cell lines expressing orphan G protein-coupled receptors (Sakurai et al., 1998). The chemical isolation procedure used allowed these investigators to determine that the longer of these two peptides was 33 amino acids in length and to define the N-terminal pyroglutamyl residue, the intrachain disulfide links, and the expected C-terminal amidation of both peptides. Since intracerebroventricular injections of these peptides increased food intake in rats, these investigators called the peptides orexin-A and orexin-B from the Greek root “orexis” meaning appetite. Importantly, this paper also reported functional information on the receptors for the two peptides: the orexin-1 receptor (OX1R) was shown to preferentially bind orexin-A over orexin-B, whereas the orexin-2 receptor (OX2R) bound both peptides with similar affinity (Sakurai et al., 1998). In the subsequent issue of Cell, the HCRTs and the orexins were confirmed to be the same peptides (Sakurai et al., 1998). The nomenclature describing this neuropeptidergic system can be confusing. As indicated above, the term “hypocretin” appeared first in the literature referring to the two neuropeptides encoded by the preprohormone (de Lecea et al., 1998). However, the cognate receptors for these peptides were first called the “orexin receptors” (Sakurai et al., 1998). The Human Genome Organization (HUGO) Gene Nomenclature Committee (Gray et al., 2015) and Genbank use the term “hypocretin (orexin)” to refer to both the peptides and the receptors and employ the abbreviations HCRT, HCRTR1 and HCRTR2 to refer to the genes encoding the preprohormone and the two receptors, respectively. In contrast, “The Concise Guide to PHARMACOLOGY 2013/2014” published by Committee on Receptor Nomenclature and Drug Classification of the International Union of Basic and Clinical Pharmacology (NCIUPHAR) refers to the receptors as “OX1 receptor” and “OX2 receptor” (Alexander et al., 2013). Thus, both terminologies are used in the literature: the prepro-Hcrt gene is identical to preproorexin; HCRT1 is equivalent to orexin-A; and HCRT2 is identical to orexin-B. Here, we will use the terms “HCRT1” and “HCRT2” to denote the two peptides, “Hcrt” to refer to the HCRT/orexin-containing cells or to the Hcrt or orexin gene, and “HCRTR1” and “HCRTR2” to refer to the receptors for these peptides. 2.3. Link to animal models of narcolepsy The Hcrt system was first linked to narcolepsy in 1999 when canarc-1 was identified as a deletion mutation in the Hcrtr2 gene (Lin et al., 1999). As described above, canarc-1 is transmitted as an autosomal recessive trait with full penetrance in Doberman pinschers and Labrador retrievers. Importantly, the mutation in these two breeds is in a different region of the Hcrtr2 gene, both of which result in a truncated, non-functional receptor protein. Shortly thereafter, the prepro-orexin ligand knockout mouse was found to exhibit periods of behavioral arrest that strongly resembled cataplexy in dogs and humans (Chemelli et al., 1999). These mice also have a disrupted sleep architecture, particularly during the dark period, as evidenced by increased levels of both REM and NREM sleep, short latency REM periods, and decreased sleep bout durations. The identification of the canarc-1 mutation as a deletion mutation in the Hcrtr2 gene through positional cloning and the creation of the orexin null mutant mouse were major advances in this field that not only drew a link between narcolepsy and the Hcrt system, but also suggested that this neuropeptidergic system, which had only been described 18 months earlier, might also be involved more generally in sleep/wake control. Subsequently, HCRT1 levels were found to be normal in the CSF of Hcrtr2-mutated narcoleptic Doberman pinschers and Labrador retrievers but were reduced or undetectable in either CSF or the brain of poodles and mixed breed dogs that exhibited sporadic (i.e., non-familial) narcolepsy (Ripley et al., 2001). A mutation in Hcrtr2 in a family of dachshunds was identified in which the protein was appropriately localized to the cell membrane, but failed to bind ligand and, consequently, Ca2+ mobilization upon receptor stimulation was greatly compromised (Hungs et al., 2001). Collectively, these observations further solidified the link between the Hcrt system and narcolepsy and demonstrated that dysfunction in Hcrt neurotransmission – whether occurring presynaptically, as in the orexin ligand null mutant mouse, or postsynaptically, as in the Hcrtr2-mutated Doberman pinschers and Labrador retrievers – could result in the similar phenotype of narcolepsy with cataplexy. 2.4. CSF peptide levels and neurodegeneration in human narcoleptics Although these studies in narcoleptic dog and mouse models strongly implicated the Hcrt system, the first direct indication of an abnormality in Hcrt neurotransmission in narcoleptic humans was suggested by undetectable levels of HCRT1 in CSF from 7 of 9 narcoleptic patients (Nishino et al., 2000). At that point, it was uncertain whether the reduced CSF HCRT1 reflected a problem in release or in synthesis of the peptide. However, 9 months later, postmortem analyses demonstrated that HCRT mRNA was undetectable in two human narcoleptic brains, although melanin-concentrating hormone (MCH) mRNA, a phenotypic marker of cells in the posterolateral hypothalamus that are distinct from Hcrt neurons, was readily detectable in both controls and narcoleptics (Peyron et al., 2000). Furthermore, an independently-conducted immunohistochemical study showed an 85–95% reduction in the number of HCRT-containing cells in human narcoleptic brains with no evident change in the number of MCH cells (Thannickal et al., 2000). Increased staining for glial fibrillary acid protein in the PFH of the human narcoleptic brains suggested that neurodegeneration likely had occurred whereas the preservation of MCH cells suggested that the Hcrt neurons selectively degenerate, possibly through an autoimmune mechanism (see Section 2.5) (Thannickal et al., 2000). Along with the animal studies described above, these studies strongly suggested that degeneration of the Hcrt cells is the likely cause of human narcolepsy. Subsequent studies documented loss of substances that are colocalized with HCRT, the neuropeptides dynorphin (Crocker et al., 2005) and neuronal-activity-regulated pentraxin (Blouin et al., 2005), thereby confirming neuronal cell loss in the narcoleptic brain, at least for narcolepsy type 1, rather than an absence of HCRT expression. The etiology of narcolepsy type 2 is less understood than the pathology underlying narcolepsy type 1. Most patients without cataplexy have HCRT1 levels above the criteria for narcolepsy type 1 diagnosis (Mignot et al., 2002), suggesting some degree of Hcrt neurotransmission may still occur in narcolepsy type 2. An immunohistochemical study of a single postmortem human brain from a narcoleptic patient without cataplexy found only a 33% loss of Hcrt cells, suggesting that narcolepsy without cataplexy can result from a partial loss of the Hcrt neuron population (Thannickal et al., 2009). An MRI study found microstructural changes in the inferior frontal gyrus, postcentral gyrus, and amygdala in narcoleptic patients with cataplexy vs. normal controls, but no differences were detected between normal controls and narcoleptic patients without cataplexy (Nakamura et al., 2013). How these morphological changes might relate to Hcrt neurodegeneration is unclear. However, two independent groups have suggested that remodelling of wake-promoting systems occurs subsequent to loss of Hcrt neurons, as they reported an increase in the number of histaminergic (HA) cells in the tuberomammillary nuclei (TM) in post mortem tissue from narcoleptic patients with cataplexy (John et al., 2013; Valko et al., 2013), and the increase in HA cells correlates with the extent of Hcrt cell loss (Valko et al., 2013). 2.5. Hypothesized autoimmunity While it is now well established that narcolepsy type 1 is caused by neurodegeneration of Hcrt cells and that a strong genetic component in immune function confers susceptibility to the disease, it is less clear how these two pieces fit together to fully understand the etiology of narcolepsy. The hypothesis that narcolepsy is an autoimmune disease that targets Hcrt neurons seems plausible but the mechanism has remained elusive for decades (Carlander et al., 1993; Mignot, 2014). Autoantibodies against HCRT peptides, HCRT receptors, or antigens co-localized on Hcrt neurons have evaded detection in numerous studies (Black et al., 2005; Overeem et al., 2006; Tanaka et al., 2006). The absence of identified autoantibodies in narcolepsy contrasts with other CNS autoimmune diseases (Graus et al., 2010), although some evidence for autoantibodies exists. Sera from a small group of patients with narcolepsy has been shown to bind tribbles homolog 2 (TRIB2) (Cvetkovic-Lopes et al., 2010) but, because this protein is expressed in many tissues both in CNS and in the periphery and not just in Hcrt neurons, TRIB2 autoantibodies are unlikely to be causative of Hcrt neurodegeneration (Kornum et al., 2011a) and instead may be secondary to the destruction of Hcrt cells (Liblau et al., 2015). When sera from narcoleptics and patients with other sleep disorders were screened on rat brain tissue, three distinct patterns of immunoreactivity were observed, one of which was identified to correspond to the C-terminal epitope of neuropeptide glutamic acid-isoleucine/alpha-melanocyte-stimulating hormone peptides (Bergman et al., 2014). A recent study, in which CSF samples from narcolepsy type 1 patients with early onset (within 1–12 months) were examined for changes in 51 cytokines and chemokines, did not find a difference in the levels of these immune markers compared to healthy controls (Kornum et al., 2015) and did not replicate a previously observed elevation of the cytokine interleukin 4 in this population (Dauvilliers et al., 2014a). Infections can induce autoimmunity through a wide variety of mechanisms, including molecular mimicry, epitope spreading, bystander activation and superantigens, and a growing body of evidence suggests pathogens can trigger narcolepsy (Arango et al., 2015; Kornum et al., 2011a). Onset of narcolepsy is more frequent in spring and early summer than in winter, consistent with triggering by winter time upper airway infections (Han et al., 2011). Streptococcal throat infection has been associated with a 5.4-fold increased risk of narcolepsy (Koepsell et al., 2010), and anti-streptococcal antibodies have been detected in 65% of narcoleptic patients with recent onset compared to age-matched controls (Aran et al., 2009). Serum from children with Syndenham's Chorea or pediatric autoimmune neuropsychiatric disorders associated with streptococcal infections (PANDAS) has been shown to contain cross-reactive antineuronal antibodies that can alter dopaminergic signaling pathways (Chang et al., 2015), but whether a similar cross-reactivity can affect the Hcrt system remains to be determined. Homology between an epitope specific to the 2009 H1N1 strain and HCRT peptides was initially claimed (De la Herran-Arita et al., 2013) but subsequently retracted (De la Herran-Arita et al., 2014), so how an immune response to the virus may ultimately cause Hcrt cell death remains to be demonstrated. Perhaps the most promising connection between narcolepsy and an infectious agent occurred following the 2009 H1N1 influenza pandemic. In China, the incidence of narcolepsy increased three-fold in the 6 months after the peak of the outbreak, then decreased to the normal rate of onset by 2011 after the pandemic had been contained (Han et al., 2013b, 2011). As initially reported in Finland and Sweden (Bardage et al., 2011; Nohynek et al., 2012; Partinen et al., 2012) and later in other European countries (Dauvilliers et al., 2013a; O'Flanagan et al., 2014; Winstone et al., 2014), a 6–9-fold increase in new narcolepsy cases in children was observed a few months following vaccination against H1N1 with Pandemrix®—a formulation that contained the AS03 adjuvant. In contrast, no elevations in the rate of narcolepsy were reported in the U.S. where only non-adjuvanted vaccines were used (Duffy et al., 2014) or elsewhere in Europe where a closely related adjuvant, MF59, was used in the vaccine Focetria® (Ahmed et al., 2014; Calabro et al., 2013). Although these results suggest that the adjuvant AS03 could be problematic, no elevation in narcolepsy rates were observed in Canada where AS03 was also used as a component of the vaccine Arepanrix® (Montplaisir et al., 2014). However, although Pandemrix® and Arepanrix® were produced by the same manufacturer and administered with AS03, slightly different protocols for antigen isolation were utilized which resulted in more nucleoprotein and neuraminidase in Pandemrix® and a larger diversity of viral and chicken proteins in Arepanrix® (Jacob et al., 2015). This has led to the hypothesis that differential composition of the vaccines may be the key to understanding the increased incidence in narcolepsy in the affected populations (Ahmed et al., 2014; Jacob et al., 2015). A recent study (Ahmed et al., 2015) has shown that Pandemrix® contained 72.7% more influenza nucleoprotein than Focetria®, and sera from HLA-DQB1*0602-positive patients with Pandemrix®-associated narcolepsy contained antibodies that cross-reacted with the influenza nucleoprotein and HCRTR2. These antibodies were found in a significantly greater proportion of sera from patients with Pandemrix®-associated narcolepsy compared to non-narcoleptic individuals with either a history of H1NI infection or Focetria® vaccination. Whether a similar mechanism of molecular mimicry against HCRT-related targets occurs in sporadic narcolepsy remains to be determined. 2.6. Rodent models of narcolepsy Since the recognition that the prepro-orexin ligand knockout mouse has a behavioral phenotype that strongly resembles cataplexy (Chemelli et al., 1999), a number of rodent models have been produced to further understanding of the link between the Hcrt system and narcolepsy and as tools to probe the Hcrt system (Ch'ng and Lawrence, 2015; Darwinkel et al., 2014; De La Herran-Arita et al., 2011; Makela et al., 2010; Muraki et al., 2004; Tanaka et al., 2012; Tsunematsu et al., 2011, 2013) (Table 1). In mice, knockout of the HCRT precursor protein (Chemelli et al., 1999) or HCRT receptors (Kalogiannis et al., 2011; Kisanuki et al., 2001; Mieda et al., 2011; Willie et al., 2003), or genetic ablation of Hcrt neurons (Beuckmann et al., 2004; Black et al., 2013; Hara et al., 2001; Tabuchi et al., 2014) result in a narcoleptic phenotype including cataplexy, sleep/wake fragmentation and increased REM sleep propensity. The Hcrtr2 knockout mouse exhibits behavioral arrests resembling cataplexy but the phenotype is less severe than the Hcrt ligand knockout or the Hcrtr2-mutated narcoleptic dog (Willie et al., 2003). Although description of the Hcrtr1 knockout mouse has only appeared in abstract form (Kisanuki et al., 2001), cataplexy is thought to be mild (if it occurs at all) in these animals. Like their human counterparts (Besset et al., 1994; Dantz et al., 1994), narcoleptic mice exhibit normal homeostatic responses to sleep loss (Mochizuki et al., 2004). A rat model has been produced in which the Hcrt neurons are targeted with a HCRT2-saporin conjugate (Gerashchenko et al., 2003, 2001). Although these animals exhibit sleepiness and sleep attacks, neurons other than the Hcrt cells are likely also destroyed. In the orexin/ataxin-3 transgenic mouse model, the HCRT promoter drives expression of the polyglutamine neurodegenerative ataxin-3 protein, resulting in a postnatal loss of Hcrt neurons (Hara et al., 2001). Degeneration of the Hcrt neurons occurs postnatally with cataplexy occurring by 6 weeks of age. Orexin/ataxin-3 mice exhibit a phenotype strikingly similar to the Hcrtr2 mutant canine model (Lin et al., 1999) and the prepro-orexin knockout mouse (Chemelli et al., 1999) with deficits that include cataplexy (Black et al., 2013), premature entries into rapid eye movement (REM) sleep, and poorly consolidated sleep patterns. These animals also become obese relative to wild type mice, emulating the increased BMI characteristic of human narcoleptics (Dahmen et al., 2001; Kok et al., 2003; Schuld et al., 2002). A similar model has been produced in the rat, which exhibits episodes resembling cataplexy as well as fragmented vigilance states, decreased latency to REM sleep, and increased REM sleep time and decreased wakefulness during the dark (active) phase (Beuckmann et al., 2004). Despite profound cell loss, HCRT1 can be detected in CSF from these rats and prolonged wakefulness can further increase CSF HCRT1, indicating that the remaining Hcrt neurons can be activated (Zhang et al., 2007). A conditional model of Hcrt neuron ablation has been introduced that in many ways is superior to the orexin/ataxin-3 transgenic mouse model (Tabuchi et al., 2014). In the orexin/tTA; TetO diphtheria toxin model (the DTA mouse), degeneration of Hcrt neurons is controlled through the tetracycline transactivator (tTA) Tet-off (TetO) system. Dietary doxycycline (DOX) binds to the tetracycline transactivator (tTA) and prevents the synthesis of diphtheria toxin A fragment (DTA) through the TetO regulatory sequence. Because the tTA is attached to the HCRT promoter, removal of DOX from the diet (DOX(−) condition) initiates the synthesis of DTA for neurotoxic degeneration exclusively in Hcrt neurons. Thus, unlike orexin/ataxin-3 mice, DTA mice can be used in pre-post study designs to serve as their own Hcrt-intact controls. Hcrt neurodegeneration can be induced postpuberty to create a model with greater fidelity to most cases of human narcolepsy. The narcoleptic phenotype of these mice appears to parallel the symptomatic progression of human narcolepsy. As described in our original report (Tabuchi et al., 2014), DTA mice lost ~86% of their Hcrt neurons and exhibited fragmented sleep/wake states by 1 week of DOX(−) that continued to worsen over subsequent weeks (Fig. 1). By 2 weeks of DOX(−), DTA mice lost ~95% of their Hcrt neurons; cataplexy first appeared and progressively increased in frequency until at least 11 weeks DOX(−). Compared to other mouse models of narcolepsy, cataplexy levels are high in these mice after 4 weeks of DOX(−) (>97% Hcrt cell loss), as they exhibit approximately 20 to 60 cataplexy episodes on average during the dark period. The behavioral and electrophysiological aspects of cataplexy in DTA mice (Fig. 2) are similar to those observed in orexin/ataxin-3 and prepro-orexin knockout mice, including hyper-synchronous theta activity in the EEG and abrupt behavioral immobilization (Bastianini et al., 2012; Vassalli et al., 2013). Partial Hcrt neuron ablation can also be induced by reinstatement of DOX after variable durations of DOX(−) to permit examination of the physiological consequences of reduced Hcrt cell numbers, and to perhaps model narcolepsy type 2. The DTA mouse will certainly expand the tool box for addressing a number of questions in narcolepsy, including developmental aspects and network reorganization in terminal fields as Hcrt input degenerates. 2.7. Hypocretin and the neural circuitry of arousal states Because narcolepsy is characterized by EDS as well as cataplexy and since the Hcrt cells are known to innervate the monoaminergic and cholinergic cell groups involved in the promotion of wakefulness (Date et al., 1999; Peyron et al., 1998), the Hcrt system was proposed soon after its discovery to be a wake-promoting system that provides excitatory input to the monoaminergic and cholinergic systems. In this model, the absence of excitatory input from the HCRT peptides in narcolepsy results in an imbalance between the monoaminergic and cholinergic systems and the consequent behavioral state instability (Kilduff and Peyron, 2000). This concept has been elaborated further in the “flip flop” switch model of arousal state control in which the Hcrt system is proposed to pivot the arousal systems from sleep to wake (Saper et al., 2001, 2010). A “flip flop” switch for REM sleep control has also been posited in which GABAergic populations that are active during REM sleep (“REM on”) or that are silent during REM sleep and active during wakefulness (“REM off”) mutually inhibit each other (Lu et al., 2006). In both of these models, the absence of stabilizing input from the HCRTs in narcolepsy causes rapid switching between wakefulness and sleep, especially REM sleep. Models of arousal state circuitry now incorporate excitatory input from Hcrt neurons to populations that are active during wakefulness (Fig. 3), including the noradrenergic locus coeruleus (LC; which receives the densest innervation), serotonergic dorsal raphe (DR), histaminergic TM nucleus, cholinergic basal forebrain (BF) and pontine reticular formation, and GABAergic ventrolateral periaqueductal gray (vlPAG) (Brown et al., 2012; Burgess and Scammell, 2012; Sakurai, 2014). HCRT facilitates motor tone during wakefulness through direct excitation of motor neurons (Peever et al., 2003; Yamuy et al., 2004) and by suppression of the circuitry necessary for REM sleep atonia (Brown et al., 2012; Burgess and Scammell, 2012; Dauvilliers et al., 2014b; Luppi et al., 2011) (Fig. 3). During REM sleep, motor neurons are inhibited by glycine (Chase et al., 1989) and GABA (Brooks and Peever, 2008, 2012) from neurons in the medial medulla (MM) and by spinal interneurons (Krenzer et al., 2011). These medial medullary and spinal interneurons are stimulated by glutamatergic input from the sublaterodorsal nucleus (SLD, functionally equivalent to the subcoeruleus in cats) to induce atonia during REM sleep (Krenzer et al., 2011). Neurons in the SLD receive strong GABAergic inhibition during wakefulness that must be disinhibited for atonia to occur (Boissard et al., 2003, 2002; Pollock and Mistlberger, 2003). REM sleep atonia can also be induced via cholinergic excitation of the SLD (Brown et al., 2006; Heister et al., 2009). These GABAergic and cholinergic inputs to the SLD are controlled by monoaminergic (Aston-Jones and Bloom, 1981; Crochet et al., 2006; Hobson et al., 1975; McGinty and Harper, 1976) and hypocretinergic (Burlet et al., 2002; Mileykovskiy et al., 2005; Peyron et al., 1998) neurons that are active during wakefulness. In the absence of HCRT in narcolepsy, cataplexy results from disinhibition of the REM sleep atonia circuitry (Luppi et al., 2011) and disfacilitation of noradrenergic activation of motor neurons (Burgess and Scammell, 2012; Dauvilliers et al., 2014b) (Fig. 4). Genetic knockout and transgenic mouse models of narcolepsy have enabled some of the neural circuitry underlying cataplexy mechanisms to be discerned. Building upon electrophysiological studies in narcoleptic dogs which showed that a population of cells in the central nucleus of the amygdala (CeA) was active during cataplexy (Gulyani et al., 2002), lesions of the CeA in prepro-orexin knockout mice markedly reduced cataplexy, especially in the context of strong emotional cues (Burgess et al., 2013). Neuronal activity, as indicated by Fos immunostaining in the dorsal portion of the medial prefrontal cortex (mPFC), positively correlated with the number of chocolate-elicited cataplexy bouts in prepro-orexin knockout mice (Oishi et al., 2013). Reversible suppression of mPFC activity with a conditional glutamate-gated chloride channel decreased this chocolate-elicited cataplexy (Oishi et al., 2013). Both the CeA and the mPFC (via the basolateral amygdala-CeA circuit) send inhibitory GABAergic projections to brainstem regions that gate cataplexy, such as the vlPAG and the lateral pontine tegmentum (Burgess et al., 2013; Oishi et al., 2013). Focal restoration of HCRT by adeno-associated virus (AAV) gene transfer into the dorsolateral pons reduced cataplexy (Blanco-Centurion et al., 2013). Together, these studies provide evidence that activation of forebrain limbic circuitry by emotional stimulation underlies cataplexy triggering and support the hypothesis that Hcrt excitation may balance this limbic inhibition to maintain muscle tone. Brainstem mechanisms underlie the direct inhibition and reduced excitation of motor neurons that defines cataplexy (Luppi et al., 2011; Peever, 2011). In narcoleptic dogs during cataplexy, neurons in the atonia circuitry of the MM become active (Siegel et al., 1991) and noradrenergic neurons of the LC become quiescent (Wu et al., 1999), but a causal role for noradrenergic neurons in cataplexy induction was uncertain. A recent study in prepro-orexin knockout mice has provided direct evidence that manipulation of adrenergic tone controls atonia during cataplexy (Burgess and Peever, 2013). In this study, antagonism of α1 receptors on trigeminal motor neurons via microdialysis induced atonia of their masseter muscle targets during wakefulness. During cataplexy, the effects of this antagonism were absent, indicating lost adrenergic tone and cataplectic attacks were halted by application of an α1 agonist (Burgess and Peever, 2013). However, focal restoration of Hcrtr1 in the LC of narcoleptic mice that lack both HCRT receptors failed to inhibit cataplexy, whereas cataplexy was blocked by targeted expression of Hcrtr2 in the dorsal raphe (Hasegawa et al., 2014). These studies highlight the complexity of the circuitry that governs motor control during arousal states and exemplify new experimental approaches to discern these mechanisms. 3. Therapeutics 3.1. Historical approaches Many health professionals in the late 1800s viewed the narcolepsy syndrome as a form of epilepsy, despite Gelineau's and Westphal's arguments to the contrary (see “history” above). Others misinterpreted narcolepsy in Freudian terms as a hysterical defense mechanism, perhaps because Westphal's index case was a rapist who suffered from pathological sleepiness (Mignot, 2001). It is not surprising then that attempted treatments for the narcolepsy syndrome, as historically misunderstood at the turn of the 20th century, were ineffective and included the anti-epileptic potassium bromide, vasodilators picrotoxin and amyl nitrate vapors, agents aimed to improve motor abnormalities such apomorphine and strychnine, and, lastly, hydrotherapy, electricity and cauterization of the nape of the neck (Dement, 2007; Schenck et al., 2007). Even caffeine granules administered by Gelineau were found to be insufficient to counter narcoleptic sleepiness (Schenck et al., 2007). In the 1930s, mild success was found with the CNS stimulant ephedrine (Doyle and Daniels, 1932). Amphetamine was introduced to treat narcolepsy in 1935 and found to be more effective at controlling sleepiness (Prinzmetal and Bloomberg, 1935); it is still prescribed for this purpose (Hishikawa and Shimizu, 2007). Pharmacological alleviation of cataplexy was first documented in 1960 with the unexpected discovery that the tricyclic antidepressant imipramine significantly decreased the occurrence of cataplexy (Akimoto et al., 1960). Neuropsychiatrists at the time hypothesized that the effectiveness of antidepressants to improve the mood and increase the activity levels of depressed and psychotic patients might also confer therapeutic potential of antidepressants to ameliorate the EDS of narcolepsy (Hishikawa and Shimizu, 2007). Although imipramine had no effect on EDS and irresistible sleep attacks, it did improve cataplexy (Akimoto et al., 1960) through its active metabolite desipramine (Hishikawa et al., 1966). These and other tricyclic antidepressants, such as protripty-line and clomipramine, were found to inhibit REM sleep and thereby control sleep paralysis and hypnogogic hallucinations in addition to cataplexy (Hishikawa and Shimizu, 2007). While tricyclic antidepressants non-selectively block serotonergic and noradrenergic reuptake as the therapeutic mechanism of action, they also antagonize histamine and muscarinic acetylcholine receptors, leading to frequently intolerable side effects such as sedation, dry mouth, sweating, constipation, blurred vision, sexual dysfunction, tachycardia, orthostatic hypotension and are contra-indicated in cardiovascular disease (Guilleminault and Cao, 2011; Mignot, 2012). Withdrawal from tricyclic antidepressants can also induce rebound cataplexy for several weeks after discontinuation of the medication (Ristanovic et al., 2009). The monoamine oxidase inhibitor selegiline, which increases synaptic DA in addition to serotonin and norepinephrine, has been noted to also strongly suppress REM sleep and improve EDS but has sympathomimetic side effects that limit its utility (Hublin et al., 1994). 3.2. Current treatments Current treatments for narcolepsy are based on symptomatic management of sleepiness and cataplexy. At least half of all narcolepsy patients take medication to manage their condition (Ohayon, 2013) and may need to do so for the rest of their lives as there is no cure yet. Medication in combination with lifestyle adaptations helps return an estimated 80% of patients with narcolepsy back to near normal functioning (Mignot, 2012). Behavioral modifications such as scheduled bedtimes, wake-up times, and napping, either as long naps in the afternoon or several brief naps distributed throughout the day, can benefit daytime performance and sometimes reduce the doses of stimulants needed (Thorpy and Dauvilliers, 2015). Behavioral management of cataplexy has not been well developed, but patients themselves may choose to avoid or control known emotional triggers (CDER, 2013; Dauvilliers et al., 2014b). The US Food and Drug Administration (FDA) has approved five pharmacotherapeutics for the treatment of narcolepsy: sodium oxybate (Xyrem®), modafinil (Provigil®), armodafinil (Nuvigil®), methylphenidate, and amphetamine (CDER, 2013). 3.2.1. Sodium oxybate Sodium oxybate, the sodium salt of gamma-hydroxybutyrate (GHB), is currently the only approved drug to treat both cataplexy and EDS in narcolepsy (Bosch et al., 2012; Boscolo-Berto et al., 2012) and, as such, is favored as the first-line therapeutic. A randomized, double blind, placebo-controlled multi-center trial compared the effects of three doses of orally administered sodium oxybate with placebo for the treatment of narcolepsy in 136 patients (Study Group, 2002). Subjects received 3, 6, or 9 g doses of sodium oxybate or placebo taken in 2 doses, the first upon retiring and the second 2.5–4 h later, for 4 weeks. Compared to placebo, weekly cataplexy attacks were decreased by sodium oxybate at the 6 g dose (p = 0.0529) and significantly at the 9 g dose (p = 0.0008). The frequency of inadvertent naps or sleep attacks and nighttime awakenings showed similar dose-response trends, becoming significant at the 9 g dose (Study Group, 2002). In a follow-up study, 55 narcoleptic patients with cataplexy who had received continuous treatment with sodium oxybate for 7–44 months (mean 21 months) were enrolled in a double-blind treatment withdrawal paradigm (Study Group, 2003a). During the 2-week double-blind phase, the abrupt cessation of sodium oxybate therapy in the placebo patients resulted in a significant increase in the number of cataplexy attacks (median = 21; p < 0.001) compared to patients who remained on sodium oxybate (median = 0). Cataplexy attacks returned gradually with placebo patients reporting a median of 4.2 and 11.7 cataplexy attacks during the first and second weeks, respectively (Study Group, 2004). Interestingly, there was no evidence of withdrawal following abrupt cessation of chronic sodium oxybate dosing in the therapeutic range (Study Group, 2003b), which is consistent with the observation that the minimum daily dose of sodium oxybate associated with withdrawal is 18 g (Miro et al., 2002). In a 12 month open label study, 118 patients exhibited a 90% reduction in cataplexy without evidence of tolerance (Study Group, 2003a). Lastly, a double-blind, placebo-controlled study in 228 patients across 42 clinics found that nightly doses of 4.5, 6 and 9 g sodium oxybate for 8 weeks resulted in statistically significant median decreases in weekly cataplexy attacks of 57.0, 65.0 and 84.7%, respectively (Study Group, 2005). Post FDA approval of sodium oxybate for cataplexy and EDS in a double-blind, placebo-controlled study showed that sodium oxybate improved nighttime sleep with a dose-related increase in slow wave sleep and total sleep time and a reduction in nocturnal awakening (Black et al., 2010). The mechanism of action of sodium oxybate as a narcolepsy therapeutic has not yet been elucidated. Some researchers have proposed that the therapeutic efficacy may be mediated by the increase in slow wave activity during NREM sleep that has been seen after acute administration of sodium oxybate (Black et al., 2010; Boscolo-Berto et al., 2012; Van Cauter et al., 1997; Walsh et al., 2010), although others have questioned the physiological relevance of GHB-induced slow waves in the EEG (Meerlo et al., 2004; Vienne et al., 2010, 2012). Despite its acute sedating effects, the therapeutic efficacy of sodium oxybate gradually emerges over time and persists after the drug has been metabolized (Boscolo-Berto et al., 2012; Mamelak, 2009). This delayed effect suggests that the therapeutic mechanism may be indirect and possibly involves secondary interactions of GABAB receptors and DA transmission (Guilleminault and Cao, 2011; Huang and Guilleminault, 2009), perhaps through disinhibition of DA release via G-protein coupled inwardly rectifying potassium channels (Cruz et al., 2004). GHB is a low affinity GABAB agonist that has been shown to preferentially inhibit GABAergic interneurons in the ventral tegmental area and consequently disinhibit dopaminergic cells—unlike high affinity GABAB agonists such as baclofen that directly inhibit both GABAergic interneurons and catecholamine neurons (Cruz et al., 2004). The effects of GHB are known to at least partially depend on the GABAB receptor (Brown and Guilleminault, 2011), as GABAB antagonists block GHB-induced inhibition of neurons (Jensen and Mody, 2001). The GHB prodrug gamma-butyrolactone does not produce behavioral or EEG effects in mice lacking GABAB1 and GABAB2 subunits (Kaupmann et al., 2003; Vienne et al., 2010). Sodium oxybate may also exert therapeutic effects via the α4βδ subunit of the GABAA receptor, which has been identified as a high-affinity target for GHB and is likely the elusive, endogenous GHB receptor (Absalom et al., 2012). While sodium oxybate is often well-tolerated and has been reported to have a positive impact on the lives of many patients with narcolepsy, it is not a medication without challenges. GHB is a controlled substance with abuse potential and possible neurotoxic side effects (Langford and Gross, 2011; van Amsterdam et al., 2012). Other side effects, even at recommended doses, include nausea, confusion, CNS and respiratory depression, neuropsychiatric depression and confusion, incontinence, sleepwalking, automatic behaviors, and involuntary movements (Xyrem®, 2005). Adverse events associated with GHB abuse consist of seizures, loss of consciousness and death (Xyrem®, 2005). Titration up to the final dose can help manage most side effects (Thorpy and Dauvilliers, 2015). Sodium oxybate has a short half-life and is usually administered in a split dose, once at bedtime and again 2.5–4 h later (Black et al., 2010), which can be difficult to manage. Sodium oxybate is contraindicated in patients with succinic semialdehyde dehydrogenase deficiency or those patients who are also taking sedative hypnotics or other CNS depressants. 3.2.2. Modafinil and armodafinil For patients who cannot take sodium oxybate, racemic modafinil or the extended release formulation of enantiomerspecific armodafinil may be suitable alternatives. Modafinil was approved for the promotion of wakefulness in narcolepsy by the US FDA in 1998. A meta-analysis comparison of modafinil and sodium oxybate has indicated similar therapeutic efficacy of the two medications in controlling EDS; however, modafinil is ineffective at reducing cataplexy when compared to placebo (Golicki et al., 2010). In contrast to amphetamines, modafinil has limited dependency and abuse potential, induces wakefulness with less psychomotor agitation (Bastuji and Jouvet, 1988) and does not cause rebound hypersomnolence (Edgar and Seidel, 1997). However, some studies have shown that modafinil has rewarding properties as indicated by reinforcing, discriminative stimulus effects (Paterson et al., 2010) or conditioned place preference in mice (Shuman et al., 2012). Similarly, modafinil has been shown to increase motivation in mice as measured by progressive ratio breakpoint (Young and Geyer, 2010). Nevertheless, modafinil and armodafinil lack the symphathomimetic side effects of amphetamines and, as such, are the first-line choice of treatment to promote wakefulness (Guilleminault and Cao, 2011). The mechanism of action of modafinil is still not fully understood but likely involves the dopamine transporter (DAT) to inhibit DA reuptake (Wisor, 2013). Modafinil has been shown to bind the DAT with very low affinity but high selectivity, with no binding at norepinephrine or serotonin transporters (Mignot et al., 1994b). Mice with genetic knockout of the DAT failed to increase wakefulness in response to modafinil (Wisor et al., 2001). Extracellular DA levels were increased in the caudate nuclei of narcoleptic dogs after modafinil administration, as would be expected by diminished activity of the DAT (Wisor et al., 2001). Whether modafinil, and particularly armodafinil, might also act postsynaptically as D1 or D2 agonists is still equivocal (Mignot et al., 1994b; Seeman et al., 2009; Young and Geyer, 2010; Zolkowska et al., 2009). Interestingly, modafinil has been shown to induce wakefulness more effectively in narcoleptic mice that lack either the HCRT ligand or Hcrt neurons vs. wild type littermates, which suggests that modafinil may act on components of wake-promoting systems that are facilitated as a compensatory response to disrupted Hcrt signaling (Willie et al., 2005), perhaps such as the mesolimbic D2 receptors that have been observed to increase in narcoleptic dogs (Bowersox et al., 1987). A proposed mechanism by which armodafinil may increase wakefulness through inhibition of sleep-active ventro-lateral preoptic neurons has been ruled out because large, cell-specific lesions to this area do not inhibit wake promotion by armodafinil (Vetrivelan et al., 2014). 3.2.3. Methylphenidate and amphetamine Methylphenidate and amphetamines are now second and third-line therapies, respectively, used to counter EDS in narcolepsy, usually to supplement modafinil or sodium oxybate (Thorpy and Dauvilliers, 2015). Like modafinil, methylphenidate and amphetamine promote wakefulness through presynaptic enhancement of DA release (Burgess and Scammell, 2012; Burgess et al., 2010; Nishino and Mignot, 2011). Amphetamine and methylphenidate both increase the release of DA and to a lesser extent, norepinephrine and serotonin (Mignot, 2012). Amphetamine also increases synaptic DA by reverse efflux through the DAT and, at higher doses, inhibits the vesicular monoamine transporter (VMAT), to increase intracellular DA concentration presynaptically (Leviel, 2011; Mignot, 2012). Methylphenidate primarily inhibits the DAT (Leonard et al., 2004). The d-isomer of these stimulants is more potent than the l-isomer in increasing wakefulness because it is more specific to DA neurotransmission (Nishino and Mignot, 2011). Although both enantiomers of amphetamine are equipotent at reducing REM sleep (Nishino and Mignot, 2011), l-amphetamine is more effective than d-amphetamine in decreasing cataplexy (Mignot, 2012). The anticataplectic effects of amphetamine may relate to its action at transporters for norepinephrine and/or serotonin, as selective DAT inhibition fails to reduce cataplexy (Wisor, 2013). Unlike modafinil, amphetamine has several other actions that lead to an unfavorable side effect profile, such as vasoconstriction and cardiac stimulation resulting from increased noradrenaline in the periphery. At high doses, amphetamines inhibit monamine oxidase to further increase synaptic DA, which can lead to cytotoxicity or psychosis (Leviel, 2011; Mignot, 2012). Rapid increases in DA concentration and high levels of DA release and reverse efflux probably contribute to amphetamine addiction (Volkow et al., 2009). 3.2.4. Antidepressants Antidepressants have not been approved by the FDA for the treatment of cataplexy, as there are currently no clinical trials on the efficacy and safety of these compounds for the indication of narcolepsy. In practice, however, both older tricyclic antidepressants and newer, selective monoaminergic reuptake inhibitors have been used off label and are reported to be very effective at reducing cataplexy (Dauvilliers et al., 2014b; Mignot, 2012; Thorpy and Dauvilliers, 2015). Because antidepressants generally do not promote wakefulness, they are usually prescribed in combination with modafinil or other stimulants (Mignot, 2012). A series of pharmacological studies in narcoleptic dogs led to the conclusion that monoaminergic reuptake inhibitors alleviate cataplexy to the extent that they, or their metabolites, activate presynaptic noradrenergic neurotransmission (Nishino and Mignot, 1997) (see Fig. 3). For this reason, the highly selective serotonergic and noradrenergic reuptake inhibitor (SNRI) venlafaxine is the first-line choice of treatment for cataplexy among the antidepressants, and low doses (below the level required to treat depression) are sufficient for effective cataplexy treatment (Dauvilliers et al., 2014b; Mignot, 2012). The selective serotonergic reuptake inhibitor (SSRI) fluoxetine is also commonly used to alleviate cataplexy, but higher doses than the level needed to control depression are required, probably because its anticataplectic effect is likely mediated by its noradrenergic-promoting metabolite norfluoxetine (Langdon et al., 1986). SNRIs are advantageous over tricyclic antidepressants because, unlike the latter, they do not block muscarinic cholinergic, H1 histaminergic, nor α1-adrenergic receptors, thereby resulting in fewer side effects (Dauvilliers et al., 2014b; Guilleminault and Cao, 2011). However, similar to tricyclic antidepressants, SNRIs are associated with an increase in the number and severity of cataplexy attacks after withdrawal, even with gradual tapering of the drugs (Ristanovic et al., 2009; Wang and Greenberg, 2013). Antidepressants have also been linked to the development of REM behavior disorder (Ju et al., 2011), although it is not clear if narcolepsy predisposes for this risk. 3.3. Use of narcoleptic mouse models for therapeutic development The pharmacology of many of the narcolepsy therapeutics used today has been examined in narcoleptic dogs in studies aimed at elucidating the receptor subtypes, active metabolites and brain regions involved the therapeutic control of cataplexy (see Section 2.1). Prior to the discovery of HCRT, these neurochemical studies in narcoleptic dogs established that an imbalance between monoaminergic and cholinergic transmission contributes to cataplexy induction (Baker and Dement, 1985; Nishino, 2007; Nishino and Mignot, 1997). This imbalance was inferred from studies that showed a reduction of monoaminergic tone and/or cholinergic stimulation exacerbated cataplexy in narcoleptic dogs (Faull et al., 1986; Mefford et al., 1983; Nishino et al., 1991, 1990; Reid et al., 1994). Although it is unclear how the loss of Hcrt signaling leads to a cholinergic/aminergic imbalance, the absence of HCRT-induced excitation of monoaminergic cells in narcolepsy may underlie the observed compensatory increase in the sensitivity of these systems to wake-promoting compounds (see Section 3.2.2. and Fig. 4). Pharmacological studies in mouse models of narcolepsy recapitulate the monoaminergic/cholinergic imbalance first described in narcoleptic dogs. Compared to wild type controls, HCRT-deficient mice exhibit reduced DA turnover (Mori et al., 2010) and increased responsiveness to modafinil (Willie et al., 2005). Cortical release of DA, NE and 5-HT can be more potently evoked in Hcrtr2 knockout mice vs. wild types (Ortega et al., 2012). In prepro-orexin ligand knockout mice, activation of dopamine D1 receptors with SKF38393 or amphetamine decreased sleep attacks while blockade of this receptor with SCH23390 had the opposite effect (Burgess et al., 2010). This study also showed that cataplexy could be suppressed by amphetamine or blockade of dopamine D2-like receptors with eticlopride and exacerbated by the D2/D3 agonist quinpirole (Burgess et al., 2010), but these effects were not replicated by others (Black et al., 2013; Fujiki et al., 2009). Cholinergic hypersensitivity has been demonstrated in mice that lack both HCRT receptors, as the enzymes necessary for acetylcholine synthesis, vesicular transport and metabolite reup-take were upregulated in laterodorsal tegmental neurons (Kalogiannis et al., 2010). Enhancement of cholinergic tone with physostigmine and muscarinic antagonism with atropine increased and decreased cataplexy, respectively, in mice that lack both HCRT receptors (Kalogiannis et al., 2011). In orexin/ataxin-3 mice, exogenous HCRT increased wakefulness more effectively than in wild type controls (Mieda et al., 2004) whereas the HCRTR1 and HCRTR2 antagonist almorexant induced sleep less effectively (Black et al., 2013). Collectively, these findings suggest that, in murine narcolepsy, compensatory changes in monoaminergic and cholinergic pathways downstream from HCRT receptors are primed to facilitate wake promotion and play a role in cataplexy induction. A challenge in the use of mouse models of narcolepsy to study cataplexy is the high inter-individual variability in the expression of this phenotype. Although not well documented, the genetic background of the mouse model and environmental factors, such as physical restrictions from EEG recording tethers and handling stress, have been thought to reduce the frequency of cataplexy episodes (Hara et al., 2005; Scammell et al., 2009). To help foster uniformity between laboratories that had been attempting to capture the same presumed cataplexy behavior using different methodologies (variously termed “narcoleptic episodes”, “abrupt arrests”, “behavioral arrests”, “direct transitions into REM”, or “cataplexy-like events”), consensus criteria were established to define murine cataplexy (Scammell et al., 2009). An episode of murine cataplexy requires (1) abrupt nuchal atonia for ≥10 s, (2) video-confirmed behavioral immobility, (3) theta-predominated EEG activity, and (4) ≥40 s of immediately prior wakefulness (Scammell et al., 2009). Individual prepro-orexin ligand knockout mice have been reported to exhibit a wide range in the frequency of presumed cataplexy during the first 4 h of the dark period, with episode counts ranging from 8 to 27 (Chemelli et al., 1999), 2 to 87 (Willie et al., 2003), and 1 to 31 (Morawska et al., 2011). Other studies have reported presumed cataplexy in the prepro-orexin ligand knockout mice during the first 4 h of the dark period to occur with a mean (±S.E.) frequency ranging from 25.1 ± 8.7 (Kisanuki et al., 2001), 18 ± 9 (Espana et al., 2007), 8.5 ± 2.5 (Liu et al., 2008), and 2 ± 1 (Burgess et al., 2010). In orexin/ataxin-3 transgenic mice, presumed cataplexy during the entire 12 h dark period has occurred with a mean (±S.E.) frequency ranging from 4.8 ± 3.2 (Fujiki et al., 2009), 16.4 ± 2.3 (Liu et al., 2011), 9.3 ± 2.2 (Black et al., 2013), 12.4 ± 3.9 (Kantor et al., 2013), 7 ± 2 (Tabuchi et al., 2014) and 6.5 ± 1 (Hasegawa et al., 2014). In a survey of 39 hemizygous orexin/ataxin-3 mice instrumented for telemetric EEG and EMG recording, 34% of the mice exhibited < 3 episodes of consensus-defined cataplexy during the dark period (Black, unpublished observation). This wide variability in basal cataplexy expression can challenge interpretation of studies that use between-groups study designs (Blanco-Centurion et al., 2013; Hasegawa et al., 2014; Kantor et al., 2013; Liu et al., 2011). Interventions that significantly increase cataplexy frequency have included stimuli intended to evoke strong emotions, such as novel environments (Mieda et al., 2004), controlled access to running wheels (Espana et al., 2007), highly palatable food (Clark et al., 2009) including chocolate (Oishi et al., 2013; Tabuchi et al., 2014), the combination of chocolate and running wheels (Burgess et al., 2013), and attractive or aversive odors (Morawska et al., 2011). While chocolate has been shown to be highly effective at increasing cataplexy from 1.6-fold (Tabuchi et al., 2014) to 8.1-fold (Oishi et al., 2013), it could potentially confound studies by introducing dietary changes or secondary effects of prolonged wakefulness. For example, the three-fold increase in cataplexy observed after chocolate with a running wheel increased wakefulness to 90% of the 12 h dark period (Burgess et al., 2013). A manipulation that stays within the bounds of the Hcrt signaling system could represent a more pure means of amplifying cataplexy. For example, cataplexy has been shown to be provoked in orexin/ataxin-3 mice in a dose × time related manner with the dual HCRT receptor antagonist almorexant (Black et al., 2013), which has led to its use in a murine narcolepsy/cataplexy assay for pharmacological studies. This assay combines a pretreatment of almorexant at the start of the dark period with a dose 30 min later of either a test compound or desipramine (5 mg/kg) as a positive control for cataplexy reduction (see Section 3.1) in the presence of a running wheel. The combination of almorexant (30 mg/kg) and desipramine (5 mg/kg) does not change the amount of time spent awake, but enables both an increase and a decrease in cataplexy to be observed in orexin/ataxin-3 mice (Fig. 5). A separate control condition in the dual dosing paradigm with a wake-promoting therapeutic such as modafinil (Fujiki et al., 2009) (see Section 3.2.2) can be added to the assay to enable full assessment of both anticataplectic and wake-promoting efficacy of test compounds. 3.4. Future therapies 3.4.1. Pharmacotherapeutics on the horizon Histaminergic neurons in the tuberomammillary nucleus of the posterior hypothalamus are one of the targets of Hcrt innervation (Peyron et al., 1998) that mediate HCRT-induced wakefulness (Huang et al., 2001; Mochizuki et al., 2011). In narcolepsy, CSF histamine levels are reduced compared to healthy controls, especially in patients with HCRT1 deficiency (Nishino et al., 2009). The activity of histaminergic neurons is preserved during cataplexy which is thought to underlie the maintenance of consciousness (John et al., 2004). For these reasons, it has been hypothesized that increasing histaminergic tone by antagonism of the histamine H3 autoreceptor could exert therapeutic effects on EDS in narcolepsy. The histamine H3 inverse agonist pitolisant has recently been tested for efficacy as a wakefulness promoter in 95 narcoleptic patients in a double-blind, randomized, parallel-group controlled clinical trial (Dauvilliers et al., 2013b). Pitolisant was found to increase wakefulness more than placebo and to a level indistinguishable from modafinil as measured by the Epworth Sleepiness Scale (Dauvilliers et al., 2013b). While pitolisant may be ultimately become a useful wake-promoting therapeutic in practice, it is not expected to show anticataplectic effects as histaminergic cells remain active during cataplexy (John et al., 2004). ADX-N05 is a phenylalanine derivative with dopaminergic and noradrenergic activity that has been assessed for treatment of daytime EDS in narcolepsy (Bogan et al., 2013). In a 10-center double-blind, placebo-controlled, randomized, cross-over study, ADX-N05 (150–300 mg/day) increased mean sleep latency by 11.8 min on the Maintenance of Wakefulness Test (MWT) compared to placebo, as well as on the Epworth Sleepiness Scale (ESS) and the Clinical Global Impressions-Change (CGI-C) after one week of treatment. A subsequent Phase 2 study confirmed the results on the primary (sleep onset latency on the MWT) and secondary (ESS and CGI-C) efficacy endpoints in patients with narcolepsy (Black et al., 2014a). To this point, there is no evidence that ADX-N05 (now known as JZP-110) is effective in cataplexy. GABAB agonism with R-baclofen, an enantiomer-specific form of racemic baclofen that has been used for decades in the treatment of muscle spasticity (Hudgson and Weightman, 1971), has recently been evaluated as a narcolepsy therapeutic in a preclinical study using two mouse models of Hcrt neuron ablation (Black et al., 2014b). The original goal of the research was to use the GABAB agonist baclofen in its most bioactive isoform as a tool compound to probe the therapeutic mechanism of action of sodium oxybate, which is known to be a partial agonist at GABAB receptors (Xie and Smart, 1992). It was hypothesized that if sodium oxybate acts on the GABAB receptor to normalize arousal states, then R-baclofen would mimic the effects of sodium oxybate on the symptoms of narcolepsy. At the doses tested (in a paradigm to model the chronic, twice-nightly administration of sodium oxybate in humans), R-baclofen was more effective than sodium oxybate at increasing the duration, intensity and consolidation of NREM sleep. As a consequence, the narcoleptic mice spent more time in consolidated bouts of wakefulness during the subsequent active phase. R-baclofen was also more effective than sodium oxybate at reducing cataplexy. Whether the high-affinity GABAB receptor agonist R-baclofen exerts greater anticataplectic efficacy via GABAB receptors on glutamatergic SLD neurons (Fig. 4) than the low affinity agonist sodium oxybate needs to be determined. The evaluation of R-baclofen and racemic baclofen in a mouse model of Fragile × Syndrome has led to clinical trials of arbaclofen (STX209) (Berry-Kravis et al., 2012; Pacey et al., 2011) and, more broadly, to preclinical efficacy tests of baclofen isoforms in mouse models of autism (Silverman et al., 2015). These paths of research encourage clinical trials of arbaclofen for narcolepsy. 3.4.2. Hypocretin replacement therapy Replacement of the HCRT that is lost from Hcrt neurodegeneration, like replacement of lost DA in Parkinson's disease, is an obvious therapeutic approach, but a number of obstacles must be overcome before being realized. However, since cataplexy and sleep fragmentation are exacerbated in narcoleptic orexin/ataxin-3 mice treated with the dual HCRTR antagonist almorexant, only small amounts of HCRT may be necessary for therapeutic benefit (Black et al., 2013). The proof of principle that HCRT replacement therapy could be effective stems from a study in which the narcoleptic mouse phenotype was independently rescued by pharmacological and genetic means. In the first approach, intracerebroventricular administration of HCRT1 into orexin/ataxin-3 mice (in which the vast majority of Hcrt neurons are ablated) rescued the narcoleptic phenotype (Mieda et al., 2004). Neither the HCRT2 peptide nor any HCRT fragments were tested for efficacy so whether other molecules related to HCRT1 can also rescue the phenotype is currently unknown. In the second approach, transgenic mice that express prepro-orexin under control of CAG promoter were bred with Hcrt neuron-ablated orexin/ataxin-3 mice to generate CAG/orexin; orexin/ataxin-3 mice. In these double transgenic mice, prepro-orexin is ectopically expressed throughout the brain but the Hcrt neurons are ablated. Narcolepsy symptoms such as sleep onset REM sleep, fragmentation of wakefulness in the dark period and cataplexy were completely inhibited in CAG/orexin; orexin/ataxin-3 mice, indicating that ectopic HCRT production could prevent narcolepsy. Given the efficacy of HCRT treatment for cataplexy suppression in the proof-of-principle study described above, a small molecule, brain penetrable HCRT receptor agonist would be ideal for symptomatic treatment of narcolepsy. Although the dual orexin receptor antagonist suvorexant has recently been approved by the FDA for the treatment of insomnia, development of agonists for G protein-coupled receptors is much more difficult than developing antagonists. Among other factors, the HCRT peptides are 33 and 28 amino acids in length and each peptide assumes a particular tertiary conformation in vivo. Screening for a small molecule that fits the binding pocket of HCRTR1 and/or HCRTR2 and contacts the necessary residues for receptor activation is a challenging task. However, the recently-described crystal structure of the human HCRTR2 (Yin et al., 2015) may accelerate development of orexin receptor agonists. Indeed, a non-peptide agonist that is selective for HCRTR2 with submicromolar potency has recently been introduced (Nagahara et al., 2015); however, the potential clinical utility of the compound remains to be determined. A major hindrance in the development of HCRT replacement therapy, whether the replacement molecule is the exogenous peptide, a prodrug precursor, or a small molecule agonist, is penetration of the blood–brain barrier. Delivery of HCRT1 through an alternative entry to the CNS along olfactory nerves has been attempted with intranasal administration in animals (Deadwyler et al., 2007; Dhuria et al., 2009) and narcoleptic patients (Baier et al., 2011; Weinhold et al., 2014) with limited success. A new technology that may aid delivery of HCRT peptides through the blood–brain barrier is receptor-mediated transcytosis using “Brain Shuttle” constructs (Niewoehner et al., 2014). The current Brain Shuttle technology consists of an anti-transferrin antibody that has been modified to monovalently bind the transferrin receptor (thereby resisting lysosomal degradation) which can also be fused to either another antibody (Niewoehner et al., 2014) or, hopefully in the future, to macromolecules such as HCRT1 as the therapeutic cargo. 3.4.3. Genetic and stem cell therapies Another potential approach is viral vector-based delivery of the prepro-HCRT gene. Expression of HCRT using recombinant adeno-associated virus (rAAV) in neurons of the zona incerta or lateral hypothalamus effectively prevented cataplexy in narcoleptic orexin/ataxin-3 mice (Liu et al., 2011); transfer into the striatum was ineffective. Orexin gene transfer into the dorsolateral pons of orexin KO mice also significantly decreased cataplexy and modestly improved wake maintenance compared to orexin KO mice that did not receive rAAV (Blanco-Centurion et al., 2013). Orexin gene transfer into the mediobasal hypothalamus only improved the timing and consolidation of sleep and wakefulness and did not change cataplexy in orexin/ataxin-3 mice (Kantor et al., 2013). Together, these results strongly suggest that viral-based HCRT replacement may be another avenue for treatment of narcolepsy. Novel approaches using pluripotent stem cells for treatment of narcolepsy are also under development. The use of induced pluripotent stem cells as in vitro models specific to individuals with narcolepsy has recently been proposed as a means to identify potential autoantigens as well as cell degenerative and survival responses (Liblau et al., 2015). Several groups have recently succeeded to generate hypothalamic neuropeptidergic neurons, including Hcrt neurons from human pluripotent stem cells (Merkle et al., 2015; Wang et al., 2015). Although much work is yet to be done, transplantation of HCRT-producing neurons generated from pluripotent stem cell from narcolepsy patients might become a useful treatment for narcolepsy in the future. 3.4.4. Immuno or neuroprotective therapies Assuming that narcolepsy is indeed due to an autoimmune attack on Hcrt neurons, the most fundamental treatment would be prevention of its development using immunotherapies or neuro-protective strategies. This approach is challenging due to the difficulty in finding suitable numbers of cases of narcolepsy close to disease onset for well-controlled studies. In a case of childhood narcolepsy, the immunosuppressant prednisone failed to improve EDS and to prevent the development of cataplexy when administered 3 months after abrupt onset (Mignot and Nishino, 2007). Attempts to remove hypothesized autoantibodies with intravenous immunoglobin (IVIg) have produced mixed results. Early attempts at IVIg therapy resulted in subjective improvement in EDS and cataplexy despite persistently low HCRT1 levels, but effects were not seen in cases in which narcolepsy onset was a year or more prior to IVIg (Dauvilliers et al., 2004). However, IVIg administered very close to disease onset (15 d) normalized HCRT1 levels and resulted in clinical improvement in cataplexy (Dauvilliers et al., 2009). More recent attempts using IVIg found that HCRT1 levels remained abnormal and any symptom improvements tended to be temporary (Knudsen et al., 2012, 2010; Valko et al., 2008). 4. Perspective 4.1. Voice of the patient In 2013, the US. FDA issued a patient-focused drug development initiative in which public meetings were held to gather information from the patients’ perspective in 20 specific disease areas. One of these meetings focused on narcolepsy in order to directly hear from patients, their caregivers and advocates about the impact of the disease on their lives and their experiences with currently available therapies. Several key themes emerged from the dialog with over 120 participants and highlighted the chronic, debilitating toll that narcolepsy takes on patients’ lives and the challenges they face in managing their condition (CDER, 2013). First, patients emphasized that EDS is the most problematic symptom that affects their lives, mostly because of the difficulty they face in fighting against it, or the consequences they face from chronic sleep deprivation such as cognitive impairments, the feeling of “brain fog”, and automatic behaviors. Second, the unpredictable loss of control that accompanies cataplexy, hallucinations and sleep paralysis can be terrifying. Other aspects of the disease, such as weight gain, insomnia, mood changes and depression were specifically noted as detrimental to patients’ lives. Third, patients reported that their symptoms can change over time. For example, a seasonal or monthly change occurs in their ability to sleep, or new symptoms emerge, such as cataplexy. Some symptoms, even when treated, worsen with time. Fourth, many patients reported that challenges often arise with medication use, including variable effectiveness, side effects, the development of tolerance, and access to currently-available treatments. These challenges necessitate a continued need to switch therapeutics, which is itself problematic. Last but not least, patients emphasized the significant impact that narcolepsy exerts on their social, emotional, and financial well-being and the frustration they experience as their disorder is misunderstood by colleagues, health care providers, and other people in their lives. This report from the patients’ perspective on narcolepsy underscores the critical need for innovative new therapies to improve patients’ lives. It also highlights some areas of unmet needs faced by patients, such as cognitive impairment, automatic behavior and anxiety, that have not yet been specifically addressed in drug development for narcolepsy. 4.2. Challenges in the development of narcolepsy therapeutics Before discussing the challenges in the development of narcolepsy therapeutics, it is appropriate to assess the advantages in targeting this disorder. First, despite the earlier confusion with epilepsy, narcolepsy type 1 is readily identified as a distinct diagnostic entity. Although other sleep disorders such as sleep apnea can result in EDS and even disrupted nighttime sleep, cataplexy is the pathognomonic symptom that is diagnostic of this disorder. Second, narcolepsy has clearly defined criteria used in both research and clinical (Eichler, 2014) settings. As described above (see Section 1.2.2), one of the first applications of the MSLT was to aid in the diagnosis of narcolepsy (Richardson et al., 1978) and the MSLT has proven to be useful as an objective measure of EDS for the subsequent ~40 years. Third, the loss of Hcrt neurons in the hypothalamus is now widely accepted as the cause of narcolepsy type 1. Although the reason for this cell loss that would complete our understanding of the etiology of this disorder remains obscure, the consequent interruption of Hcrt neurotrans-mission resulted in another asset for study of this disorder: a decline of CSF HCRT1 levels that has thereby enabled a diagnostic test. Fifth, recognition of Hcrt cell loss and interruption of Hcrt neurotransmission as an essential component of human narcolepsy type 1 has allowed creation of numerous animal models that recapitulate various symptoms of narcolepsy. These animal models will be extremely valuable for testing of potential therapeutics, as exemplified by a recent study (Black et al., 2014b). Particularly critical for future therapeutic development have been the proof of principle studies that have utilized some of these animal models to demonstrate mitigation of cataplexy and normalization of REM sleep levels after HCRT replacement by either pharmacological or genetic means (Blanco-Centurion et al., 2013; Liu et al., 2011; Mieda et al., 2004). Sixth, recognition of Hcrt cell loss as the source of interruption of Hcrt neurotransmission suggests that, in contrast to Hcrtr2-mutated narcoleptic Doberman pinschers and Labrador retrievers, HCRT receptors in human narcoleptics are intact and functional and thus represent viable pharmacological targets for HCRT replacement therapy whether by small molecule agonists or other innovative therapeutic means. Lastly, the search for new therapeutics will be greatly aided by the rich database of information that has resulted from extensive pharmacological testing in narcoleptic Doberman pinschers (Crocker et al., 2005; Nishino and Mignot, 1997), as these studies have suggested the downstream targets of Hcrt innervation that become unbalanced with Hcrt cell loss and should be normalized by effective therapeutics. Despite the advantages stated above, a number of obstacles remain problematic for future development of narcolepsy therapeutics. Perhaps the paramount obstacle is the relatively low prevalence of this disorder which may limit the number of companies that are willing to invest in new therapeutic development for a disorder with a small market. With a prevalence of 0.05%, there are approximately 150,000 individuals with narcolepsy in the US. This is obviously a small fraction of the population of patients that are suffering from depression, autism or Alzheimer's disease, for example. On the other hand, the US. Orphan Drug Act of 1983 was specifically designed to facilitate the development and commercialization of drugs to treat rare diseases such as narcolepsy. The FDA's Office of Orphan Products Development administers the Orphan Drug Designation program that provides orphan status to drugs and biologics for the treatment diseases and disorders that affect fewer than 200,000 people in the US. Government intervention on behalf of orphan drug development can be in the form of tax incentives, enhanced patent protection and marketing rights, subsidization of clinical research and even the creation of a government-run enterprise to engage in research and development. Since 1984, seven applications for orphan drug status for the treatment of narcolepsy have been successful (Table 2). As the era of the multi-billion dollar blockbuster drug recedes and precision medicine segments diseases and disorders into smaller markets, rare disorders and diseases, particularly life-long diseases with early age of onset such as narcolepsy, may become more attractive to large pharmaceutical companies specifically because of the possibility of orphan drug designation and the resultant market exclusivity. Another major challenge in the development of narcolepsy therapeutics is the incomplete understanding of the etiology of this disorder. Although loss of Hcrt cells is widely accepted the final endpoint of narcolepsy type 1, it is unclear why Hcrt neurons are lost in the first place. While some evidence suggests that narcolepsy type 2 may result from less severe loss of Hcrt neurons than in narcolepsy type 1 (Thannickal et al., 2009), whether these two types of narcolepsy differ in patterns of neurodegeneration, mechanisms of cell loss, compensatory preservation of remaining cells or Hcrt function (e.g., axonal sprouting, increased HCRT release, decreased degredation, etc.) is unknown. Clearly, a genetic predisposition involving the HLA system has been established as an important component across multiple ethnic populations and in family studies, but only about 25% of monozygotic twins are concordant for narcolepsy (Mignot, 1997), implicating unspecified environmental factors that may vary among patients. Although an autoimmune mechanism was suggested by the original association with HLA-DR2 over 30 years ago (Juji et al., 1984), as indicated in Section 2.5, the search for autoantibodies in sporadic narcolepsy has been fruitless to date, which stands in stark contrast to well-established autoimmune neurological disorders such as myasthenia gravis (Graus et al., 2010). Nonetheless, it is appropriate here to keep in mind the old adage that “absence of evidence is not evidence of absence.” The existence of streptococcal infections in a large proportion of recent narcolepsy onset cases may be an important clue both in the search for an environmental trigger and in the mechanism of the autoimmune response (Aran et al., 2009). Surmounting the blood–brain barrier is a formidable challenge to any drug development effort directed toward a CNS target. In the case of narcolepsy, as indicated above, the most straightforward therapeutic strategy for symptomatic treatment would be HCRT replacement therapy. However, because the HCRTs are neuropep-tides, peripheral administration renders them vulnerable to enzymatic hydrolysis, although the disulfide bridges and two alpha-helices in HCRT1 (Kim et al., 2004) confers greater stability than that of HCRT2 (Lee et al., 1999). For small molecules, the size and charge limitations encapsulated in Lipinski's rule of 5 applies (Lipinski et al., 2001). Hypocretin replacement therapy enabled by gene transfer may be one means of bypassing the blood–brain barrier, however, controlling the diurnal timing of ectopic HCRT expression and its restriction to wakefulness is an important problem that has not yet been solved (Willie et al., 2011). Until a solution is found, the nighttime use of HCRTR1 and HCRTR2 antagonists, such as suvorexant (Michelson et al., 2014), could conceivably be employed, but the benefit of increased sleep propensity must be weighed against the possibility of cataplexy exacerbation in patients with narcolepsy (Black et al., 2013). Construction of a “Brain Shuttle” for receptor-mediated transcytosis across the blood–brain barrier (see Section 3.4.2) is a promising approach, but the technology is still in its infancy for peptide delivery. Determination of the minimal peptide length of the HCRTs that can both bind to the shuttle antibody and engage HCRTR2 to effect a cellular response is a difficult challenge. With respect to small molecule development, HCRT replacement therapy implies synthesis of an agonist at the HCRT receptors. In contrast to antagonists, identification of receptor agonists is much more difficult, likely due to the constraints on identifying molecules that can both fit the binding pocket of a particular receptor and contact the appropriate amino acid residues for receptor activation. The recently-described crystal structure of the human HCRTR2 (Yin et al., 2015) may facilitate development of receptor agonists by enabling virtual screening of compounds. Another approach would be the development of a positive allosteric modulator at the HCRT receptors, but the efficacy of this approach will be limited by the availability of enough endogenous ligand to activate the receptor. On the other hand, postmortem human studies suggest that 5–15% of Hcrt neurons may remain even in patients who have experienced narcolepsy symptoms for over 50 years (Thannickal et al., 2000). Furthermore, only a small degree of HCRT receptor activation may be necessary for therapeutic benefit since cataplexy and sleep fragmentation are exacerbated in narcoleptic orexin/ataxin-3 mice treated with almorexant (Black et al., 2013). In conclusion, narcolepsy represents a model neurodegenerative disease for the development of therapeutics. The loss of a small, discrete and homogeneous population of neurons translates to a relatively simple system in which to develop gene- and pharmacology-based therapies. Although the symptomatic consequences of Hcrt cell loss are wide and varied, rodent animal models recapitulate the cardinal features of arousal state boundary dysregulation and cataplexy with clearly defined end points. Restoration of Hcrt neurotransmission, whether by small molecule agonists or by exogenous peptides, may be the most parsimonious means of treating the many disparate features of narcolepsy. Whether the compensatory neurochemical and molecular changes that accompany Hcrt cell loss can be fully surmounted, or even reversed, remains to be determined. Until the cause of Hcrt neurodegeneration can be understood and prevented, development of therapeutics to provide symptomatic relief by improving Hcrt neurotransmission remains a worthy goal. Acknowledgments This work was supported by NIH R01 HL059658, R01 NS077408, R21 NS087550, R01 NS082876, R21 NS083639 and R21 NS085757. We thank Drs. Michael Schwartz, Theresa Steininger and Jed Black for helpful comments on the manuscript. The content is solely the responsibility of the authors and does not necessarily represent the official views of the National Institutes of Health. Abbreviations 5-HT 5-hydroxytrytamine (serotonin) α1 noradrenergic alpha 1 receptor α2 noradrenergic alpha 2 receptor ACh acetylcholine Atax orexin/ataxin-3 transgenic BAC bacterial artificial chromosome BAT brown adipose tissue BF basal forebrain BLA basolateral amygdala BMI body mass index CeA central nucleus of the amygdala CGI-C Clinical Global Impressions-Change CSF cerebrospinal fluid Ctx cerebral cortex D1 dopamine 1 receptor D2 dopamine 2 receptor D3 dopamine 3 receptor DA dopamine DAT dopamine transporter DOX doxycycline DR dorsal raphe nucleus DTA orexin/tTA TetO DTA transgenic EDS excessive daytime sleepiness EEG electroencephalograph EMG electromyograph ESS Epworth Sleepiness Scale FDA Food and Drug Administration FECT Food-elicited Cataplexy Test GABA gamma-aminobutyric acid GABAA gamma-aminobutyric acid A receptor GABAB gamma-aminobutyric acid B receptor Glu glutamate Gly glycine H3 histamine receptor 3 HA histamine Hcrt hypocretin (orexin) HCRT1 hypocretin 1 peptide (orexin-A peptide) HCRT2 hypocretin 2 peptide (orexin-B peptide) HCRTR1 hypocretin receptor 1 (orexin-1 receptor, OX1R) HCRTR2 hypocretin receptor 2 (orexin-2 receptor, OX2R) GHB gammahydroxybutyrate (sodium oxybate) HLA human leukocyte antigen IVIg intravenous immunoglobin LC locus coeruleus LDT laterodorsal tegmental nucleus MCH melanin-concentrating hormone MM medial medulla mPFC medial prefrontal cortex MSLT Multiple Sleep Latency Test MWT Maintenance of Wakefulness Test NE norepinephrine NREM non-rapid eye movement sleep PANDAS pediatric autoimmune neuropsychiatric disorders associated with streptococcal infections PFH perifornical nucleus PPT pedunculopontine tegmental nucleus rAAV recombinant adeno-associated virus REM Rapid eye movement sleep SLD sublaterodorsal nucleus SNRI serotonergic and noradrenergic reuptake inhibitor SOREMP sleep-onset REM period SSRI selective serotonergic reuptake inhibitor T b core body temperature TetO tetracycline operator TM tuberomammillary nucleus TRIB2 tribbles homologue 2 tTA tetracycline transactivator VEH Vehicle vlPAG ventrolateral periaqueductal gray WT Wild type ZT Zeitgeber time Fig. 1 Hypnograms depicting arousal state (C, cataplexy; R, REM sleep; W, wakefulness; S, NREM sleep) changes over time in a representative orexin/tTA; TetO diphtheria toxin (DTA) mouse before hypocretin neuron ablation, while maintained on doxycycline chow (DOX(+)), and 1, 2, 4 and 13 weeks (wk) after return to standard mouse chow (DOX(−)) in comparison to an orexin-ataxin3 mouse. Hypnograms are plotted for 24 h beginning at lights off at 20:00, with the 12 h dark period in black and 12 h light period in orange. Sleep/wake fragmentation occurred within 1 wk after DOX(−) and progressively worsened throughout the recording period. Cataplexy appeared after 2 wks DOX(−), at which point arousal states resembled those of the orexin-ataxin3 mouse. Cataplexy was highly enriched at 13 wks DOX(−) when compared to earlier ages and to the orexin-ataxin3 mouse. Fig. 2 Electrophysiological and behavioral indices of cataplexy in a representative DTA mouse at 9 weeks DOX(−). (A) 80 s recording (demarcated in 10 s epochs by vertical lines) shows ~40 s cataplexy episode (bracket) and prior wakefulness with wheel-running activity revealed by EEG (blue), EMG (black), EEG periodogram (blue area under curve, 0–25 Hz), and gross motor activity (red, as inferred by telemetry unit signal strength). (B) Frames from video in the seconds before cataplexy onset, at onset and during the bout of cataplexy, and 2 s after cataplexy termination. Bars = 200 μV (EEG and EMG), 200 μV2 (EEG periodogram), and 5 arbitrary units (signal strength measure of gross motor activity). Fig. 3 Schematic illustrating the brain regions currently known to be involved in the control of wakefulness and muscle tone. Neuronal populations that are active during wakefulness (green) consist of hypocretin neurons (Hcrt) that project most densely and provide excitatory input (solid arrowheads) to the locus coeruleus (LC) and other wake-promoting areas: the basal forebrain (BF), tuberomamillary nucleus (TM), dorsal raphe (DR), laterodorsal and pedunculopontine tegmental nuclei (LDT/PPT), ventrolateral periaqueductal gray (vlPAG), and directly to cortex and spinal motor neurons. Hcrt neurons also increase motor tone through suppression of REM sleep atonia circuitry, which consists of sublaterodorsal nucleus (SLD) excitation of medial medulla (MM) and spinal interneurons that inhibit motor neurons. Active inhibition of atonia circuitry is mediated by HCRT excitation of monoaminergic and GABAergic pathways that inhibit (blunt terminals) the SLD. Disinhibition of REM sleep atonia circuitry during wakefulness may underlie cataplexy in narcolepsy (see Fig. 4). Key: solid lines/arrows, active excitation; solid lines/blunt terminals, active inhibition; dashed lines/arrows, disfacilitation; dashed lines/blunt terminals, disinhibition; thick black lines, Hcrt projections; red, neurons and pathways that are active in REM sleep; REMoff, neurons that are silent in REM sleep; Ctx, Cerebral cortex; mPFC, medial prefrontal cortex; BLA, basolateral amygdala; CeA, central nucleus of the amygdala; MCH, melanin-concentrating hormone cells; ACh, acetylcholine; HA, histamine; Glu, glutamate; GABA, gamma-aminobutyric acid; Gly, glycine; 5-HT, serotonin; NE, norepinephrine; α2, noradrenergic autoreceptor; α1, noradrenergic α1 receptor. Fig. 4 Schematic illustrating arousal-state circuitry in narcolepsy and cataplexy. Hypocretin (Hcrt) neurons and their projections to wake-promoting regions (see Fig. 3) are absent in narcolepsy. Presumably as a compensatory consequence, pontine cholinergic supersensitivity (thick lined box), monoaminergic hypoactivity in the amygdala (thin lined boxes) and increased numbers of HA neurons develop. Neuronal populations that are active during cataplexy (yellow) include regions that are also active during wakefulness and REM sleep. Cataplexy can be triggered by positive emotional stimuli that activate neurons in the mPFC and amygdala, which then may disinhibit REM sleep atonia circuitry. In individuals without narcolepsy, HCRT excitation onto LC neurons could balance the GABAergic inhibition from CeA to maintain normal muscle tone. Activation of the atonia circuitry is mediated by withdrawal of GABAergic inhibition of SLD neurons from the vlPAG and monoaminergic inhibition from the DR and LC. Direct activation of SLD neurons could result from upregulated cholinergic mechanisms in the LDT/PPT. Cataplexy can be alleviated by antidepressants that increase noradrenergic tone via blockade of α2 autoreceptors; mechanisms of GABAB therapeutics for cataplexy are unknown, but may involve inhibition of SLD neurons to suppress atonia. Key: see Fig. 3. Fig. 5 The narcolepsy/cataplexy assay for orexin/ataxin-3 transgenic mice. (A) Cataplexy density (the number of cataplexy bouts per time awake) and (B) percent time awake during the 6 h following pretreatment with almorexant (ALM, black) vs. vehicle (VEH, white) at ZT12 and treatment with desipramine (DES 0–5 mg/kg) 30 min later. Two-way repeated measures ANOVA: * p < 0.05 vs. VEH pretreatment, *p < 0.05 vs. DES (0 mg/kg); n = 4. Table 1 Rodent models of narcolepsy, hypocretin dysfunction or transgenic tools. Strain & alternative names Structural mutation Phenotype Reference Mouse Prepro-orexin knockout; orexin−/− Constitutively absent Hcrt precursor gene Sleep/wake fragmentation, reduced REM onset, increased REM time, decreased wake during dark period, frequent cataplexy; obesity Chemelli et al. (1999); Mochizuki et al. (2004) HcrtR1 knockout; OX1R−/− Constitutively absent HcrtR1 Mild sleep/wake fragmentation, no cataplexy Kisanuki et al. (2001) HcrtR2 knockout; OX2R−/− Constitutively absent HcrtR2 Mild sleep/wake fragmentation, sleep attacks, mild cataplexy Willie et al. (2003) HcrtR1 & HcrtR2 double knockout; OX1R−/−/OX2R−/− Constitutively absent HcrtR1 and HcrtR2 Sleep/wake fragmentation, reduced REM onset, increase REM time, decreased wake during dark period, cataplexy Kisanuki et al. (2001); Kalogiannis et al. (2011) Orexin/ataxin-3 transgenic, Ataxin Postnatal Hcrt neuron ablation Sleep/wake fragmentation, reduced REM onset, increased REM time, decreased wake during dark period, variable cataplexy; obesity Hara et al. (2001) Orexin/eGFP transgenic eGFP reporter driven by Hcrt promoter None; permits visualization of Hcrt cells Yamanaka et al. (2003); Muraki et al. (2004) Prepro-Hcrt overexpressor Constitutive overexpression of prepro-orexin, decreased HcrtR2 in hypothalamus Small decrease in REM during recovery from sleep deprivation Makela et al. (2010) O/E3 null mutant Constitutively absent helix-loop-helix transcription factor, decreased Hcrt cell number Sleep/wake fragmentation, reduced REM onset, increased REM time, decreased wake during dark period, cataplexy De la Herran-Arita et al. (2011) Orexin/Halo transgenic Halorhodopsin expressed in Hcrt cells None; permits inhibition of Hcrt cells Tsunematsu et al. (2011) Orexin/tTA;TetO Chr2 (C128S) double transgenic Conditional step-function opsin expression in Hcrt cells None; permits widespread expression of ChR2 in Hcrt cells under Dox(-) control & excitation of Hcrt cells Tanaka et al. (2012) Orexin/tTA;TetO ArchT double transgenic Conditional archaerodopsin expression in Hcrt cells Unknown; permits wide-spread expression under Dox(-) control & inhibition of Hcrt cells Tsunematsu et al. (2013) OX/tTA transgenic Tetracycline transactivator driven by Hcrt promoter None; useful with Tet-on or Tet-off expression systems, or opsins through breeding or viral delivery Tsunematsu et al. (2013) Orexin/tTA;TetO DTA double transgenic, DTA Conditional Hcrt neuron ablation Extreme sleep/wake fragmentation, reduced REM onset, increased REM time, decreased wake during dark period, extreme cataplexy; obesity Tabuchi et al. (2014) OXlR/ eGFP transgenic eGFP reporter driven by first coding exon of Hcrtr1 gene None; permits visualization of cells that express Hcrtr1 Darwinkel et al. (2014); Ch'ng and Lawrence (2015) Rat Hcrt2-saporin conjugate Ablation of Hcrt, MCH and ADA cells Sleep/wake fragmentation, reduced REM onset, increased REM time, decreased wake during dark period, cataplexy, attenuated sleep/wake circadian rhythm Gerashchenko et al. (2001) Orexin/ataxin-3 transgenic Postnatal Hcrt neuron ablation Sleep/wake fragmentation, reduced REM onset, increased REM time, decreased wake during dark period, cataplexy Beuckmann et al. (2004) Table 2 Drugs reviewed for orphan designation for narcolepsy by the US Food and Drug Administration. Generic name Trade name Sponsor Designation date Orphan designation FDA marketing approval date Exclusivity end date Viloxazine HCL Stuart Pharmaceuticals 6/11/1984 Treatment of cataplexy and narcolepsy Not FDA Approved for Orphan Indication NA Gamma-hydroxybutyric acid Sigma Chemical Company 1/22/1985 Treatment of narcolepsy and the auxiliary symptoms of cataplexy, sleep paralysis, hypnagogic hallucinations, and automatic behavior Not FDA Approved for Orphan Indication NA Gamma hydroxybutyrate Biocraft Laboratories, Inc. 12/3/1987 Treatment of narcolepsy and the auxiliary symptoms of cataplexy, sleep paralysis, hypnagogic hallucinations, and automatic behavior Not FDA Approved for Orphan Indication NA Modafinil Provigil1 Cephalon, Inc. 3/15/1993 Treatment of excessive daytime sleepiness in narcolepsy 12/24/1998 12/24/2005 Oxybate Xyrem1 Jazz Pharmaceuticals 11/7/1994 Treatment of narcolepsy 11/18/2005 11/18/2012 BF2.649 (Pitolisant) Bioprojet Pharma 5/17/2010 Treatment of narcolepsy Not FDA Approved for Orphan Indication NA Optically pure phenylalanine derivative Jazz Pharmaceuticals International III Limited 8/20/2012 Treatment of narcolepsy Not FDA Approved for Orphan Indication NA Disclosure statement Within the last 12 months, Dr. Kilduff and Dr. Black have received research support from Hoffmann La-Roche and Dr. Kilduff has received honoraria from Merck Pharmaceuticals and Pfizer. 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PMC005xxxxxx/PMC5114177.txt
LICENSE: This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. 9607835 20545 Mol Psychiatry Mol. Psychiatry Molecular psychiatry 1359-4184 1476-5578 27184122 5114177 10.1038/mp.2016.75 NIHMS770897 Article Haploinsufficiency of the 22q11.2-microdeletion gene Mrpl40 disrupts short-term synaptic plasticity and working memory through dysregulation of mitochondrial calcium Devaraju Prakash 1 Yu Jing 1 Eddins Donnie 1 Mellado-Lagarde Marcia M. 1 Earls Laurie R. 13 Westmoreland Joby J. 13 Quarato Giovanni 2 Green Douglas R. 2 Zakharenko Stanislav S. 1* 1 Department of Developmental Neurobiology, St. Jude Children’s Research Hospital, Memphis, TN 38105, USA 2 Department of Immunology, St. Jude Children’s Research Hospital, Memphis, TN 38105, USA * Contact information: Stanislav S. Zakharenko M.D., Ph.D., Department of Developmental Neurobiology, Mail Stop 323, St. Jude Children’s Research Hospital, Memphis, TN 38105, USA, stanislav.zakharenko@stjude.org 3 Present address: Department of Cell and Molecular Biology, Tulane University, New Orleans, LA, 70118, USA 22 3 2016 17 5 2016 9 2017 18 11 2016 22 9 13131326 This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. Hemizygous deletion of a 1.5- to 3-megabase region on chromosome 22 causes 22q11.2 deletion syndrome (22q11DS), which constitutes one of the strongest genetic risks for schizophrenia. Mouse models of 22q11DS have abnormal short-term synaptic plasticity (STP) that contributes to working memory deficiencies similar to those in schizophrenia. We screened mutant mice carrying hemizygous deletions of 22q11DS genes and identified haploinsufficiency of Mrpl40 (mitochondrial large ribosomal subunit protein 40) as a contributor to abnormal STP. Two-photon imaging of the genetically encoded fluorescent calcium indicator GCaMP6, expressed in presynaptic cytosol or mitochondria, showed that Mrpl40 haploinsufficiency deregulates STP via impaired calcium extrusion from the mitochondrial matrix through the mitochondrial permeability transition pore. This led to abnormally high cytosolic calcium transients in presynaptic terminals and deficient working memory but did not affect long-term spatial memory. Thus, we propose that mitochondrial calcium deregulation is a novel pathogenic mechanism of cognitive deficiencies in schizophrenia. Introduction Schizophrenia (SCZ) is a catastrophic disease that affects approximately 1% of the world’s population and is characterized by multiple symptoms that include cognitive abnormalities such as deficits in working memory, executive function, and learning1. Mechanisms of cognitive symptoms of SCZ are poorly understood, partly because only weak associations have been identified between any single gene and the disease, and valid animal models have been lacking2. Mouse models of 22q11 deletion syndrome (22q11DS) are among the few animal models that replicate abnormalities associated with SCZ. The 22q11DS is the most common multi-gene syndrome in humans and is considered a genetic risk factor for SCZ. The 22q11DS is caused by the hemizygous deletion of a 1.5- to 3-megabase region on the q arm of chromosome 22, resulting in the haploinsufficiency of multiple genes3. Approximately 30% of children with 22q11DS experience SCZ during late adolescence or early adulthood4, 5. Symptoms of 22q11DS-related SCZ are indistinguishable from those of the idiopathic disease5, suggesting that the biological mechanisms involved in SCZ arising from the 22q11 deletion are similar to those involved in non–deletion-related SCZ. The diagnosis of SCZ usually includes positive symptoms (i.e., disorderly thinking, hallucinations, and delusional ideas), negative symptoms (i.e., low levels of emotional arousal or social activity), and cognitive symptoms (i.e., deficits in attention, working memory, executive function, and learning and memory). Recognition of cognitive deficits as a core feature of SCZ and 22q11DS is increasing, as these deficits better predict disease progression than do the other symptoms6, 7. Many cognitive symptoms of SCZ are thought to originate in the hippocampus8, 9, a key brain region involved in learning and memory. Spatial working-memory deficits occur in patients with 22q11DS10, 11 and are also seen in 22q11DS mouse models. Mouse models of 22q11DS exhibit abnormal hippocampal short- and long-term synaptic plasticity12, 13, which is consistent with the notion that synaptic plasticity is a cellular mechanism of learning and memory16. Short-term synaptic plasticity (STP) acting on the millisecond-to-minute time scale is believed to underlie reliable information transfer between hippocampal excitatory synapses in an activity-dependent manner14–17, working memory18, and decision making19. STP predominantly occurs in presynaptic neurons20. Several studies have shown that presynaptic abnormalities can be attributed to dysregulation of presynaptic calcium (Ca2+). For example, altered STP resulting from deregulated presynaptic Ca2+ are seen in models of neuropsychiatric diseases such as FMRP-related autism, Alzheimer disease, and 22q11DS12, 21, 22. Because 22q11DS is a multi-gene deletion syndrome, more than one gene may affect STP. Initially, STP dysregulation in Df(16)1+/− models of 22q11DS was linked to haploinsufficiency of microRNA-processing gene Dgcr823, which is mapped to a proximal part of the microdeletion. Depletion of microRNAs miR-185 and miR-25 leads to presynaptic Ca2+ dysregulation and abnormal STP through the abnormal elevation of (sacro)endoplasmic reticulum ATPase type 2 (Serca2), the Ca2+ pump that extrudes Ca2+ from the cytoplasm into the endoplasmic reticulum23. SERCA2 is also elevated in the hippocampus of schizophrenic patients23, and the most comprehensive genome-wide association study to date linked the ATP2A2 gene, which encodes SERCA2, with SCZ24. Other genes that affect STP remain unknown. Here we report results of our STP screening of the distal region of the 22q11DS microdeletion, which encompasses six genes: Cldn5, Cdc45l, Ufd1l, 2510002D24Rik, Mrpl40, and Hira. Using mutant mice carrying hemizygous deletions of individual genes, we discovered that haploinsufficiency of Mrpl40 (mitochondrial large ribosomal subunit protein 40, also known as Nlvcf) causes abnormal STP and short-term memory deficits via Serca2-independent deregulation of presynaptic Ca2+. Using two-photon Ca2+ imaging of the genetically encoded Ca2+ indicator GCaMP625, expressed either in the presynaptic cytosol or mitochondria, we showed that Mrpl40 haploinsufficiency hindered the extrusion of Ca2+ from the mitochondrial matrix through impaired mitochondrial permeability-transition pore (mPTP). This leads to abnormally high levels of Ca2+ in the presynaptic cytosol and elevated STP. Our data implicate Mrpl40 as a 22q11DS gene, the haploinsufficiency of which contributes to cognitive deficits in microdeletion-related SCZ. Materials and Methods Animals Mature (16–20 weeks) mice of both sexes were used. Production and genotyping of Df(16)5+/−, Dgcr8+/−, Cldn5+/−, and Hira+/− mice were previously described23, 26–28. To generate Cdc45/+/− and Ufd1l+/− mice, we obtained SIGTR embryonic stem (ES) cell clones containing gene-trap disruptions of the pGT01Lxr vector for Cdc45l (cell line AJ0425) and a Ufd1l allele (cell line AW0532) from the Mutant Mouse Regional Resource Center (University of California, Davis). The AJ0425 ES cell line carries a Genetrap insertion in exon 3 of the Cdc45l gene. Offspring were genotyped using the following primers: Cdc45lF: GCTGGGTACCTGAGTGTCATTG, Cdc45lR: CGAGACTGGTATGTGTGTGTGTG, and the betageo primer 2: ATTCAGGCTGCGCAACTGTTGGG, producing a 353-bp wild-type (WT) amplicon and a 309-bp mutant amplicon. The AW0532 ES cell line disrupts the Ufd1l gene in the first intron. This line was genotyped with the following primers: Ufd1lF: GTTGACGCTAACGTCCAGTCAC, Ufd1lR: GAAGCAGCGGTACTGCGTGGAG, and the Betageo primer: ATTCAGGCTGCGCAACTGTTGG, producing a 612-bp WT amplicon and a 304-bp mutant amplicon. To generate the Mrpl40+/− mice, we obtained sperm from the C57BL/6 strain carrying the Mrpl40tm1(KOMP)vlcg allele of the Mrpl40 gene from the trans-NIH Knock-Out Mouse Project (www.komp.org). Sperm was used to produce Mrpl40+/− offspring via in vitro fertilization. Mrpl40+/− mice were genotyped using the following primers: Mrpl40F: CAGGCACACGTCAGACACA, Mrpl40R: GAGATCCCAGAAGGCCAGTAAG, and LacZR: CCCACCAGAGAGCTTC, producing a 102-bp WT amplicon and a 387-bp mutant amplicon. To expand the colony, we bred 2510002D24Rik+/−, Mrpl40+/−, Ufd1l+/−, and Cdc45l+/− mice harboring the disrupted alleles to C57BL/6J mice in the St. Jude Animal Resource Center. All mouse strains in this study were back-crossed onto the C57BL/6J genetic background for at least 5 generations. Individual experiments were conducted in age-matched and sex-matched animals. The care and use of animals were reviewed and approved by the Institutional Animal Care and Use Committee at St. Jude Children’s Research Hospital. Brain slice preparation Mouse brains were quickly removed and placed in cold (4°C) dissecting artificial cerebrospinal fluid (ACSF) containing 125 mM choline-Cl, 2.5 mM KCl, 0.4 mM CaCl2, 6 mM MgCl2, 1.25 mM NaH2PO4, 26 mM NaHCO3, and 20 mM glucose (295–300 mOsm), under 95% O2/5% CO2, and acute transverse hippocampal slices (400-µm thick) were prepared. After dissection, slices were incubated for 1 h in ACSF containing 124 mM NaCl, 2.5 mM KCl, 2 mM CaCl2, 2 mM MgCl2, 1.25 mM NaH2PO4, 26 mM NaHCO3, and 10 mM glucose (285–295 mOsm), under 95% O2/5% CO2 at 32°C to 34°C and then transferred into the submerged recording chamber and superfused (1.5–2 mL/min) with ACSF. Long-term potentiation (LTP) experiments were performed as previously described12. Because the bath temperature is crucial for short-term potentiation (STP) experiments29, all electrophysiology and imaging experiments were conducted in a perfusion chamber maintained at near physiological temperature (33°C-34°C, measured at the center of the bath) by using both inline and bath heaters. Whole-cell electrophysiology Electrophysiological data were acquired using a Multiclamp 700B amplifier, filtered at 2 kHz and digitized at 10/20 kHz using a Digidata 1440 digitizer controlled by Clampex acquisition software. All offline analyses of electrophysiological data were done in Clampfit. To evoke excitatory postsynaptic currents (EPSCs) in CA1 neurons, we stimulated Schaffer collaterals with a concentric bipolar stimulating electrode (125-µm outer diameter; 12.5-µm inner diameter) connected to an Iso-Flex stimulus isolator with 100-µs pulses. Stimulating and recording electrodes were separated by at least 350 to 400 µm. For STP experiments, a cut was placed between the CA3 and CA1 regions to avoid recurrent stimulation. Recording electrodes were borosilicate glass capillaries pulled in a Sutter P-1000 puller and had resistances approximately 3.5 to 5 mΩ. CA1 neurons were whole cell voltage-clamped using electrodes filled with 130 mM K gluconate, 10 mM KCl, 0.5 mM EGTA, 2 mM MgCl2, 5 mM NaCl, 2 mM ATP-Na2, 0.4 mM GTP-Na, 10 mM HEPES, and 10 to 25 µM Alexa 594 (pH 7.35, ~ 290 mOsm). EPSCs were recorded by holding the cells at –74 mV (accounting for a liquid junction potential of ~14 mV). Access resistance was monitored using a –5 mV step before each recording (range, 25–50 mΩ), and cells that displayed unstable access resistance (variations >20%) were excluded from the analyses. All EPSC recordings for STP experiments were done in the presence of the GABAAR antagonist picrotoxin (100 µM) to prevent inhibitory responses and the NMDA receptor antagonist D-2-amino-5-phosphonovalerate (D-AP5, 50 µM) to avoid induction of long-term synaptic plasticity. STP components were separated using an adapted procedure29. A baseline of stable EPSCs was established to evoke 150- to 200-pA EPSCs. Stimulation intensities ranged from 30 to 60 µA and were held constant for each cell throughout the experiment. Stimulation intensity did not differ significantly between slices from WT and mutant littermates (P > 0.05). The stimulation protocol consisted of the following: 5 pre-train pulses (0.2 Hz), a high-frequency train (100 pulses, 80-Hz), 24 pulses at 5 Hz (to measure recovery from depression), and 24 pulses at 0.2 Hz (to measure augmentation). The 80-Hz (100 pulses) train was chosen because it induced both strong depression and augmentation on the basis of STP induced by trains of different frequencies (data not shown). EPSCs during and after the train were normalized to the average of the 5 pre-train EPSCs (shown as a single baseline point), and the amplitudes are reported as normalized EPSC peak amplitudes. For each cell, we averaged the data from 3 to 4 trials by using this stimulation protocol. To measure the EPSC amplitudes during the train, we resorted to a binning procedure, instead of the template waveform-based subtraction protocol, as previously described29. The measured EPSC train of 1,250 ms (80 Hz × 100 pulses) was divided into 100 equal bins of 12.5 ms, and the peak amplitude within each bin was graphed as the normalized EPSC amplitude during the train. This procedure was sufficient to separate EPSCs in the train. Augmentation, the slowest component of STP, has negligible contamination from depression and facilitation and is reported as measured without corrections. Statistical comparisons of augmentation were made using the measured peak augmentation at 5 s after the 80-Hz train, instead of the extrapolated augmentation at 0 s. Recovery from depression (200 to 4,800 ms) after the 80-Hz train was contaminated by augmentation and some residual facilitation. Because the EPSCs measured during the recovery phase had an interstimulus interval of 200 ms, the contamination by facilitation was minimal and corrected only for overlying augmentation. To that end, the measured augmentation decay curve (5–120 s after the 80-Hz train) was extrapolated from 200 to 4,800 ms after the train by using a standard exponential fit in Clampfit. The normalized EPSCs during the recovery phase were then corrected for the overlying extrapolated augmentation for each time point. Facilitation was measured in separate experiments by using paired pulses at interstimulus intervals of 20 to 1,000 ms. To measure excitability, we held CA3 neurons in current clamp mode and added D-AP5 (50 µM) and picrotoxin (100 µM) to the external ACSF bath to avoid possible long-term effects. Action potential (AP) parameters were estimated by clamping the cell at –65 mV using automatic slow-current injection. Input resistance, AP threshold, rheobase (intensity of current reached at threshold), number of APs (evoked by holding at the minimum current needed to reach threshold) were measured by injecting 1-s steps of 25-pA current (12 steps from –25 pA to 250 pA). To measure AP widths, we evoked APs by injecting 5 short current steps (1,500–2,000 pA, 1-ms duration, 0.2 Hz). AP durations were calculated as the time interval between the up-stroke and down-stroke of the AP waveform at –10 mV. AP duration during the 80-Hz train was normalized to the AP duration at baseline, as previously described21. Electrophysiology experiments were done without blinding. Generation of plasmids and viruses To generate adeno-associated viruses (AAVs) expressing cytoplasmic GCaMP6f (GCaMP6) and mitochondrial-targeted GCaMP6f (mitoGCaMP6), we used PCR to amplify the human synapsin promoter (hSyn) from pAAV-6P-SEWB30. The pAAV-GFP (Addgene plasmid 32395) was cut with SnaB1 and Sac1 to replace CMV with hsyn (pAAV-hsyn-GFP). EcoRI and BamHI were used to replace GFP with mCherry to generate pAAV-hsyn-mCherry. To generate pAAV-hSyn-mCherry-2A-GCaMP6, oligonucleotides containing the coding sequence for the 2A peptide were used for PCR amplification of GCaMP6 from pGP-CMV-GCaMP6 (Addgene plasmid 40755). To generate pAAV-hSyn-mCherry-2A-mitoGCaMP6, oligonucleotides containing the coding sequence for the 2A peptide and the mitochondrial-targeting sequence (MSVLTPLLLRGLTGSARRLPVPRAKIHSL) were used for PCR amplification of GCaMP6 from pGP-CMV-GCaMP6 (Addgene plasmid 40755). To generate AAV-Slc25a4 OE, we used PCR to amplify the open reading frame of Slc25a4. Drd2 open reading frame from AAV-CamKII-Drd2 OE31 was replaced with the Slc25a4 open reading frame using HindIII. DNA sequencing was used to verify the absence of PCR-induced mutations. Lentivirus vector siRNA plasmids (control shRNA, 5′-TACGTCCAAGGTCGGGCAGGAAGA-3′; Slc25a4 shRNA1, 5′- GCAAGGGATCTTCCCAGCGAGAATTCAAT-3′; Slc25a4 shRNA2, 5′-CGTTTGACACTGTTCGTCGTAGGATGATG-3′; Slc25a4 shRNA3, 5′- GCACATTATCGTGAGCTGGATGATTGCCC-3′) were generated by Applied Biological Materials (Richmond, BC, Canada). Viruses (1.8 × 108 to 1 × 109 particles/ml) were produced by either the St. Jude or University of Tennessee Health Sciences Center Viral Vector Cores. Two-photon imaging of presynaptic calcium and in vivo injections Two-photon laser-scanning microscopy was performed using an Ultima imaging system (Prairie Technologies, Middleton, WI), a Ti:sapphire Chameleon Ultra femtosecond-pulsed laser (Coherent Inc., Santa Clara, CA), and 60× (0.9 NA) water-immersion IR objectives (Olympus, Center Valley, PA). Calcium (Ca2+) transients in presynaptic terminals were recorded using GCaMP6 expressed in the CA3 hippocampal neurons. To express GCaMP6, mice were anaesthetized using isoflurane (2% for induction and 1.5% for maintenance) in 100% oxygen, and their heads were restrained on a stereotaxic apparatus. An approximately 1-cm midline incision was made centered about 0.25 cm behind bregma. Viruses were injected into 3 locations within the CA3 region, in 1 or both hemispheres. The stereotaxic coordinates for the 3 injections were as follows, in relation to the bregma: (1) –1.5-mm anteroposterior, 1.8-mm lateral, and 1.7-mm deep; (2) 2.2-mm anteroposterior, 2.3-mm lateral, and 1.8-mm deep; (3) 2.5-mm anteroposterior, 2.8-mm lateral, and 2.2-mm deep. Craniotomy holes were drilled at these locations, and 200 nL of AAVs was slowly (20 nL/min) injected via a 33G cannula. After each injection, the cannula was left in place for 2 to 3 min before being retracted. Following injections, the skin was sutured, and the mice were allowed to recover before returning to the holding cages. Imaging experiments were performed 4 to 7 weeks after AAV injections. During each experiment, care was taken to limit the differences in post-injection durations to a maximum of 2 to 3 days across experimental groups to avoid substantial differences in the levels of AAV expression. To visualize GCaMP6 or mitoGCaMP6, we used brain slices prepared from AAV-injected mice. Schaffer collaterals were stimulated via field stimulation using bipolar stimulating electrodes, as in STP experiments. In addition to D-AP5 and picrotoxin, the AMPA receptor antagonist NBQX (3 µM) was added to the bath ACSF to prevent excitation of postsynaptic neurons. GCaMP6 was visualized at 940 nm, and mCherry was visualized at 1,040 nm by two Ti:Si lasers. Presynaptic boutons were identified in a 34 µm × 34 µm region of interest by activity-dependent increase in GCaMP6 fluorescence during time-series scans. Line-scans through identified boutons were then used for experiments. Boutons from 4 to 8 regions of interests in the stratum radiatum of the CA1 area were imaged for each mouse. In some experiments, we used whole-cell recordings from CA3 neurons and filled the cells with Alexa Fluor 594 (30 µM) and Fluo 5F (300 µM) at 820 nm to visualize presynaptic Ca2+. Axons emanating from the cell bodies were identified based on their morphology and lack of spines. Presynaptic terminals were identified as boutons in secondary and tertiary axonal branches. Those axons could not be tracked beyond 200 µm from the CA3 cell bodies due to the limitation of the approach. APs were evoked by holding the cells at –70 mV (current clamp mode) and injecting depolarizing current (3.5–4.0 nA, 500 µs). We recorded Ca2+ transients in line-scan mode from 3 to 7 boutons per cell. For GCaMP6 or mitoGCaMP6 experiments, the baseline fluorescence (F0) was used to calculate the change in signal (ΔF/F0). For Fluo5F experiments, fluorescence changes (ΔG/R) were quantified as an increase in Fluo 5F fluorescence (ΔG) normalized to the respective Alexa 594 fluorescence (R). Imaging experiments were done without blinding. Two-photon glutamate uncaging For two-photon glutamate uncaging (TGU), MNI-glutamate (2.5 mM) was added to the recording ACSF. The timing and intensity of glutamate uncaging were controlled by TriggerSync (Prairie Technologies). In typical experiments, 0.2-ms pulses from a second Ti:sapphire Chameleon Ultra laser (720 nm) were delivered to the vicinity of a targeted dendritic spine, and TGU-evoked EPSCs (uEPSCs) were recorded. The duration and intensity of illumination of the uncaging laser were then adjusted to induce responses that mimicked spontaneous miniature EPSCs, which were recorded in CA1 neurons and averaged 10 to 15 pA. After the uncaging parameters (i.e., site, laser duration, and laser intensity) were adjusted for a single spine, the parameters remained constant for the STP experiments on the particular spine. An 80-Hz train of 100 TGU pulses was delivered to a single dendritic spine to measure TGU-induced STP. Electron microscopy Mice were anesthetized with ethyl carbamate (1.5 g/kg, 25% solution, intraperitoneal) and perfused transcardially with phosphate-buffered saline (PBS) for 1 to 2 min and then a fixative (2.5% gluteraldehyde and 2% paraformaldehyde in 0.2 M sodium cacodylate). Brains were isolated, stored at 4°C overnight in the same fixative, and sagittal sections (100-µm thick) were prepared on a Leica vibratome. Smaller regions (~ 500 µm × 500 µm) containing the stratum radiatum of the CA1 hippocampal region were processed for 3-dimensional (3D) scanning electron microscopy (SEM). The samples were stained with a modified heavy-metal–staining method, processed through a graded series of alcohol and propylene oxide, and then embedded in Epon hard resin32. Sections (0.5-µm thick) were cut to determine the correct area and then coated with iridium in a Denton Desk II sputter coater. The 3D EM images were collected on a Helios Nanolab 660 Dualbeam system. From the 3D stacks of electron micrographs (10 × 10 x 10 nm voxel size, 250 to 260 sections of 10 nm thickness and approximately 30 × 20 µm area, synapses were identified based on the presence of postsynaptic densities and presynaptic vesicles. The mitochondria in presynaptic terminals were identified and counted manually. For transmission electron microscopy (TEM), 100-µm-thick vibratome sections containing the CA1 stratum radiatum region were prepared as described above and fixed in 2.5% glutaraldehyde and 2% paraformaldehyde in 0.1 M sodium cacodylate buffer (pH 7.4). Sections were post fixed in 2% osmium tetroxide in 0.1 M sodium cacodylate buffer with 0.3% potassium ferrocyanide for 1.5 h. After rinsing in the same buffer, the sections were dehydrated through a series of graded ethanol and propylene oxide solutions, infiltrated and embedded in epoxy resin, and polymerized at 70°C overnight. Thin sections (0.5 µm) were stained with toluidine blue for examination by light microscopy. Ultrathin sections (80 nm) were cut and imaged using an FEI Tecnai F 20 FEG Electron Microscope with A AT XR41 Camera. Mitochondrial DNA quantification RNA was isolated from the hippocampus of 4-month-old mice by using the mirVana RNA isolation kit (Ambion, Life Technologies) The SuperScript III reverse transcriptase kit (Invitrogen, Life Technologies) was used to synthesize cDNA from 1 µg RNA. The following primers were used in the qPCR experiments: COI (5'-GCCCCAGATATAGCATTCCC-3'and 5'-GTTCATCCTGTTCCTGCTCC-3'); ND2 (5'-CCCATTCCACTTCTGATTACC-3' and 5'-ATGATAGTAGAGTTGAGTAGCG-3'); 18S (5'-TAGAGGGACAAGTGGCGTTC-3' and 5'-CGCTGAGCCAGTCAGTGT-3'). The ratio of mitochondrial (CO1 and ND2) transcripts to the nuclear 18S transcript was used to quantify relative mitochondrial DNA. Mitochondrial respiration Mice were decapitated, and their brains were dissected immediately in cold (4°C) dissecting ACSF. Hippocampi were removed and washed in a mitochondrial isolation buffer (MIB) containing 250 mM sucrose, 1 mg/mL bovine serum albumin, 5 mM EDTA, and 10 mM Tris-HCl at pH 7.4. A crude mitochondrial fraction was then isolated by differential centrifugation. Briefly, the hippocampal tissue was finely minced on a pre-chilled glass dish, washed several times, resuspended in 1 mL MIB and homogenized in a 2-mL Dounce homogenizer (glass/glass, 5–7 runs in an ice bath). The homogenized tissue was centrifuged at 700 ×g for 5 min; the supernatant was then transferred to a new 1.5-mL tube and centrifuged at 7,000 ×g for 10 min. The resulting pellet was washed in 1 mL MIB and resuspended in 30 µL MIB. The protein concentration in the pellet was typically 25 to 35 mg protein/mL. The mitochondrial integrity was tested by measuring the glutamate/malate-dependent respiratory control ratio (i.e., State III/State IV of respiration). The resulting mitochondrial samples were used immediately to measure respiration (mitochondrial oxygen consumption) and Ca2+-retention capacity. Mitochondrial oxygen consumption was measured using a Clark-type electrode (Hansatech Instruments, Ltd, Norfolk, U.K.) in a thermostatically controlled chamber equipped with a magnetic stirring device and a gas-tight stopper fitted with a narrow port for additions via a Hamilton microsyringe. Isolated mitochondria were placed in the respiration chamber at 37°C in 0.4 mL respiration buffer (250 mM sucrose, 1 g/L bovine serum albumin, 10 mM KH2PO4, 2.7 mM KCl, 3 mM MgCl2, 40 mM Hepes, 0.5 mM EGTA, pH 7.1) to yield a final concentration of 0.5 mg/mL. State-III respiration was stimulated by the addition of 2 mM ADP. Respiratory control ratios were obtained by dividing the rate of oxygen consumption in the presence of ADP (state III) by that in the absence of ADP (state IV). The measurement protocol involved sequential addition (with 5-min intervals) of 5 mM glutamate, 2.5 mM malate (activating the CI-CIII-CIV span), 1 µM rotenone, 10 mM succinate (activating the CII-CIII-CIV span), 1 µM antymicin A, 10 mM ascorbate, 0.4 mM TMPD (activating the CIV span), and 5 mM KCN. The rates of oxygen consumption were calculated online, as first derivatives of the dioxygen-content changes by manufacturer-provided software. Quantitative real-time PCR The cDNA was generated from 1 µg hippocampal RNA by using Superscript III (Life Technologies, Waltham, MA). Primers for qPCR were as follows: Hira: TCCGCCATCCATCAATTC and CTATCCTTCACCAGCCTAG, Cldn5: CGCAGACGACTTGGAAGG and GCCAGCACAGATTCATACAC, Mrpl40: CTGGTAGTTAGAGATAGGTGGTG and GAGGAGCTGAAACTTGAATCTG, Ufd1l: TCAAGCATGTATTCATTCTGC and TTTATTTACAGTGACTCAGAAGG, 2510002D24Rik: GTGTTCCAGGTCAAGTAA and AGAAGGACAAGTGATAAGC, Cdc45l: GATTTCCGCAAGGAGTTCTACG and TACTGGACGTGGTCACACTGA. Co1: GCCCCAGATATAGCATTCCC and GTTCATCCTGTTCCTGCTCC, Nd2: CCCATTCCACTTCTGATTACC and ATGATAGTAGAGTTGAGTAGCG, 18s: TAGAGGGACAAGTGGCGTTC and CGCTGAGCCAGTCAGTGT. We performed qPCR using SYBR green in an Applied Biosystems 7900HT Fast Real-time PCR system and the standard protocol. A serial dilution of cDNA was used to generate a standard curve for each primer set, and this curve was used to calculate gene concentrations for each sample. All samples were run in triplicate. Mouse behavior Mature animals (16- to 20-weeks) were used for all behavior experiments. Morris water maze One hour prior to testing, animals were brought into the testing room and allowed to habituate. Testing was performed during the animal’s inactive phase under dim-light conditions. Mice were allowed to navigate in the maze, and swim patterns were recorded with a video camera tracking system (HVS Image, Co., Buckingham, UK) mounted above the pool. Animals learned to find a hidden, clear platform by using the standard spatial version of the Morris water maze task for 4 successive days. Each day, animals were given four 1-min trials from each starting position with an inter-trial latency of 60 s. The order of the starting locations was counterbalanced each day by using a Latin-square design. A spatial learning (probe) trial was administered 1 h after the completion of spatial training. A spatial memory (probe) trial was administered 48 h after completion of the spatial learning. During both probe trials, the platform was removed, and the mice received a single 1-min trial in which the animal tried to find the escape platform. These trials originated from the starting location that was the farthest from the platform’s location throughout training. Mice also completed a nonspatial learning task at least 7 days after completion of the spatial protocol. In that task, mice were trained to find a black visible platform for 2 successive days. During Day 1, the escape platform was located in the same position used during spatial training. The next day, the escape platform was moved to a new quadrant. Each day, the mouse was given four 1-min trials in the same manner that occurred during spatial training. To avoid hypothermia, immediately after each round of training and testing trials, animals were dried with paper towels and placed in warmed holding cages. Delayed non–matched-to-position task To motivate mice to complete the delayed non–matched-to-position task, they were subjected to water restriction for 2 days prior to testing. Specifically, mice were allowed 2 h of free access to water per day. Mice were weighed daily to ensure that weight decrease during deprivation did not surpass the recommended 20% loss. One hour prior to testing, animals were brought into the testing room and allowed to habituate. Testing was performed during the animal’s inactive phase under well-lit lighting conditions. The testing apparatus consisted of a Y-maze (Cleversys Inc., Reston, VA) with a start arm (20 cm × 16 cm × 7 cm; l × w × h) leading to 2 goal arms (20 cm × 16 cm × 7 cm). Mice were allowed to habituate to the maze and were given a positive reinforcer (i.e., Chocolate Yoohoo) before behavioral testing. To achieve this, mice were allowed to investigate the Y-maze baited with Yoohoo for 15 min. Maze habituation was performed for 2 consecutive days. After maze habituation was complete and the animal had consumed the food rewards, we conducted a test of spatial working memory. First, the mouse was constrained in the start arm with a guillotine door. Next, a sample arm was determined at random and the choice arm was closed off with a guillotine door (there was a limit of 2 consecutive same-side sample arms in a 10-trial test). Both arms were then baited with 20 µL Yoohoo. The mouse was released from the start chamber and allowed to run to the sample arm and consume the reward. The mouse was then returned to the start arm and the guillotine door to the nonsample arm was removed. All efforts were made to keep the intratrial interval at 5 s. The mouse was again released from the start chamber and allowed to run to either the previously entered sample arm or new choice arm to consume the reward. A return to the sample arm was counted as an incorrect response. Incorrect responses resulted in no reward and return to the start arm. A total of 10 trials were given. The Y-maze spatial recognition The maze was shaped like a “Y”, with 3 equally spaced arms (20 cm × 7 cm × 16 cm) radiating from a triangular center section. The Y-maze was constructed from blue opaque plastic to aid in video detection. The maze was located in a lit room with abundant extra-maze cues. The procedure consisted of an acquisition and a recognition session. During the acquisition session, the mouse was placed facing the distal end of an arm (start arm; determined semirandomly) and allowed to freely explore the maze for 15 min. During acquisition, the mouse was allowed to freely explore 2 of the 3 arms (determined semirandomly). After completing the acquisition session, the mouse was returned to its home cage for 1 h. Next, the mouse was given a 2-min recognition session, where all 3 arms were available for the mouse to freely explore. Time spent in each arm and the triangular center section and the total distance traveled during each trial were automatically recorded using TopScan software (CleverSys Inc.). Mice prefer novelty; therefore, if a mouse recognized and remembered which arms were familiar during the recognition session, the mouse would spend more time in the novel arm (expressed as a percent of total arm time) than would be expected by chance. Acoustic startle and prepulse inhibition Each day before testing, the mice were allowed a 1-h habituation in the testing room after being transported from the animal housing room. Before experiments were initiated, the mice were allowed to acclimate to the Plexiglas restraint chamber (6 cm × 6 cm × 4.8 cm) for 20 min. Acoustic-startle and prepulse inhibition (PPI) tests were performed in ventilated, sound-attenuated chambers (Med Associates, St. Albans City, VT). For acoustic-startle experiments, the mice had a 5-min acclimation period to a 65-dB background white noise, which played throughout the session. Three startle pulses (8 kHz, 120 dB, 40 ms) were then delivered at 15-s intertrial intervals. For PPI experiments (conducted on different days than acoustic-startle experiments), mice had a 5-min acclimation period to a 65-dB background white noise, which played throughout the session. Three acoustic startles (broadband white noise click, 120 dB, 40 ms) were then delivered separated by a 15-s intertrial interval. The testing session consisted of 39 trials of 5 trial types: pulse alone, in which the startle pulse was presented; the combination of a 40-ms prepulse of 74 dB, 82 dB, or 90 dB preceding the startle pulse by 100 ms; and no stimuli. Trials were separated by 15 s and presented in a pseudo-random order. PPI was calculated as follows: 100 × (pulse-alone response – prepulse + pulse response)/pulse-alone response. All mouse behavior experiments were performed in a blind manner in respect to mouse genotypes. Western blotting AAV5-hSyn-mCherry-2A-mitoGCaMP6f or AAV5-hSyn-mCherry-2A-GCaMP6f viruses were injected in vivo into the mouse hippocampus as described above. Four weeks after injections, mice were euthanized and dorsal hippocampi were isolated at 4°C for fractionation into nuclear/cell debris, cytoplasm, and crude mitochondrial fractions. Freshly extracted hippocampi from each mouse were homogenized in isolation buffer (250 mM sucrose, 75 mM mannitol, 1 mM EGTA, and 5 mM Hepes, at pH 7.4) by using a glass-teflon tissue homogenizer on ice. Homogenized hippocampi were centrifuged twice at 1,400 ×g for 3 min at 4°C to separate nuclei and cell debris. The supernatant was then centrifuged at 17,200 ×g for 10 min at 4°C to separate cytosol and crude mitochondria. Ice-cold RIPA buffer (Santa Cruz Biotechnology, Dallas TX) with protease inhibitors (Roche, Basel, Switzerland) was added to the mitochondria but not the cytoplasmic fraction, and both were briefly sonicated. Samples were centrifuged at 17,200 ×g for 20 min at 4°C, and the pellet was kept at –80°C for protein quantification. Protein quantification was performed using a Pierce BCA Protein Assay Kit (Thermo Scientific). For loading-sample preparation, we used NuPAGE LDS sample buffer (Life Technologies). The Western-blot experiments were performed similar to a previously described method12. Briefly, NuPAGE 10% Bis-Tris gels and MES-SDS running buffer (Life Technologies) were used to load mitochondria and cytoplasmic fractions (10 µg total protein/well) and run the gels. The primary antibody used to detect GCaMP6 was rabbit–anti-GFP (1:1000, Abcam, 6556). We also used rabbit–anti-Prohibitin 1 (1:1000, Thermo Scientific, PA5-12274) and mouse–anti–β-actin (1:10,000, Sigma, 5316) primary antibodies. Secondary antibodies were Odyssey goat–anti-rabbit IRDye-680LT (1:40,000, LI-COR Biosciences, Lincoln, NE, 926-68021) or Odyssey donkey–anti-mouse IRDye-800CW (1:15,000, LI-COR Biosciences, 926-32212). Membranes were imaged using an Odyssey Infrared Imager (LI-COR Biosciences). Images were analyzed using Odyssey V3.0 software. Subcellular localization of mitoGCaMP6 and GCaMP6 Neuro-2a (N2a) mouse neuroblastoma cells (ATCC, CCL-131) were plated in 4-well chamber slides (Thermo-Scientific Lab-Tek 177399) at 1.25 × 105 cells/well and maintained in culture using Eagle’s Medium Essential Media (EMEM) (ATCC) plus 10% fetal bovine serum (heat inactivated, Life Technologies) and 1× PenStrep (Life Technologies) in an incubator at 37°C and 95% O2/5% CO2. Following a 24-h incubation, cells were transfected with hSyn-mCherry-2A-mitoGCaMP6f or hSyn-mCherry-2A-GCaMP6f plasmids (0.5 µg DNA/well) using Fugene HD transfection reagent (Promega) (Ration Fugene HD/DNA 1:4) in serum-free EMEM. Twenty-four hours later, cells were supplemented with additional fresh complete media, and 48 h later, they were incubated in complete media with Mitotracker DeepRed (1:2,000, Life Technologies) for 15 min at 37°C. Next, Mitotracker was washed out and replaced with fresh complete media, and cells were placed back to the incubator for 15 to 20 min. Cells were then washed with sterile PBS and fixed in 4% paraformaldehyde for 15 min at room temperature. Following fixation, cells were washed 3 times for 5 min with PBS and blocked with 10% normal goat serum and 0.1% TritonX-100 in PBS for 1 h at room temperature. We used the following antibodies: chicken–anti-GFP to detect GCaMP6 or mitoGCaMP6 (1:1000, Abcam, 13970) and goat–anti-chicken–Alexa-488 (1:1000, Life Technologies, A11039). Cell imaging was performed using an LSM-780 confocal microscope (Zeiss). Other drugs and chemicals Bongkrekic acid solution was purchased from Sigma-Aldrich. D-AP5, picrotoxin, tetrodotoxin, NBQX, CGP 37157, MNI glutamate were from Tocris. Stock solutions of these drugs were prepared in manufacturer recommended solvents and stored at −20°C. Ru360 was from Calbiochem. Statistical analyses Data are presented as the mean ± SEM. Statistical analyses were performed using SigmaPlot software. Parametric or nonparametric tests were chosen based on the normality and variance of data distribution. Independent or paired two-tailed t-tests (t value), Mann-Whitney Rank Sum test (U value), one-way analysis of variance (ANOVA) / Kruskal Wallis one-way analysis of variance on ranks followed by a multiple-comparison procedure (Dunn’s method), two-way ANOVA / two way repeated measures ANOVA with one factor repetition followed by Holm-Sidak multiple comparison procedure were the statistical tests used. F values were reported for ANOVA and Q values from multiple comparison procedure were reported for ANOVA on ranks. Differences with p < 0.05 were considered significant. Results Abnormal presynaptic augmentation underlies aberrant STP in Df(16)5+/− mice To determine whether haploinsufficiency of distal genes in the 22q11DS region contributes to hippocampal pathophysiology, we used Df(16)5+/− mice33 carrying a hemizygous deletion of six genes: Cldn5, Cdc45l, Ufd1l, 2510002D24Rik, Mrpl40, and Hira (Fig. 1a). Similar to the late onset of SCZ symptoms, synaptic plasticity abnormalities in mouse models of 22q11DS do not appear until later in life23; thus, we used 4- to 5-month-old mice for these experiments. Df(16)5+/− mice developed normally and had no visible gross morphologic abnormalities (data not shown). Using the whole-cell voltage-clamp technique we recorded excitatory postsynaptic currents (EPSCs) at glutamatergic synapses between CA3 and CA1 pyramidal neurons in the hippocampus (CA3–CA1 synapses) by electrically stimulating Schaffer collaterals. Basal synaptic transmission measured as the input–output relation between stimulation intensity and EPSCs in Df(16)5+/− mice was comparable to wild-type (WT) littermates [F(1,12) = 1.435, p = 0.231] (Fig. 1b). EPSC kinetics, such as rise time [t(19) = 0.442, p = 0.663], half-width (U = 51, p = 0.805), and decay time [t(19) = 0.0377, p = 0.970] were also normal between mutants and controls (Supplementary Fig. 1). However, an 80-Hz train (100 stimuli) applied to Schaffer collaterals evoked a substantially larger STP [t(16) = 2.196; p = 0.010] in Df(16)5+/− mutants than in WT mice (Fig. 1c). Because STP is not a unitary process but rather consists of several temporally and mechanistically distinct components (e.g., facilitation, augmentation, and depression of presynaptic transmission20), we measured STP components individually. The STP increase in Df(16)5+/− mutants could arise from the increased facilitation/augmentation, decreased short-term depression, or a combination thereof21. To differentiate among these possibilities, we used an established protocol to separate STP components29 and assess their individual contributions to the STP increase in Df(16)5+/− mice. First, using the paired-pulse ratios of two consecutive EPSCs, we found no significant difference [F(1,5) = 2.142, p = 0.146] in facilitation between Df(16)5+/− and WT mice (Fig. 1d). We then examined whether the increased STP in Df(16)5+/− mice resulted from reduced short-term depression. We examined the recovery from depression by using a 5-Hz stimulus train applied during the first 5 s after the 80-Hz train of Schaffer collateral stimuli. Because recovery from depression overlaps with the decay of augmentation during those 5 s, the actual EPSC peak amplitude reflects the net effect of the two processes21. To isolate the depression component, we corrected the synaptic responses for contribution from augmentation21, 29 (see Online Methods). This analysis revealed no significant difference [F(1,23) = 1.947; p = 0.182] in recovery from short-term depression between Df(16)5+/− and WT littermates (Fig. 1e). Next, we assessed the role of augmentation, which is the longest-lasting component of STP and operates on a time scale of tens of seconds29. Using a previously reported approach29, we isolated augmentation by applying a single stimulus to Schaffer collaterals every 5 s for 2 min, starting 5 s after the 80-Hz train (Fig. 1f). Augmentation was significantly increased [t(16) = 4.758, p = 0.0002] in Df(16)5+/− mice compared to WT controls (Fig. 1f). This increased augmentation in Df(16)5+/− mice was maximal at the onset and decayed to normal values after 20 s. Elevated augmentation in Df(16)5+/− mutants was not sensitive to the Serca inhibitor thapsigargin (4 µM) [without thapsigargin: t(16) = 4.404, p < 0.001; with thapsigargin: t(10) = 1.954, p = 0.0396] (Supplementary Fig. 2a). Further, Serca2 protein levels were normal (U = 107, p = 0.836) in Df(16)5+/− mice (Supplementary Fig. 2b), suggesting that haploinsufficiency of genes within the Df(16)5 genomic region resulted in abnormal STP through Serca2-independent mechanisms. To ensure that the STP increase in Df(16)5+/− mice originated from the presynaptic CA3 neurons, we examined the role of the postsynaptic component by performing two-photon glutamate uncaging (TGU) (100 TGU pulses, 80 Hz) to activate individual dendritic spines on CA1 neurons, the postsynaptic sites of CA3 inputs. Because TGU focally releases exogenous glutamate from inactive (caged) glutamate (MNI-glutamate), thereby bypassing the release of endogenous neurotransmitter from CA3 terminals, this method tests only postsynaptic mechanisms of synaptic transmission and plasticity. TGU-induced STP did not differ [t(25) = −0.405, p = 0.689] between Df(16)5+/− and WT littermates (Supplementary Fig. 3a), suggesting that the causative locus of the abnormal STP increase in Df(16)5 mutants resides in the presynaptic CA3 neurons. CA3 pyramidal neuron recordings revealed that presynaptic neurons had normal resting membrane potential [t(18) = −1.621, p = 0.122], input resistance [t(18) = 0.978, p = 0.341], and depolarization-induced action potentials (APs) [rheobase: t(18) = 0.451, p = 0.658 ; AP width: t(18) = 0.384, p = 0.706) (Supplementary Fig. 3b). An 80-Hz train of depolarization pulses delivered to the CA3 soma progressively increased the AP width, but to the same extent [100th AP width: t(12) = 0.845, p = 0.414] in both Df(16)5+/− and WT littermates (Supplementary Fig. 3c, d), thereby ruling out CA3 excitability as the culprit mechanism and implicating abnormal presynaptic glutamate release as a possible underlying mechanism of elevated STP in Df(16)5+/− mice. Mrpl40 haploinsufficiency causes abnormal STP in Df(16)5+/− mice To identify the culprit gene(s) whose haploinsufficiency causes abnormal augmentation and STP in Df(16)5+/− mice, we tested STP parameters in Cldn5+/− and Hira+/− mice27, 28 and the following new mutants that we generated: Cdc45l+/−, Ufd1l+/−, 2510002D24Rik+/−, and Mrpl40+/− mice (Supplementary Fig. 4). All transcripts were reduced by approximately 50% in the Df(16)5+/− mice [Cldn5+/−: p < 0.001; Cdc45l+/−: p = 0.03; Ufd1l+/−: p = 0.004; 2510002D24Rik+/−: p = 0.005; Mrpl40+/− : p = 0.010; Hira+/−: p = 0.003] and the respective individual mutants [Cldn5+/−: p < 0.001; Cdc45l+/: p < 0.001; Ufd1l+/−: p < 0.001; 2510002D24Rik+/−: p = 0.004; Mrpl40+/− : p < 0.001; Hira+/−: p = 0.03] (Supplementary Fig. 4). Testing STP in all six mouse mutants revealed that Mrpl40+/− mice had elevated STP and augmentation compared to their WT littermates [STP: t(29) = 2.368, p = 0.025; augmentation: t(29) = 3.150, p = 0.0037], whereas Cldn5+/−, Cdc45l+/−, Ufd1l+/−, 2510002D24Rik+/−, and Hira+/− mutants had normal STP and augmentation [STP and augmentation, respectively: Cldn5+/−: t(12) = 0.349, p = 0.733 and t(12) = −1.205, p = 0.250; Cdc45l+/−: t(18) = 0.566, p = 0.579 and t(18) = −0.637, p = 0.532; Ufd1l+/−: U = 43, p = 0.903 and U = 35, p = 0.438; 2510002D24Rik+/−: t(35) = 0.789, p = 0.436 and t(35) =1.773, p = 0.085; Hira+/−: t(11) = −0.644, p = 0.532 and t(11) = −0.687, p = 0.507] (Fig. 1g, h, Supplementary Fig. 5). Mrpl40 haploinsufficiency did not affect mRNA expression of other genes in the Df(16)5 microdeletion [Gapdh: U = 28, p = 0.871; Mrpl40: t(14) = 4.225, p < 0.001; Cldn5: t(14) = −0.0174, p = 0.986; Ufd1l: t(14) = −0.368, p = 0.719) (Supplementary Fig. 6). The full complement of Mrpl40 gene appeared to be essential for prenatal development as its homozygous deletion was embryonically lethal. The enhanced STP and augmentation in Mrpl40+/− mice were comparable to that in Df(16)5+/− mice, suggesting that hemizygous deletion of Mrpl40 underlies the abnormal synaptic plasticity in Df(16)5+/− mice. Df(16)5 deletion does not disrupt mitochondrial structure or oxidative phosphorylation Because Mrpl40 is thought to be one of the proteins of the mitoribosome complex34, 35, we investigated whether mitochondrial numbers, structure, or function were affected in Df(16)5+/− mice. We found no significant difference in mitochondrial ultrastructure imaged with TEM in the CA1 area of the hippocampus (Fig. 2a), in total mitochondrial DNA (Co1: U = 89, p = 0.147; Nd2: U = 101, p = 0.318) or in oxidative phosphorylation [F(1,8) = 0.108, p = 0.745] in isolated mitochondria from the hippocampus between Df(16)5+/− and WT littermates, suggesting normal energy production in mice with a Df(16)5-hemizygous deletion (Supplementary Fig. 7). Furthermore, 3D scanning electron microscopy (SEM) imaging of the hippocampal CA1 area revealed a normal distribution of mitochondria in presynaptic terminals of Df(16)5+/− mice compared to WT littermates (U = 34.5, p = 0.093) (Supplementary Fig. 8), suggesting normal trafficking of mitochondria to presynaptic terminals in Df(16)5+/− mice. Dysregulation of activity-dependent presynaptic and mitochondrial Ca2+ in Mrpl40+/− mice Because mitochondria also regulate presynaptic Ca2+ levels, we measured activity-dependent Ca2+ changes in response to the 80-Hz stimulation of Schaffer collaterals in presynaptic CA3 terminals in the hippocampal stratum radiatum (CA1 area). To this end, we took advantage of the highly sensitive genetically encoded Ca2+ indicator GCaMP6f (GCaMP6)25. After infecting the CA3 area of the hippocampus in vivo with recombinant adeno-associated viruses (AAVs) encoding mCherry and GCaMP6, we observed high expression of fluorescent proteins in neuronal cell bodies in the CA3 area but not in the CA1 area (Fig. 2b). In the stratum radiatum we observed fluorescent boutons, which responded to 80-Hz electrical stimulation (10 pulses) of Schaffer collaterals with GCaMP6 fluorescence transients with fast rise and decay (rise time20%-80%, 100.46 ± 4.03 ms; decay time (τ), 222.71 ± 9.40 ms) (Fig. 2c). These activity-dependent kinetics of GCaMP6 fluorescence were similar to those observed in CA3 presynaptic terminals in which the inorganic Ca2+ indicator Fluo 5F was used (data not shown), suggesting that GCaMP6 reliably measures cytosolic Ca2+ in presynaptic terminals. The activity-dependent increase in GCaMP6 fluorescence during the 80-Hz train of stimulations was substantially higher (U = 537, p < 0.001) in Df(16)5+/− mice than in their WT littermates (Fig. 2d), which is consistent with the notion that higher presynaptic Ca2+ levels lead to elevated augmentation and STP20. To directly measure Ca2+ in the CA1 stratum radiatum mitochondria localized to the presynaptic terminals originating from CA3, we expressed GCaMP6 with a mitochondrial-localization signal (mitoGCaMP6) in the CA3 area using recombinant AAVs (Fig. 2b). We verified the specific localization of mitoGCaMP6 to mitochondria using subcellular fractionation followed by Western blotting and co-immunolocalization with mitochondrial markers (Supplementary Fig. 9). We also verified that the activity-dependent increase in mitoGCaMP6 fluorescence was sensitive to an inhibitor of the mitochondrial Ca2+ uniporter Ru360 (10 µM) (U = 15, p < 0.001) (Supplementary Fig. 10). An 80-Hz train (10 pulses) applied to the Schaffer collaterals induced an activity-dependent increase in mitoGCaMP6 but with substantially slower kinetics compared to cytosolic GCaMP6 (mitoGCaMP6: rise time20%-80%, 210.21 ± 27.03 ms, decay time > 1 s; GCaMP6: rise time20%-80%, 100.46 ± 4.03 ms; decay time (τ), 222.71 ± 9.40 ms; U = 540, p < 0.001) (Fig. 2e). Similar to cytosolic Ca2+, mitochondrial Ca2+ was elevated (U = 889, p = 0.020) in Df(16)5+/− mice in response to the 80-Hz synaptic stimulation (Fig. 2e). The increases in cytosolic and mitochondrial Ca2+ were also observed in Mrpl40+/− mice to a similar degree as in Df(16)5+/− mice (GCaMP6: U = 482, p < 0.001; mitoGCaMP6: U = 618, p < 0.001) (Fig. 2f–i). These data suggest that Mrpl40 is the gene in the Df(16)5 genomic region that is responsible for the STP phenotype by deregulating activity-dependent mitochondrial and cytoplasmic presynaptic Ca2+ dynamics. Mrpl40+/− mice are deficient in short-term but not long-term spatial memory or long-term synaptic plasticity To test if the hemizygous Mrpl40 deletion affects cognitive function, we compared the performance of Mrpl40+/− and WT mice in several behavioral tests. Mrpl40+/− mice behaved normally in the acoustic startle [F(1,7) = 0.0711, p = 0.79] and pre-pulse inhibition [F(1,2) = 1.314, p = 0.274] of acoustic startle tests (Fig. 3a, b), a measure of sensorimotor gating that is believed to be associated with positive symptoms of SCZ31. To test spatial working memory, we used a delayed, non-matched-to-position task (DNMPT), in which timing between runs ranged from 0 to 5 s. In this test Mrpl40+/− mice performed significantly worse [t(28) = 3.3, p = 0.003] than WT littermates (Fig. 3c). However, Mrpl40+/− mice performed normally in the tasks that assessed long-term memory (e.g., Morris Water Maze task). In this task, mutant mice learned to find the invisible escape platform (Fig. 3d) and retained this spatial memory for 48 h similar to WT controls [F(1,3) = 0.0425, p = 0.837, Fig. 3e]. Mrpl40+/− mice also performed comparably to WT controls [day 1: t(33) = −0.457, p = 0.651; day 2: U = 149.5, p = 0.921] when the escape platform was visible (Fig. 3f). Mrpl40+/− mutants also showed no memory deficits in the Y-maze [t(14) = 0.160, p = 0.873], where we measured the amount of time a mouse spends in a novel arm 1 h after exploring the other two arms of the maze (Fig. 3g). These data suggest that Mrpl40 haploinsufficiency affects short-term (working) memory but not long-term memory. Consistent with this notion, STP was abnormal in Mrpl40+/− mice (Fig. 1g, h), but long-term potentiation (LTP) of excitatory synaptic transmission, a major form of long-term synaptic plasticity at CA3–CA1 synapses, did not differ (t(53) = 0.161, p = 0.873) between Mrpl40+/− mice and WT littermates (Fig. 3h). Mitochondrial Ca2+–extrusion deficit underlies STP and Ca2+ phenotypes in Mrpl40+/− mice The abnormally high increase in cytoplasmic Ca2+ induced by the 80-Hz synaptic stimulation in Mrpl40+/− mice coincided with the enhanced mitochondrial Ca2+ increase. A role for slow mitochondrial Ca2+ extrusion in STP has been implicated in crayfish neuromuscular junction36 and led us to hypothesize that our results in the hippocampus could also be explained by impaired Ca2+ extrusion from mitochondria. Two major mechanisms extrude Ca2+ from the mitochondrial matrix to the cytoplasm: mitochondrial Ca2+ exchangers and the mPTP37, 38. The selective antagonist of the mitochondrial Na+–Ca2+ exchanger, CGP 37157 (5 µM), had no effect on STP or augmentation in WT mice [STP: t(18) = 0.999, p = 0.333; augmentation: t(18) = 1.007, p = 0.330], suggesting that this Ca2+ extrusion mechanism is not required for Ca2+ handling by mitochondria during 80-Hz–induced synaptic plasticity (Supplementary Fig. 11). However, bongkrekic acid (BKA, 2 µM), a non-selective inhibitor of the adenine nucleotide (ADP/ATP) translocases (ANTs)39, which are required for sensitivity of mPTP to calcium40, significantly increased STP and augmentation [STP: U = 14, p = 0.005; augmentation: t(19) = −3.169, p = 0.005] in WT mice (Fig. 4a, Supplementary Fig. 12a,c). This increase mimicked the STP and augmentation enhancement in Df(16)5+/− and Mrpl40+/− mice. Interestingly, BKA did not increase STP or augmentation further [STP: t(19) = −0.107, p = 0.916; augmentation: t(19) = −0.928, p = 0.365] in Df(16)5+/− mice (Fig. 4a, Supplementary Fig. 12b,d). BKA also did not affect basal synaptic transmission [F(3,12) = 1.179, p = 0.318], paired-pulse facilitation [F(3,5) = 0.402, p = 0.752], or recovery from depression [F(3,23) = 1.114, p = 0.358] in either WT or Df(16)5+/− mice (Supplementary Fig. 13), indicating that the BKA effect is specific for the augmentation component of STP. Furthermore, BKA significantly enhanced the magnitudes of cytosolic and mitochondrial Ca2+ transients evoked by the 80-Hz train in WT mice (GCaMP6: Q = 2.821, p < 0.05; mitoGCaMP6: Q = 4.908, p < 0.05) (Fig. 4b,c, Supplementary Fig. 12e,g) but failed to increase Ca2+ transients in Df(16)5+/− mice (GCaMP6: Q = 0.246, p > 0.05; mitoGCaMP6: Q = 1.767, p > 0.05) (Fig. 4b,c, Supplementary Fig. 12f,h), suggesting that the STP enhancement in Df(16)5+/− mutants acts through the same mechanisms as BKA. Like Df(16)5+/− mice, Mrpl40+/− mice showed no effect of BKA on STP, augmentation, or Ca2+ transients [STP: U = 52, p = 0.371; augmentation: t(23) = −1.091, p = 0.287; GCaMP6: Q = 0.418, p > 0.05; mitoGCaMP6: Q = 0.052, p > 0.05] in presynaptic terminals or mitochondria, whereas BKA enhanced these parameters in WT littermates [STP: t(13) = −3.685, p = 0.0028; augmentation: t(13) = −0.2670, p = 0.02; GCaMP6: Q = 5.038, p < 0.05; mitoGCaMP6: Q = 2.645, p < 0.05] (Fig. 4d–f, Supplementary Fig. 14). These results suggest that haploinsufficiency of the Df(16)5 gene Mrpl40 impairs Ca2+ handling by mPTP. Therefore, we sought to rescue this deficit by enhancing mPTP function through overexpression of ANTs. To that end, we designed the AAV-Slc25a4 OE (Fig. 5), which overexpresses Ant1 (also known as Slc25a4), a gene encoding a regulator of mPTP activity40, 41. Only three isoforms of Ant (Ant1, 2, and 4) have been found in mice42, 43, and we identified Ant1 as the highest expressed isoform in the mouse hippocampus (data not shown). When expressed in the hippocampus, AAV-Slc25a4 OE increased the level of Slc25a4 protein [t(7) = 7.868, p < 0.001] (Supplementary Fig. 15a, b). We verified that AAV-Slc25a4 OE did not change the localization of Slc25a4 protein to mitochondria. Thus, Slc25a4 was co-localized with the mitochondrial fluorescent marker mitotracker (Supplementary Fig. 15c), and AAV-Slc25a4 OE did not change this pattern (Supplemental Fig. 15d). AAV-Slc25a4 OE expressed in the CA3 area of the hippocampus (Fig. 5a) rescued STP and augmentation in Mrpl40+/− mice [STP: U = 15, p = 0.005; augmentation: t(22) = 2.543, p = 0.019] but did not affect WT littermates [STP: t(16) = 0.566, p = 0.578 ; augmentation: t(16) = −0.654, p = 0.522] (Fig 5b, Supplementary Fig. 16). To confirm that the BKA-induced reduction in mPTP function mimics the Df(16)5+/− phenotype, we downregulated Slc25a4 by using the shRNA approach. To that end, we injected lentiviruses encoding three different shRNAs against Slc25a4 into the CA3 area of the hippocampus. STP and augmentation of synaptic transmission at CA3–CA1 synapses increased in WT mice infected with all three Slc25a4 shRNAs compared to the control shRNA [shRNA1 STP: t(13) = −1.882, p = 0.041; augmentation: U = 9, p = 0.029; shRNA2 STP: t(15) = −1.910, p = 0.04; augmentation: t(17) = −2.757, p = 0.014; shRNA3 STP:U = 9, p = 0.02; augmentation: t(13) = −2.475, p = 0.028] (Fig. 5c, Supplementary Fig. 17). However, Slc25a4 shRNAs did not further affect STP or augmentation in Mrpl40+/− mice [shRNA1 STP: U = 23, p = 0.382; augmentation: U = 28, p = 0.721; shRNA2 STP: U = 23, p = 0.091; augmentation: t(19) = 1.038, p = 0.312; shRNA3 STP U = 27, p = 0.267; augmentation: U = 24, p = 0.107] (Fig. 5c, Supplementary Fig. 17), suggesting that Mrpl40 haploinsufficiency altered STP by affecting mPTP function. Discussion Approximately 30% of patients with 22q11DS meet the diagnostic criteria for SCZ4. Cognitive symptoms of SCZ include deficits in working memory, attention, executive function, and learning and memory; these symptoms have a more prognostic value than do the positive or negative symptoms of the disease, and they contribute more to the patients’ functional disability44. The mechanisms underlying the cognitive deficits in SCZ and 22q11DS are still debated. Here we presented evidence that 22q11DS affects working memory and STP through a novel pathogenic mechanism––abnormal Ca2+ handling by mitochondria. We also elucidated several features of this pathogenic mechanism: (1) By screening mice carrying hemizygous deletions of individual genes mapped within the distal part of the 22q11 microdeletion, we identified Mrpl40 as a culprit gene that causes abnormal STP. (2) We identified that the augmentation component of STP is specifically affected. (3) Mrpl40 haploinsufficiency led to abnormal STP through mitochondria-mediated deregulation of presynaptic Ca2+ levels. (4) We pinpointed a functional abnormality in mitochondrial Ca2+ extrusion through the mPTP as a pathogenic mechanism caused by Mrpl40 haploinsufficiency. (5) Mrpl40 haploinsufficiency led to deficits in working memory but not in long-term plasticity or long-term memory. The hippocampus, prefrontal cortex, and interactions between these brain regions all contribute to working memory45–48. Deficits in working memory in patients with SCZ and/or 22q11DS are well documented49, 50. STP, an associative, short-lived synaptic strengthening, is considered a cellular correlate of short-term memory, a term often used synonymously with working memory20, 51. Consistent with this notion, deficits in STP are well established in animal models of SCZ and 22q11DS12, 48, 52–54. Because symptoms of SCZ typically appear during late adolescence or early adulthood, age appears to be an important variable in synaptic plasticity phenotypes associated with 22q11DS mice. In our experiments, we used mice that were older than 4 months. At this age, STP and LTP at CA3–CA1 synapses are substantially increased in Df(16)1+/− mouse models of 22q11DS, whereas at younger ages, both forms of synaptic plasticity are normal23. These experiments led to the identification of the microRNA-processing gene Dgcr8 as the culprit gene residing in the proximal part of the microdeletion affecting both short- and long-term synaptic plasticity in the hippocampus. Deletion of one allele of Dgcr8 causes depletion of miR-185 and miR-25 and posttranscriptional upregulation of Serca2 in the forebrain of older but not younger mice23. Because 22q11DS is a multigene syndrome, it is extremely likely that more than one gene is involved in STP abnormalities. Our present work showed that deletion of one allele of Mrpl40 residing in the distal part of the microdeletion, which is outside of the Df(16)1 genomic region caused independent deficits in STP and working memory in 22q11DS. First, we identified the STP increase in Df(16)5+/− mice, which were hemizygous for genes that mapped distally to Dgcr8. The STP screen revealed that only Mrpl40+/− mice replicated the Df(16)5+/− phenotype. Furthermore, the Mrpl40-related STP increase was mechanistically distinct from the STP increase identified in Dgcr8+/− mice. Dgcr8 haploinsufficiency elevates Serca2 protein12, but in the Df(16)5+/− mice, Serca2 levels were normal, and the Serca inhibitor thapsigragin did not rescue the STP defect. Mrpl40 was originally identified as a nuclear gene involved in mitochondrial function55. Mitochondrial dysfunction has been strongly implicated in SCZ pathophysiology56, though the exact connection between SCZ pathogenesis and mitochondria has not been established. For instance, the gene encoding DISC1 (disrupted-in-schizophrenia 1) has been localized to mitochondria and is involved in maintaining mitochondrial morphology and regulating mitochondrial transport57. Several mitochondrial genes, including Mrpl40, are mapped within the 22q11.2 locus and expressed in the brain throughout development, thus implicating mitochondria in the pathogenesis of 22q11DS58, 59. Mrpl40 haploinsufficiency does not affect the mitochondrial ultrastructure and does not reduce mitochondrial numbers in presynaptic terminals or total mitochondrial DNA, which is consistent with the view that SCZ is not a neurodegenerative disease. This is also consistent with our observations that Df(16)5+/− or Mrpl40+/− mice develop normally and have normal gross brain morphology. Mitochondria provide energy through oxidative phosphorylation and regulate Ca2+ dynamics during synaptic transmission in neurons. Because of the mitochondrion’s high capacity for Ca2+ uptake, it acts as a rapid buffering system during periods of intense synaptic activity, then slowly releases Ca2+ when activity subsides. This rapid uptake of Ca2+ into mitochondria occurs through channels (i.e. voltage-dependent anion channel VDAC1) in the outer membrane and the mitochondrial calcium uniporter in the inner membrane. Ca2+ is slowly released from the mitochondria through the calcium exchangers and via the mPTP. mPTP has been shown to open during high frequency stimulation in mammalian neurons, and that transient activation of the mPTP may play a role in the normal contribution of mitochondria to STP60. Oxidative phosphorylation appeared to be normal, whereas Ca2+ dynamics in presynaptic terminals was substantially altered in Df(16)5+/− and Mrpl40+/− mice. Our two-photon Ca2+ imaging in presynaptic terminals revealed that synaptic high frequency stimulation that induces STP evokes enhanced Ca2+ transients in both the presynaptic mitochondrial matrix and presynaptic cytosol of mutant mice. This data argues for a problem with mitochondrial Ca2+ extrusion rather than with mitochondrial Ca2+ uptake. Indeed, if Mrpl40 haploinsufficiency reduced the Ca2+ uptake into mitochondria, we would expect to see increased amplitudes of cytoplasmic Ca2+ transients but decreased Ca2+ transients within mitochondria. Our data is more consistent with a model for a reduced Ca2+ extrusion from mitochondria. Impaired Ca2+ extrusion from mitochondria will result in Ca2+ accumulation in the mitochondrial matrix and this will contribute to the fast rise in mitochondrial Ca2+ that we observed with mitoGCaMP6. This will then reduce the effective mitochondrial buffering capacity and lead to enhanced cytoplasmic Ca2+ transients that we observed with the cytoplasmic GCaMP6 (Fig. 5d). Moreover, slow Ca2+ extrusion from mitochondria (evident from extremely slow decay times of mitoGCaMP6) is an unlikely contributor to fast cytosol Ca2+ transients that occur during high frequency synaptic activity. Because inhibition of mPTP but not the mitochondrial Na+–Ca2+ exchanger increased presynaptic Ca2+ transients in WT mice, we concluded that the main route of Ca2+ extrusion from mitochondria during STP is mPTP. In WT mice, the pharmacological or molecular inhibition of mPTP with BKA or Slc25a4 shRNA, respectively, mimicked the STP and Ca2+-transient phenotypes we observed in Df(16)5+/− and Mrpl40+/− mice. Moreover, AAV-Slc25a4 OE rescued the STP abnormality in Mrpl40+/− mice, indicating that deletion of one allele of Mrpl40 causes mPTP deficiency and STP increase. Although our experiments demonstrated that Mrpl40 haploinsufficiency leads to abnormal Ca2+ handling by mitochondria during STP, the exact connection between Mrpl40 and mPTP function remains unclear. Some pharmacological agents that affect mPTP function61 can be beneficial adjuvants to antipsychotics to alleviate SCZ symptoms56. However, because mPTP8 is involved not only in Ca2+ extrusion from mitochondria but also in ATP transport, we cannot rule out the possibility that impaired mPTP regulation leads to the abnormal production of ATP in presynaptic terminals, which in turn could result in abnormal presynaptic function. This theory could be addressed using a novel ATP probe that visualizes ATP dynamics in the presynaptic terminals of neurons in culture, but those experiments have not yet been tailored for acute brain slices62. In summary, we report that haploinsufficiency of Mrpl40, a gene mapped within the 22q11.2 microdeletion associated with SCZ, causes deficient working memory. This behavioral abnormality, which typically manifests in patients with SCZ, is associated with abnormal STP changes in synaptic transmission in the hippocampus and caused by elevated presynaptic Ca2+ and impaired Ca2+ extrusion from mitochondria. Supplementary Material 1 This work was supported, in part, by National Institutes of Health grants R01 MH095810 and R01 MH097742 and by ALSAC. We thank Drs. Elizabeth Illingworth, Peter Scambler, and Mikio Furuse for providing Df(16)5+/−, Hira+/−, and Cldn5+/− mice; Sharon Frase, Randall Wakefield and staff in the Electron Microscopy Division of the St. Jude Cell and Tissue Imaging Center for help with electron microscopy; John Swift, Amber Braden, Lisa Emmons, and staff in the St. Jude Transgenic Core for help in producing mouse mutants; and staff in the St. Jude and University of Tennessee Vector Cores for producing the AAVs and lentiviruses. We also thank Jay Blundon for valuable comments and Angela McArthur and Vani Shanker for editing the manuscript. Figure 1 Abnormal synaptic plasticity in Df(16)5+/− mice is caused by Mrpl40 haploinsufficiency (a) Diagram depicting genes in the 22.q11.2 genomic region of the human chromosome 22 and the syntenic region of mouse chromosome 16. Red horizontal bar represents genomic regions hemizygously deleted in Df(16)5+/− mice and grey horizontal bar represents genomic regions hemizygously deleted in Df(16)1+/− mice. Note that 2510002D24Rik, Mrpl40, and Hira genes are mapped outside the Df(16)1 microdeletion. (b) Input–output relations in Df(16)5+/− and WT littermates. (c) STP (comprising facilitation, depression, and augmentation) induced by the high-frequency (80-Hz) train. The first time point represents an average of 5 baseline EPSCs delivered at low frequency. The top inset shows the protocol for measuring STP, recovery from depression, and augmentation in the same experiment. (d-f) Average facilitation tested by paired-pulse ratio in separate experiments (d), recovery from depression tested 5 s after the 80-Hz train (e), and augmentation tested 5 to 120 s after the 80-Hz train in Df(16)5+/− and WT mice (f). Insets show representative EPSC traces. (g,h) Mean STP of EPSCs induced by the 80-Hz train of synaptic stimulation of Schaffer collaterals (g) and augmentation (h) in Mrpl40+/− mice and their WT littermates. Numbers of neurons are shown in parentheses or inside columns. Data are represented as mean ± SEM. *p <0.05. Figure 2 Normal mitochondrial structure but abnormal presynaptic cytosolic and mitochondrial calcium regulation in Df(16)5+/− and Mrpl40+/− mice (a) Three representative TEM images of mitochondrial ultrastructure in the CA1 area of the hippocampus of WT and Df(16)5+/− mice. (b) Representative fluorescent image of mCherry after infection of the CA3 area with AAVs encoding either GCaMP6 or mitoGCaMP6. (c) Line scan of mCherry and GCaMP6 fluorescence in a CA3 presynaptic terminal before and after the 80-Hz stimulation of Schaffer collaterals (arrow). (d-g) Mean normalized cytosolic GCaMP6 (d, f) and mitoGCaMP6 (e, g) fluorescence in CA3 presynaptic terminals imaged in the CA1 area of the hippocampus, before and after 80-Hz stimulation in Df(16)5+/− and WT littermates (d, e) and Mrpl40+/− and WT littermates (f, g). (h, i) Normalized mean peak amplitudes of GCaMP6 (h) or mitoGCaMP6 (i) in Df(16)5+/− and WT littermates and Mrpl40+/− and WT littermates. Numbers of fluorescent puncta are shown inside columns. *P <0.05. Figure 3 Deficient working memory and normal long-term spatial memory, long-term synaptic plasticity, and acoustic startle in Mrpl40+/− mice (a, b) Mean maximal startle responses as a function of sound intensity (a) and prepulse inhibition (PPI) (b) in Mrpl40+/− and WT littermates. (c) The mean numbers of correct choices made in the delayed non–matched-to-position task by Mrpl40+/− and WT littermates. (d-f) Morris water maze tasks. Average time to find a submerged platform during the learning phase (d), time spent in quadrants during the probe test performed 24 h after the last learning session (e), and time to travel to a visible platform (f) in Mrpl40+/− and WT littermates. Abbreviations: AdL, adjacent left quadrant; AdR, adjacent right quadrant; Opp, opposite quadrant; Tg, target quadrant. (g) Average percentage of time spent in the novel arm in the novel-recognition version of the Y-maze task by Mrpl40+/− and WT mice. (h) Long-term potentiation at CA3–CA1 synapses measured as mean field EPSP (fEPSP) as a function of time before and after tetanization of Schaffer collaterals with 200-Hz trains (arrows) in Mrpl40+/− and WT mice. Dashed lines in c and g indicate the level of performance expected by chance. Numbers of mice or slices are shown in parentheses or inside columns. *P <0.05. Figure 4 The mPTP inhibitor BKA mimics the STP and calcium transient phenotypes of Df(16)5+/− and Mrpl40+/− mice (a-f) BKA effect on augmentation (a,d), peak GCaMP6 (b,e), and peak mitoGCaMP6 fluorescence intensities (c,f) in WT and Df(16)5+/− littermates (a-c) or WT and Mrpl40+/− littermates (normalized to WT levels) (d-f). Numbers of neurons or fluorescent puncta are shown inside columns. *P <0.05. Figure 5 The mPTP gain- or loss-of-function molecular manipulations rescue or mimic, respectively, the STP phenotypes of Mrpl40+/− mice (a) Overexpression of Slc25a4 and GFP in the CA3 area of the hippocampus. (b) Mean augmentation measured in sham- or Slc25a4-OE–injected WT and Mrpl40+/− mice. (c) Mean augmentation measured in control or Slc25a4 shRNA–injected WT and Mrpl40+/− mice. The data are shown for three different Slc25a4 shRNAs (shRNA1, shRNA2, shRNA3). Normalized to respective WT control levels. Numbers of neurons are shown inside columns. *P <0.05. (d) Model of mPTP-dependent mechanisms of STP dysfunction in 22q11DS. MRPL40 haploinsufficiency in 22q11DS reduces mitochondrial Ca2+ extrusion through impaired mPTP. This leads to a Ca2+ build-up in the mitochondrial matrix and enhanced Ca2+ transients in the mitochondrial matrix and cytosol during high-frequency activity, which in turn leads to enhanced synaptic vesicle release in presynaptic terminals. VGCC, voltage-gated calcium channels, NCX, Na+/Ca2+ exchanger, MCU, mitochondrial Ca2+ uniporter, VDAC1, voltage-dependent anion channel 1. Upper traces represent cytosolic Ca2+ transients (GCaMP6) and lower traces represent mitochondrial Ca2+ transients (mitoGCaMP6). Conflict of Interest The authors declare no conflict of interest. References 1 Carpenter WT Jr Buchanan RW Schizophrenia N. Engl. J. Med 1994 330 681 690 8107719 2 Nestler EJ Hyman SE Animal models of neuropsychiatric disorders Nat. Neurosci 2010 13 1161 1169 20877280 3 Scambler PJ The 22q11 deletion syndromes Hum. Mol. 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PMC005xxxxxx/PMC5114849.txt
LICENSE: This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. 0410462 6011 Nature Nature Nature 0028-0836 1476-4687 27383983 5114849 10.1038/nature18849 NIHMS822517 Article Interactions between the microbiota and pathogenic bacteria in the gut Bäumler Andreas J. 1 Sperandio Vanessa 23 1 Department of Medical Microbiology and Immunology, University of California, Davis, School of Medicine, Davis, California 95616, USA 2 Department of Microbiology, University of Texas Southwestern Medical Center, Dallas, Texas 75390-9048, USA 3 Department of Biochemistry, University of Texas Southwestern Medical Center, Dallas, Texas 75390-9038, USA Correspondence should be addressed to V.S. (vanessa.sperandio@utsouthwestern.edu) 13 10 2016 06 7 2016 06 7 2016 18 11 2016 535 7610 8593 This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. The microbiome has an important role in human health. Changes in the microbiota can confer resistance to or promote infection by pathogenic bacteria. Antibiotics have a profound impact on the microbiota that alters the nutritional landscape of the gut and can lead to the expansion of pathogenic populations. Pathogenic bacteria exploit microbiota-derived sources of carbon and nitrogen as nutrients and regulatory signals to promote their own growth and virulence. By eliciting inflammation, these bacteria alter the intestinal environment and use unique systems for respiration and metal acquisition to drive their expansion. Unravelling the interactions between the microbiota, the host and pathogenic bacteria will produce strategies for manipulating the microbiota against infectious diseases. Appreciation of the important role of the microbiota in human health and nutrition has grown steadily in the past decade. Initial studies focused on cataloguing the microbial species that comprise the microbiota and correlating the composition of the microbiota with the health or disease state of the host. The present period of renaissance has resulted in technologies and interdisciplinary research that are conducive to mechanistic studies and, in particular, those that focus on associations between the microbiota, the host and pathogenic bacteria. Exciting research is now starting to unravel how the composition of the microbiota can offer either resistance or assistance to invading pathogenic species. The majority of these studies were conducted in the gastrointestinal tract, in which associations between the host and microbes are of paramount importance. The gut microbiota of each individual is unique at the genus and species levels; however, it is more generally conserved at the phylum level, which is populated most prominently by Bacteroidetes and Firmicutes, followed by Proteobacteria and Actinobacteria. Host genetics, diet and environmental insults such as treatment with antibiotics alter the microbiota1–4, which can lead to varying susceptibility to infectious diseases between individuals5. The microbiota can promote resistance to colonization by pathogenic species6–9. For instance, mice that are treated with antibiotics or that are bred in sterile environments (known as germ-free mice) are more susceptible to enteric pathogenic bacteria such as Shigella flexneri, Citrobacter rodentium, Listeria monocytogenes and Salmonella enterica serovar Typhimurium10–13. And some microbiotas can lead to the expansion or enhanced virulence of pathogenic populations7. A notable example concerns how differences in the composition of microbiotas determine the susceptibility of the mice to infection with C. rodentium: the transplantation of microbiotas from strains of mice that are susceptible to infection induced similar susceptibility in animals that were previously insusceptible, and the transplantation of microbiotas from resistant animals led to resistance to infection in previously susceptible animals14,15. Epidemiological surveys reinforce this idea. For example, differential susceptibility to infection with Campylobacter jejuni was shown to depend on the species composition of the microbiotas in a study of Swedish adults16. Individuals with a higher diversity within their microbiotas, and with an abundance of bacteria from the genera Dorea and Coprococcus, were significantly recalcitrant to C. jejuni infection compared with people who had low-diversity microbiotas and non-abundance of Dorea and Coprococcus. The host’s diet profoundly affects the composition of the microbiota, with repercussions for the physiology, immunity and susceptibility to infectious diseases of the host17. Dietary choices have been shown to affect colonization by enterohaemorrhagic Escherichia coli (EHEC) serotype O157:H7 and the severity and length of its resulting disease18, and supplementation of the diet with phytonutrients promotes the expansion of beneficial Clostridia species that protect mice from colonization by C. rodentium19. The use of innovative technologies, in combination with more conventional approaches, is driving our understanding of the interactions between the microbiota, the host and pathogenic bacteria. The genetic tractability of several species of bacteria, as well as of their mammalian hosts (such as mice), allows for the mechanistic investigation of these relationships. The investigation of changes in the composition of microbiotas has been driven by next-generation sequencing, which also facilitated the analysis of transcriptomes. The growing power and finesse of metabolomics studies are quickly expanding our knowledge of the impact of both the microbiota and of pathogenic bacteria on the metabolic landscape of the gut. Here, we review advances in our understanding of the complex relationships that determine the severity and outcome of gastrointestinal infections. The majority of the mechanistic studies that investigate these interactions have been conducted in S. Typhimurium, EHEC and Clostridium difficile: therefore, these pathogenic organisms are covered more extensively than others in this Review. Antibiotics Antibiotics revolutionized medicine and were justifiably dubbed ‘magic bullets’ against bacterial infections. However, conventional antibiotics are generally bacteriostatic or bactericidal, which means that they indiscriminately kill or prevent the growth of both pathogenic and beneficial microbes. Antibiotics can alter the taxonomic, genomic and functional features of the microbiota, and their effects can be rapid and sometimes everlasting20. They can decrease the diversity of the microbiota, which compromises resistance to colonization by incoming pathogenic bacteria20 — most notably leading to an expansion of C. difficile that can cause diarrhoea that leads to potentially fatal colitis21. C. difficile is a spore-forming bacterium that, on germination, colonizes the large intestine and causes colitis through the action of two toxins: TcdA and TcdB. The majority of C. difficile infections are nosocomial, but there has also been an increase in community-acquired infections, mainly due to the ubiquitous presence of C. difficile spores. C. difficile can colonize the mammalian intestine without causing disease, but one of the most important risk factors for colitis that is mediated by C. difficile is the use of antibiotics21. The antibiotics-mediated loss of resistance to colonization also allows colonization by S. Typhimurium and the development of disease22. Both C. difficile and S. Typhimurium catabolize sialic acid as a source of carbon in the lumen to promote their expansion23. They rely on saccharolytic members of the microbiota, such as Bacteroides thetaiotaomicron, to make this sugar freely available in the intestinal lumen. Treatment with antibiotics increases the abundance of host-derived free sialic acid as well as enhancing its release into the lumen by B. thetaiotaomicron, which promotes the expansion of the two pathogenic bacteria23. Antibiotic use also triggers production of the organic acid succinate, another microbiota-derived nutrient that confers a growth advantage to C. difficile. It is often present at a low concentration in the microbiotas of conventional mice, but its presence increases on treatment with antibiotics, which promotes a bloom of C. difficile24 (Fig. 1). Knowledge of how microbiota disruption affects the ability of bona fide or opportunistic pathogenic organisms to infect hosts is still in its infancy. However, two underlying themes converge: microbiota-induced changes in the metabolite landscape of the gut and inflammation. Utilization of nutrients Simple dietary sugars are absorbed in the small intestine, which means that they are unavailable as sources of carbon for the microbiota and pathogenic bacteria in the colon. The most abundant members of the microbiota are those that are able to utilize the undigested plant polysaccharides and host glycans that are present in the colon25. The gut epithelium is protected by a layer of mucus that is composed of proteins known as mucins that are rich in fucose, galactose, sialic acid, N-acetylgalactosamine, N-acetylglucosamine and mannose. These sugars are harvested by saccharolytic members of the microbiota, such as Bacteroidales in the gut, which makes them available to species within the microbiota that lack this capability26. However, pathogenic bacteria in the gut can also exploit the availability of these sugars to promote their own expansion. Several studies have used B. thetaiotaomicron as a model Bacteroides in which to investigate these syntrophic links. Sialic acid is a terminal sugar of some mucosal glycans, and B. thetaiotaomicron has sialidase activity but lacks the catabolic pathway for sialic-acid utilization. The bacterium therefore releases sialic acid to gain access to underlying glycans that it can use as a source of carbon. The sialic acid that B. thetaiotaomicron releases from the mucus can be catabolized by both C. difficile and S. Typhimurium, which provides them with a growth advantage23. The ability of the microbiota to use sialic acid therefore depends on the action of B. thetaiotaomicron, and mutants that lack sialidase fail to enhance the growth of these two pathogenic bacteria23. B. thetaiotaomicron also releases fucose from the mucus. It harbours multiple enzymes that can cleave fucose from host glycans, so its presence results in the high availability of fucose in the lumen of the gut27–30. This free fucose can also be used as a source of carbon by S. Typhimurium23. Importantly, B. thetaiotaomicron can promote the fucosylation of mucosal glycans when introduced into monoassociated germ-free mice31,32. The microbiota resides in the lumen and the outer mucus layer of the intestine. EHEC, however, aims to achieve a unique niche by closely adhering to the enterocytes of the intestinal epithelium. To achieve its goal, EHEC must successfully compete with the microbiota for nutrients. B. thetaiotaomicron does not need to compete with EHEC, however, because it can utilize polysaccharides; EHEC can only utilize monosaccharides and disaccharides13,33. EHEC’s main competitors are commensal E. coli, which preferentially utilizes fucose as a source of carbon when growing in the mammalian intestine13,33. To circumvent this competition, EHEC utilizes other sources of sugar, such as galactose, the hexuranates, mannose and ribose, which commensal E. coli cannot catabolize optimally33,34 (Fig. 2). EHEC uses fucose as a signalling molecule with which to adjust its metabolism and to regulate the expression of its virulence repertoire in the lumen and the outer mucus layer of the colon35. It horizontally acquired a pathogenicity island of genes that encode a fucose-sensing signalling-transduction system35. This system is unique to EHEC and to C. rodentium35 (which is used extensively in mouse models as a surrogate for the human pathogen EHEC36). It is composed of the membrane-bound histidine sensor kinase FusK, which specifically autophosphorylates in response to fucose. FusK then transfers its phosphate to a response regulator called FusR, which is a transcription factor. Phosphorylation activates FusR, which represses the expression of the fucose utilization genes in EHEC, and helps EHEC to avoid the need to compete for this nutrient with commensal E. coli35. To prevent the unnecessary expenditure of energy by EHEC, FusR represses the genes that encode the EHEC virulence machinery, a syringe-like apparatus known as a type III secretion system (T3SS), which the bacterium uses to adhere itself to enterocytes and highjack the function of these host cells35. EHEC therefore uses fucose, a host-derived signal that is made available by the microbiota, to sense the environment of the intestinal lumen and to modulate its own metabolism and virulence. To reach the lining of the epithelium, EHEC and C. rodentium produce mucinases37, which cleave the protein backbone of mucin-type glycoproteins. Expression of these enzymes is increased by metabolites that are produced by B. thetaiotaomicron38. Because mucus is one of the main sources of sugar in the colon, where EHEC and C. rodentium colonize, obliteration of the mucus layer creates a nutrient-poor environment near the epithelium that is referred to as gluconeogenic. The colonization of mice by B. thetaiotaomicron therefore profoundly changes the metabolic landscape of the mouse gut because it raises the levels of organic acids such as succinate24,38,39. Moreover, several metabolites that indicate a gluconeogenic environment, such as lactate and glycerate, are also elevated38. EHEC and C. rodentium sense this gluconeogenic and succinate-rich environment through the transcriptional regulator Cra. On receiving the cue that they have reached the lining of the gut epithelium, these bacteria activate the expression of their T3SSs38. EHEC therefore exploits metabolic cues from B. thetaiotaomicron, and probably other members of the microbiota, to precisely programme its metabolism and virulence (Fig. 2). Other pathogenic bacteria can also adjust their gene expression in the presence of microbiota-produced succinate. C. difficile induces a pathway that converts succinate to butyrate, which confers a growth advantage in vivo24. Populations of C. difficile mutants that are unable to convert succinate fail to expand in the gut in the presence of B. thetaiotaomicron24. Several short-chain fatty acids that are produced by the microbiota, are important determinants of interactions between the microbiota and pathogenic bacteria in the gut. The abundance and composition of short-chain fatty acids is distinct in each compartment of the intestine, and the ability to sense these differences might help pathogenic bacteria in niche recognition. The most abundant short-chain fatty acids in the gut are acetate, propionate and butyrate. S. Typhimurium preferably colonizes the ileum40, which generally contains acetate at a concentration of 30 mM. This acetate concentration enhances the expression of the S. Typhimurium Salmonella pathogenicity island 1 (SPI-1)-encoded T3SS (T3SS-1), which is involved in the bacterium’s invasion of the host. Conversely, 70 mM propionate and 20 mM butyrate, concentrations typical of the colon, suppress the expression of the T3SS-1 (ref. 41). Propionate and butyrate seem to affect the T3SS-1 regulatory cascade at various levels. However, the detailed mechanism of this regulation is yet to be unravelled. In EHEC, exposure to the levels of butyrate found in the colon increases the expression of the EHEC T3SS through post-transcriptional activation of the transcriptional regulator Lrp42. Exposure to the concentrations of acetate and propionate that are found in the small intestine does not significantly affect the virulence of EHEC. Diet has a profound effect on the composition of the microbiota and the concentration of short-chain fatty acids in the gut17. A diet that is high in fibre results in the enhanced production of butyrate by the gut microbiota. That increases the host’s expression of globotriaosylceramide, which is a receptor for the Shiga toxin that is produced by EHEC18. Shiga toxin can lead to the development of haemolytic uraemic syndrome (HUS) and is the cause of the morbidity and mortality associated with outbreaks of EHEC43. Consequently, animals that are fed a high-fibre diet are more susceptible to Shiga toxin than are those on a low-fibre diet and develop more severe disease18. Conversely, increased levels of microbiota-derived acetate protect animals from disease that is caused by the toxin. Certain species of Bifidobacteria contribute to higher levels of acetate in the gut, which helps to improve the barrier function of the intestinal epithelium and to prevent Shiga toxin from reaching the bloodstream44. Enteric pathogenic bacteria also use other nutrients to successfully overcome the microbiota’s resistance to their colonization. Ethanolamine is abundant in the mammalian intestine45. It can be used as a source of carbon and of nitrogen by a number of pathogenic species46, and food-borne bacteria are particularly adept at using it. However, it cannot be metabolized by the majority of commensal species47. S. Typhimurium, EHEC and L. monocytogenes gain a growth advantage in the intestine through their ability to use this compound45,48,49. Ethanolamine is also used as a signal by EHEC and S. Typhimurium to activate the expression of virulence genes50,51. And S. Typhimurium uses hydrogen produced by the microbiota as an energy source to enhance its growth during the initial stage of infection52. The exploitation of microbiota-derived molecules as both nutrients and signals is crucial for the successful infection of the host by pathogenic bacteria. Although such organisms have clearly developed many strategies through which to circumvent the microbiota’s resistance to colonization, and in many cases even employ its help, the microbiota pushes back, which creates an intense competition for resources. The ability of EHEC to colonize the intestine stems from differences in the sources of sugar that are used by EHEC and by commensal E. coli. For example, the presence of multiple strains of commensal E. coli with overlapping nutritional requirements interferes with the colonization of the mouse intestine by EHEC53. This study uses a streptomycin-treated mouse model of EHEC and three distinct commensal strains of E. coli to assess differential sugar requirements for the successful colonization of the intestines53. EHEC could colonize mice that were pre-colonized with any one of the commensal strains, but it could not colonize mice that were pre-colonized with all three strains53. EHEC has evolved to exploit distinct sources of sugar during colonization of the gut. It utilizes catabolic pathways for the hexuronates glucuronate and galacturonate and for sucrose that are not employed by commensal E. coli within the gut33,53. It can also metabolize several sugars simultaneously. The loss of multiple catabolic pathways has an additive effect on colonization. This phenomenon is not observed in commensal E. coli, however, which suggests that E. coli uses available sugars in a stepwise fashion54. EHEC therefore differs from commensal E. coli in metabolic strategy and the use of nutrients for the colonization of the mammalian intestine. C. rodentium is outcompeted and then cleared from the mouse gut through a bloom in the population of commensal E. coli, which competes with C. rodentium for monosaccharides for nutrition13. By contrast, C. rodentium is not cleared by B. thetaiotaomicron in germ-free mice that are fed a diet that contains both monosaccharides, which can be used by Enterobacteriacae such as C. rodentium, and polysaccharides, which can be used by Bacteroides. However, when the mice are switched to a diet that consists only of monosaccharides, B. thetaiotaomicron and C. rodentium are forced to compete for sugars, and B. thetaiotaomicron outcompetes C. rodentium13. The ability of pathogenic bacteria to successfully compete with commensal species for nutrients is therefore important for their establishment in the gut. Interception of signals from the microbiota and the host The microbiota affects the risks and courses of enteric diseases. Vibrio cholerae is a major cause of explosive diarrhoea in which there is extensive disruption of the intestinal population of microbes. Metagenomic studies of the faecal microbiota of people with cholera in Bangladesh show that recovery is characterized by a certain microbiota signature. Reconstitution of this microbiota in germ-free mice restricts the infectivity of V. cholerae. Specifically, the presence of Ruminococcus obeum can hamper the colonization of the intestines by V. cholerae through the production of the furanone signal autoinducer-2, which causes the repression of several V. cholerae colonization factors55. Another example of the effect of microbiota-derived signals on host colonization is their use by EHEC in the colonization of its ruminal reservoir. EHEC exclusively colonizes the recto–anal junction of adult cattle. Through the sensor protein SdiA, EHEC detects acyl-homoserine lactone signals from the rumen microbiota, which it uses to reprogram itself to survive the acidic pH of the animal’s stomachs and to successfully colonize the rectoanal junction56. As well as being able to directly detect signals that are derived from the microbiota, pathogenic bacteria can detect host-derived signals that have been modified by the microbiota to modulate their virulence. V. cholerae has a type VI secretion system (T6SS), which it uses to kill other bacteria. During its colonization of the intestine, V. cholerae comes in contact with the mucosal microbiota, which can affect the composition of bile acids in the intestine. For example, Bifidobacterium bifidum negatively regulates the T6SS activity of V. cholerae through the metabolic conversion of three bile acids (glycodeoxycholic acid, taurodeoxycholic acid and cholic acid) into the bile acid deoxycholic acid. Deoxycholic acid, but not its unmodified salts, decreases the expression of T6SS genes. This leads to a decrease in the killing of E. coli by V. cholerae owing to bile-acid conversion by other commensals, which decreases the activity of the T6SS57. Another microbiota-modified host signal that is detected by pathogenic bacteria is the neurotransmitter noradrenaline. The gut is highly innervated, and neurotransmitters are important signals in the gastrointestinal tract, where they modulate peristalsis, the flow of blood and the secretion of ions58. The microbiota affects the availability of neurotransmitters in the intestinal lumen, as well as their biosynthesis. For example, the microbiota induces biosynthesis of serotonin59, and microbiota-derived enzymatic activities increase the levels of active noradrenaline in the gut lumen60. Noradrenaline is synthesized by the adrenergic neurons of the enteric nervous system61 and it is inactivated by the host through conjugation with glucuronic acid (to produce a glucuronide). Microbiota-produced enzymes known as glucuronidases then deconjugate glucuronic acid from noradrenaline, which increases the amount of active noradrenaline in the lumen of the intestine60. Several pathogenic bacteria of the gut, including EHEC, S. Typhimurium and V. parahaemolyticus, sense noradrenaline to activate the expression of virulence genes62–65. Two adrenergic sensors have been identified in bacteria: the membrane-bound histidine kinases QseC and QseE66,67. QseC also detects the microbiota-produced signal autoinducer-3 (refs 64 and 66), so the sensing of signals from both the host and the microbiota converge at the level of a single receptor, a process known as inter-kingdom signalling. Inflammation Although diet and the composition of the microbiota heavily influence the availability of nutrients in the gut, the host also has an important part to play. A crucial driver of changes in the gut environment is the inflammatory response of the host. Intestinal inflammation in people is associated with an imbalance in the microbiota, known as dysbiosis, and is characterized by a reduced diversity of microbes, a reduced abundance of obligate anaerobic bacteria and an expansion of facultative anaerobic bacteria in the phylum Proteobacteria, mostly members of the family Enterobacteriaceae68–73. Similar changes in the composition of the gut microbiota are observed in mice with chemically induced colitis74 and genetically induced colitis75. These changes in the structure of the microbiota probably reflect an altered nutritional environment that is created by the inflammatory response of the host. The availability of nutrients in the large intestine is altered during inflammation through changes in the composition of mucous carbohydrates. Interleukin (IL)-22, a cytokine that is prominently induced in the intestinal mucosa when mice and rhesus macaques are infected with S. Typhimurium76,77, stimulates the epithelial expression of galactoside 2-α-L-fucosyltransferase 2 and enhances the α(1,2)-fucosylation of mucus carbohydrates78,79. The gut microbiota can liberate fucose from mucus carbohydrates23,80, which leads to the induction of genes for fucose utilization in E. coli78. Similarly, increased fucosylation of glycans is observed during S. Typhimurium-induced colitis in mice, which correlates with elevated synthesis of the proteins involved in fucose utilization81. Mucus fucosylation that is induced during infection with C. rodentium causes changes in the composition of the gut microbiota that help to protect the host from the expansion and epithelial translocation of the pathobiont Enterococcus faecalis79. Another driver of changes in the nutritional environment of the gut is the generation of reactive oxygen species and reactive nitrogen species during inflammation. Pro-inflammatory cytokines such as interferon-γ (IFN-γ) activate dual oxidase 2 in the intestinal epithelium, which produces hydrogen peroxide82. Increased expression of DUOX2, the gene that encodes dual oxidase 2, in the intestinal mucosa of patients with Crohn’s disease and ulcerative colitis correlates with an expansion of Proteobacteria in the gut microbiota83. IFN-γ also induces epithelial expression of the gene Nos2 (ref. 84), which encodes inducible nitric oxide synthase, the enzyme that catalyses the production of nitric oxide from L-arginine85. As a result, the concentration of nitric oxide is elevated in gases from the colons of people with inflammatory bowel disease86–88. Although reactive oxygen and nitrogen species have antimicrobial activity, these radicals quickly form non-toxic compounds in the lumen of the gut as they diffuse away from the epithelium. For example, when they are generated during inflammation by host enzymes in the intestinal epithelium, these species react to form nitrate89. This by-product of inflammation is present at elevated concentrations in the intestines of mice with chemically induced colitis90 (Fig. 3). Nitrate reductases, enzymes that are broadly conserved among the Enterobacteriaceae, couple the reduction of nitrate to energy-conserving electron transport systems for respiration, a process termed nitrate respiration. However, the genes that encode them are absent from the genomes of obligate anaerobic Clostridia or Bacteroidia91. Nitrate respiration drives the Nos2-dependent expansion of commensal E. coli in mice with chemically or genetically induced colitis, but not in animals without signs of intestinal inflammation91. Respiratory electron acceptors that are generated as a by-product of the host inflammatory response therefore create a niche in the lumen of the intestines that supports the uncontrolled expansion of commensal Enterobacteriaceae rather than of obligate anaerobic bacteria91. The resulting bloom in the inflamed intestine is one of the most consistent and robust ecological patterns that has been observed in the gut microbiota92. The creation of a niche for respiratory nutrients during inflammation is also an important driver of the strategies that pathogenic bacteria from the family Enterobacteriaceae use to invade the gut ecosystem. In the absence of inflammation or treatment with antibiotics, members of the gut microbiota occupy all available nutrient niches, which makes it very challenging for pathogenic Enterobacteriaceae to enter the community. One solution is for these bacteria to trigger intestinal inflammation, which would coerce the host into creating a fresh niche of respiratory nutrients that is suitable for its expansion — an approach that is used by S. Typhimurium93. On ingestion, S. Typhimurium uses T3SS-1 to invade the intestinal epithelium94 and T3SS-2 to survive in the tissue of the host95. Both of these processes trigger acute intestinal inflammation in cattle and in mouse models of gastroenteritis96–98 (Fig. 3). The inflammatory response of the host drives the expansion of S. Typhimurium in the lumen of the gut99, which is required for the transmission of this pathogenic species to a new host through the faecal–oral route100. Although such expansion allows S. Typhimurium to side-step competition with obligate anaerobic Clostridia and Bacteroidia, this strategy forces the bacterium into battle with commensal Enterobacteriaceae over limited resources. For example, S. Typhimurium expands in the inflamed gut through nitrate respiration101,102, which results in rivalry with commensal Enterobacteriaceae that pursue a similar strategy91. S. Typhimurium can gain an edge in this competition through its ability to utilize a broader range of inflammation-derived electron acceptors than its rivals. A source of one such electron acceptor is sulfate-reducing species of Desulfovibrio from the microbiota, which release hydrogen sulfide, a compound that is converted to thiosulfate by the epithelium of the colon to avoid toxicity103. Deployment of the virulence factors of pathogenic bacteria leads to the recruitment of neutrophils to the intestinal mucosa, which is the histopathological hallmark of S. Typhimurium-induced gastroenteritis96. A fraction of these recruited neutrophils migrate into the lumen of the intestine — a diagnostic marker of inflammatory diarrhoea104. In the lumen, neutrophils help to protect the mucosa by engulfing bacteria in the vicinity of the epithelium105, but reactive oxygen species that are generated by the phagocyte-produced NADPH oxidase 2 (also known as cytochrome b-245 heavy chain) convert thiosulfate into tetrathionate, a respiratory electron acceptor that supports the expansion of S. Typhimurium in the lumen of the inflamed gut106 (Fig. 3). Although tetrathionate respiration is a characteristic of Salmonella serovars and has been used empirically in their isolation in clinical microbiology laboratories since 1923 (ref. 107), insights into the respiratory nutrient niche that Salmonella occupies suggest that this property is part of a strategy to edge out competing commensal Enterobacteriaceae in the inflamed gut106. The inflammatory response of the host also ignites competition between commensal and pathogenic Enterobacteriaceae over trace elements such as iron, which is less available during inflammation. IL-22 induces the release of the antimicrobial protein lipocalin-2 (also known as neutrophil gelatinase-associated lipocalin) from the epithelium in mice and rhesus macaques108,109. Lipocalin-2 reduces iron availability by binding to enterobactin, a low-molecular-weight iron chelator (or siderophore) that is produced by Enterobacteriaceae110,111. To overcome this, S. Typhimurium and some commensal E. coli secrete a glycosylated derivative of enterobactin, termed salmochelin, which is not bound by lipocalin-2 (ref. 108). By producing salmochelin as well as two further siderophores that are not bound by lipocalin-2, yersiniobactin and aerobactin, the probiotic E. coli strain Nissle 1917 can limit the expansion of S. Typhimurium in the lumen of the inflamed gut112. Conversely, lipocalin-2 secretion by the epithelium generates an environment that enables S. Typhimurium to edge out commensal Enterobacteriaceae that depend solely on enterobactin for the acquisition of iron109 (Fig. 3). Through its limitation of iron availability, intestinal inflammation also sets the stage for battles between Enterobacteriaceae that use protein-based toxins known as colicins113 that affect a narrow range of hosts. Iron limitation induces the synthesis of siderophore receptor proteins for the bacterial outer membrane113, which also commonly serve as receptors for colicins114–116. Expression of a siderophore receptor protein termed the colicin I receptor (CirA) confers commensal E. coli with sensitivity to colicin Ib produced by S. Typhimurium113. The respiratory nutrient niche that is generated by the inflammatory response of the host is therefore a battleground on which commensal and pathogenic Enterobacteriaceae struggle for dominance using a diverse arsenal of nutritional and antimicrobial strategies. Perspective and the future The study of the microbiome began more than a century ago. equencing of 16S rRNA genes provided the first insights into the taxonomic composition of microbial communities. Later, sequencing of the complete metagenome of microbial communities provided a more detailed insight into the full genetic capacity of such a community. The use of germ-free animals, either alone or in combination with emerging technologies such as laser-capture microdissection and transcriptomics, enabled mechanistic studies of the associations between the microbiota, the host and pathogenic bacteria117. Multi-taxon insertion sequencing now allows researchers to investigate both the assembly and the shared and strain-specific dietary requirements of communities of microbes, and it has also facilitated the informed manipulation of such communities through diet118. The development of quantitative imaging technologies has provided insight into the localization of microbes within the gastrointestinal tract, and it has also enabled studies on the proximity of and interactions between microbes119. The increasing refinement and power of metabolomics, imaging mass spectrometry and three-dimensional mapping of mass-spectrometry data provide a high-resolution image of the complex chemistry landscape of the interactions between microbes and the host, which sets the stage for manipulating this chemistry to prevent or treat infectious diseases24,38,120–127. A marriage of metagenomics and mathematical modelling promises to enhance the precision of microbiome reconstitution, which has proven successful for tackling C. difficile infections in mice128. In these exciting times, the expansion of multidisciplinary research is rapidly generating new technologies and mechanistic insights into interactions between the microbiota, the host and pathogenic bacteria (Box 1). BOX 1 Microbiota interventions as therapeutic strategies to limit pathogen expansion An imbalance in the gut microbiota might underlie many human diseases but, in most cases, the development of treatment options is still in its infancy. This could be in part because the mechanisms that lead to adverse effects in the host differ for each disease, which means that intervention strategies must be developed for each. The treatment options for antibiotic-induced dysbiosis are perhaps the most advanced, mainly because faecal microbiota transplantation can reverse this imbalance in the gut microbiota129. Nonetheless, the mechanisms through which treatment with antibiotics encourages an uncontrolled expansion of the obligate anaerobe C. difficile differ markedly from those that stimulate the growth of the facultative anaerobes Enterobacteriaceae, which has implications for the development of precision microbiome interventions. Mice that are treated with streptomycin have a reduced abundance of members of the class Clostridia130, which are credited with producing the lion’s share of the short-chain fatty acid butyrate in the large intestine131. The resulting depletion of short-chain fatty acids drives an expansion of Enterobacteriaceae through mechanisms that are not fully resolved44,132. Depletion of Clostridia-derived butyrate affects the metabolism of enterocytes in the colon, which derive most of their energy by butyrate respiration133. The depletion of short-chain fatty acids also leads to a contraction in the pool of regulatory T cells in the colonic mucosa134–136. These changes in the host physiology increase the inflammatory tone of the mucosa, as indicated by the elevated expression of Nos2, the gene that encodes inducible nitric oxide synthase, and contributes to the expansion of commensal E. coli through nitrate generation137. Although other mechanisms probably contribute to the post-antibiotic expansion of certain populations of bacteria in the gut126, the transfer of Clostridia, with their capacity for producing short-chain fatty acids, represents the most effective treatment for limiting the growth of E. coli in streptomycin-treated mice138. By contrast, the post-antibiotic expansion of the C. difficile population is driven by a depletion of secondary bile salts. The liver produces the primary bile salts cholate and chenodeoxycholate, which are conjugated to the amino acids taurine (to produce taurocholate and taurochenodeoxycholate) or glycine (to produce glycocholate and glycochenodeoxycholate) and then secreted into the gut. Bile salt hydrolases, enzymes that are produced by many members of the gut microbiota, remove the conjugated amino acid from the primary bile salt. C. scindens is one of a limited number of species of bacteria that can actively transport cholate and chenodeoxycholate into its cytosol, where these unconjugated primary bile salts are converted into the secondary bile salts deoxycholate and lithocholate, which are subsequently secreted into the extracellular environment139 (Box Fig.). Although both primary and secondary bile salts induce the germination of C. difficile spores, only secondary bile salts efficiently prevent the growth of vegetative C. difficile cells140. By significantly reducing the abundance of species that are capable of producing deoxycholate and lithocholate, treatment with antibiotics causes a depletion of these secondary bile salts and promotes the expansion of vegetative C. difficile cells in the large intestine141,142. Faecal microbiota transplantation restores the production of secondary bile salts and therefore prevents the expansion of C. difficile143. Direct supplementation of the diet with secondary bile salts warrants caution because increased concentrations of bile salts have been linked to gastrointestinal cancers144. However, inoculation with only the secondary-bile-salt-producing C. scindens confers mice with resistance to C. difficile expansion following treatment with antibiotics128. This remarkable observation opens the door to novel precision microbiome interventions that aim to prevent or treat the colitis that is associated with C. difficile infection after antibiotic therapy. Work in the V.S. laboratory is supported by US National Institutes of Health (NIH) grants AI053067, AI077613, AI05135 and AI114511. Work in the A.J.B. laboratory is supported by US Department of Agriculture grant 2015-67015-22930 and NIH grants AI044170, AI096528, AI112445, AI114922 and AI117940. The contents of this Review are solely the responsibility of the authors and do not necessarily represent the official views of the NIH National Institute of Allergy and Infectious Diseases. Figure 1 The impact of antibiotics on the microbiota and the expansion of enteric pathogens a, A diverse and non-disturbed microbiota confers resistance to colonization by enteric pathogens in the intestinal epithelium. b, Treatment with antibiotics decreases the diversity of the microbiota and leads to expansion of the C. difficile population. Toxins that are released from C. difficile (TcdA and TcdB) enter and damage the cells of the epithelium, which leads to inflammation (colitis) and cell death. c, Treatment with antibiotics also leads to an increase in the levels of free sialic acid (from the host) and succinate (from the microbiota) in the lumen of the intestine. Elevated sialic acid promotes the expansion of the S. Typhimurium population, which can lead to inflammation (gastroenteritis) if the bacterium invades the cells of the intestinal epithelium. Elevated levels of sialic acid and succinate further promote the expansion of the C. difficile population and the development of colitis and cell death. Figure 2 Modulation of enterohaemorrhagic E. coli virulence through nutrients provided by the microbiota a, The microbiota resides in the lumen and outer mucus layer of the intestine. The saccharolytic bacterium Bacteroides thetaiotaomicron is a prominent member of the microbiota. It can release fucose from the mucus and makes the sugar available to other bacteria. When EHEC senses fucose through the FusKR signalling system, it represses both its use of the sugar and the expression of genes that encode the T3SS, a protein-translocation apparatus that enables the bacterium to secrete effector proteins into host cells. This repression prevents EHEC from competing for fucose with commensal E. coli and from expending energy unnecessarily on T3SS expression. b, Metabolites that are provided by B. thetaiotaomicron, such as succinate, lead to an increase in the expression by EHEC of the enzyme mucinase, which obliterates the mucus layers of the intestine. EHEC is then able to reach the intestinal epithelium. B. thetaiotaomicron then begins to secrete succinate and other metabolites that are required for gluconeogenesis into the now nutrient-poor environment. The compounds are sensed by EHEC, which upregulates its expression of the T3SS to enable the bacterium to attach to the epithelial cells of the host intestine and form lesions that cause diarrhoea. Figure 3 The effect of intestinal inflammation on nutrient availability S. Typhimurium uses its virulence factors (T3SS-1 and T3SS-2) to trigger intestinal inflammation. Cytokines that are released during inflammation, such as IL-22 and IFN-γ, trigger the release of antimicrobial molecules lipocalin-2, reactive oxygen species (ROS) and reactive nitrogen species (RNS) from the intestinal epithelium. Lipocalin-2 can block the growth of commensal Enterobacteriaceae that rely on the siderophore enterobactin for the acquisition of iron (Fe3+). It does not bind to the S. Typhimurium siderophone salmochelin, however, which confers the bacterium with resistance to its effects on growth. RNS and ROS react to form nitrate, which drives the growth of Enterobacteriaceae through nitrate respiration. Microbiota-derived hydrogen sulfide is converted to thiosulfate by colonic epithelial cells. Neutrophils that migrate into the lumen of the intestine during inflammation generate ROS that convert endogenous sulfur compounds (thiosulfate) into an electron acceptor (tetrathionate) that further boosts the growth of S. Typhimurium through tetrathionate respiration. The authors declare no competing financial interests. 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PMC005xxxxxx/PMC5114884.txt
LICENSE: This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. 2985117R 4816 J Immunol J. Immunol. Journal of immunology (Baltimore, Md. : 1950) 0022-1767 1550-6606 27815424 5114884 10.4049/jimmunol.1601279 EMS70109 Article Activating KIR2DS4 is expressed by uterine NK cells and contributes to successful pregnancy1 Kennedy Philippa R. *#¶ Chazara Olympe *# Gardner Lucy *# Ivarsson Martin A. *# Farrell Lydia E. *# Xiong Shiqiu *#║ Hiby Susan E. *# Colucci Francesco #§ Sharkey Andrew M. *# Moffett Ashley *# * Department of Pathology, University of Cambridge, Cambridge CB2 1QP, United Kingdom # Centre for Trophoblast Research, University of Cambridge, Downing Street, Cambridge CB2 3EG, United Kingdom ¶ Manchester Collaborative Centre for Inflammation Research, University of Manchester, 46 Grafton Street, Manchester M13 9NT, United Kingdom ║ Department of Molecular and Cell Biology, University of Leicester, Leicester LE1 7RH, United Kingdom § Department of Obstetrics and Gynaecology, University of Cambridge School of Clinical Medicine, NIHR Cambridge Biomedical Research Centre, Addenbrooke’s Hospital, Box 111, Hills Road, Cambridge CB2 0SP, United Kingdom. Phone Number +441612751536, Fax Number +441612755082, philippa.kennedy@manchester.ac.uk, am485@cam.ac.uk 16 11 2016 4 11 2016 1 12 2016 01 6 2017 197 11 42924300 This file is available to download for the purposes of text mining, consistent with the principles of UK copyright law. Tissue-specific Natural Killer (NK) cells are abundant in the pregnant uterus and interact with invading placental trophoblast cells that transform the maternal arteries to increase the feto-placental blood supply. Genetic case-control studies have implicated Killer-cell Immunoglobulin-like Receptor (KIR)2 genes and their Human Leukocyte Antigen (HLA) ligands in pregnancy disorders characterized by failure of trophoblast arterial transformation. Activating KIR2DS1 or KIR2DS5 (when located in the centromeric region as in Africans) lower the risk of disorders when there is a fetal HLA-C allele carrying a C2 epitope. Here, we investigate another activating KIR, KIR2DS4, and provide genetic evidence for a similar effect when carried with KIR2DS1. KIR2DS4 is expressed by ~45% of uterine NK cells (uNK)3. Similarly to KIR2DS1, triggering of KIR2DS4 on uNK led to secretion of GM-CSF and other chemokines, known to promote placental trophoblast invasion. In addition, XCL1 and CCL1, identified in a screen of 120 different cytokines, were consistently secreted upon activation of KIR2DS4 on uNK. Inhibitory KIR2DL5A, carried in linkage disequilibrium with KIR2DS1, is expressed by peripheral blood NK cells (pbNK)4 but not by uNK cells, highlighting the unique phenotype of uNK compared to pbNK. That KIR2DS4, KIR2DS1 and some alleles of KIR2DS5 contribute to successful pregnancy suggests that activation of uNK by KIR binding to HLA-C is a generic mechanism promoting trophoblast invasion into the decidua. Introduction Natural Killer (NK) cells use a combination of activating and inhibitory receptors to recognise viruses and cancerous cells (1). That the same receptors are also used to recognise fetal cells by tissue-specific uterine NK cells (2) indicates two strong contrasting evolutionary pressures: disease resistance and successful reproduction, both showing evidence of balancing selection (3, 4). NK cells in the pregnant uterus, decidual NK cells (dNK)5, are different phenotypically and functionally from peripheral blood NK cells (pbNK)6 (5–10). Evidence from genetic and functional studies suggests that dNK regulate trophoblast transformation of the uterine spiral arteries necessary for increasing the blood supply to the feto-placental unit until the end of gestation (11–14). The NK cell receptors particularly implicated in reproductive health are the highly polymorphic Killer-Cell Immunoglobulin-like Receptor family (KIR)7 (15). A KIR genotype is made up of two KIR haplotypes that can differ by both gene content and allelic variation. The genes in these haplotypes are so densely clustered on chromosome 19 that they are generally inherited as haplotypic centromeric and telomeric blocks (16, 17) (Figure 1A). The dominant ligands for KIR are HLA-C allotypes. All individuals have KIR that will bind to HLA-C allotypes as two groups depending on the C1 or C2 epitope that they bear. There is an increased risk of pregnancy disorders with certain inhibitory maternal KIR and fetal HLA-C combinations. Case-control genetic studies of Europeans have shown that pregnancy disorders that result from defective placentation with inadequate trophoblast arterial transformation (eg pre-eclampsia, fetal growth restriction, FGR and recurrent miscarriage, RM) are linked to an absence of the telomeric-B (Tel-B)8 KIR region in the mother (Figure 1A) and the presence of paternal C2 in the fetus (13, 18, 19). In contrast, pregnancies resulting in babies with increased birth weights are also associated with the presence of a paternal C2 allele in the fetus, but with a maternal Tel-B KIR region (20). The tight linkage disequilibrium (LD)9 of KIR makes it difficult to determine through genetic studies alone which gene is responsible, so functional studies are required to complement this work. Of the KIR in the Tel-B region, activating KIR2DS1 is the most likely candidate for enhancing placentation, because it can bind to C2 allotypes. The inhibitory counterpart, KIR2DL1, also binds strongly to C2 allotypes, is present in the centromeric-A (Cen-A)10 and some centromeric-B (Cen-B)11 regions and is carried by ~98% of individuals. Therefore, in the absence of KIR2DS1 (55-60% of Europeans), the dominant effect of paternal trophoblast C2 allotypes interacting with dNK is inhibition. Ligation of KIR2DS1 on dNK induces production of cytokines and chemokines, such as GM-CSF, which can induce trophoblast migration (12). Thus, our current model of pregnancy indicates that when C2 allotypes derived from the father are expressed by trophoblast, KIR2DS1 activates dNK to secrete cytokines that encourage deeper invasion of the uterus by trophoblast, promote spiral artery remodelling and a better blood supply for the fetus (2). In the absence of KIR2DS1, insufficient activation of dNK results in poor trophoblast invasion, placental stress, growth restriction of the fetus and pre-eclampsia. In a similar Ugandan case-control study, we found no protective effect for pre-eclampsia of the Tel-B region including KIR2DS1 (carried by ~20% of control women). Instead, certain alleles of an activating KIR, KIR2DS5, present in Cen-B were more frequent in controls compared to pre-eclamptic pregnancies (21). KIR2DS5 is always located in the Tel-B region in non-African populations and is carried in tight LD with KIR2DS1. It thus could contribute to the protective effect of Tel-B in Europeans but whether it is expressed or binds C2 allotypes is still controversial. In addition KIR2DS1 and KIR2DS5, KIR2DL5A is also present in Tel-B and remains an enigmatic KIR in terms of ligands and functions (22). Other activating KIR that might recognise ligands on trophoblast and influence pregnancy outcome include KIR3DS1 and KIR2DS2-4. KIR3DS1, in LD with KIR2DS1, binds HLA-B allotypes carrying the Bw4 motif (23), but HLA-B molecules are never expressed by trophoblast (24, 25). KIR2DS2 is predicted to bind the C1 motif through homology with KIR2DL2/3; the presence of fetal C1 alone is always neutral in our genetic case control studies. KIR2DS3 is not expressed at the cell surface (26). This leaves KIR2DS4, present in the Tel-A region, that occurs either as a truncated (KIR2DS4del) (alleles *003/004/006 are carried by ~80% of Europeans) or full length (KIR2DS4wt) form (allele *001 is carried by ~35% of Europeans). KIR2DS4del has a 22bp deletion which introduces a frameshift mutation that results in a soluble protein with only one intact Ig-like domain (27). While KIR2DS4wt has been reported to bind some HLA-C alleles carrying both the C1 and C2 epitopes, soluble KIR2DS4del does not bind HLA class I molecules (28). We previously found a negative association of KIR2DS4del with pregnancy outcome, but no positive effect of KIR2DS4wt (13). Here, in order to investigate the role of KIR other than KIR2DS1 in successful pregnancy, we have studied the expression and function of KIR2DS4 and KIR2DL5 on dNK cells. From this we demonstrate that activation of dNK is a general mechanism that is beneficial to pregnancy. Materials and Methods Primary tissue Tissue and matched peripheral blood samples were obtained from women undergoing elective terminations in the first trimester of pregnancy; blood was also obtained from healthy volunteers. Both sets of patients gave informed consent. Ethical approval for the use of these tissues was obtained from the Cambridge Local Research Ethics Committee (REC 04/Q0108/23). Leukocytes and placental samples were isolated as previously described (29). Cell lines Cell lines transfected with cDNA for single KIR were used to test antibody specificities. KIR2DL1+, KIR2DL3+, KIR2DS1+, KIR2DS2+, KIR2DS4+ (30) or KIR3DS1+ (31) BWZ cells were the gift of Eric Vivier. KIR2DL2+, KIR2DS5+, KIR3DL1+ (31) or KIR3DL3+ (32) BA/F3 cells were the gift of Chiwen Chang as was cDNA for KIR2DL5 used to transiently transfect HEK293T cells. KIR2DL4+ Jurkat cells were the gift of Kerry Campbell. Paul Norman supplied cDNA of KIR3DL2 for transient transfection into HEK293T cells. Flow cytometry dNK were gated on as live, CD9+ CD56+ cells. pbNK were gated on as live CD56+ CD3- cells. The following antibodies were used: LIVE/DEAD discriminator (LifeTechnologies), CD9 (SN4 or M-L13 from eBioscience or Becton Dickinson, respectively), CD56 (HCD56 from Biolegend) and CD3 (SK7) from Becton Dickinson. Fibroblasts and macrophages were identified using CD10 (HI10a from Biolegend) and CD14 antibodies (MφP9 and HCD14 from BD Pharmingen and Biolegend), respectively. The following antibodies were used to stain KIR: UPR1 (KIR2DL5) from Biolegend and Carlos Vilches (33); 179315 (KIR2DS4), 143211 (KIR2DL1) and 181703 (KIR2DL4) from R&D Systems; FES172 (KIR2DS4) and EB6 (KIR2DL1/S1) from Beckman Coulter; CHL (KIR2DL2/3/S2) from BD Pharmingen, DX9 (KIR3DL1) from Biolegend; NKVFS1 (KIR2DL1/2/3/S1/2/4) from Abcam; 5.133 (KIR3DL2) from Marco Colonna (34); and FLAG antibodies (Sigma Aldrich). Intracellular staining was performed according to manufacturers’ instructions with antibodies against Ki647, (BD Pharmingen), CCL3 (R&D Systems) and GM-CSF (BD Biosciences). Functional assays Purified NK cells (CD56-positive selection using magnetic beads, Miltenyi Biotec) or mixed decidual mononuclear cells were stimulated with plate-bound anti-KIR2DS4 (179315) antibodies or an isotype control for 4-48 hours. After this time supernatants were removed (spun at 500g for 5min to remove cellular contaminants) or stimulated cells were mechanically dislodged. Supernatants were analysed using a chip-based fluorescence-linked immunosorbent assay (Human Cytokine Antibody Array G Series 1000, RayBioTech) or a standard ELISA for CCL1 and XCL1 (DuoSets, R&D Systems). Cells activated cells in the presence of monensin and brefeldin-A for 5h were analysed for surface expression of CD107a (H4A3, BD Pharmingen) or the intracellular cytokines listed above. Immunohistochemistry Paraffin sections of decidual implantation sites were heat-treated in 0.1M citrate buffer for 20min at 99.5°C. Slides were left in hot buffer for a further 20min for antigen unmasking. Anti-XCR1 (191704 from R&D Systems) was stained in Tris-buffered saline with 0.1% Tween for 45min. The staining was detected with goat anti-rabbit IgG-biotin and avidin-biotin-HRP complexes (Vector Laboratories). Genetic typing The case-control cohort analysed here has previously been described (13). KIR and HLA-C1/2 genetic typing of new patient samples was performed as in this previous study. Two-digit HLA-C typing was performed by the Tissue Typing facility at Addenbrookes Hospital, Cambridge. Statistics Statistical tests were carried out using the computational site http://vassarstats.net/; the statistical packages within GraphPad Prism v6 (GraphPad Software, California); the Real Statistics Resource Pack for Excel 2010 http://www.real-statistics.com/ ; and PLINK (version 1.07) http://pngu.mgh.harvard.edu/purcell/plink/ (35). The product rule was calculated by multiplying the observed frequency of individual receptors to generate the expected frequency of double positive receptors: pExp(AB) = pObs(A).pObs(B). The following genetics tests were performed: Chi-squared test and Fisher Exact test with two-tailed mid p adjustment; Breslow-Day test; Cochran-Mantel-Haenszel test. Results KIR2DS4wt in epistasis with KIR2DS1 is associated with a lower risk of pre-eclampsia KIR2DS4wt, the full length form of activating KIR2DS4, is potentially important in pregnancy as it can bind to some HLA-C allotypes (28, 36). Indeed, we previously found in a case-control cohort of European women that KIR2DS4del associates with increased risk of pregnancy disorders (13). The presence of KIR2DS4wt was neutral in this analysis. However, we only considered presence/absence of this gene and did not consider the effect of both KIR telomeric regions that make up the women’s genotypes. There are three possible regions: Tel-A containing KIR2DS4wt, Tel-A containing KIR2DS4del and Tel-B containing KIR2DS1 (Figure 1A) that provides a strong protective effect (13). Here, therefore, we re-analysed this dataset for the effect of KIR2DS4wt, now controlling for the clear protective effect of KIR2DS1. Indeed, the presence/absence of KIR2DS1 does alter the effect of KIR2DS4wt, indicative of epistasis (Breslow-Day test, p=0.003). KIR2DS4wt is protective compared to KIR2DS4del in KIR2DS1+ women (p=5.7x10-4, OR=0.59)(Figure 1B). This effect is not found in the absence of KIR2DS1 (p=0.83, OR=1.0). This indicates that women who carry both KIR2DS4wt and KIR2DS1 are further protected against disorders of pregnancy affecting placentation (p=6.8x10-5, OR=0.45)(Figure 1C). Because of the similar functions and overlapping ligands of KIR2DS1 and KIR2DS4, it is likely that the epistasis detected at the statistical level reflects a biological interaction. KIR2DS4 is expressed by a large proportion of both pbNK and dNK Two mAbs (FES172 and 179315) were tested to confirm specificity against KIR2DS4 on cell lines expressing single KIR (Supplemental Figure 1). The frequency of KIR2DS4+ CD56+ cells is high in both dNK and pbNK populations (Figure 2A-C). In contrast, both KIR2DS1 and KIR2DL1 have increased frequency of expression in dNK compared to pbNK (12, 37, 38) and so, in accordance with the product rule, there is a higher frequency of dNK co-expressing these KIR than for pbNK (12). This means that the proportion of cells co-expressing KIR2DS4 and other KIR is probably different for dNK and pbNK. We chose to look at the distribution of KIR2DS4 relative to KIR2DL1, because KIR2DL1 is carried by almost all donors allowing us to analyse KIR co-expression with sufficient statistical power. KIR2DL1 is also critical to our model of pregnancy disorders as it is strongly inhibitory for HLA-C allotypes bearing C2 epitopes. Our findings (Figure 2D-E) show that in pbNK, most KIR2DS4+ cells lack KIR2DL1 (Figure 2E, mid grey segment), but in dNK, most KIR2DS4+ cells co-express KIR2DL1 (Figure 2E, dark grey segment). This increased co-expression obeys the product rule (Supplemental Figure 2A), suggesting it reflects the combined frequency of KIR2DL1 and KIR2DS4. In line with this, Ki-67 staining shows that KIR+ dNK proliferate more than KIR- cells, but there is no preferential proliferation by KIR2DS4+ KIR2DL1+ cells compared to single positive cells (Supplemental Figure 2B). Therefore, in donors carrying KIR2DS4wt, a large proportion of dNK co-express KIR2DS4 with other KIR that have the potential to modulate its function. Using KIR Fc-fusion proteins, KIR2DS4 binds and responds to certain HLA-C alleles carrying both C1 and C2 epitopes (28, 36). Binding of KIR2DS4 on dNK to trophoblast HLA-C ligands might affect the frequency of KIR2DS4+ cells, but we find no difference in the proportion of dNK expressing KIR2DS4 when the mother or fetus carries its ligands (Supplemental Figure 3A-B). There is a suggestion that allogeneic ligands affect KIR2DS4 expression as there are fewer dNK expressing KIR2DS4 when the fetus alone carries a ligand, compared to the mother alone (Supplemental Figure 3C). Given that KIR2DS4wt is protective in genetic case-control studies only in the presence of KIR2DS1, and that both are mutually exclusive on a KIR haplotype, protected individuals must have one copy of each gene. Therefore, we analysed the effect of KIR2DS4wt copy number on frequency of expression: as two copies; as one copy in the presence of KIR2DS4del; or as one copy in the presence of KIR2DS1. KIR2DS4 frequency on dNK is similar in these different genetic backgrounds, suggesting that an altered frequency of KIR2DS4+ dNK in KIR2DS1+ KIR2DS4+ individuals is not the mechanism by which KIR2DS4 provides protection against pregnancy disorders (Supplemental Figure 3D). KIR2DS4 activation on dNK induces cytokine responses HLA-C ligands for KIR2DS4 are shared with other NK receptors on dNK. To investigate the functional consequences specific to activation of KIR2DS4 alone we used cross-linking with a specific mAb. Decidual NK cells are poor killers, as measured by chromium-release assays (6, 9, 39), but CD107a degranulation does occur in the presence of low dose IL-15 (40) and offers a reproducible assay to quantify dNK activation. We find that degranulation of both pbNK and dNK occurs in response to increasing concentrations of anti-KIR2DS4 (Scheirer-Ray-Hare modification of Kruskal-Wallis test, effect of mAb concentration p=4.1x10-10)(Figure 3). Since cytokine responses are more physiologically relevant to human pregnancy than degranulation (12, 41), we next analysed the cytokines produced following KIR2DS4 stimulation of dNK using a semi-quantitative screen of 120 cytokines (Supplemental Table I). Mixed decidual mononuclear cells were co-cultured in wells coated with anti-KIR2DS4 or control IgG antibody so that contact with stromal cells is maintained, as this improves viability. We identified 8 candidates that were upregulated >1.25 fold in at least 1 out of 4 donors tested (Figure 4A-B). After cross-linking with anti-KIR2DS4, flow cytometry (GM-CSF and CCL3) or ELISA (XCL1 and CCL1) assays were used to validate 4 of these 8 cytokines (Figure 4C-F). The percentage of dNK positive for intracellular GM-CSF and the median fluorescence intensity for CCL3 increases (p<0.05)(Figure 4C-E) and secretion assayed by ELISA for both XCL1(p<0.01) and CCL1 (p<0.05) is augmented (Figure 4F). In summary, stimulation of KIR2DS4 on dNK cells triggers the release of cytokines, many of which are related to the cytokines upregulated at the mRNA level by dNK cells upon KIR2DS1 activation (XCL2, CCL3L3, GM-CSF, IFNG) (12), although this is the first time XCL1 and CCL1 have been identified as secreted by dNK cells in response to activating signals. Trophoblast and maternal decidual cells express receptors for newly-identified cytokines produced by activated dNK Recently we have shown that GM-CSF induces migration of human primary trophoblast cells (12). CCL3 production by decidual and trophoblast cells may attract NK cells, as well as monocytes and T cells, which all bear receptors for this cytokine (42, 43). Receptors for chemokines XCL1 and CCL1 have not been described on cells at the site of placentation. We therefore stained sections of decidua and placenta and cell isolates by flow cytometry for these receptors. Several cell types within the placenta, including fetal endothelial cells, villous trophoblast and invasive EVT express XCR1, the receptor for XCL1 (Figure 5). Within the dNK-rich decidua, XCR1 is found on cells with branching processes, (Figure 5B) identified by flow cytometry as a small proportion of the CD14+ macrophage population (Figure 5D-E). CCR8, the receptor for CCL1, is expressed by all decidual macrophages and a small proportion of dNK (Figure 5F). KIR2DL5 – the only inhibitory receptor in the Tel-B region – is not expressed on the surface of dNK In the Tel-B region, KIR2DS1 is in LD with KIR2DL5A, which codes for an orphan inhibitory receptor. To determine whether KIR2DL5A affects dNK activation and pregnancy outcome, we first looked for expression of KIR2DL5A in dNK. KIR2DL5 alleles are also found in the Cen-B region, where they are known as KIR2DL5B (Figure 1A). To distinguish between these alleles we used antibody UPR1, which binds the most common KIR2DL5A allele in Europeans, KIR2DL5A*001 (~30% Europeans) (33), but not KIR2DL5A*005 (~8% Europeans) or KIR2DL5B (~20-40% Europeans) (22). UPR1 binds KIR2DL5 and not other KIR using KIR-negative cell lines transfected with single KIR genes (Supplemental Figure 1). In donors where there were detectable KIR2DL5+ pbNK, there was no surface expression of KIR2DL5 on dNK (Figure 6A-B). The donors who expressed KIR2DL5 in blood, always also carry KIR2DS5 (Figure 6C), which is in LD with KIR2DS1 and KIR2DL5*001 in the Tel-B haplotype in Europeans, suggesting we might only detect Tel-B KIR2DL5*001 and not other KIR2DL5 allotypes. The absence of KIR2DL5 surface expression on dNK means it is unlikely to be affecting the activity of dNK and so the protective effect of the Tel-B region is due to activating KIR alone. Discussion We have shown that KIR2DS4wt is associated with lower risk of pregnancy disorders in the presence of KIR2DS1 – a synergistic interaction. KIR2DS4wt has been linked to higher viral load and increased transmission of HIV infection (44–47), and with clinical outcomes in arthritis (48–50), cancer (51) and allogeneic cell transplantation (52). Because KIR are in tight LD and there are confounding effects of genes on alternative haplotypes, it can be difficult to determine which particular KIR has a role in disease (53). Here we have ruled out the effect of alternative haplotypes by stratifying the cohort according to the presence of Tel-B. A clear biological rationale for a particular KIR’s involvement can also help distinguish the effect of KIR in tight LD. KIR2DS4wt is in LD with KIR3DL1 alleles, but in the context of pregnancy, the ligand for KIR3DL1, HLA-Bw4, is not expressed by trophoblast. HLA-Bw4 can be expressed by stromal cells, so it is possible it modulates uNK activity. Nevertheless, KIR2DS4, known to bind to certain HLA-C allotypes expressed on trophoblast, is the likely candidate for the protective effect. To explain how a particular KIR could affect trophoblast migration, the candidate KIR needs to be expressed by NK cells in contact with EVT in the decidua. KIR2DS4 is expressed by a large proportion of dNK and its frequency of expression follows the product rule of co-expression with other KIR. Co-expression of KIR is relevant because the balance of activating and inhibitory signals within the cell determines activation of NK cells. Like KIR2DL1, KIR2DS1 has increased frequency of expression in dNK compared to pbNK. KIR2DS4wt could swing the balance in favour of activation when co-expressed with KIR2DS1 or in the context of activating cytokines, but may fail to activate dNK in the absence of another activating receptor. Indeed, KIR2DS1 may also require the presence of another activating receptor to have measurable effects on population genetics, but unlike KIR2DS4wt, KIR2DS1 is in LD with two other activating receptors in Europeans. There is precedence for co-operation of activating KIR from pregnancy and allogeneic hematopoietic stem cell transplantation, where cumulative Cen-B and Tel-B haplotypes that carry multiple activating KIR, contribute to increasing beneficial effects (18, 54). Indeed, our finding that certain centromeric alleles of another different activating KIR, KIR2DS5, is protective against pre-eclampsia in Ugandans (21) supports this model. There is still limited evidence that KIR2DS4 responds to HLA-C molecules, but our preliminary findings suggest that the size of the KIR2DS4+ dNK subset is smaller when KIR2DS4 ligands are present in the fetus, but not the mother. This observation supports the hypothesis that KIR2DS4 does bind these HLA-C ligands on trophoblast. Why should KIR2DS4 act as a co-receptor in this way, requiring the presence of another activating receptor? The mechanism of this co-operation remains unclear, but we can exclude some factors. Firstly, we have shown that the frequency of expression of KIR2DS4wt on dNK is unaffected by the presence of Tel-B or Tel-A on the women’s other haplotype. Therefore higher frequency of expression of KIR2DS4wt in the presence of KIR2DS1 cannot be the mechanism by which epistasis is achieved. Similarly, there is only one prevalent allele of KIR2DS1 and functional KIR2DS4 amongst Europeans (KIR2DS1*002 and KIR2DS4*001), so allelic variation on particular haplotypes is unlikely to affect the association in our European case-control cohorts. One reason for the dependence of KIR2DS4wt on the presence of KIR2DS1 could be the nature of its interaction with HLA-C molecules. Whilst there are functional responses of KIR2DS1+ NK cells upon interaction with HLA-C alleles carrying C2 epitopes ex vivo (12, 55, 56), similar responses of KIR2DS4+ NK cells have only been demonstrated for HLA-C*0401 (36) and HLA-A*1102 (28). The interaction of KIR2DS4 with HLA-C could be of lower avidity than that of KIR2DS1; KIR2DS4 recognition of HLA-C allotypes might be peptide dependent, as has been shown for KIR3DS1 (23); or KIR2DS4 may be interacting with open conformers of HLA molecules (57) expressed by trophoblast. All these factors could affect the way KIR2DS4 binds to HLA-C molecules on trophoblast. Specialised functions for pbNK and dNK are likely to have arisen because of the conflicting demands of disease resistance and reproductive success (3). When trying to assess the impact of KIR in health and disease, it is necessary, therefore, to study these receptors in the species and tissue of interest. Upon triggering of KIR2DS4 with specific antibodies, dNK degranulate and secrete cytokines, such as GM-CSF, that are known to have direct effects on trophoblast migration, and other cytokines (XCL1, CCL1 and CCL3) that have the potential to directly impact trophoblast and other cells in the decidua, including decidual macrophages. Recently, KIR2DS4 has been highlighted for promoting trogocytosis (58), a process that has been implicated in dNK acquisition of HLA-G from trophoblast (59). There may be several mechanisms, therefore by which triggering of dNK could aid placentation. The view that immune cells must be suppressed for successful pregnancy – both locally in the uterus and systemically - originated with Medawar and the birth of transplant biology (60). There is now mounting evidence that for uterine NK cells this is not correct. We show that activation of dNK cells through KIR2DS4wt provides help to trophoblast migration and the establishment of pregnancy. Perhaps KIR2DS5 in the Cen-B may protect Africans from pre-eclampsia in the same way (21). Moreover, we find here that inhibitory receptor KIR2DL5A in the protective Tel-B region is not expressed by dNK, suggesting it does not affect pregnancy outcome. Together these data support a model of generic activation of dNK cells counter-acting strong inhibition by KIR2DL1 and benefitting pregnancy. Supplementary Material Supplementary material Acknowledgements We would like to thank all the donors and research nurses for providing samples. We thank Carlos Vilches, Hugo Hilton, Paul Norman, Peter Parham, Eric Vivier, Chiwen Chang, John Trowsdale, Kerry Campbell, Michela Falco and Massimo Vitale for reagents relating to this study, as well as Sarah Peacock and Craig Taylor of the Tissue Typing facility at Addenbrookes Hospital Cambridge. We thank Daniel Davis for helpful comments on the manuscript. Figure 1 KIR2DS4wt in epistasis with KIR2DS1 is associated with a lower risk of pregnancy disorders. A. The LD blocks that make up more than 94% of Caucasian KIR genotypes (17). An individual’s KIR genotype contains two haplotypes, each with one centromeric (left) and one telomeric (right) block. These blocks contain activating (white) and inhibitory (black) genes in LD. Framework genes (grey) are found in all haplotypes. The three most common telomeric blocks contain either KIR2DS4wt, KIR2DS4del or KIR2DS1. B. Women were stratified according to the presence or absence of the protective gene KIR2DS1 as a Breslow-Day test indicated epistasis between KIR2DS1 and KIR2DS4wt. The carrier frequency of KIR2DS4wt was then compared between women with affected pregnancies and healthy control pregnancies within each subgroup. The presence of KIR2DS4wt was protective, Cochran-Mantel-Haenszel test p = 5.7x10-4, OR 0.59. C. Then, within the women carrying KIR2DS1, it is the double positive KIR2DS1+ KIR2DS4wt+ that are the most protected, p = 6.78x10-5, OR = 0.45. Figure 2 KIR2DS4 is expressed by a large proportion of both pbNK and dNK. A. Flow cytometry plots from a typical donor showing the gating strategy for pbNK and dNK. B. Flow cytometry plots showing KIR2DS4 and KIR2DL1 staining on pbNK and dNK from a representative donor. The percentage of cells in each quadrant is shown. C. The proportion of KIR2DS4+ cells was compared for pbNK and dNK in matched donors (n=22). The proportion of KIR2DL1+ (n=41) and KIR2DS1+ (n=11) NK cells is shown for comparison only. Data points for KIR2DS1 and some KIR2DL1 (shown in grey) are already published (12) and are reproduced with permission from the Journal of Clinical Investigation. D-E. The proportion of NK cells from each KIR+ subset (single positive (sp), double positive (dp) or double negative (dn) for the receptors) was compared for pbNK and dNK cells. D. Values for individual donors. Black lines represent donors, red lines represent the median, *** p<0.001 Wilcoxon Signed Rank Test. E. The mean values for each subset displayed as a pie chart. Figure 3 KIR2DS4 is functional on dNK cells. pbNK and dNK cells from KIR2DS4+ donors were incubated in wells coated with anti-KIR2DS4 or an isotype control for 4 hours in the presence of monensin. A. dNK cells from a represenative donor, gated as in Figure 2, are shown stained for KIR2DS4 and CD107a following activation with plate-bound antibody (anti-KIR2DS4 or an isotype control). B. The percentage of KIR2DS4+ NK cells positive for CD107a upon activation was calculated by subtracting the %CD107a+ when cells were cross-linked with IgG. The extent of degranulation for a range of antibody concentrations is shown. pbNK and dNK cells were not from the same donor. Scheirer-Ray-Hare modification of Kruskal-Wallis test, effect of concentration p=4.1x10-10; effect of cell type p=0.24; effect of interaction p=0.87. Bars represent medians and interquartile ranges. Figure 4 Cytokine secretion by dNK cells in response to KIR2DS4 activation. A-B. A semi-quantitative fluorescent chip-based sandwich ELISA was used to screen for 120 cytokines in supernatants taken from mixed decidual leukocytes of KIR2DS4+ donors (see Supplemental Table 1). Leukocytes were cultured on antibody-coated plastic for 12-24 hours, where the only cells to express KIR2DS4 were the dNK cells. Fluorescent spots for cytokines of interest are highlighted in A. The cropped regions of interest are taken from different chips and different donors. They are grouped according to whether they show greater than 1.5-fold increase in secretion on average across all donors (‘Increase’); secretion was already high within the isotype control stimulation, so the screen was insensitive (‘Ambiguous’); and control spots (‘Control’). B. The cytokines that were upregulated more than 1.25-fold upon KIR2DS4 activation in at least one of four donors tested are listed in the table. The mean fold change across all four donors in shown to the right. C-E. Mixed decidual leukocytes were cultured on plastic coated with either anti-KIR2DS4 antibody or an isotype control (IgG2a) in the presence of monensin and brefeldin A. After 5h, cells were fixed and live CD56+ CD9+ KIR2DS4+ dNK cells were identified by flow cytometry (C). Although KIR2DS4 expression reduced upon cross-linking (C) the majority retained KIR2DS4 expression. These KIR2DS4+ dNK were assessed for intracellular cytokines: (D) GM-CSF (n=7) and (E) CCL3 (n=7). F. Where antibodies for flow cytometry were not available, purified dNK cells were cultured on antibody-coated plastic for 12-48 hours and the production of CCL1 and XCL1 (n=8) were detected in supernatants by commercial sandwich ELISA. Colour-coded according to donor. Wilcoxon signed rank test, * p<0.05, ** p<0.01. Figure 5 Receptors for XCL1 and CCL1 on placenta and in the pregnant uterus. A. XCR1, the receptor for XCL1, was identified on trophoblast through immunohistochemical staining of sections of placenta invading the pregnant uterus. VT villous trophoblast, EVT extravillous trophoblast. B. Within the maternal compartment, XCR1 was identified on individual cells with branching processes often adjacent to vessels. C. Isotype control staining of trophoblast (left panel) invading the uterus (right panel). D. Chemokine receptor expression on live CD14+ decidual macrophages was confirmed by flow cytometry for (E) XCR1 (n=6) and (F) CCR8 (n=5). A population of cells that did not express the receptor (dNK for XCR1 and fibroblasts for CCR8, since some dNK express low amounts of CCR8) are shown for comparison. Figure 6 KIR2DL5 is detected by flow cytometry on the surface of pbNK cells, but not dNK cells. A. Flow cytometry plots from a typical donor showing matched pbNK and dNK, gated as in Figure 2, stained for KIR2DL5 (mAb UPR1) or an isotype control (IgG1). B. The frequency of the KIR2DL5+ population was defined as (%UPR1+) - (%IgG1+). The frequency of this population was measured for all pbNK and dNK cells from donors where there was UPR1+ staining in blood (n=8). For comparison, staining of KIR2DL5- donors is shown alongside (n=7). Each line represents one donor. Wilcoxon signed rank test. * p<0.05 C. All donors that carried KIR2DL5 according to SSP-PCR were assessed for KIR2DL5 staining, but a positive KIR2DL5+ subset was only seen as part of the genotype that carried KIR2DS5 alongside KIR2DL5. Lines show the median. 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PMC005xxxxxx/PMC5115177.txt
LICENSE: This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. 9110829 2209 J Biomol NMR J. Biomol. NMR Journal of biomolecular NMR 0925-2738 1573-5001 26968894 5115177 10.1007/s10858-016-0028-y NIHMS768266 Article Insights into Furanose Solution Conformations: Beyond the Two-State Model Wang Xiaocong Woods Robert J. * Complex Carbohydrate Research Center, University of Georgia, Athens, GA, 30605 * To whom all correspondence should be addressed, rwoods@ccrc.uga.edu, Phone: +1 (706) 542-4454, Fax: +1 (706) 542-4412 5 4 2016 12 3 2016 4 2016 01 4 2017 64 4 291305 This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. A two-state model is commonly used for interpreting ring conformations of furanoses based on NMR scalar 3J-coupling constants, with the ring populating relatively narrow distributions in the North and the South of the pseudorotation itinerary. The validity of this simple approach has been questioned, and is examined here in detail employing molecular dynamics (MD) simulations with a new GLYCAM force field parameter set for furanoses. Theoretical 3J-coupling constants derived from unrestrained MD simulations with the new furanose-specific parameters agreed with the experimental coupling constants to within 1 Hz on average. The results confirm that a two state model is a reasonable description for the ring conformation in the majority of methyl furanosides. However, in the case of methyl α-D-arabinofuranoside the ring populates a continuum of states from North to South via the eastern side of the pseudorotational itinerary. Two key properties are responsible for these differences. Firstly, East and West regions in β- and α-anomers, respectively, are destabilized by the absence of the anomeric effect. And, secondly, East or West conformations can be further destabilized by repulsive interactions among vicinal hydroxyl groups and ring oxygen atoms when the vicinal hydroxyl groups are in syn-configurations (such as in ribose and lyxose) more so than when in anti (arabinose, xylose). Pseudorotation Anomeric effect Potential energy surface Molecular dynamics simulation GLYCAM AMBER Introduction Furanoses are essential components in the backbone of nucleic acids (RNA and DNA) and are also frequent components of complex polysaccharides found in organisms ranging from bacteria to protozoa, fungi and plants (Taha et al. 2013). Their conformational properties affect the structure and recognition of the polymers in which they are found. In marked contrast to six-membered sugar rings (pyranoses), the five-membered forms (furanoses) exhibit a high level of internal ring flexing (Bartenev et al. 1987; Levitt and Warshel 1978; Seo et al. 2008). As a result, furanoses can interconvert between multiple ring conformations (Houseknecht et al. 2003a), whereas pyranoses are usually found in single, energy-favorable chair conformation (Angyal 1984). This feature of furanoses greatly complicates the development and interpretation of structure-function relationships for these small but crucial molecules. The conformational analysis of ring conformations of carbohydrates molecules in solution relies heavily on deconvoluting NMR scalar 3J-coupling constants into ring puckering geometries and populations (De Leeuw and Altona 1983; Padrta and Sklenar 2002; Sun et al. 2004). In the case of furanoses, interpreting their conformational populations from 3J-coupling constants typically requires assumptions regarding to the number of states that are present. In the two-state model introduced by Altona et al. (1972) to interpret the ring conformations of the ribofuranosyl ring in nucleic acids, it is assumed that the rings populate only two states (Altona and Sundaral.M 1972; Altona and Sundaralingam 1973), referred to as North and South, with respect to their location on the pseudorotational itinerary (Fig. 1). However, the validity of a two-state model has been questioned when applied to other furanoses, particularly in the case of arabinofuranose (Hendrickx et al. 2010; Seo et al. 2008; Taha et al. 2010; Taha et al. 2011). An alternative approach that has shown promise, is to perform MD simulations of the furanose (Hatcher et al. 2009), and then back-calculate the 3J-values directly from the MD data (Hendrickx et al. 2010; Raman et al. 2010; Taha et al. 2010). This approach eliminates the need for assumptions regarding states, but requires an accurate force field, adequate conformational sampling, and a reliable method for deriving scalar couplings from the MD trajectory. In general, the calculation of NMR 3J-values from MD data can be performed in one of two ways, most commonly by employing a Karplus-type relationship to convert torsion angles between coupled spins into 3J-values (Altona et al. 1994; Bose et al. 1998; Cloran et al. 1999; Haasnoot et al. 1980; Houseknecht et al. 2003b; Stenutz et al. 2002; Taha et al. 2010; Taha et al. 2011; Zhao et al. 2007), or by computing the 3J-values quantum mechanically (QM) for each state (Gonzalez-Outeirino et al. 2006), The latter approach eliminates the approximations implicit in Karplus-relationships, but is far more computationally demanding, and has not yet been applied to furanoses, although it has shown benefits when applied to analyses of pyranose conformational properties (Gonzalez-Outeirino et al. 2006). Previously, the GLYCAM06 force field (Kirschner et al. 2008) was created to be applicable broadly to a range of carbohydrates, including pyranoses and furanoses, however, MD simulations of furanoses have not resulted in consistently acceptable reproduction of solution NMR properties (Seo et al. 2008). Therefore, developing a reliable force field for furanoses that is capable of describing their conformational properties in solution, is essential for both theoretical and experimental studies of these molecules. As might be expected, the fluxional properties of furanosyl rings leads to unique challenges in developing a force field for these molecules, requiring long MD simulation times to ensure converged conformational sampling. In addition, the five-membered ring has more strain than found in pyranoses, as evidenced by the compression of bond angles, and this feature places unique demands on the derivation of the torsion terms relevant to the ring. To address the question of the apparent discrepancy between MD-derived and NMR-derived ring populations in furanoses (Seo et al. 2008), we begin by first developing a set of furanose-specific parameters that are compatible with the GLYCAM06 force field (Kirschner et al. 2008), which are able to reproduce the quantum-computed relative energies of the ring as it traverses the pseudorotational itinerary. Having derived a suitable set of parameters, MD simulations were performed in explicit water for both α and β anomers of the four methyl D-aldofuranosides: methyl D-arabinofuranoside (1), methyl D-lyxofuranoside (2), methyl D-ribofuranoside (3), methyl D-xylofuranoside (4), as well as methyl 2-deoxy-β-D-ribofuranoside (5β) (Fig. 2). 3J-coupling constants derived from the MD simulations of the examined furanosides with this new set of parameters were found to be in agreement with NMR 3J-values to within an average error of less than 0.9 Hz. More importantly, ring conformations from the MD simulations have shown the two-state model is a reasonable description of the ring properties in the majority of the furanosides, but not in the case of the arabino configuration (1α). Further analysis indicated that, for the two-state model to be applicable, barriers in the East and West must exist to confine the conformations to low-energy regions in the northern and southern quadrants of the pseudorotational surface. The relative stability of northern and southern conformations has been rationalized in terms of the numbers of stabilizing gauche effects between vicinal oxygen atoms (Callam and Lowary 2001; D'Souza et al. 2000; Plavec et al. 1993; Thibaudeau and Chattopadhyaya 1997) as well as the presence of the anomeric effect (Callam and Lowary 2001; Cosse-Barbi and Dubois 1987; Cossé-Barbi et al. 1989; D'Souza et al. 2000; Ellervik and Magnusson 1994; Houseknecht et al. 2003a; Plavec et al. 1994; Plavec et al. 1996; Plavec et al. 1993; Thibaudeau and Chattopadhyaya 1997; Thibaudeau et al. 1994). Here, we find that whether or not there is a barrier in the eastern or western regions depends on the absence of an anomeric effect, as well as the presence of unfavorable syn-orientations of vicinal hydroxyl groups. In the unique case of 1α, there is no barrier in the eastern quadrant due to the absence of any conformation in which hydroxyl groups can adopt syn-orientations, enabling the furanose to populate a continuum of states from North to South. The present analysis provides an independent method for interpreting furanose conformational properties that does not rely on experimental NMR data as constraints, nor on assumptions of preferred states. In addition, QM calculations have been employed here to quantify for the first time the strength of the anomeric and exo-anomeric effects in furanosides. Results & Discussion Parameters New atom type In order to develop the parameters specific for furanoses, which are orthogonal with the current parameters for pyranoses, two new atom types were introduced: “Cf”, representing ring carbon atoms, and “Of”, representing the ring oxygen atom (Fig. S1). The “upper case lower case” naming of atom types in AMBER is reserved for use with carbohydrates in the GLYCAM force field Van der Waals terms for Cf and Of were assumed to be the same as for the corresponding atoms in pyranoses (Kirschner et al. 2008). Ensemble-averaged partial atomic charges for the new atom types, as well as all other atoms (Table S1 and Table S2), were computed according to the standard GLCYAM protocol (Kirschner et al. 2008), discussed in METHODS. Bond length and bond angle parameters The average bond lengths for C-C and C-O bonds in furanose ring are nearly identical with those in pyranose ring (Ishii et al. 2014; Ishii et al. 2015; Longchambon et al. 1976; McDonald and Beevers 1952; Ohanessian et al. 1977; Ohanessian and Gillierpandraud 1976). Therefore, the bond length parameters for furanose ring were imported from GLYCAM06, and simulations with these parameters demonstrated good agreement with the corresponding crystallographic values (Table S3 and Table S4). In earlier bond angle parameter development for pyranoses in GLYCAM06 (Kirschner et al. 2008), acyclic molecules were distorted from their equilibrium geometries in order to determine the force constants and equilibrium angle values. Similarly, bond lengths were stretched or compressed to determine appropriate bond parameters. However, to determine these values for furanoses, an alternative procedure was adopted, in which the ring was distorted by twisting the relevant torsion angles over a range of +/− 50 degrees. QM energy profiles for valence bond and angle parameter fitting were generated by optimizing tetrahydrofuran (THF) structures with ring torsion angles changing from −50° to 50° in 5° increments. Due to the symmetry of THF, only three energy profiles were necessary, namely for the C1-C2-C3-C4, C2-C3-C4-O4 and C3-C4-O4-C1 torsion angles. Parameters for the Cf-Cf-Cf, Cf-Cf-Of and Cf-Of-Cf angles were derived simultaneously by minimizing the differences between QM and molecular mechanics (MM) ring distortion energies. To assess the performance of the new parameters in reproducing the QM energy profiles, the errors between QM and MM energies were computed over the entire range of the distortion curves (<|Error|>all), as well as for the low energy conformations (<|Error|>low). The new parameters reproduced the gas-phase relative energies for THF markedly better than GLYCAM06 (Fig. S2). The <|Error|>all for the new parameters for the three energy profiles in Fig. S2 is 0.1 kcal/mol, and in contrast to GLYCAM06, the new parameters better reproduced the QM energies in high energy regions. Average values for the C-C-C, C-C-O, and C-O-C angles were computed from 300 ns MD simulations and compared to relevant crystallographic values (Table S3 and Table S4). Although both C-C-O and C-O-C angles showed larger differences from the crystallographic values, they are within the standard deviation. Torsion angle parameters Torsion terms associated with the five-membered ring were optimized based on their ability to reproduce the QM pseudorotational energies for discrete conformations of the ring generated at 1° increments in the ring phase angle (P). In this procedure several contributing torsion terms could be simultaneously optimized. Simultaneous parameter fitting has been applied recently in the generation of a set of force field parameters for protein modeling (Cerutti et al. 2014). Model structures were selected that nevertheless enabled the fitting of as few simultaneous torsion terms as possible, in order to minimize the number of new torsion terms, maximize parameter transferability, and provide insight into the underlying structural preferences (Table S5). All other torsion terms were generated directly by fitting to internal rotational energies. In order to reduce energy variations originating from interactions involving exocyclic moieties, the conformation of each of the exocyclic moieties was restrained throughout the MM and QM pseudorotation energy minimizations (Table S5). To assess the performance of the torsion angle parameters, the average errors between QM and MM energies were computed for the entire energy curves, <|Error|>pseudo, as well as for the minima, <|Error|>minima. The parameters resulting from the development protocol discussed below are presented in Table S6. THF The torsion terms (Cf-Cf-Cf-Cf, Cf-Cf-Cf-Of and Cf-Cf-Of-Cf) derived simultaneously from fitting to the pseudorotational energies for THF (6) are fundamental to all furanoses. The agreement between the MM and QM energies (Fig. 3) for the pseudorotational energy of THF computed with the optimized torsion parameters was within 0.1 kcal/mol for both <|Error|>pseudo and <|Error|>minima. It is notable that the energy minima for the THF pseudorotation was observed to lie in the East/West quadrants, rather than North/South, as typically observed for furanoses. This observation suggests that the exocyclic groups in furanoses alter the conformational preferences of the five-membered ring, although the parries to interconversion are less than approximately 0.5 kcal/mol. As can be seen in Fig. 3, the energy minima for the five-membered ring in THF occur at P = 90 and 270°, corresponding to East and West pseudorotational quadrants, respectively. In these conformations the C1-C2-C3-C4 torsion angle is 0°. However, in this conformation hydroxyl groups at C2 and C3 can be eclipsed (as in lyxose and ribose), disfavoring East/West conformations. Models for mono- and dihydroxy substituents in furanoses The ring conformation of furanoses is greatly affected by the configurations of the hydroxyl groups (Church et al. 1997; Houseknecht et al. 2003b; Kline and Serianni 1990; Serianni and Barker 1984; Taha et al. 2010; Taha et al. 2011), and presumably arises from a combination of steric and electrostatic interactions. These interactions may be between hydroxyl groups, as well as between the ring atoms and the hydroxyl groups. To reproduce the effect of these interactions on the ring psudorotational energies, torsion terms were developed for the Oh/Of-Cf-Cf-Oh, and Cf/Hc-Cf-Cf-Oh sequences, employing the model compounds cis- (7) and trans-tetrahydrofuran-3,4-diol (8) and tetrahydrofuran-3-ol (9). As shown in Fig. S3, the new parameters reproduced the shapes of the QM pseudorotational energy curves for both molecules. In the case of 9, the errors in the fits were similarly small. With the introduction of the vicinal hydroxyl groups, the minima now occur in the North/South regime, as expected in general for furanoses. Models for pentofuranoses To extend the model to pentofuranoses, a hydroxymethyl group was introduced into THF, which corresponds to the C4-substituent in pentofuranoses, employing 2-(hydroxymethyl)tetrahydrofuran (10) as the model compound. This molecule enabled us to develop the Cf-Cf-Cf-Cg and Cf-Of-Cf-Cg torsion terms (pertinent to the C2-C3-C4-C5 and C1-O4-C4-C5 atomic sequences). The fitting to the pseudorotational energies for 10 was performed for each of the three rotamers of the hydroxymethyl substituent (Fig. S4). While the average errors were all less than 0.5 kcal/mol, not all low-energy states were well reproduced, however in the worst case the error was less than 1 kcal/mol. Similar agreements were obtained for cis- and trans-2-(hydroxymethyl)tetrahydrofuran-3-ol (11 and 12, respectively), which tested the ability of the parameters to reproduce the relative energies of the C4-C5 rotamers in the presence of a vicinal hydroxyl group at C3 (Fig. S5 and Fig. S6). Models for methyl furanosides The simplest model for the effect of anomeric configuration on five-membered ring conformational energy is (S)-2-methoxytetrahydrofuran (13), and, by analogy to the preceding section, the effect of interactions between the anomeric substituent and the adjacent hydroxyl group at C2 can be inferred from an analysis of cis- and trans-2-methoxytetrahydrofuran-3-ol (14 and 15, respectively). Torsion terms derived from fitting to 13 (Cf-Of-Cf-Os and Cf-Cf-Cf-Os), implicitly include any contributions from the anomeric effect (Callam and Lowary 2001; Cosse-Barbi and Dubois 1987; Cossé-Barbi et al. 1989; D'Souza et al. 2000; Ellervik and Magnusson 1994; Plavec et al. 1993; Thibaudeau and Chattopadhyaya 1997). In GLYCAM06, both the endo- and exo-anomeric torsion terms were parameterized by fitting to small acyclic molecular fragments, leading to the same set of terms for both applications. Here the torsion terms were derived for intact five-membered rings, with furanose-specific atom types for the ring atoms (Cf and Of), leading to unique terms for the endo- (Cf-Of-Cf-Os, and Cf-Cf-Cf-Os) and exo-anomeric (Of-Cf-Os-Cf/Cg and Cf-Cf-Os-Cf/Cg) sequences. As shown in Fig. S7, the torsion angle terms for endo-anomeric sequence reproduced the lowest energy conformation, as well as the overall shape of pseudorotational energy curve. It should be noted that the new parameters lead to a local energy minimum at P = 99°, while a similar minimum appears at P = 71° in the QM energy curve. The torsion angle parameters derived from 14 and 15 gave rise to slightly larger errors, reflecting in part the challenge of fitting highly asymmetric energy curves using a sum of symmetric cosine functions. The torsion angle terms for exo-anomeric sequence reproduced the rotational energy profiles of 13 in both northern (P = 0°) and southern (P = 180°) ring conformations (Fig. S8). Features of the endo- and exo-anomeric effects in furanoses are discussed in the following sections. Endo-anomeric effect In carbohydrates, the anomeric effect relates to the preference of the endocyclic C-O-C-O torsion angle to adopt the gauche orientation over the anti conformation (Cossé-Barbi et al. 1989; Jeffrey et al. 1978; Juaristi and Cuevas 1992), and has been estimated from quantum mechanical calculations for pyranoses (Lii et al. 2003; Senderowitz et al. 1996) and related acyclic fragments (Jeffrey et al. 1978; Lii et al. 2005) to be 1–2 kcal/mol. Its presence in furanoses has been invoked as contributing to ring conformational preferences (Callam and Lowary 2001; Cosse-Barbi and Dubois 1987; Cossé-Barbi et al. 1989; D'Souza et al. 2000; Ellervik and Magnusson 1994; Houseknecht et al. 2003a; Plavec et al. 1994; Plavec et al. 1996; Plavec et al. 1993; Thibaudeau and Chattopadhyaya 1997; Thibaudeau et al. 1994), and is consistent with the observation that electronegative substituents at C1 in furanoses prefers a pseudoaxial over a pseudoequatorial configuration,29–34 but it has not been quantified computationally. We address this here by noting that, over the course of the pseudorotational itinerary for 13, the endocyclic C4-O4-C1-O torsion angle spans a range of 80 to 160°, or pseudo-gauche to pseudo-anti. Thus the strength of the endo-anomeric effect in furanoses can be estimated to be 3.2 kcal/mol at the B3LYP/6-31G* level. In contrast, methoxycyclopentane (16) shows no such effect (Fig. 4). The endo-anomeric effect stabilizes eastern ring conformations (C4-O4-C1-O angle is less than 100°) but not western conformations (C4-O4-C1-O angle is greater than 140°). Therefore, western conformations in α-anomers (or eastern conformation in β-anomers) display high potential energies. Exo-anomeric effect The preference of the exocyclic C1-O bond in pyranoses to adopt gauche orientations is a direct corollary to the endo-anomeric effect, and this exo-anomeric effect has been extensively studied in pyranoses and acyclic molecules (Jeffrey et al. 1978; Kirschner et al. 2008; Lemieux and Koto 1974; Tvaroska and Bleha 1989). To determine the strength of the exo-anomeric effect in furanoses, the rotational energies of the O4-C1-O-CH3 torsion angle in 13 were computed for both North (P = 0°) and South (P = 180°) conformations. The exo-anomeric energy stabilizes the gauche orientations of the C1-O bond in 13, relative to the cyclopentane analog 16, by approximately 4 kcal/mol, which is comparable to that reported for pyranoses (Kirschner et al. 2008) (Fig. 5). This contribution is particularly important for defining the 3D structure of polymers of furanoses, as it reduces the conformational freedom of the C1-O bond to effectively a single state. Assessments of solution populations The performance of the new parameters was assessed by comparing NMR 3J-coupling constants for conformations observed in MD simulations (300 ns) of furanosides with their experimental values. Based on monitoring the P-values (Fig. S9) convergence in ring interconversion was obtained within this timescale. By employing quantum mechanical 3J-coupling constants corresponding to the states observed in the MD simulation, it was possible to avoid employing empirical Karplus equations (Altona et al. 1994; Bose et al. 1998; Cloran et al. 1999; Haasnoot et al. 1980; Houseknecht et al. 2003b; Stenutz et al. 2002; Taha et al. 2010; Taha et al. 2011; Zhao et al. 2007) or invoking approximations associated with the two-state model. GLYCAM06 was developed for use with partial atomic charges derived from electrostatic fitting to QM values computed at the HF/6-31G* level, however, we wished to examine what impact might arise from fitting to potentials computed at a higher level of theory. Recently, it has been shown that dipole moments computed at the B3LYP/cc-pVTZ level have approximately one half of the average error of those computed at the HF/6-31G* level (Hickey and Rowley 2014), and so we compared data for monosaccharide charge sets computed at both levels. Both charge sets led to very similar distributions of solution conformations, as indicated by the resulting J-couplings, which differ by on average 0.1 Hz (Table 1 and Table S7). Thus the following discussion focuses only on the data generated with the B3LYP/cc-pVTZ charges. The average error between the computed and experimental 3J-coupling constants for 1–4 (α and β) and 5β was within 0.9 Hz. It is notable that, while the overall agreement with experiment is good, in the case of 2α, the theoretical value for the 3JC1,H4 coupling constant (0.6 Hz) is significantly below that reported experimentally (3.7 Hz). However, this coupling constant is less than 0.5 Hz in all other α-anomers, suggesting a potential error in the experimental data. In the case of 5β there is also a significant difference between the theoretical (9.2 Hz) and experimental (~5.7 Hz) values for the 3JH2R,H3 coupling constant, however, the experimental report noted uncertainty in that particular measurement (Church et al. 1997). The rotamer distributions for the C4-C5 were also generated, and the average error between theoretical and experimental 3J-values associated with this bond for 1 (α and β), 3 (α and β) and 5β was 0.4 Hz; while that for 2 (α and β) and 4 (α and β) was 1.4 Hz (Table 2 and Table S8). The origin of the larger average error in these latter cases is uncertain, but may relate to the fact that the parameters for the C4-C5 bond were imported from GLYCAM06 and not re-derived herein. The overall correlation (R2) between the theoretical and experimental 3J-values for coupling constants related to ring conformation was computed to be 0.76 (see Fig. S10). Two-state equilibrium model The ring conformation distributions of 1–4 (α and β) and 5β in explicit solvent MD simulations are shown in Fig. 6. The majority of the furanoses populated conformations predominantly in the northern and southern regions, and could therefore be described as approximately satisfying a two-state distribution, regardless of the partial charge model. A notable exception to this was seen for 1α, which populated a continuum of states from North to South via the eastern side of the pseudorotational itinerary. This is in contrast both to the other furanoses, and to earlier studies of 1α, performed with GLYCAM06 that indicated a preponderant population of states in the North (Seo et al. 2008). The overall agreement between the theoretical and experimental NMR data from the present simulations provides compelling support for the present simulation results. By plotting conformational energies onto the pseudorotational surface (Fig. 7 and Fig. S11), it is possible to conveniently visualize the presence or absence of energy barriers between northern and southern states. In the case of a furanoside such as 3β, that prefers conformations in the North and South, both quantum- and classically-computed conformational energies confirm the presence of barriers in the East and West, resulting in a clear division of the conformational space into northern and southern quadrants (Fig. 7). In contrast, in the case of 1α, both quantum and classical mechanical methods indicate a barrier only in the West, enabling the ring to populate a continuous distribution of conformations from North to South via the East. Previous NMR (Angyal 1979; Serianni and Barker 1984; Taha et al. 2010), as well as QM (D'Souza et al. 2000; Gordon et al. 1999) studies, have also been shown to be consistent with conformations in the North, East, and South and it has been proposed that the anomeric effect (Cosse-Barbi and Dubois 1987; Cossé-Barbi et al. 1989; D'Souza et al. 2000; Ellervik and Magnusson 1994; Juaristi and Cuevas 1992; Plavec et al. 1993; Richards et al. 2013; Thibaudeau and Chattopadhyaya 1997) and the gauche effect (Callam and Lowary 2001; D'Souza et al. 2000; Houseknecht et al. 2003a; Plavec et al. 1994; Plavec et al. 1996; Plavec et al. 1993; Thibaudeau and Chattopadhyaya 1997; Thibaudeau et al. 1994) among the vicinal hydroxyl groups and the ring oxygen atom were the key influences on ring conformation in furanoses. In the case of 1α, it has been argued that the anomeric and gauche effects both stabilize the South conformation (Callam and Lowary 2001; D'Souza et al. 2000; Gordon et al. 1999; Houseknecht et al. 2003a). From the analysis of the anomeric effect presented in Fig. 4, we can conclude that the barrier in the western quadrant in 1α is due in part to the absence of stabilizing contributions from the anomeric effect. In the case of other furanoses, for example 3β, in which there are syn-interactions between hydroxyl groups, an examination of the interaction energies between the hydroxyl groups and the ring oxygen atom (Fig. 8) leads to the conclusion that repulsions between these groups introduce a barrier in the eastern quadrant. Thus in furanoses other than 1α (that has no cis-hydroxyl groups), either the lack of an anomeric effect, or the presence of repulsive oxygen-oxygen interactions results in barriers in both the East and West, effectively establishing a preference for the populations in the North and South. Conclusions The present study confirms that the two-state model, commonly employed in interpreting ring conformations of furanoses in solution, is not applicable to all furanoses. Results from MD simulation indicated that 1α exhibited a continuum distribution from North to South via East of pseudorotation, which agreed with the low energy pathway found in its pseudorotational potential energy surface, and gave rise to experimentally-consistent scalar coupling values for the ring protons. Nevertheless, the two-state model is a reasonable description for other furanoses, to the extent that their ring conformations broadly populate the northern and southern quadrants. The division (or not) of the populations into two states can be explained by the presence (or absence) energy penalties in East and West regions of the pseudorotation itinerary. These barriers are found to arise from the absence of a stabilizing anomeric effect and unfavorable interactions among vicinal hydroxyl groups and the ring oxygen atom. Notably, the new force field parameters permit accurate simulations of furanoses to be performed (average difference between theoretical and experimental NMR 3J-values was within 1 Hz), making the need to adopt an assumption about state preferences obsolete. This is likely to be particularly valuable when examining complex oligofuranosides that may contain additional chemical modifications, as are typical in bacterial (Besra et al. 1995; Bhamidi et al. 2008; Brennan and Nikaido 1995; Crick et al. 2001) or fungal pathogen (Beauvais et al. 2007; Costachel et al. 2005; Fontaine et al. 2000; Lamarre et al. 2009; Latge et al. 1994; Leitao et al. 2003) surfaces. The ability to characterize the conformational properties of such structures is an important component in understanding the mechanisms of disease infection (Carapito et al. 2009; Golgher et al. 1993), as well as immune response (Cooper and Petrovsky 2011; Predy et al. 2005). Supplementary Material 10858_2016_28_MOESM1_ESM The authors thank the NIH for support (R01 GM100058, P41 GM103390) and wish to thank Dr. Anthony S. Serianni at the University of Notre Dame for helpful discussions. Fig. 1 Pseudorotational itinerary of furanoses depicting different Envelope (E) and Twist (T) ring conformations with associated conformational phase angle (P) values in degrees. Fig. 2 Methyl D-furanosides examined in present study. Fig. 3 Pseudorotational energy curves for 6. Solid lines: energies computed at the B3LYP/6-31G* level to be consistent with the GLYCAM06 parameters (Kirschner et al. 2008); dashed lines: energies computed with new parameters. Fig. 4 Upper: pseudorotational energy curves for 13 with each quadrant of pseudorotation color coded and 16 (grey) computed at the B3LYP/6-31G* level, with the orientation of the exocyclic O4-C1-O-CH3 torsion angle restrained at 60°. Lower: the relative energy of 13 and 16 as functions of the C4-O4-C1-O and C4-C5-C1-O torsions, respectively. Fig. 5 Rotational energy curves of O4-C1-O-CH3 angle in 13 (black) and C5-C1-O-CH3 angle in 16 (grey) computed at B3LYP/6-31G* level, while maintaining the ring conformation at P = 0 (a) and 180° (b); rotational energy curves of O5-C1-O-CH3 angle in (S)-2-methoxytetrahydropyran (17) (black) and C6-C1-O-CH3 angle in methoxycyclohexane (18) (grey) computed at B3LYP/6-31G* level, while maintaining the ring conformation at 1C4 (c) and 4C1 (d). Regions stabilized by the exo-anomeric effect are indicated by vertical arrows. Fig. 6 Ring conformation distribution for 1–4 (α and β) and 5β from MD simulations (300 ns each), red/blue lines correspond to data from the HF/6-31G* and B3LYP/cc-pVTZ-derived partial charge models, respectively. a-d: α anomers of 1–4, e-i: β anomers of 1–5. Fig. 7 Pseudorotational potential energy surfaces for 1α (left) and 3β (right), generated with partial atomic charges computed at the B3LYP/cc-pVTZ level. a, b: energies computed at the B3LYP/6-31G* level; c, d: energies computed after energy minimization in the gas phase; e, f: energies computed for conformations observed in explicitly solvated MD simulations, without energy minimization. Details provided in METHODS. Fig. 8 Pseudorotational energy curves for 7 (upper) and 8 (bottom) computed at the B3LYP/6-31G* level, with the orientation of the vicinal hydroxyl groups (C2-C3-O3-H3O and C3-C2-O2-H2O) restrained at 180°. Curves in each quadrant of pseudorotation are color coded. Table 1 MD-deriveda, Karplus-equation-derived, and experimental 1H-1H and 13C-1H coupling constants for 1–4 (α and β) and 5β. 1H- 1H coupling constants (Hz) 3JH1,H2 3JH2,H3 3JH3,H4 3JC1,H4 MD/ QMb MD/ Karplusc,d Expt. MD/ QM MD/ Karplusd Expt. MD/ QM MD/ Karplusd Expt. MD/ QM MD/ Karplus f Expt. 1α 1.7 2.2 1.7e 3.6 2.9 3.4e 5.5 4.6 5.8e 0.8 1.0 <0.5f,g 1β 5.4 5.6 4.5h 5.9 4.7 7.9h 5.3 4.8 6.7h 3.9 1.8 3.2f 2α 3.4 4.5 3.6i 5.4 4.9 4.8i 5.4 4.9 4.3i 0.7 0.6 3.7f 2β 6.1 5.7 4.8i 5.6 4.9 5.0i 4.7 4.5 4.6i 1.8 0.3 2.2f 3α 4.7 5.5 4.3j 6.2 5.3 6.2j 5.9 5.4 3.4j 0.7 1.1 <0.5f,g 3β 0.6 1.2 1.2j 5.7 4.9 4.6j 8.2 7.0 6.9j 2.8 0.9 2.7f 4α 4.4 5.0 4.5i 2.9 2.3 5.5i 5.3 4.6 6.1i 0.1 0.3 <0.5f,g 4β 0.4 1.3 -i 1.5 1.3 1.7i 4.6 4.7 5.1i 1.4 0.4 2.4f 5β 1.7/6.2k 2.3/6.5k 2.6/5.4k,l 7.9/9.2k 7.7/6.9k 6.7/~5. 7k,l 5.2 5.2 4.2l a Computed with partial atomic charges fit to the B3LYP/cc-pVTZ QM potentials. b The standard derivations of all MD derived 3J-values are within approximately 0.3 Hz. c The standard derivations of all Karplus-equation-derived 3J-values are within approximately 0.1 Hz. d Altona et al. 1994. e Taha et al. 2010. f Houseknecht et al. 2003b. g A value of 0 Hz was employed in calculations of average error between the computed and experimental 3J-values. h Taha et al. 2011. i Serianni and Barker 1984. j Kline and Serianni 1990. k Reference are reported for couplings involving H2S and H2R (S/R). l Church et al. 1997. Table 2 MD-deriveda, Karplus-equation-derived, and experimental 3JH4,H5S and 3JH4,H5R values for 1–4 (α and β) and 5β. 1H-1H coupling constants (Hz) 3JH4,H5S 3JH4,H5R MD/QMb MD/Karplusc,d Expt. MD/QM MD/Karplus Expt. 1α 3.9 3.3 3.3e 6.1 5.3 5.8e 1β 4.0 3.4 3.4f 6.5 5.8 6.7f 2α 3.5 3.1 4.4g 8.7 7.8 6.7g 2β 3.1 3.0 4.5g 9.2 8.1 7.6g 3α 3.5 3.0 3.3h 5.1 4.8 4.6h 3β 3.5 3.1 3.1h 6.8 6.0 6.6h 4α 3.6 3.3 3.8g 8.8 7.7 6.0g 4β 3.3 3.1 4.4g 9.1 7.9 7.6g 5β 3.4 3.2 4.6i 6.8 6.0 7.0i a Computed with partial atomic charges fit to the B3LYP/cc-pVTZ QM potentials. b The standard derivations of all MD derived 3J-values are within approximately 0.5 Hz. c The standard derivations of all Karplus equation derived 3J-values are within approximately 0.4 Hz. d Altona et al. 1994. e Taha et al. 2010. f Taha et al. 2011. g Serianni and Barker 1984. h Kline and Serianni 1990. i Church et al. 1997. 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Experimental Evidence from Conformationally Restricted Compounds J Am Chem Soc 116 2340 2347 10.1021/ja00085a013 Fontaine T 2000 Molecular organization of the alkali-insoluble fraction of Aspergillus fumigatus cell wall Journal of Biological Chemistry 275 27594 27607 10869365 Golgher DB Colli W Soutopadron T Zingales B 1993 GALACTOFURANOSE-CONTAINING GLYCOCONJUGATES OF EPIMASTIGOTE AND TRYPOMASTIGOTE FORMS OF TRYPANOSOMA-CRUZI Molecular and Biochemical Parasitology 60 249 264 10.1016/0166-6851(93)90136-l 8232416 Gonzalez-Outeirino J Kirschner KN Thobhani S Woods RJ 2006 Reconciling solvent effects on rotamer populations in carbohydrates - A joint MD and NMR analysis Can J Chem-Rev Can Chim 84 569 579 10.1139/v06-036 Gordon MT Lowary TL Hadad CM 1999 A computational study of methyl alpha-D-arabinofuranoside: Effect of ring conformation on structural parameters and energy-profile J Am Chem Soc 121 9682 9692 10.1021/ja9915091 Haasnoot CAG de Leeuw FAAM Altona C 1980 The relationship between proton-proton NMR coupling constants and substituent electronegativities—I : An empirical generalization of the karplus equation Tetrahedron 36 2783 2792 doi:http://dx.doi.org/10.1016/0040-4020(80)80155-4 Hatcher E Guvench O MacKerell AD 2009 CHARMM Additive All-Atom Force Field for Aldopentofuranoses, Methyl-aldopentofuranosides, and Fructofuranose J Phys Chem B 113 12466 12476 10.1021/jp905496e 19694450 Hendrickx PMS Corzana F Depraetere S Tourwe DA Augustyns K Martins JC 2010 The Use of Time-Averaged (3)J(HH) Restrained Molecular Dynamics (tar-MD) Simulations for the Conformational Analysis of Five-Membered Ring Systems: Methodology and Applications Journal of Computational Chemistry 31 561 572 10.1002/jcc.21345 19530112 Hickey AL Rowley CN 2014 Benchmarking Quantum Chemical Methods for the Calculation of Molecular Dipole Moments and Polarizabilities The Journal of Physical Chemistry A 118 3678 3687 10.1021/jp502475e 24796376 Houseknecht JB Lowary TL Hadad CM 2003a Gas- and solution-phase energetics of the methyl alpha- and beta-D-aldopentofuranosides J Phys Chem A 107 5763 5777 10.1021/jp027716w Houseknecht JB Lowary TL Hadad CM 2003b Improved Karplus equations for (3)J(C1,H4) in aldopentofuranosides: Application to the conformational preferences of the methyl aldopentofuranosides J Phys Chem A 107 372 378 10.1021/jp026610y Ishii T Ohga S Fukada K Morimoto K Sakane G 2014 beta-d-Gulose Acta crystallographica Section E, Structure reports online 70 o569 10.1107/s1600536814008046 Ishii T Senoo T Kozakai T Fukada K Sakane G 2015 Crystal structure of beta-d,l-allose Acta crystallographica Section E, Crystallographic communications 71 o139 10.1107/s2056989015000353 Jeffrey GA Pople JA Binkley JS Vishveshwara S 1978 APPLICATION OF ABINITIO MOLECULAR-ORBITAL CALCULATIONS TO STRUCTURAL MOIETIES OF CARBOHYDRATES. 3 J Am Chem Soc 100 373 379 10.1021/ja00470a003 Juaristi E Cuevas G 1992 RECENT STUDIES OF THE ANOMERIC EFFECT Tetrahedron 48 5019 5087 10.1016/s0040-4020(01)90118-8 Kirschner KN Yongye AB Tschampel SM Gonzalez-Outeirino J Daniels CR Foley BL Woods RJ 2008 GLYCAM06: A generalizable Biomolecular force field Carbohydrates Journal of Computational Chemistry 29 622 655 10.1002/jcc.20820 17849372 Kline PC Serianni AS 1990 C-13-ENRICHED RIBONUCLEOSIDES - SYNTHESIS AND APPLICATION OF C-13-H-1 AND C-13-C-13 SPIN-COUPLING CONSTANTS TO ASSESS FURANOSE AND N-GLYCOSIDE BOND CONFORMATIONS J Am Chem Soc 112 7373 7381 10.1021/ja00176a043 Lamarre C 2009 Galactofuranose attenuates cellular adhesion of Aspergillus fumigatus Cellular Microbiology 11 1612 1623 10.1111/j.1462-5822.2009.01352.x 19563461 Latge JP 1994 CHEMICAL AND IMMUNOLOGICAL CHARACTERIZATION OF THE EXTRACELLULAR GALACTOMANNAN OF ASPERGILLUS-FUMIGATUS Infection and Immunity 62 5424 5433 7960122 Leitao EA 2003 beta-Galactofuranose-containing O-linked oligosaccharides present in the cell wall peptidogalactomannan of Aspergillus fumigatus contain immunodominant epitopes Glycobiology 13 681 692 10.1093/glycob/cwg089 12851285 Lemieux RU Koto S 1974 The conformational properties of glycosidic linkages Tetrahedron 30 1933 1944 doi:http://dx.doi.org/10.1016/S0040-4020(01)97324-7 Levitt M Warshel A 1978 Extreme conformational flexibility of the furanose ring in DNA and RNA J Am Chem Soc 100 2607 2613 10.1021/ja00477a004 Lii J-H Chen K-H Allinger NL 2003 Alcohols, ethers, carbohydrates, and related compounds. IV. carbohydrates Journal of Computational Chemistry 24 1504 1513 10.1002/jcc.10271 12868113 Lii JH Chen KH Johnson GP French AD Allinger NL 2005 The external-anomeric torsional effect Carbohydr Res 340 853 862 10.1016/j.carres.2005.01.032 15780251 Longchambon F Avenel D Neuman A 1976 CRYSTAL-STRUCTURE OF ALPHA-D-MANNOPYRANOSE Acta Crystallogr Sect B-Struct Sci 32 1822 1826 10.1107/s0567740876006468 McDonald TRR Beevers CA 1952 THE CRYSTAL AND MOLECULAR STRUCTURE OF ALPHA-GLUCOSE Acta Crystallographica 5 654 659 10.1107/s0365110x52001787 Ohanessian J Avenel D Kanters JA Smits D 1977 2 INDEPENDENT DETERMINATIONS OF CRYSTAL-STRUCTURE OF ALPHA-D-TALOPYRANOSE Acta Crystallogr Sect B-Struct Sci 33 1063 1066 10.1107/s0567740877005378 Ohanessian J Gillierpandraud H 1976 CRYSTAL-STRUCTURE OF ALPHA-D-GALACTOSE Acta Crystallogr Sect B-Struct Sci 32 2810 2813 10.1107/s0567740876008947 Padrta P Sklenar V 2002 Program MULDER - A tool for extracting torsion angles from NMR data Journal of Biomolecular Nmr 24 339 349 10.1023/a:1021656808607 12522298 Plavec J Thibaudeau C Chattopadhyaya J 1994 How Does the 2'-Hydroxy Group Drive the Pseudorotational Equilibrium in Nucleoside and Nucleotide by the Tuning of the 3'-Gauche Effect? J Am Chem Soc 116 6558 6560 10.1021/ja00094a009 Plavec J Thibaudeau C Chattopadhyaya J 1996 How do the energetics of the stereoelectronic gauche and anomeric effects modulate the conformation of nucleos(t)ides? Pure Appl Chem 68 2137 2144 10.1351/pac199668112137 Plavec J Tong W Chattopadhyaya J 1993 How do the gauche and anomeric effects drive the pseudorotational equilibrium of the pentofuranose moiety of nucleosides? J Am Chem Soc 115 9734 9746 10.1021/ja00074a046 Predy GN Goel V Lovlin R Donner A Stitt L Basu TK 2005 Efficacy of an extract of North American ginseng containing poly-furanosyl-pyranosyl-saccharides for preventing upper respiratory tract infections: a randomized controlled trial Canadian Medical Association Journal 173 1043 1048 10.1503/cmaj.1041470 16247099 Raman EP Guvench O MacKerell AD 2010 CHARMM Additive All-Atom Force Field for Glycosidic Linkages in Carbohydrates Involving Furanoses The Journal of Physical Chemistry B 114 12981 12994 10.1021/jp105758h 20845956 Richards MR Bai Y Lowary TL 2013 Comparison between DFT- and NMR-based conformational analysis of methyl galactofuranosides Carbohydr Res 374 103 114 10.1016/j.carres.2013.03.030 23660004 Senderowitz H Parish C Still WC 1996 Carbohydrates: United Atom AMBER*Parameterization of Pyranoses and Simulations Yielding Anomeric Free Energies J Am Chem Soc 118 2078 2086 10.1021/ja9529652 Seo M Castillo N Ganzynkowicz R Daniels CR Woods RJ Lowary TL Roy PN 2008 Approach for the simulation and modeling of flexible rings: Application to the alpha-D-arabinofuranoside ring, a key constituent of polysaccharides from Mycobacterium tuberculosis J Chem Theory Comput 4 184 191 10.1021/ct700284r 25339852 Serianni AS Barker R 1984 C-13 -ENRICHED TETROSES AND TETROFURANOSIDES - AN EVALUATION OF THE RELATIONSHIP BETWEEN NMR PARAMETERS AND FURANOSYL RING CONFORMATION J Org Chem 49 3292 3300 10.1021/jo00192a009 Stenutz R Carmichael I Widmalm G Serianni AS 2002 Hydroxymethyl Group Conformation in Saccharides: Structural Dependencies of 2JHH, 3JHH, and 1JCH Spin Spin Coupling Constants The Journal of Organic Chemistry 67 949 958 10.1021/jo010985i 11856043 Sun G Voigt JH Filippov IV Marquez VE Nicklaus MC 2004 PROSIT: Pseudo-Rotational Online Service and Interactive Tool, Applied to a Conformational Survey of Nucleosides and Nucleotides Journal of Chemical Information and Computer Sciences 44 1752 1762 10.1021/ci049881+ 15446834 Taha HA Castillo N Sears DN Wasylishen RE Lowary TL Roy PN 2010 Conformational Analysis of Arabinofuranosides: Prediction of (3)J(H,H) Using MD Simulations with DFT-Derived Spin-Spin Coupling Profiles J Chem Theory Comput 6 212 222 10.1021/ct900477x 26614332 Taha HA Richards MR Lowary TL 2013 Conformational Analysis of Furanoside-Containing Mono- and Oligosaccharides Chem Rev 113 1851 1876 10.1021/cr300249c 23072490 Taha HA Roy PN Lowary TL 2011 Theoretical Investigations on the Conformation of the beta-D-Arabinofuranoside Ring J Chem Theory Comput 7 420 432 10.1021/ct100450s 26596163 Thibaudeau C Chattopadhyaya J 1997 The discovery of intramolecular stereoelectronic forces that drive the sugar conformation in nucleosides and nucleotides Nucleosides & Nucleotides 16 523 529 10.1080/07328319708002912 Thibaudeau C Plavec J Chattopadhyaya J 1994 Quantitation of the Anomeric Effect in Adenosine and Guanosine by Comparison of the Thermodynamics of the Pseudorotational Equilibrium of the Pentofuranose Moiety in N- and C-Nucleosides J Am Chem Soc 116 8033 8037 10.1021/ja00097a010 Tvaroska I Bleha T 1989 ANOMERIC AND EXO-ANOMERIC EFFECTS IN CARBOHYDRATE CHEMISTRY Tipson RS Horton D Advances in Carbohydrate Chemistry and Biochemistry 45 124 Zhao H Pan Q Zhang W Carmichael I Serianni AS 2007 DFT and NMR Studies of 2JCOH, 3JHCOH, and 3JCCOH Spin-Couplings in Saccharides: C O Torsional Bias and H-Bonding in Aqueous Solution The Journal of Organic Chemistry 72 7071 7082 10.1021/jo0619884 17316047
PMC005xxxxxx/PMC5115637.txt
LICENSE: This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. 101652055 43566 J Nat Sci J Nat Sci Journal of nature and science 2377-2700 27868087 5115637 NIHMS827866 Article Diabetic Wound Healing and Activation of Nrf2 by Herbal Medicine Senger Donald R. 1 Cao Shugeng 2* 1 Department of Pathology and Center for Vascular Biology Research, Beth Israel Deaconess Medical Center, Harvard Medical School, 330 Brookline Avenue, Boston, MA 02215, USA 2 Department of Pharmaceutical Sciences, Daniel K Inouye College of Pharmacy, University of Hawaii at Hilo, 200 W. Kawili Street, Hilo, HI 96720, USA * Corresponding Author. scao@hawaii.edu 6 11 2016 2016 18 11 2016 2 11 e247This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. Nrf2 defense is a very important cellular mechanism to control oxidative stress, which is implicated in wound healing. Nrf2 can induce many cytoprotective genes, including HO-1, NQO1 and G6PD. Among many natural products that have been reported as Nrf2 activators, sulforaphane and curcumin have been studied more widely than any others, and both are in clinical trials for non-cancerous disorders. Recently, we reported 4-ethyl catechol and 4-vinyl catechol as Nrf2 co-factors that can induce Nrf2 as potently as sulforaphane and curcumin. These new Nrf2 co-factors were identified in hot aqueous extract of an herbal medicine Barleria lupulina, and fermented Noni (Morinda citrifolia) juice, which are used traditionally for diabetic wound healing. Nrf2 diabetic wound healing herbal medicine Barleria lupulina Morinda citrifolia alkyl catechols The Nrf2 defense pathway In mammals, the master regulator of antioxidant defense is the Nrf2 pathway1,2. The Nrf2 transcription factor controls expression of anti-oxidant and detoxifying enzymes that maintain a healthy cellular redox state and protect against toxic foreign chemical substances through phase II modification3, which neutralizes dangerous species, generating less reactive and more soluble substances that are readily eliminated4. The network of cytoprotective genes regulated by Nrf2 is more than two hundred5, accounting for more than 1% of the genome6. In the absence of stress, Nrf2 with a half-life of about 20 minutes7 is sequestered within the cytosol by the actin-binding protein Kelch-like ECH-associated protein 1 (KEAP1) and Cullin 3, which degrade Nrf2 through ubiquitination8. Under conditions of oxidative stress, Nrf2 is released from Keap1 and rapidly moves to the nucleus to induce transcription of anti-oxidant and detoxifying enzymes. The “redox sensor” mechanism that releases Nrf2 from Keap1, resulting in Nrf2 transport to the nucleus, involves oxidation-sensitive sulfhydryl groups in cysteine residues of Keap19. Nrf2 induction of cytoprotective genes and diabetic wound healing Compelling evidence for the importance of the Nrf2 pathway comes from numerous studies with mice lacking the Nrf2 gene. These Nrf2 null mice exhibit increased sensitivity to a multitude of chemical toxins, resulting in increased inflammation and damage to brain, lung, and kidney2,10. Similarly, Nrf2 null mice are considerably more sensitive to chemical carcinogens, with increased incidence of cancers demonstrated in skin, stomach, colon, and bladder2,11,12. Also, mice engineered with a dominant negative Nrf2 mutant transgene develop skin cancer at three times the frequency of control mice in a classical two-stage model of chemical carcinogenesis13. Additional problems for Nrf2 null mice include impaired liver regeneration14, accelerated UVB-induced photo-ageing of skin15, increased rheumatoid arthritis16, development of lupus-like autoimmune nephritis17, and development of age-related retinopathy18. Thus, the protective importance of the Nrf2 pathway is well established. Diabetes often causes slow-healing wounds that can worsen rapidly. The Keap1-Nrf2 system is a critical target for preventing the onset of diabetes mellitus19. Nrf2 transcription factor, a novel target of keratinocyte growth factor action, regulates gene expression and inflammation in the healing skin wound20. In a streptozotocin-induced diabetes mouse model, Nrf2−/− mice have delayed wound closure rates compared with Nrf2+/+ mice21. Hence, Nrf2 can be activated to potentially heal diabetic wounds and improve overall health. Nrf2 small molecule co-factors were first discovered as “cancer-protective” compounds, which could be utilized for diabetic wound healing Long before the discoveries of Nrf2 and the antioxidant response element (ARE) to which Nrf2 binds, a variety of small chemical compounds were observed to protect rodents from chemically induced carcinogenesis22. Remarkably, these “cancer-protective” compounds were from distinctly different chemical classes, but they all shared the critical property of high susceptibility to oxidation-reduction reactions23. The simplest of these active cancer-protective compounds were identified as 1,4-diphenol (hydroquinone) and 1,2-diphenol (catechol), and more complex examples include the isothiocyanate sulforaphane isolated from broccoli24 and curcumin from the turmeric plant25 (see Figure 1). With the discovery of Nrf2, it became clear that these previously identified redox-sensitive, cancer-protective compounds worked as co-factors for Nrf2 activation26. Collectively, these findings suggested that support of Nrf2 activation by redox-sensitive co-factors, particularly dietary factors such as sulforaphane and curcumin, could be employed as an effective anti-cancer strategy27. This provided impetus for clinical trials28,29, which are continuing. Sulforaphane and curcumin are also currently in clinical trials for non-cancer disorders in which the Nrf2 pathway has been implicated. Current challenges with the application of sulforaphane and curcumin for clinical benefit appear to involve bioavailability of these compounds28–32. Acrolein (CHO-CH=CH) induces Nrf2 translocation and ARE-luciferase reporter activity33. Cinnamaldehyde (Ph-CH=CH-CHO, trans double bond) inhibits thioredoxin reductase and induce Nrf234. Recent studies have demonstrated the protective role of Nrf2 and the potential therapeutic effect of Nrf2 activators, sulforaphane and cinnamaldehyde in a diabetic nephropathy animal model21. The alkyl catechols, 4-ethyl catechol and 4-vinyl catechol, potent Nrf2 co-factors, from Barleria lupulina and Morinda citrifolia, both of which are used traditionally for diabetic wound healing Barleria lupulina (BL): Recently, our work with a traditional Vietnamese medicine (Barleria lupulina, BL) has identified 4-ethyl catechol and 4-vinyl catechol as potently active, natural Nrf2 co-factors35 (Figure 2) in the hot water extract of Barleria lupulina. Although these compounds had been reported, they had not been recognized as important Nrf2 co-factors. Nonetheless, these compounds each satisfy the well-defined structural criteria for “oxidation-reduction lability” that is required for a compound to induce protective enzymes23,36. Interestingly, catechol (Figure 2) was among the first compounds recognized as an Nrf2 co-factor23, but 4-ethyl catechol and 4-vinyl catechol had not received attention. Importantly, we found that 4-ethyl catechol and 4-vinyl catechol are much more potent Nrf2 co-factors than catechol and that they are comparably potent to sulforaphane and curcumin37. Thus, apart from sulforaphane and curcumin, we believe that 4-ethyl catechol and 4-vinyl catechol may be the most potent of the naturally occurring Nrf2 co-factors. Moreover, the relatively small size and simple structure of these compounds, suggests the likelihood of better bioavailability than sulforaphane and curcumin. We have reported the activities of these alkyl catechols recently37. Besides inducing Nrf2, BL, 4-EC and 4-VC significantly improved the organization of the endothelial cell actin cyto-skeleton, reduced actin stress fibers, organized cell-cell junctions, and induced expression of mRNA encoding claudin-5 that is important for formation of endothelial tight junctions and reducing vascular leak35. Morinda citrifolia (Noni): Encouraged by the discovery of new Nrf2 co-factors, 4-MC, 4-EC, and 4-VC from the hot water extract of Barleria lupulina, we screened many herbs for their activity of Nrf2 activation. Only fermented Noni juice (Order Number 809979, Virgin Noni juice, http://www.virginnonijuice.com) showed Nrf2 activation, which was as strong as BL. The traditional medicinal plant Morinda citrifolia L. (Rubiaceace) is believed to have the origin in Southeast Asia and later on distributed to Polynesia. It is called Indian mulberry in India, ba ji tian () in China, nono in Tahiti, and noni in Hawaii38. Noni is now widely cultivated in tropical areas of the South Pacific, including Hawaii39. Traditionally, noni bark and roots were used as dye or clothing, while medicinal usage of all plant parts, including leaves and fruits, were mostly restricted to treat wounds, infections, menstrual cramps, bowel irregularities, diabetes, high blood pressure or as a purgative40. Pacific Islanders and Native Hawaiians consume fresh fruits or noni juice prepared by fermenting the fruits39,41. Claims of its ‘healing powers’ fuelled much of the commercial interest in noni and promoting a worldwide market for noni-based dietary supplements including fruit juice, in North America, Mexico, Australia, and Asia. Young Noni fruits are green, and will turn yellow before ripe, but harvested Noni fruits are mainly whitish (Figure 3), and will turn dark after fermentation. We tested FNJ from ripe Noni fruits, and juices from both green and whitish Noni fruits for their activity of Nrf2 activation. Results showed that juice from young green Noni fruits was inactive, and both juice from ripe whitish Noni fruits and FNJ exhibited Nrf2 activation (Figure 4, Figure 5). Using the same assay-guided separation method as described in our previous publication35, we have identified 4-MC, 4-EC, and 4-VC (Figure 2, Figure 6) in FNJ, which partially accounted for the Nrf2 activation. We are in progress of identifying other Nrf2 activators. At the same time, questions remain why juice from ripe whitish Noni fruits with a fouling smell was active while juice from young green Noni fruits was not, and why people prefer FNJ to juice from ripe whitish Noni fruits. Discussion Nrf2 is a master regulator that can modulate many cytoprotective genes. Many small molecules, including natural products, were reported as Nrf2 activators, but only a few showed strong Nrf2 induction. Sulforaphane and curcumin are in clinical trials for non-cancer disorders, and dimethyl fumarate (CH3O-CO-CH= CH-OC-OCH3, trans), an Nrf2 activator, is also in phase III clinical trials for multiple sclerosis42. Many traditional herbal medicines have been used for diabetic wound healing, but most of the active compounds and mechanisms of actions are unknown. We have studied BL and more recently Noni, and we have identified 4-MC, 4-EC, and 4-VC as Nrf2 co-factors. 4-EC and 4-VC demonstrated Nrf2 induction, which were as potent as sulforaphane and curcumin. Since Nrf2 activation by Noni has not been fully characterized, it is worthy of further investigation. This publication was made possible by grant number R01AT007022 (to D.R.S. and S.C.) from the National Center for Complementary and Integrative Health (NCCIH) at the National Institutes of Health. Its contents are solely the responsibility of the authors and do not necessarily represent the official views of NCCIH. This study was also supported by faculty start-up funds from the Daniel K. Inouye College of Pharmacy, University of Hawaii at Hilo (to S.C). Abbreviation BL Barleria lupulina Noni Morinda citrifolia FNJ fermented Noni juice 4-MC 4-methyl catechol 4-EC 4-ethyl catechol 4-VC 4-vinyl catechol Figure 1 Known natural Nrf2 co-factors Figure 2 New Nrf2 co-factors identified in Barleria lupulina and Morinda citrifolia. Figure 3 A Noni tree on campus of University of Hawaii at Hilo and fruits (Young: bottom left, green & hard; Ripe: bottom right, whitish & soft). Figure 4 FNJ induces nuclear translocation of Nrf2 in MVECs MVECs were incubated with FNJ at 1:25 dilution. Staining of Nrf2 in human MVECs incubated with FNJ (right), in comparison with control (left). Green = Nrf2, red = F-actin. Note increased nuclear staining for Nrf2 in cells incubated with FNJ. Overall intensity of Nrf2 staining is also increased, because Nrf2 activation typically involves Nrf2 stabilization in combination with nuclear translocation. Figure 5 Induction of Nrf2 target gene RNAs by FNJ in MVECs, as measured with RT-PCR Y-axis = (mRNA copies)/(106 18S rRNA copies). Nrf2 target genes = heme oxygenase-1 (HO-1), NAD(P)H:quinone oxidoreductase 1 (NQO1), glucose 6-phosphate dehydrogenase (G6PD). Control, non-NRF2 target mRNAs = CD31 (PECAM-1) and VE-cadherin (cadherin-5). FNJ was added to a final dilution of 1:25, and cells were harvested at 24 hours. For all panels, error bars = ± standard deviation (S.D.); n ≥ 4 for each data point. Statistical significance: For HO-1, NQO1, and G6PD panels: FNJ vs. vehicle Ctrl = all extremely significant (p<0.001); for CD31 and VE-cadherin panels: no significant differences. Figure 6 Agilent prep-HPLC HPLC chromatogram of the aqueous acetonitrile eluent of FNJ Sample: FNJ (2 mL/injection, about 150 mg); Flow-rate: 10 mL/min; Solvents: 100% water (0.1% formic acid) for 10 min (0–10 min), then to 100% acetonitrile (0.1% formic acid) in 20 min (10–30 min), finally 100% acetonitrile for 10 min (30–40 min). Y-axis = absorbance at 254nm (mAU), X-axis = minutes. Fraction 11 (tR = 29–31 min) was active and Nrf2 activators 4-MC, 4-EC and 4-VC (minor compounds) were identified. 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Nrf2-deficient female mice develop lupus-like autoimmune nephritis Kidney international 2001 60 4 1343 1353 11576348 18 Zhao Z Chen Y Wang J Age-related retinopathy in NRF2-deficient mice PloS one 2011 6 4 e19456 21559389 19 Uruno A Furusawa Y Yagishita Y The Keap1-Nrf2 system prevents onset of diabetes mellitus Molecular and cellular biology 2013 33 15 2996 3010 23716596 20 Braun S Hanselmann C Gassmann MG Nrf2 transcription factor, a novel target of keratinocyte growth factor action which regulates gene expression and inflammation in the healing skin wound Molecular and cellular biology 2002 22 15 5492 5505 12101242 21 Long M Rojo de la Vega M Wen Q An Essential Role of NRF2 in Diabetic Wound Healing Diabetes 2016 65 3 780 793 26718502 22 Wattenberg LW Coccia JB Lam LK Inhibitory effects of phenolic compounds on benzo(a)pyrene-induced neoplasia Cancer research 1980 40 8 Pt 1 2820 2823 7388831 23 Prochaska HJ De Long MJ Talalay P On the mechanisms of induction of cancer-protective 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PMC005xxxxxx/PMC5115934.txt
LICENSE: This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. 7704136 4076 Histopathology Histopathology Histopathology 0309-0167 1365-2559 27374168 5115934 10.1111/his.13027 NIHMS799889 Article A Proportion of Primary Squamous Cell Carcinomas of the Parotid Gland Harbor High Risk Human Papillomavirus Xu Bin 1 Wang Lu 1 Borsu Laetitia 1 Ghossein Ronald 1 Katabi Nora 1 Ganly Ian 2 Dogan Snjezana 1 1 Department of Pathology, Memorial Sloan Kettering Cancer Center, New York, NY 2 Department of Surgery, Memorial Sloan Kettering Cancer Center, New York, NY Corresponding Author: Snjezana Dogan, Department of Pathology, Memorial Sloan Kettering Cancer Center, 1275 York Avenue, New York, New York, 10065, dogans@mskcc.org 1 9 2016 23 8 2016 12 2016 01 12 2017 69 6 921929 This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. Aims In the current study, we aimed to examine primary parotid squamous cell carcinoma (ParSCC) for the presence of HR-HPV and associated molecular alterations. Methods and results Eight cases of ParSCC were retrieved after a detailed clinicopathologic review to exclude a possibility of metastasis and/or extension from another primary site. HR-HPV status was determined based on immunohistochemistry (IHC) for p16 protein expression and by chromogenic in situ hybridization (CISH) for HR-HPV. All cases were genotyped by multiplexed mass spectrometry assay interrogating 91 hotspot mutations in 8 cancer-related genes (EGFR, KRAS, NRAS, BRAF, PIK3CA, AKT1, MEK1 and ERBB2), and studied by fluorescence in situ hybridization (FISH) for PTEN copy number alteration. Three of 8 cases (37.5%) were positive for presence of HR-HPV by CISH and p16 IHC. One of three (33%) HR-HPV-positive cases harbored PTEN hemizygous deletion, and one (33%) HR-HPV-positive case harbored PIK3CA E545K somatic mutation. No alteration of PTEN-PI3K pathway was detected in HR-HPV-negative tumors. Over a median follow-up period of 66.2 months, only the patient with HR-HPV-positive PIK3CA-mutated tumor died of his disease, while the remaining 7 patients were disease free. Conclusions Given the established etiologic role of HR-HPV in other head and neck squamous cell carcinoma, it is likely that HR-HPV represents an oncogenic driver in the pathogenesis of more than one third of ParSCC. Presence of HR-HPV in ParSCC may be coupled with alterations in PTEN-PI3K pathway. HR-HPV and molecular characterization of a larger number of ParSCC is needed to determine the clinical significance of these findings. human papillomavirus squamous cell carcinoma parotid gland p16 in situ hybridization Introduction High risk human papillomavirus (HR-HPV) is a well-established oncogenic agent causing about 5% of human cancers worldwide, in particular the vast majority of cervical and oropharyngeal carcinomas, and a subset of anogenital squamous cell carcinoma 1–3. Over the past two decades, the prevalence of HR-HPV in oropharyngeal squamous cell carcinoma (SCC) has increased dramatically, from 21% prior to 1990 to 75% at present 3, 4. More importantly, recent research has shown that HR-HPV is an important prognostic and predictive biomarker in oropharyngeal squamous carcinoma. HPV-positive oropharyngeal SCC tends to affect relatively younger individuals that those usually affected by conventional HPV-negative SCC, and is associated with a favorable overall prognosis, excellent loco-regional control, prolonged disease specific survival, and improved response to radiation therapy 5, 6. The clinical significance of HR-HPV in head and neck SCC outside of the oropharynx, in particular salivary glands, remains unclear. A handful of published studies have investigated the effects of HPV, including HR-HPVs, in epithelial neoplasms, benign or malignant, of salivary glands 7–15. The results were somewhat inconsistent with a documented incidence of HPV ranging from nil to 100%. In addition, the majority of prior published studies have employed polymerase chain reaction (PCR)-based assays. Despite its well-documented high sensitivity, a positive PCR result does not necessarily imply the integration of the viral oncogenes into the host DNA, which is the first initiating step leading to malignant transformation. Primary squamous cell carcinoma of the parotid gland (parSCC) is a rare and aggressive malignant epithelial tumor with a 5-year disease specific survival rate of 33% to 50% 16, 17. To date, only one published study has reported HPV positivity in a single case of squamous cell carcinoma of salivary gland, using a nested two-step-PCR assay and customized primers targeting both high risk and low risk HPVs 8. In the present study, our aim was to examine ParSCC for the presence of HR-HPV and any associated molecular alterations. Additionally, we performed molecular and cytogenetic analyses to explore the molecular alterations of HPV-positive and negative parSCCs. Material and Methods Case selection and characteristics and Confirmation of HPV status using p16 immunohistochemistry and CISH The study was approved by the institutional review board. Eight cases fulfilling the following criteria were retrieved from the pathology database: 1) patients who underwent surgical resection at Memorial Sloan Kettering Cancer Center (MSKCC, New York, NY, US) between 2000 to 2014; 2) a final pathological diagnosis of squamous cell carcinoma of the parotid gland (parSCC); 3) no documented prior history of squamous cell carcinoma in the head and neck region; 4) no squamous cell carcinoma outside of the parotid gland detected on extensive radiological, clinical, and endoscopic work-up; 5) no evidence of direct connection of the tumor to the skin on radiological studies, macroscopic and microscopic examination; and 6) an epicenter of the tumor within the parotid gland by imaging and/or macroscopic examination. All histologic and immunohistochemistry slides were reviewed by four head and neck pathologists. The pathologic and clinical stages were assigned using the American Joint Committee on Cancer (AJCC) staging manual 18. Immunohistochemistry studies were performed to confirm the presence of squamous differentiation and to exclude diagnostic mimics. Antibodies and ISH probes utilized are listed in Table 1. HPV status was confirmed using p16 immunostain and CISH against HPV types 16, 18, 31, 33, and 51. Immunopositivity for p16 was defined as a diffuse and strong cytoplasmic and nuclear stain of p16 in at least 70% of tumor cells (Figure 1G). A carcinoma was considered as positive for HR-HPV only when the integrated pattern was observed (Figure 1H). Additionally, FISH for PLAG1, MAML2 or EWSR-1 loci was performed in three individual cases to exclude diagnostic mimickers. Clinico-pathological features captured included: age, gender, smoking history, duration of clinical follow-up, disease status at the last follow-up, clinical staging, size of the tumor, tumor necrosis, mitotic index,, perineural invasion, lymphovascular invasion, AJCC pT and pN stages 18. Molecular and cytogenetic analyses All cases were genotyped using a multiplexed mass spectrometry assay for hotspot alterations (Sequenom) based on matrix-assisted laser desorption/ionization time-of-flight mass spectrometry (MALDI-TOF MS). DNA from the tumor samples was used to interrogate presence of single nucleotide variation (SNV) in 91 hot-spots in 8 oncogenes: EGFR, KRAS, BRAF, PIK3CA, AKT1, NRAS, MEK1, and ERBB2 as previously described 19. Immunohistochemistry studies and FISH were performed to investigate the status of PTEN in these tumors. Results A total of 8 patients were identified from the MSKCC pathology database, fulfilling the inclusion criteria stated above. All eight cases harbored poorly differentiated predominantly non-keratinizing squamous cell carcinoma, among which four exhibited focal abrupt keratinization (Figure 1). All eight tumors studied were infiltrative and were devoid of lymphoid cuff. The squamous differentiation was confirmed by diffuse and strong immunopositivity for p63 (7/8, 88%), cytokeratin 34βE12 (5/5, 100%), Cytokeratin 5/6 (4/4, 100%) and/or p40 (8/8, 100%); as well as immuno-negativity for androgen receptor (0/8), calponin (0/3), smooth muscle actin (0/4), and S100 (0/4). A positive HPV status, as confirmed using CISH positivity for HR-HPV, was identified in 3 tumors (38%). All tumors that were positive for HR-HPV on CISH analysis showed strong nuclear and cytoplasmic p16 immunostain in > 70% of cells; while only one of the five HR-HPV negative cases were positive for p16 immunostain. The demographic, clinical and pathological features of HPV-positive and HPV-negative carcinomas are summarized in Table 2. In our series, primary parSCC affected predominantly elderly male patients. The median age of presentation was 68 years and the male to female ratio was 7:1. None of the patients had an identifiable history of previous radiation to the head and neck region. Three patients were ex-smokers (10 to 70 pack-years), while the remaining were non-smokers. No noticeable difference was identified between the HPV-positive and HPV-negative carcinomas in terms of age, gender, and risk factors. HPV-positive carcinomas were associated with a higher risk of lymphovascular invasion and lymph node metastases, compared to their HPV-negative counterparts. The remaining histological features, including tumor size, mitotic index, tumor necrosis, perineural invasion, AJCC pT and pN staging, were indistinguishable between HPV-positive and negative tumors. The median follow-up period was 61 months (range: 8 to 150 months). All patients underwent parotidectomy, selective neck dissection, and adjuvant radiation therapy at initial presentation. Seven patients were disease-free at the time of last follow-up, including 5 HPV-negative and 2 HPV-positive cases. One patient who was diagnosed with pT3 pN2b HPV-positive poorly differentiated SCC developed a neck recurrence and possible metastases in the mediastinum and lungs 5 months post-surgery and died 4 months later. While no mutation was identified using Sequenom assay from the tumors of the 7 patients who were disease-free at last follow-up, a missense somatic mutation of PIK3CA c.1633G>A (p.E545K) on exon 9 was detected in the patient with HPV-positive parSCC who suffered disease-specific death. Additionally, one HPV-positive parSCC demonstrated complete loss of PTEN protein expression, and a somatic hemizygous PTEN deletion on FISH assay (Figure 1E and 1F). The remaining tumors did not show PTEN deletion. Discussion Recent epidemiological data have implicated a key pathogenesis role of HR-HPV in head and neck squamous cell carcinoma, particularly those arising within the oropharynx 2, 20. In addition, HR-HPV has emerged as a prognostic and predictive biomarker in oropharyngeal SCC. A positive HR-HPV status has been associated with a favorable loco-regional control, overall survival, and disease specific survival, as well as an improved response to radiation therapy 5, 6. The roles of HR-HPV in head and neck cancer outside of the oropharynx, in particular within the salivary glands, remain unclear. Emerging yet scanty and controversial evidence has been published demonstrating the presence of HPV in certain but not all types of salivary gland epithelial neoplasms with a reported incidence ranging widely from nil to 100% (reviewed and summarized in Table 3) 7–15. Since the parotid gland directly communicates with the oral cavity through Stensen’s duct, it is possible that HR-HPV could theoretically gain access to the parotid gland via retrograde transportation. Using ISH or PCR techniques, HR-HPV positivity was detected in a variety of benign and malignant salivary gland epithelial lesions, including pleomorphic adenoma, oncocytoma, Warthin’s tumor, squamous cell carcinoma, acinic cell carcinoma, adenoid cystic carcinoma, adenocarcinoma, and mucoepidermoid carcinoma (Table 3) 7–15. However, most of these studies included only a limited number of cases, and the documented frequency of any particular entity was not always consistent across studies. For example, Vagali et al. (2007) 9 and Teymoortash et al. (2013) 14 showed that HPV DNA was absent in Warthin’s tumor, a benign salivary epithelial neoplasm. In contrast, Teng et al. (2014) 15 detected the presence of HR-HPVs, including HPV 16 and 18, in 4 of 12 (33%) Warthin’s tumors. Similarly, the reported incidence of HR-HPV in mucoepidermoid carcinoma, the most common malignant salivary gland epithelial tumor, varied from nil 7, 11 to 47 – 100% 12, 15. With regard to squamous cell carcinoma of the parotid gland, the only case with documented HPV status has been reported by Fischer and Von Winterfeld (2003) 8 who detected the presence of HPV in a single case of squamous cell carcinoma of the parotid gland. The authors employed a nested two step-PCR assay with customized primers targeting HPV 6, 11, 13, 16, 31 and 33. Thus, it was unclear whether this specific tumor harbored HR or low risk-HPV. The marked variation in the reported frequency of HPV in salivary gland tumors might be due to the small number of cases included in these studies, but could also be attributed to the different detection methods used. Although HPV infection is nearly ubiquitous in humans, the vast majority are transient and not carcinogenic. Thus, the ultimate goal of HPV detection is to recognize oncogenic HR-HPV infection. PCR-based assays, in particular nested PCR, are extremely sensitive. Therefore, a positive PCR result using GP5+/6+ primers detects the presence of the virus genome, even at a very low copy number, and may not represent clinically relevant HPV infection. Indeed, HPV is only implicated in tumorigenesis when E6/E7 mRNA is transcriptionally activated, while a significant proportion (14–50%) of carcinomas with detected HR-HPV genomic DNA using PCR do not contain transcribed E6/E7 mRNA 1, 21–23. Moreover, PCR techniques do not distinguish between episomal and integrated HPV DNA, or between non-neoplastic and neoplastic tissue, leading to a further increase in the detection of clinically insignificant HPV infection. In situ hybridization (ISH), on the other hand, is a highly specific method allowing reliable topographical visualization of HPV within the nuclei of tumor cells. Additionally, the ISH technique allows discrimination between the integrated and the episomal state of HPV. Compared with the diffuse nuclear staining for episomal virus, a punctuated nuclear signal indicates integration of the viral DNA into the host DNA, which would then trigger carcinogenesis in the host cell 1, 21–23. P16 protein overexpression, detected by immunohistochemistry, is an indirect consequence of E7 oncogene transcription, and can serve as a cost-effective surrogate marker with 94–100% sensitivity and 79 – 82% of specificity for tumorigenic HR-HPV infection 1, 21–23. The majority of previously published studies have adopted PCR-based assays 7–9, 11, 12, 14, 15. Hence, the detection of HPV in these studies did not necessarily indicate a pathogenic role of HR-HPV in these tumors. Only three groups have studied the status of HPV in salivary gland tumor using ISH techniques 10, 13, 14. While Seethala et al. (2012) 13 did not detect HR-HPV in 7 cases of lymphadenoma Boland et al. (2012) 10 identified HR-HPV in 2 of 25 (8%) cases of adenoid cystic carcinoma; and Teymoortash et al. (2013) 14 reported HR-HPV positivity in 13 of 40 (33%) Warthin’s tumors. Interestingly, the ISH staining pattern in HPV-positive Warthin’s tumors was episomal 14, suggesting that the HR-HPV may not be pathogenic in Warthin’s tumor. The current study is the first study showing that some primary SCCs of the parotid gland (38%) may be driven by HR-HPV as demonstrated by positive CISH studies and confirmed by immunohistochemistry for p16. One potential weakness of the present study was that the CISH probe utilized only detected the most common HR-HPV types, namely 16, 18, 31, 33, and 51, but not other rare types of HR-HPVs. The current study is also the only study with a long-term clinical follow-up allowing evaluation of the clinical relevance and prognostic value of HR-HPV in these tumors. We intentionally excluded cases from our consult service, and included only those patients who received surgical resection and clinical follow-up at our center. This approach minimized selection bias, ensured comparable and consistent results of HPV detection, and allowed collection of reliable long term clinical data. Unlike SCC of the oropharynx which is associated with an improved clinical outcome 2, 20, our study showed that HPV positivity in SCC of the parotid gland had no significant impact on clinical and pathological staging and prognosis. However, the small number of cases is a limiting factor, and additional larger scale studies are needed. The facts that HR-HPV related parotid squamous cell carcinomas was associated with a propensity for lymphovascular invasion and metastases to neck lymph nodes may raise concerns that these cases are parotid metastases rather than primary squamous cell carcinoma of the parotid gland. However, this possibility was excluded on the basis of an extensive clinico-radiological examination and/or multiple benign biopsies of the oropharynx. Additionally, two of three patients with HR HPV-related ParSCC showed no evidence of disease 23 and 66 months after the initial resection, which also argues against the metastatic nature of their disease. Recent genomic evidence has shown that alteration in PTEN-PIK3CA-AKT-mTOR pathway is the most frequent genomic alteration detected in 48 to 53% of HPV-positive head and neck squamous cell carcinomas 24–28. Such alterations include PTEN inactivation by mutation and deletion, and PIK3CA mutation or amplification. Using Sanger sequencing, Chiosea et al. (2013) 24 have detected PIK3CA alteration in 31% of oropharyngeal SCC, the most common one being p.E545K missense mutation. Similarly, using massive parallel high throughout DNA sequencing, three recent studies have shown that PIK3CA and PTEN alterations are present in 37% and 11% of HPV-positive head and neck squamous cell carcinomas, respectively 26, 27, 29. Consistent with what has been reported in the literature, we identified PIK3CA E545K mutation (1/3, 33%) and PTEN hemizygous deletion (1/3, 33%) in HPV-positive parSCCs. Although previous studies reported that the presence of PIK3CA alteration did not alter clinical prognosis of head and neck squamous cell carcinoma 24, the patient with HPV-associated SCC harboring PIK3CA somatic mutation in our series was the only patient who suffered adverse outcomes, including distant recurrence and ultimately disease specific death. As SCC is a rare malignancy of salivary gland, future collaborative studies across different tertiary centers are needed to collect sufficient evidence in order to clarify the prognostic value of PIK3CA somatic mutation in HPV-positive and HPV-negative SCCs of parotid gland. Conclusions To the best of our knowledge, our study is the first to report the presence of high risk human papillomavirus in a proportion of primary squamous cell carcinoma of the parotid gland suggesting that HPV may contribute to the pathogenesis of parSCCs. PTEN hemizygous deletion and PIK3CA somatic mutation were detected in HPV-positive primary SCCs, suggesting that alteration in PTEN-PIK3CA-AKT-mTOR pathway may play a role in HPV-related parSCC. Unlike oropharyngeal squamous cell carcinoma in which HPV is associated with an improved survival, HPV in parotid SCC may not correlate with better outcome. However, future studies with larger number of cases are needed to confirm such findings. Grant numbers and sources of support: Research reported in this publication was supported in part by the Cancer Center Support Grant of the National Institutes of Health/National Cancer Institute under award number P30CA008748. The content is solely the responsibility of the authors and does not necessarily represent the official views of the National Institutes of Health. Figure 1 Table 1 Antibodies and in situ hybridization probes utilized in the current study. Antibody specificity Clone Dilution Source p16 E6H4 RTU Ventana Medical Systems Inc p63 4A4 RTU Ventana Medical Systems Inc p40 PC373 1: 3000 EMD Millipore Cytokeratin 5/6 D5/16B4 RTU Ventana Medical Systems Inc Cytokeratin 34βE12 34BE12 RTU Ventana Medical Systems Inc Calponin EP789Y RTU Ventana Medical Systems Inc Smooth muscle actin asm-1 1:50 Vector laboratory S100 Z0311 1:8000 DAKO PTEN 6H2.1 1:100 DAKO Androgen receptor AR441 1:200 DAKO CISH probe for high risk HPV type 16, 18, 3133, and 51 PATHO-GENE® NA ENZO Life Sciences Inc. FISH probe for PTEN Vysis® LSI PTEN/CEP 10 FISH probe NA Abbott Laboratories RTU: ready to use Table 2 Clinicopathologic characteristics of high risk human papillomavirus (HR-HPV)-negative and positive squamous cell carcinoma in the parotid gland a. Overall HR-HPV (-) HR-HPV (+) N 8 5 3 Clinical characteristics Age, median ( range) 68 (51-87) 67(51 – 87) 70 (58 – 81) Gender Male 7 5 2 Female 1 0 1 Smoking status Non-smoker 5 3 2 Ex-Smoker 3 2 1 Clinical staging II 4 4 0 III 1 1 0 IVa 3 0 3 Follow-up period (months)a 61 (8 – 150) 78 (21 – 150) 31 (8 – 69) Disease status at last F/U No evidence of disease 7 5 2 Dead of disease 1 0 1 Pathological characteristics Tumor Size (cm) 3.7 (2.1 – 5.0) 3.1 (2.1 – 4.5) 4.7 (2.0 – 6.0) Mitotic index (/10 HPFs) 12 (2 – 38) 11 (2 – 38) 13 (9 – 19) Surgical Margin Status Negative 4 3 1 Close (<0.1 cm) 1 1 0 Positive 3 1 2 Lymphovascular invasion Yes 4 1 3 No 4 4 0 Perineural invasion Yes 5 2 3 No 3 3 0 Tumor necrosis Yes 5 2 3 No 3 3 0 AJCC pT stage T2 4 3 1 T3 3 2 1 T4a 1 0 1 AJCC pN stage N0 5 5 0 N2b 3 0 3 PIK3CA E545K mutation Yes 1 0 1 No 7 5 2 Loss of PTEN immunoexpression and PTEN deletion on FISH analysis Yes 1 0 1 No 7 5 2 a Values were expressed as N or mean (range). AJCC: American Joint Committee on Cancer, FISH: fluorescence in situ hybridization, F/U: clinical follow-up, HPFs: high power fields (400X), HPV: human papilloma virus. Table 3 Reported frequency of HPV in salivary gland epithelial neoplasms in English literature Ref. Tumor tested (N) HPV detection methods primers/probe) HPV N (%) HR- HPV N (%) HPV16 N (%) HPV18 N (%) Atula, 1998 [7] N = 34 PA (19) ACC (4) SCC (3) MEC (3) Adenocarcinoma (2) AdCC (1) EMC (1) MC (1) PCR (GP5+/GP6+) 0 N/A N/A N/A Fischer, 2003 [8] SCC of parotid (1) Nested PCR (customized primers) 1 (100%) N/A N/A N/A Vageli, 2007 [9] N = 8 Oncocytoma (1) ACC (1) Warthin’s tumor (1) Adenocarcinoma HG (1) PA (2) Lymphoepithelial cyst (1) PLGA (1) Solution PCR (GP5+/GP6+) Multiplex qRT-PCR (E6/E7 of HPV16, 18, 31, 33, 35, 52, 58 and 67) In situ PCR 6 (75%) 6 (75%) 5 (63%) 4 (50%) Boland, 2012 [10] AdCC (n = 25) ISH for LR- and HR- HPV 2 (8%) 2 (8%) N/A N/A Descamps, 2012 [11] N = 79 PA (40) AdCC (15) MEC (9) CAexPA (9) ACC (6) PCR (GP5+/GP6+) qRT-PCR (type specific sequences) 4 (5%) PA (3) ACC (1) 2 (3%) PA (1) ACC (1) 2 (3%) 0 Isayeva, 2012 [12] MEC (89) Nested RT-PCR (primers N/A) IF (C1P5 antibody) N/A 42 (47%) N/A N/A Seethala 2012 [13] Lymphadenoma (7) ISH (wide spectrum HPV-DNA probe) 0 N/A N/A N/A Teymoortash, 2013 [14] Warthin’s tumor (40) ISH for HR-HPV PCR (GP5+/GP6+ and E1 gene regions) 13 (33%) episomal by FISH 0 by PCR N/A N/A N/A Teng, 2014 [15] N = 59 PA (36) Adenoma (3) Warthin’s tumor (12) Myoepithelioma (1) Adenocarcinoma (3) AdCC (1) MEC (1) Others (2) PCR (37 LR and HR HPV type-specific probes) 34 (58%) N/A 11 (19%) 14 (24%) ACC: acinic cell carcinoma, AdCC: adenoid cystic carcinoma, CAexPA: carcinoma ex-pleomorphic adenoma, EMC: epithelial myoepithelial carcinoma, HPV: human papillomavirus, HR-HPV: high risk-human papillomavirus, IF: immunofluorescence, ISH: in situ hybridization, LR-HPV: low risk-human papillomavirus, MC: myoepithelial carcinoma, MEC: myoepithelial carcinoma, N/A: not available, PA: pleomorphic adenoma, PCR: polymerase chain reaction, PLGA: polymorphous low-grade adenocarcinoma, qRT-PCR: quantitative real-time PCR, Ref. References, RT-PCR: reverse transcriptase PCR, SCC: squamous cell carcinoma. Disclosure/conflict of interest: No competing financial interests exist for all contributory authors. Author contributions: Bin Xu: Organized the database, reviewed the immunohistochemistry and histologic slides, and drafted the manuscript. Lu Wang: Performed the fluorescence in situ hybridization studies. Laetitia Borsu: Performed the sequenom (mass spectrum) studies. Ronald Ghossein: Reviewed the pathology, and provided feedbacks on the study design and manuscript. Nora Katabi: Reviewed the pathology, and provided feedbacks on the study design and manuscript. Ian Ganly: Provide clinical aspect of the study and feedbacks on the manuscript. Snjezana Dogan: Designed the study, reviewed all pathology and molecular aspects of the study, and finalized the manuscript. References 1 Groves IJ Coleman N Pathogenesis of human papillomavirus-associated mucosal disease The Journal of pathology 2015 235 527 538 25604863 2 Woods R Sr. O'Regan EM Kennedy S Martin C O'Leary JJ Timon C Role of human papillomavirus in oropharyngeal squamous cell carcinoma: A review World journal of clinical cases 2014 2 172 193 24945004 3 Stein AP Saha S Yu M Kimple RJ Lambert PF Prevalence of human papillomavirus in oropharyngeal squamous cell carcinoma in the united states across time Chemical research in toxicology 2014 27 462 469 24641254 4 Young D Xiao CC Murphy B Moore M Fakhry C Day TA Increase in head and neck cancer in younger patients due to human papillomavirus (hpv) Oral oncology 2015 5 Masterson L Moualed D Liu ZW De-escalation treatment protocols for human papillomavirus-associated oropharyngeal squamous cell carcinoma: A systematic review and meta-analysis of current clinical trials European journal of cancer 2014 50 2636 2648 25091798 6 Petrelli F Sarti E Barni S Predictive value of human papillomavirus in oropharyngeal carcinoma treated with radiotherapy: An updated systematic review and meta-analysis of 30 trials Head & neck 2014 36 750 759 23606404 7 Atula T Grenman R Klemi P Syrjanen S Human papillomavirus, epstein-barr virus, human herpesvirus 8 and human cytomegalovirus involvement in salivary gland tumours Oral oncology 1998 34 391 395 9861347 8 Fischer M von Winterfeld F Evaluation and application of a broad-spectrum polymerase chain reaction assay for human papillomaviruses in the screening of squamous cell tumours of the head and neck Acta oto-laryngologica 2003 123 752 758 12953779 9 Vageli D Sourvinos G Ioannou M Koukoulis GK Spandidos DA High-risk human papillomavirus (hpv) in parotid lesions The International journal of biological markers 2007 22 239 244 18161653 10 Boland JM McPhail ED Garcia JJ Lewis JE Schembri-Wismayer DJ Detection of human papilloma virus and p16 expression in high-grade adenoid cystic carcinoma of the head and neck Modern pathology : an official journal of the United States and Canadian Academy of Pathology, Inc 2012 25 529 536 11 Descamps G Duray A Rodriguez A Detection and quantification of human papillomavirus in benign and malignant parotid lesions Anticancer research 2012 32 3929 3932 22993339 12 Isayeva T Li Y Maswahu D Brandwein-Gensler M Human papillomavirus in non-oropharyngeal head and neck cancers: A systematic literature review Head and neck pathology 2012 6 Suppl 1 S104 S120 22782230 13 Seethala RR Thompson LD Gnepp DR Lymphadenoma of the salivary gland: Clinicopathological and immunohistochemical analysis of 33 tumors Modern pathology : an official journal of the United States and Canadian Academy of Pathology, Inc 2012 25 26 35 14 Teymoortash A Bohne F Jonsdottir T Human papilloma virus (hpv) is not implicated in the etiology of warthin's tumor of the parotid gland Acta oto-laryngologica 2013 133 972 976 23944949 15 Teng WQ Chen XP Xue XC Distribution of 37 human papillomavirus types in parotid gland tumor tissues Oncology letters 2014 7 834 838 24527091 16 Lee S Kim GE Park CS Primary squamous cell carcinoma of the parotid gland American journal of otolaryngology 2001 22 400 406 11713725 17 Wang L Li H Yang Z Chen W Zhang Q Outcomes of primary squamous cell carcinoma of major salivary glands treated by surgery with or without postoperative radiotherapy Journal of oral and maxillofacial surgery : official journal of the American Association of Oral and Maxillofacial Surgeons 2015 18 Edge SB Byrd DR Compton CC Fritz AG Greene FL Trotti A Ajcc cancer staging manual 2009 Springer 19 Arcila M Lau C Nafa K Ladanyi M Detection of kras and braf mutations in colorectal carcinoma roles for high-sensitivity locked nucleic acid-pcr sequencing and broad-spectrum mass spectrometry genotyping The Journal of molecular diagnostics : JMD 2011 13 64 73 21227396 20 El-Mofty SK Hpv-related squamous cell carcinoma variants in the head and neck Head and neck pathology 2012 6 Suppl 1 S55 S62 22782224 21 Mirghani H Amen F Moreau F Human papilloma virus testing in oropharyngeal squamous cell carcinoma: What the clinician should know Oral oncology 2014 50 1 9 24169585 22 Mirghani H Amen F Moreau F Lacau St Guily J Do high-risk human papillomaviruses cause oral cavity squamous cell carcinoma? Oral oncology 2014 23 Venuti A Paolini F Hpv detection methods in head and neck cancer Head and neck pathology 2012 6 Suppl 1 S63 S74 22782225 24 Chiosea SI Grandis JR Lui VW Pik3ca, hras and pten in human papillomavirus positive oropharyngeal squamous cell carcinoma BMC cancer 2013 13 602 24341335 25 Chun SH Jung CK Won HS Kang JH Kim YS Kim MS Divergence of p53, pten, pi3k, akt and mtor expression in tonsillar cancer Head & neck 2014 26 Cancer Genome Atlas N Comprehensive genomic characterization of head and neck squamous cell carcinomas Nature 2015 517 576 582 25631445 27 Chung CH Guthrie VB Masica DL Genomic alterations in head and neck squamous cell carcinoma determined by cancer gene-targeted sequencing Ann Oncol 2015 26 1216 1223 25712460 28 Lechner M Frampton GM Fenton T Targeted next-generation sequencing of head and neck squamous cell carcinoma identifies novel genetic alterations in hpv+ and hpv− tumors Genome Med 2013 5 49 23718828 29 Seiwert TY Zuo Z Keck MK Integrative and comparative genomic analysis of hpv-positive and hpv-negative head and neck squamous cell carcinomas Clinical cancer research : an official journal of the American Association for Cancer Research 2014
PMC005xxxxxx/PMC5115953.txt
LICENSE: This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. 8302946 4093 Hepatology Hepatology Hepatology (Baltimore, Md.) 0270-9139 1527-3350 27628766 5115953 10.1002/hep.28811 NIHMS817609 Article IRAKM-Mincle axis links cell death to inflammation: Pathophysiological implications for chronic alcoholic liver disease Zhou Hao 1 Yu Minjia 1 Zhao Junjie 1 Martin Bradley N. 1 Roychowdhury Sanjoy 2 McMullen Megan R. 2 Wang Emily 1 Fox Paul L. 3 Yamasaki Sho 4 Nagy Laura E. 256 Li Xiaoxia 16 1 Department of Immunology, Lerner Research Institute, Cleveland Clinic, Cleveland, Ohio, USA 2 Center for Liver Disease Research, Department of Pathobiology, Lerner Research Institute, Cleveland Clinic, Cleveland, Ohio, USA 3 Department of Cellular and Molecular Medicine, Lerner Research Institute, Cleveland Clinic, Cleveland, Ohio, USA 4 Division of Molecular Immunology, Research Center for Infectious Diseases, Medical Institute of Bioregulation, Kyushu University, 3-1-1 Maidashi Higashiku, Fukuoka, Japan 5 Department of Gastroenterology, Cleveland Clinic, Cleveland, Ohio, USA Correspondence should be addressed to L. E. N. (nagyL3@ccf.org) or X. L. (lix@ccf.org) 6 These authors contributed equally to this work. 22 9 2016 25 10 2016 12 2016 01 12 2017 64 6 19781993 This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. Lipopolysaccharide (LPS)-mediated activation of Toll-like receptors (TLRs) in hepatic macrophages and injury to hepatocytes are major contributors to the pathogenesis of alcoholic liver disease (ALD). However, the mechanisms by which TLR-dependent inflammatory responses and alcohol-induced hepatocellular damage coordinately lead to ALD are not completely understood. In this study, we found that mice deficient in IRAKM, a proximal Toll-like receptor pathway molecule typically associated with inhibition of TLR signaling, were actually protected from chronic ethanol-induced liver injury. In bone marrow derived macrophages challenged with low concentrations of LPS, which reflect the relevant pathophysiological levels of LPS in both alcoholic patients and ethanol-fed mice, the IRAKM Myddosome was preferentially formed. Further, the IRAKM Myddosome mediated the up-regulation of Mincle, a sensor for cell death. Mincle-deficient mice were also protected from ethanol-induced liver injury. The endogenous Mincle ligand, SAP130 is a danger signal released by damaged cells; culture of hepatocytes with ethanol increased the release of SAP130. Ex vivo studies in bone marrow derived macrophages suggested that the endogenous Mincle ligand, SAP130, and LPS synergistically activated inflammatory responses, including inflammasome activation. Conclusion: This study reveals a novel IRAKM-Mincle axis that contributes to the pathogenesis of ethanol-induced liver injury. Toll-like receptor C-type lectin receptor innate immune response Introduction Alcoholic liver disease (ALD) ranges from simple steatosis to alcoholic hepatitis, fibrosis, cirrhosis and hepatocellular carcinoma. Alcohol exposure induces endoplasmic reticulum (ER) stress and mitochondrial dysfunction in hepatocytes, which leads to hepatocyte apoptosis, necrosis, necroptosis and inflammation (1). Alcohol disrupts the balance of gut microflora associated with an increased intestinal permeability, resulting in increased translocation of bacterial products into the circulation (2, 3). Increased levels of lipopolysaccharide (LPS) are indeed detected in the serum of alcoholic patients (4, 5) and alcohol-treated experimental animals, ranging from 80–130 pg/ml (5–9). The activation of hepatic macrophages (Kupffer cells) in response to portal endotoxin/LPS plays a key role in the early pathogenesis of alcohol-induced liver injury. LPS recognition by Toll-like receptor 4 (TLR4) on hepatic macrophages results in the release of inflammatory cytokines, such as TNF and IL-1, that can in turn impact hepatocyte function. Mice deficient in TLR4 or interlukin-1 receptor (IL-1R) are resistant to ethanol-induced liver disease (9, 10). Conversely, previous studies have shown that signals released from hepatocytes injured by alcohol are also critical to the activation of hepatic macrophages. Thus, one important question is how TLR-dependent inflammatory responses and alcohol-induced cellular damage coordinately lead to the pathogenesis of ALD. TLRs transduce signals through the adaptor molecule MyD88 and IL-1R-associated kinase (IRAK) family members, which include: IRAK1, IRAK2, IRAKM (also known as IRAK3) and IRAK4 (11). We recently reported the co-existence of two parallel TLR-mediated NFκB activation pathways: TAK1-dependent and MEKK3-dependent, respectively (12–14). IRAK4 kinase activity and its substrates, IRAK1 and IRAK2, are necessary for TAK1-dependent NFκB activation and mRNA stabilization of chemokines and cytokines, but not for MEKK3-dependent NFκB activation (15–17). IRAKM is able to interact with MyD88-IRAK4 to form IRAKM Myddosome, allowing it to control TAK1-independent MEKK3-dependent NFκB activation (18). This IRAKM-dependent pathway is necessary for the second wave of TLR-induced NFκB activation in the company of IRAK1/IRAK2. Notably, the IRAKM-dependent pathway only induces expression of the inhibitory molecules SOCS1, SHIP1, A20 and IκBα. Thus, IRAKM exerts an overall inhibitory effect on inflammatory response. In this study, we were surprised to discover that IRAKM-deficient mice were protected from ethanol-induced liver injury and inflammation. Mechanistically, IRAKM-dependent NFκB activation was the dominant pathway in hepatic macrophages challenged with low dose of LPS (100 pg/ml). Analysis of TLR4-induced IRAKM-dependent genes revealed one gene of particular interest: Mincle, a C-type lectin receptor, that senses non-homeostatic cell death. Induction of Mincle in hepatic macrophages was ablated in IRAKM-deficient mice and Mincle-deficient mice were protected from ethanol-induced liver injury. Spliceosome-associated Protein 130 (SAP130, also known as SF3B3), the endogenous ligand of Mincle, was released from hepatocytes after ethanol exposure, while recombinant SAP130 synergized with low dose LPS to robustly induce inflammatory gene expression and activate the inflammasome in macrophages. Since Mincle is a sensor for cell death and its expression is IRAKM-dependent, our results suggest that TLR-induced IRAKM-dependent Mincle up-regulation in hepatic macrophages critically links alcohol-induced cell death to subsequent inflammatory responses, contributing to the pathogenesis of ALD. Materials and methods Details regarding materials, details of the animal procedures and basic biochemical methods are given in the Supporting Information. Mouse models IRAKM deficient and Mincle deficient mice were previously described (19, 20). All procedures using animals were approved by the Cleveland Clinic Institutional Animal Care and Use Committee. KO and wild-type (WT) mice in the ethanol-fed groups were allowed free access to an ethanol containing diet: 1% (vol/vol) ethanol for 2d followed by 2% ethanol for 2d, 4% ethanol for 1w, 5% ethanol for 1w followed by 6% ethanol (32% of total calories) for the final week. Control mice were pair-fed a control diet which iso-calorically substituted maltose dextrins for ethanol over the entire feeding period. Inflammasome activation Bone marrow derived macrophages (BMDMs) were plated in 6-well plates at a concentration of 2.0 × 106 cells per well the day before the experiment. The day of the experiment, cells were stimulated with low concentration of LPS (100 pg/ml), recombinant SAP130 (5 µg/ml) or TDB (10 µg/ml) for the indicated time. Cell free supernatants were then prepared as described in Supporting information. Immunoblotting Cells and tissues were harvested and lysed in a Triton-containing lysis buffer (0.5% Triton X-100, 20 mM HEPES (pH 7.4), 150 mM NaCl, 12.5 mM β-glycerophosphate, 1.5 mM MgCl2, 10 mM NaF, 2 mM dithiothreitol, 1 mM sodium orthovanadate, 2mM EGTA, 1 mM phenylmethylsulfonyl fluoride and complete protease inhibitor cocktail from Roche). Cell lysates were then separated by 10% SDS-PAGE, transferred to Immobilon-P membranes (Millipore), and subjected to immunoblotting. Data analysis and Statistics Date were normally distributed, if not, non-parametric statistical analysis was applied to all data sets. Data are expressed as mean ± SEM. Differences were analyzed by Student t test and one-way ANOVA were used to compare normally distributed data set. Mann-Whitney U test and Kruskal-Wallis test were used for non-parametric analysis. P < 0.05 was considered significant. Results IRAKM is required for low dose LPS-mediated NFκB activation Recently, we reported a novel role for IRAKM in TLR signaling: IRAKM interacts with MyD88-IRAK4 to mediate a MEKK3-dependent second wave NFκB activation (18). In response to typical doses of LPS (10 ng/ml-1 µg/ml), MEKK3 modification and second wave IκBα phosphorylation are ablated in IRAKM-deficient macrophages, whereas LPS-induced IRAK1 modification/degradation, TAK1 activation and IKKα/β phosphorylation are not affected ((18), Fig. 1A and Suppl. Fig. 1). This IRAKM-dependent second wave of NFκB activation in response to LPS (10 ng/ml–1 µg/ml) induces expression of genes that are not regulated at the posttranscriptional level (including inhibitory molecules SOCS-1, SHIP-1, A20 and IκBα). Surprisingly, here we find that IRAKM-MEKK3-dependent NFκB activation was actually the dominant pro-inflammatory pathway in response to stimulation with low dose of LPS (100 pg/ml). In BMDMs (Fig. 1A) or primary Kupffer cells (Fig. 1B) treated with low dose LPS (100 pg/ml), IκBα phosphorylation – without IκBα degradation was observed, while IRAK1 modification/degradation and IKKα/β phosphorylation were absent, together indicating MEKK3-dependent NFκB activation. Importantly, IκBα phosphorylation and MEKK3 modification induced by low dose LPS were completely abolished in IRAKM-deficient cells (Fig. 1A & B). Based on these results, we hypothesized that IRAKM is dominantly activated to mediate MEKK3-dependent NFκB activation at low concentrations of LPS, whereas the IRAK1-TAK1-dependent pathway is not activated by low dose LPS. In support of this, we found that mRNA induction of the inflammatory genes CXCL1, TNF-α and IL-6 in response to low dose LPS was normal in IRAK1/2-deficient macrophages, but was greatly reduced in IRAKM-deficient cells (Fig. 1C). Similar results were also observed in cultures of primary Kupffer cells isolated from liver of WT and IRAKM-deficient mice (Fig. 1 D). Together, these data suggest that low dose LPS preferentially induces formation of the IRAKM Myddosome, leading to MEKK3-dependent NFκB activation. Low-dose LPS preferentially induces the formation of an IRAKM Myddosome via the death domain of IRAKM One important question is how low dose LPS activate the IRAKM-MEKK3 pathway. We previously reported that upon high dose ligand stimulation, the kinase activity of IRAK4 is required for TLR-induced IRAK1-TAK1-, but not MEKK3-, dependent NFκB activation (12–14). Further, IRAK1 and its phosphorylation are required for TLR-induced TAK1- but not MEKK3-, dependent NFκB activation in response to high doses of ligand (15, 16). Thus, we hypothesized that the TLR4 complex induced by low dose LPS fails to trigger the aggregation of IRAK4, leading to recruitment of IRAKM, but not IRAK1, and formation of the IRAKM Myddosome, with subsequent MEKK3-dependent NFκB activation. We indeed found that, upon low dose LPS stimulation (100 pg/ml), IRAKM, but not IRAK1, was recruited to the IRAK4-MyD88 complex, whereas both IRAK1 and IRAKM interacted with IRAK4 upon high dose LPS stimulation (1 µg/ml) (Fig. 2A). Furthermore, low dose LPS-induced MEKK3 modification and NFκB activation were unaffected in IRAK4 kinase inactive knock-in (KI) BMDMs (Suppl. Fig. 2). Taken together, these data suggest that IRAKM-dependent MEKK3-mediated NFκB activation in response to low dose LPS does not require IRAK4 kinase activity. To further elucidate the mechanism for the specific activation of the IRAKM-MEKK3-dependent pathway by low dose LPS, we compared IRAKM versus IRAK1 in their differential recruitment to the TLR-MyD88-IRAK4 complex. The crystal structure of the Myddosome complex suggests that assembly of MyD88-IRAK4 with IRAK1, IRAK2 or IRAKM occurs via death domain (DD) interactions (21). We thus hypothesized that differential recruitment of IRAKM versus IRAK1 in response to low versus high dose LPS stimulation is determined by their respective death domains. We generated a chimeric protein by replacing the death domain of IRAK1 with that of IRAKM (DD(M)-IRAK1). IRAK1/2/M-deficient macrophages were then retrovirally infected with Flag-tagged wild-type IRAK1, wild-type IRAKM, and DD(M)-IRAK1, followed by stimulation with low dose LPS. Indeed, we found that interaction of both wild-type IRAKM and DD(M)-IRAK1, but not IRAK1, with MyD88-IRAK4 was induced in response to low dose LPS stimulation (Fig. 2B). The weak constitutive interaction of between IRAK1 and IRAK4 was probably due to the overexpression of IRAK1 (Fig. 2B). Similarly, IRAKM and DD(M)-IRAK1, but not IRAK1, restored low dose LPS-induced IκBα phosphorylation (Fig. 2C) and target gene expression (Fig. 2D). Together, these data suggest that the IRAKM death domain mediates the specific recruitment of IRAKM to the TLR-MyD88-IRAK4 complex in response to low dose LPS and promotes MEKK3-dependent NFκB activation. IRAKM-dependent pathway is required for the development of chronic ethanol-induced liver disease Alcohol intake increases gut permeability, allowing accumulation of low levels of TLR ligands in the circulation. Activation of hepatic macrophages (Kupffer cells) in response to portal endotoxin/LPS plays a key role in the early pathogenesis of ALD (22). Considering the reported low concentrations of LPS in serum of alcoholic patients and ethanol-treated experimental animals (ranging from 80–130 pg/ml), our findings led us to hypothesize that IRAKM-dependent signaling induced at low concentrations of LPS might be the dominant TLR-activated pathway in ALD. To test this hypothesis, we subjected female IRAKM-deficient and littermate control WT mice to chronic ethanol feeding via the Lieber-DeCarli liquid diet to model steatosis and mild inflammation. Compared to pair-fed control mice, chronic ethanol-fed WT mice had increased hepatocyte injury, as assessed by serum aspartate aminotransferase (AST) and alanine aminotransferase (ALT) levels (Fig. 3A) and steatosis, characterized by the presence of lipid droplets in hepatocytes by H&E and Oil Red O staining, (Fig. 3B and 3C) and hepatic triglycerides (Fig. 3D). Compared to WT mice, IRAKM-deficient mice had reduced serum AST and ALT levels (Fig. 3A) and hepatic steatosis (Fig. 3B–D). Moreover, IRAKM deficiency significantly reduced the chronic ethanol-induced upregulation of TNF-α, IL-6, pro-IL-1β and MCP-1 mRNA in liver of ethanol-fed mice (Fig. 3E). Together, these data support the crucial role of IRAKM in the pathogenesis of chronic ethanol-induced inflammatory responses in the liver. IRAKM is required for TLR-mediated Mincle expression Given that low dose of LPS induced only modest levels of inflammatory cytokines and chemokines in wild-type BMDMs (Fig. 1E), we suspected that the impact of IRAKM on ALD might not be solely due to its direct role in induction of canonical inflammatory genes. Interestingly, we found that Mincle, a C-type lectin (CLR) membrane receptor that senses cell death, was strongly induced by low dose of LPS in WT, but not in IRAKM-deficient, BMDMs (Fig. 4A) and primary Kupffer cells (Suppl. Fig. 3A). It is important to note that induction of Mincle was not affected in IRAK1/2-double deficient macrophages (Fig. 4B). We next examined Mincle expression in liver in pair-fed and ethanol-fed WT and IRAKM-deficient mice. Interestingly, immunofluorescent staining showed that Mincle expression was increased in liver of ethanol-fed wild-type mice. Mincle expression co-localized with F4/80, a marker of resident macrophages (Fig. 4C). In contrast, chronic ethanol-induced expression of Mincle was attenuated in IRAKM-deficient mice. To further confirm this finding, we performed flow cytometry-based sorting of macrophages (F4/80+CD11b+) from the livers of pair-fed and ethanol-fed mice. Mincle mRNA expression was induced by ethanol-feeding in resident macrophages of WT mice; this response was attenuated in resident macrophages from IRAKM-deficient mice (Fig. 4D). Consistent with an induction of Mincle, the phosphorylation of Syk, a tyrosine kinase known to be activated CLR-mediated signaling(23, 24), was increased in the liver of ethanol-fed WT mice, but not in IRAKM-deficient mice (Fig. 4E). Taken together, these data implicate the induction of Mincle as a possible effector in mediating the impact of IRAKM in the pathogenesis of ethanol-induced liver injury. Mincle-mediated pathway is required for the development of chronic ethanol-induced liver disease Given that ethanol feeding induced Mincle expression in hepatic macrophages in an IRAKM-dependent manner, we hypothesized that this upregulation of Mincle might contribute to the pathogenesis of ALD. To test this hypothesis, we examined the impact of genetic deletion of Mincle on ethanol-induced liver injury. Compared to WT, Mincle-deficient mice indeed showed reduced chronic ethanol-induced hepatocyte injury and steatosis, demonstrated by lower levels of ALT/AST in the plasma, reduced lipid droplet formation in hepatocytes and reduced hepatic triglyceride concentrations (Fig. 5A–D). Further, phosphorylation of Syk was upregulated in liver of ethanol-fed WT mice, but not Mincle-deficient mice (Fig. 5E). Mincle deficiency also attenuated the upregulation of TNF-α, IL-6, pro-IL-1β and MCP-1 gene expression in the livers of ethanol-fed mice, suggesting a crucial role for Mincle in the pathogenesis of chronic ethanol-induced inflammatory responses in the liver (Fig. 5F). SAP130 activates Mincle and induces inflammasome activity following priming with low dose LPS Mincle was originally discovered based on its strong induction in macrophages by inflammatory stimuli, including TLR ligands (25). Interestingly, a known endogenous ligand for Mincle is SAP130, a component of the small nuclear ribonucloprotein, which diffuses out of dying cells and initiates an inflammatory response (19). Alcohol exposure is known to induce endoplasmic reticulum (ER) stress and mitochondrial dysfunction in hepatocytes, resulting in hepatocyte apoptosis, necroptosis and necrosis. Exposure of primary hepatocyte cultures to ethanol results in both apoptotic and necroptotic cell death (26) (Suppl. Fig. 4). Interestingly, we observed that hepatocytes challenged with ethanol released SAP130 into the culture supernatant (Fig. 6A), suggesting the possibility that Mincle might mediate chronic ethanol-induced inflammatory responses in the liver in response to SAP130. We indeed found that, while individually low dose LPS or SAP130 only induced very low levels of inflammatory gene expression in BMDMs, SAP130 was able to induce much higher levels of inflammatory gene expression in wild-type BMDMs primed by low dose of LPS (Fig. 6B). This synergistic impact of low LPS with SAP130 was abolished by Mincle deficiency, indicating low LPS-induced Mincle expression allows SAP130, a ligand associated with dying cells, to induce a robust inflammatory response (Fig. 6B). In addition to ligands released during necrotic cell death, fungal and mycobacterial ligands for Mincle have also been identified. Mincle is essential for recognition of the mycobacterial cord factor and its synthetic analog Trehalose-Dibehenate (TDB) (27). Interestingly, while TDB has been shown to activate the NLRP3 inflammasome (28, 29), Dectin-1, another member of C-type lectin receptors, activates processing of IL-1β via a noncanonical caspase-8 inflammasome (30). Thus, we tested the possibility that Mincle might also mediate inflammasome activation in response to SAP130. Indeed, recombinant SAP130 induced caspase-1 cleavage and IL-1β production in macrophages primed with low dose LPS (to up-regulate Mincle). This response was abolished in Mincle-, ASC- and NLRP3-deficient macrophages (Fig. 6 C–D & Suppl. Fig. 5). These results suggest that Mincle ligation by SAP130 in macrophages results in activation of ASC-dependent inflammasomes. Recent studies have shown that mice deficient in inflammasome components, such as the adaptor ASC and caspase 1, or IL-1R are protected from ethanol-induced liver injury (10). However, it has remained unclear how the inflammasome is activated in the liver of ethanol-fed mice. Based on the ability of recombinant SAP130 to activate the inflammasome in vitro, we hypothesized that in vivo Mincle senses SAP130 released during chronic ethanol-induced hepatocyte necrosis or necroptosis. SAP130 ligation of Mincle then activates an NLRP3/ASC-dependent inflammasome, leading to caspase1 activation and IL-1β production. Indeed, we detected increased caspase-1 activity (shown as cleaved caspase 1 and processed IL-1β) in the liver of ethanol-fed mice, which was greatly reduced in IRAKM- and Mincle-deficient mice (Fig. 6 E–F). Discussion Alcohol intake increases gut permeability and leads to accumulation of low levels of LPS in the circulation. Here we have identified a novel TLR4-IRAKM-dependent signaling pathway induced by low dose LPS that contributes to the pathogenesis of ALD. We found that low dose LPS preferentially induces the formation of an IRAKM Myddosome resulting in MEKK3-dependent NFκB activation. Importantly, whereas the low dose LPS-activated IRAKM Myddosome induced only very modest induction of inflammatory gene expression, it mediated strong up-regulation of Mincle, a sensor of cell death. SAP130, the endogenous ligand of Mincle, was released from hepatocytes after ethanol exposure, while recombinant SAP130 synergized with low dose LPS to robustly induce inflammatory gene expression and inflammasome activation in macrophages. Consistent with the IRAKM-Mincle synergy observed ex vivo, upregulation of Mincle was ablated in the liver of IRAKM-deficient mice and deficiency of either IRAKM or Mincle was strongly protective from chronic ethanol-induced liver injury (Fig. 7). Further, phosphorylation of Syk, a hallmark of Mincle signaling, was increased in the liver of ethanol-fed WT mice, but not in IRAKM-deficient mice. These results suggest that the IRAKM-Mincle axis may represent a critical and previously missing link between ethanol-induced hepatocellular damage and innate immune activation during the pathogenesis of ALD. Low concentrations of LPS have been detected in alcoholic patients and in ethanol-treated experimental animals. Importantly, mice deficient in TLR4 show a reduced ALD phenotype (9, 31). To our knowledge, this is the first study to show that the MyD88 downstream component IRAKM-Mincle axis is required for the development and pathogenesis of chronic ethanol-induced liver injury. Interestingly, Wang et al reported that IRAKM deficiency worsened liver injury in mice in response to an acute challenge with alcohol; in their study, mice were treated with 10% alcohol in drinking water for 7 day then gavaged with alcohol (6 g/Kg body weight) on day 7 (32). Furthermore, Mandrekar et al, making use of primary human monocytes in culture, found that IRAKM differentially contributes to the acute and chronic effects of alcohol on LPS-induced inflammation (33). Taken together with our study, these results suggest that the IRAKM-Mincle axis may differentially contribute to acute versus chronic effects of ethanol. Another important model to consider is the acute on chronic (Gao-binge) model of ethanol exposure that induces a more severe liver damage (34). In preliminary studies, we found that Mincle expression was not induced in Kupffer cells isolated from mice exposed to the Gao-binge protocol (unpublished data, Li and Nagy), in contrast to the strong induction observed in response to the Lieber-DeCarli chronic ethanol feeding protocol used here (Fig. 4C & D). Future studies are required to carefully compare and contrast the role of IRAKM-Mincle axis in these different models of ethanol-induced liver injury, likely leading to a better understanding of the multiple pathways by which different drinking patterns (acute, chronic and binge) can differentially lead to liver injury. We and others have previously shown that high doses of LPS lead to rapid clustering/aggregation of the TLR-MyD88-IRAK4 complex and activation of IRAK4, which then recruits and phosphorylates IRAK1 to activate TAK1-dependent NFκB activation (14). In support of this, we reported that IRAK4 dimerization is required for both IRAK4 auto-phosphorylation and activation of kinase activity (35). Importantly, the IRAKM Myddosome, via the MEKK3-dependent pathway, is required for the late phase of NFκB activation which upregulates the inhibitory molecules SOCS-1, SHIP-1, A20 and IκBα. Furthermore, IRAKM, through interaction with IRAK2, inhibits TLR-mediated production of cytokines and chemokines at the levels of translational. Thus, IRAKM is known to function as a net negative regulator of overt microbial infection (modeled in vitro by high-doses LPS) (20). However, the function of IRAKM in chronic inflammatory diseases, in which LPS concentrations are much lower than in response to infections, has not been carefully studied. Here, our data suggest that the low dose LPS-induced IRAKM Myddosome-dependent pathway plays a pathogenic pro-inflammatory role in ALD. Mechanistically, low dose LPS-induced IRAKM-dependent MEKK3-mediated NFκB activation does not require IRAK4 kinase activity, but does require IRAK4 as a structural adaptor for recruitment of IRAKM to proximal TLR-MyD88 complexes. Furthermore, the death domain of IRAKM specifically directs IRAKM recruitment to the TLR-MyD88-IRAK4 complex in response to low dose of LPS, leading to MEKK3-dependent NFκB activation. One important question is how the IRAKM-dependent pathway mediates the pathogenesis of ALD. Since low dose of LPS induced only modest levels of inflammatory cytokines and chemokines in wild-type BMDMs, we suspect that the impact of IRAKM on ALD is not solely due to its direct role in TLR-mediated inflammatory gene expression. Through a search for novel IRAKM-dependent genes, we found that Mincle, a CLR membrane receptor that senses microbial products and cell death, is strongly induced by low dose of LPS and this induction was greatly reduced in IRAKM-deficient cells. Mincle-mediated responses are critical for anti-fungal and anti-mycobacterial host defense (36–39). Importantly, Mincle also functions as a sensor of non-homeostatic cell death in which the cellular contents are released (e.g. necroptosis and pyroptosis), thus promoting sterile inflammation. SAP130 was identified as an endogenous ligand recognized by Mincle following necrotic cell death (19). In this study, we found that TLR-induced Mincle expression is dependent on IRAKM in macrophages. In addition, Mincle is upregulated in hepatic macrophages from of ethanol-fed wild-type mice, but not in IRAKM-deficient mice. Both IRAKM- and Mincle-deficient mice were protected from chronic ethanol-induced hepatocyte injury, steatosis and liver inflammation. Since IRAKM’s expression is restricted to myeloid cells (Suppl. Fig. 3A–C), these results suggest that IRAKM-dependent Mincle expression in myeloid cells likely contributes to the pathogenesis of ALD. Mincle is commonly thought to be expressed mainly in myeloid lineage cells, such as macrophages. Notably, some Mincle positive cells in the liver of ethanol-fed wild-type and IRAKM-deficient mice did not co-localize with F4/80+ cells. We indeed found that Mincle expression was induced in primary hepatocytes by IL-1β (Suppl. Fig. 3B–C). Cell-specific deletion will help to determine the impact of Mincle in different cell populations on the pathogenesis of ALD. In the future, we will also test whether restoration of Mincle expression in IRAKM-deficient mice via generation of Mincle-transgenic mice would be sufficient to drive ethanol-induced liver injury. Recent studies have shown that mice with genetic deletion of either inflammasome components or IL-1R are protected from ALD (10). In this study, we found that low dose LPS upregulates Mincle expression in macrophages and subsequent treatment with recombinant SAP130 was able to activate the ASC/NLRP3/caspase-1 inflammasome. Chronic ethanol-feeding induced caspase-1 and IL-1β activation in the liver; this response was dramatically reduced in IRAKM- and Mincle-deficient mice. However, future studies are required to elucidate the precise molecular mechanism by which the SAP130-induced Mincle-dependent pathway activates the inflammasome. Interestingly, Tanaka el al reported that resident macrophages in adipose tissue express Mincle, which is activated by an endogenous ligand released from dying adipocytes. This Mincle signaling was shown to be required for macrophages to form crown-like structures (CLS), as well as for the development of adipose tissue fibrosis (40). Additionally, Mincle was shown to play a pivotal role in a model of ischemic stroke (41). These studies thus underline the potentially wide-ranging importance of the IRAKM-Mincle axis and suggest this novel pathway as a possible therapeutic target for the treatment of diverse disease states. Supplementary Material Supp info This work was supported by grants from NIH (1R01AA023722 to X.L. and L.E.N. (MPI); 2PO1HL029582-26A1 & PO1CA062220-16A1 to X.L; R01AA011975 & 5P20AA017837 to L.E.N). We thank Dr. Richard A Flavell (Department of Immunobiology, Yale University School of Medicine, New Haven, Connecticut) for providing the IRAKM-deficient mice. We thank Dr. Christine A. Wells (The Australian Institute for Bioengineering and Nanotechnology, University of Queensland, Brisbane, Australia) for providing anti-Mincle antibody for immune fluorescence staining. Abbreviations LPS lipopolysaccharide TLRs Toll-like receptors ALD alcoholic liver disease IL-1R Interlukin-1 receptor IRAK IL-1R-associated kinase KO knockout WT wild-type TDB trehalose-dibehenate DD death domain SAP130 Spliceosome-associated protein 130 AST Aspartate transaminase ALT Alanine transaminase Fig. 1 IRAKM is required for low dose LPS-mediated NFκB activation Cell lysates were prepared from A. WT and IRAKM KO BMDMs and B. primary cultures of mouse Kupffer cells after they were untreated or treated with high dose LPS (1 µg/ml) and low dose LPS (100 pg/ml) for the indicated times and analyzed by Western blot analysis. C. Total mRNA from BMDMs of WT, IRAK1/2-DKO and IRAKM KO mice treated with low dose LPS (100 pg/ml) for the indicated times were subjected to RT-PCR analyses. D. Total mRNA from BMDMs of WT and IRAKM KO mice treated with low dose LPS (100 pg/ml) for the indicated times were subjected to RT-PCR analyses. E. BMDMs were treated with high dose LPS (1 µg/ml) or low dose LPS (100 pg/ml) for 24 hours. Cell-free supernatants were collected and cytokine concentrations were measured by ELISA assay. The experiments were repeated for five times with similar results. Data represent mean ± SEM; *, P<0.05. Fig. 2 Low-doses LPS preferentially induces the formation of IRAKM Myddosome via the death domain of IRAKM A. WT BMDMs were treated with high dose LPS (1 µg/ml) and low dose LPS (100 pg/ml) for the indicated times, followed by immunoprecipitation (IP) with anti-IRAK-4 antibody and analyzed by Western blot analysis. B–D. IRAK-1/2/M-triple deficient immortalized BMDMs infected with adenovirus expressing FLAG-tagged IRAK1, FLAG-tagged chimeric IRAKM death domain with IRAK1 kinase domain (DD(M)+IRAK1) and FLAG-tagged IRAKM were treated with low dose LPS (100 pg/ml) for indicated times. B. immunoprecipitates and C. cell lysates were analyzed by Western blot analysis. D. Total mRNA from transfected cells was subjected to RT-PCR analyses. Fig. 3 IRAKM-dependent pathway is required for the development of chronic ethanol-induced liver disease WT and IRAKM KO mice were allowed free access to ethanol (EtOH) (n=6) or pair-fed control diets (n=4). A. AST and ALT activity was determined in plasma. B. Paraffin-embedded liver sections were stained with hematoxylin and eosin. C. Frozen liver sections were subjected to Oil Red O staining. All images were acquired using a 10× objective. D. Hepatic triglyceride content was measured in whole liver homogenates. E. Total mRNAs from livers of WT and IRAKM KO mice (pair-fed and EtOH-fed) were subjected to RT-PCR analysis. Fig. 4 IRAKM is required for TLR and chronic ethanol-induced Mincle upregulation A. Cell lysates from WT and IRAKM KO BMDMs untreated or treated with low dose LPS (100 pg/ml) for the indicated times were analyzed by Western blot analysis B. Cell lysates from WT and IRAK1/2 DKO BMDMs untreated or treated with low dose LPS (100 pg/ml) for the indicated times were analyzed by Western blot analysis. C. Immunostaining of F4/80 (green) and Mincle (red) was performed on frozen sections of liver from of WT and IRAKM KO mice (pair-fed and EtOH-fed). Confocal images are representative of five mice per group. D. Resident macrophages (F4/80+CD11b+) from livers of pair-fed and ethanol-fed mice were isolated by flow cytometry-based sorting. Total RNA was subjected to RT-PCR analysis. E. Tissue lysates from the whole liver of WT and IRAKM KO mice (pair-fed and EtOH-fed) were analyzed by Western blot analysis. Fig. 5 Mincle-dependent pathway is required for the development of chronic ethanol-induced liver disease WT and Mincle KO mice were allowed free access to ethanol (EtOH) (n=6) or pair-fed control diets (n=4). A. AST and ALT activity was determined in plasma. B. Paraffin-embedded liver sections were stained with hematoxylin and eosin. C. Frozen liver sections were subjected to Oil Red O staining. All images were acquired using a 10× objective. D. Hepatic triglyceride content was measured in whole liver homogenates. E. Tissue lysates from the whole liver of WT and Mincle KO mice (pair-fed and EtOH-fed) were analyzed by Western blot analysis. The black arrows point out the specific bands of pSyk. F. Total mRNAs from livers of WT and Mincle KO mice (pair-fed and EtOH-fed) were subjected to RT-PCR analysis. Fig. 6 SAP130-mediated mincle activation is required for low concentration LPS induced inflammation through inflammasome activation A. Primary hepatocytes from WT mice were treated with EtOH (50 mM) for 24 hours. Cell-free supernatants were collected and SAP130 was measured by Western blot analysis. B. BMDMs from WT and Mincle KO mice were treated with PBS, LPS (100 pg/ml) for 24 hours, SAP130 (5 ug/ml) for 2 hours, TDB (100 µg/ml, 2 hours), LPS (100 pg/ml, 24 hours) + SAP130 (5 µg/ml, 2 hours) or LPS (100 pg/ml, 24 hours) + TDB (100 µg/ml, 2 hours). Total mRNA was subjected to RT-PCR analyses. C. BMDMs from WT and Mincle KO mice were treated with PBS, LPS (100 pg/ml) for 24 hours, LPS (100 pg/ml, 24 hours) + SAP130 (5 µg/ml, 6 hours) or LPS (100 pg/ml, 24 hours) + TDB (100 µg/ml, 6 hours). Cell lysates and supernatants were collected together and analyzed by Western blot. D. IL-1β was measured in Cell-free supernatants by ELISA. E. Tissue lysates from the whole liver of WT and IRAKM KO mice (pair-fed and EtOH-fed) were analyzed by Western blot. F. Tissue lysates from the whole liver of WT and Mincle KO mice (pair-fed and EtOH-fed) were analyzed by Western blot analysis. Fig. 7 IRAKM-Mincle axis contributes to the pathogenesis and development of ALD Chronic alcohol consumption results in increased intestinal permeability and changes in bacterial microflora increase levels of bacterial products in alcoholic patients and animal models of ALD. Further, alcohol exposure can induce endoplasmic reticulum (ER) stress and mitochondrial dysfunction in hepatocytes, contributing to hepatocellular injury and death. TLR4- induced IRAKM-mediated MEKK3-dependent NFκB activation is required for the up-regulation of Minlce in hepatic macrophages. Mincle sense the necroptotic hepatocytes-released nuclear protein, SAP130, which in turn activates the inflammasome activation in macrophages. Secreted IL-1β may further act on hepatocytes inducing pyroptosis or on Stellate cells which leads to fibrosis. 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PMC005xxxxxx/PMC5115960.txt
LICENSE: This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. 7707449 656 Ann Neurol Ann. Neurol. Annals of neurology 0364-5134 1531-8249 27686464 5115960 10.1002/ana.24789 NIHMS820622 Article RNAi prevents and reverses phenotypes induced by mutant human ataxin-1 Keiser Megan S. PhD 1 Monteys Alejandro Mas PhD 1 Corbau Romuald PhD 12 Gonzalez-Alegre Pedro PhD, MD 13 Davidson Beverly L. PhD 14 1 The Raymond G Perelman Center for Cellular and Molecular Therapeutics, The Children's Hospital of Philadelphia, Philadelphia, PA 2 Spark Therapeutics Inc. Philadelphia, PA 3 Department of Neurology, the University of Pennsylvania, Philadelphia, PA 4 Department of Pathology and Laboratory Medicine, the University of Pennsylvania, Philadelphia, PA Correspondence should be addressed to Beverly L. Davidson, Raymond G Perelman Center for Cellular and Molecular Therapeutics, 5060 Colket Translational Research Building, 3501 Civic Center Boulevard, Philadelphia, PA 19104, davidsonbl@email.chop.edu 4 10 2016 2 11 2016 11 2016 02 11 2017 80 5 754765 This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. Objective Spinocerebellar ataxia type 1 is an autosomal dominant fatal neurodegenerative disease caused by a polyglutamine expansion in the coding region of ATXN1. We showed previously that partial suppression of mutant ataxin-1 (ATXN1) expression, using virally-expressed RNAi triggers, could prevent disease symptoms in a transgenic mouse model and a knock in mouse model of the disease, using a single dose of virus. Here, we set out to test if RNAi triggers targeting ATXN1 could not only prevent, but also reverse disease readouts when delivered after symptom onset. Methods We administered recombinant adeno-associated virus (rAAV) expressing miS1, an artificial miRNA targeting human ATXN1 mRNA (rAAV.miS1) to a mouse model of SCA1 (B05 mice). Viruses were delivered prior to or after symptom onset at multiple doses. Control B05 mice were treated with rAAVs expressing a control artificial miRNA, or with saline. Animal behavior, molecular phenotypes, neuropathology and magnetic resonance spectroscopy were done on all groups and data were compared to wildtype littermates. Results We found that SCA1 phenotypes could be reversed by partial suppression of human mutant ATXN1 mRNA by rAAV.miS1 when delivered after symptom onset. We also identified the therapeutic range of rAAV.miS1 that could prevent or reverse disease readouts. Interpretation SCA1 disease may be reversible by RNAi therapy, and the doses required for advancing this therapy to humans are delineated. INTRODUCTION Spinocerebellar ataxia type 1 (SCA1) is an autosomal dominant progressive neurodegenerative disease caused by a polyglutamine repeat expansion in exon 8 of the ataxin-1 (ATXN1) gene.1 Healthy individuals have from 6 – 42 CAG repeats in ATXN1 interspersed by 1 – 3 CAT codons. A pure CAG expansion exceeding 40 glutamines causes disease pathogenesis by a toxic gain-of-function mechanism. Although ataxin-1 protein (ATXN1) is ubiquitously expressed, specific cerebellar Purkinje cells (PCs) and brainstem neurons are more susceptible to expanded ATXN1 expression and carry the bulk of pathology. As a result, patients with SCA1 develop a prominent cerebellar syndrome with brainstem features, including gait and limb ataxia, dysarthria or dysphagia, among others. To date, SCA1 remains a fatal disease with no known disease modifying therapies. The initial mouse model for SCA1 is a transgenic line expressing mutant human ATXN1 from a Purkinje cell specific promoter (Pcp2).2,3 This mouse, known as the B05 model, develops progressive disease, with many features similar to SCA1 including measurable gait deficits by 7 weeks of age. Additionally, there are transcriptional changes by postnatal day 25 and PC loss by 24 weeks of age.3 Earlier, a doxycycline-inducible form of the B05 model revealed that pre-existing phenotypes were reversible after many weeks of mutant ATXN1 expression.4 This suggests that a window of opportunity exists not only for halting the disease, but perhaps also to reverse the presence or severity of symptoms once present. We previously assessed the utility of gene silencing strategies as a putative therapy for SCA1 in this and a knock in (KI) model of disease. Delivery of recombinant AAVs (rAAV) expressing RNAi triggers in the form of shRNAs provided clinical benefit in B05 mice after direct injection into the cerebellar cortex.5 More recently, we showed that delivery of rAAVs expressing artificial miRNAs directed at mutant ATXN1 mRNA, to the deep cerebellar nuclei (DCN) for transport to PCs and other brainstem neurons, also improved pathologic and behavioral phenotypes in this model.6 Similarly, rAAVs expressing microRNAs (miRNAs) directed at mutant mouse Atxn1 mRNA was beneficial when applied to the KI SCA1 model.7 Importantly, the DCN-directed approach is scalable from mice to larger mammals; clinically relevant biodistribution and silencing was observed when tested in nonhuman primates.8 While these studies provided the necessary proof-of-principal for advancing RNAi therapy for SCA1, the treatment was applied before symptom onset. Here, we set out to test the clinically-relevant hypothesis stating that viral-expressed RNAi provides therapeutic benefit when delivered after symptom onset. Furthermore, before advancing this treatment to patients it is critical to define the dosing window between the minimal effective doses and the toxicity threshold. We therefore evaluated the effects of increasing doses of a clinical SCA1 gene therapy product directed at silencing mutant ATXN1 mRNA, on the prevention or reversal of clinical and neuropathological signs in B05 mice. Methods and Materials Plasmids and viral vectors The therapeutic miRNA sequence targeting human and rhesus Ataxin-1 (miS1) has been previously described.7 The original therapeutic vector rAAV1.miS1.eGFP was modified to no longer express eGFP and instead contain a “safe stuffer” sequence.9 Recombinant rAAV serotype 2/1 vectors (rAAV1.miS1 and rAAV1.miControl) were generated at The Children’s Hospital of Philadelphia Research Vector Core. AAV vectors were resuspended in Diluent Buffer (The Children’s Hospital of Philadelphia Research Vector Core) and titers (viral genomes/ml) were determined by QPCR. Cell culture and transfection HEK293 cells were transfected (Lipofectamine™ 2000) in quadruplicate in 24-well plates per manufacturer’s instructions with 500ng of plasmid containing pAAV.miS1.eGFP, pAAV.miS1, pAAV, or no plasmid. Total RNA was harvested 24 hours with TRIzol®. Animals All animal protocols were approved by The Children’s Hospital of Philadelphia Animal Care and Use Committee. Wild type FVB mice were obtained from Jackson Laboratories (Bar Harbor, ME). B05 transgenic mice were previously provided by Dr. H.T. Orr and re-derived by Jackson Laboratories. The B05 line was maintained on the FVB background. Mice were genotyped using primers specific for the mutant human ataxin-1 transgene.2 Hemizygous and age-matched wildtype littermates were used for the indicated experiments. Treatment groups comprised of approximately equal numbers of male and female mice. Mice were housed in a controlled temperature environment on a 12-hour light/dark cycle. Food and water were provided ad libitum. AAV injections and brain tissue isolation B05 mice were injected with rAAV1 vectors expressing miS1 or a control scrambled miRNA sequence (miC). Mice were stereotaxically injected bilaterally to the deep cerebellar nuclei (coordinates −6.0 mm caudal to bregma, ± 2.0 mm from midline, and −2.2 mm deep from the cerebellar surface) with 4 μl of rAAV1 virus at doses of 1×107 vg, 1×108 vg, 6×108 vg, 1×109 vg, 6×109 vg or 1×1010 vg/hemisphere or saline (Diluent Buffer). Mice were anesthetized with 4% isoflurane/oxygen mixtures and transcardially perfused with 20 ml of ice cold saline. Mice were decapitated, and for histological analyses, brains were removed and post-fixed overnight in 4% paraformaldehyde. Brains were stored in 30% sucrose/0.05% azide solution at 4°C until cut on a sledge microtome at 40 μm thickness and stored at – 20 °C in a cryoprotectant solution. For RNA and metabolite analyses, brains were removed and cerebellar hemispheres were flash frozen in liquid nitrogen and stored at – 80 °C. RNA was isolated from whole cerebellum using 1 ml of Trizol®, RNA quantity and quality were measured using a NanoDrop® 2000. For metabolite analysis, tissues were subjected to a perchloric acid extraction. Frozen samples were weighed and homogenized using beads in a TissueLyzer LT (Qiagen). Ice cold 3.6% HClO4 was added, further homogenized and centrifuged at 4°C. Supernatant was buffered to a pH of ~7.0 with KOH, centrifuged, lyophilized and again weighed. Immunohistochemical analysis Free-floating sagittal cerebellar sections (40 μm thick) were washed in 1 X TBS with 0.05% Triton®X-100 at room temperature and blocked for 1 hour in 5% serum, 0.05% Triton®X-100, in 1X TBS. Sections were incubated with primary antibody in 3% serum and 0.05% Triton®X-00 in TBS overnight at room temperature. Primary antibodies used were polyclonal rabbit anti-Calbindin (1:2000; Sigma), polyclonal anti-Iba1 (1:1000; WAKO), polyclonal anti-GFAP (1:2000; DAKO), and polyclonal rabbit 12NQ (1:1000; Orr Lab10). For Fluorescent IHC, sections were incubated with goat anti-rabbit Alexa Fluor 488 or 568 (1:200; Life Technologies) in 3% serum and 0.05% Triton®X-100 in 1 X TBS for 1 hour at room temperature. For DAB IHC, sections were incubated in goat anti-rabbit biotin-labeled secondary antibody (1:200; Jackson Immunoresearch) in 3% serum and 0.05% Triton®X-100 in 1 X TBS for 1 hour at room temperature. Tissues were developed with Vectastain® ABC Elite Kit (Vector Laboratories), according to the manufacturer’s instructions. All sections were mounted onto Superfrost Plus slides (Fischer Scientific) and cover-slipped with Fluoro-Gel (Electron Microscopy Sciences) or dehydrated and cover-slipped with DPX. Images were captured on a Leica DM6000B fluorescence microscope using LAS X software. Semi-quantitative PCR Reverse transcription (High Capacity cDNA Reverse Transcription Kit, Applied Biosystems) was performed on 1 μg total RNA collected from cerebellum using a standard stem-loop PCR primer designed to identify miS1 previously described.7 sqRT-cDNA was subjected to RT-PCR with a standard reverse primer and a forward primer specific to miS1. Quantitative PCR Random-primer first-strand cDNA synthesis was performed using 2 μg total RNA (High Capacity cDNA Reverse Transcription Kit, Applied Biosystems) per manufacturer’s instructions. Assays were performed on a BioRad CFX384 Real Time System using TaqMan® (Thermo-Fischer Scientific) primer/probe sets specific for human Ataxin-1, mouse Pcp2, mouse Grm1 or mouse β-Actin (TaqMan® 2X Universal Master Mix by Life Technologies). 1H-magnetic resonance spectroscopy Analysts were blinded to the treatment groups. NMR spectroscopy was performed at 400MHz on a Bruker Avance III 400 wide-bore spectrometer. Each lyophilized tissue extract was dissolved in 0.4 ml of D2O, the pH adjusted to 7.0 and the solution was introduced in a 5 mm NMR tube. An external standard made of a sealed capillary containing a solution of trimethylsilylpropionic acid (TSP) in D2O was centered in the NMR tube and used as chemical shift reference and quantitation standard. Fully relaxed proton spectra were acquired with a 5 mm proton probe. Standard acquisition conditions were as follows: PW 5 μs (45°) TR 8.84s (AQ 4.84s, D1 4s), SW 6775 Hz, TD 64k, 128 scans 4 DS. A soft water saturation pulse was applied during the 4s relaxation delay. Rotarod Analysis Mice were tested by a tester blinded to the treatment groups on an accelerated rotarod apparatus (model 47600; Ugo Basile). For distribution to groups of equal abilities at baseline, mice were first tested at 5 weeks of age prior to treatment. Mice were habituated to the rotarod for 4 min then subjected to three trials per day (with at least 30 min of rest between trials) for four consecutive days. For each trial, acceleration was from 4 to 40 rpm over 5 min, and then speed maintained at 40 rpm. Latency to fall (or if mice hung on for two consecutive rotations without running) was recorded for each mouse per trial. Trials were stopped at 500 seconds, and mice remaining on the rod at that time were scored as 500 seconds. Two-way analysis of variance followed by a Tukey post-hoc analysis was used to assess for significant differences. Variables were time and treatment. Statistical Analysis For all studies, p values were obtained by using one-way analysis of variance followed by Tukey post-hoc analysis to assess for significant differences between individual groups. In all statistical analysis, P < 0.05 was considered significant. Figure Preparation All photographs were formatted with Adobe Photoshop software. All graphs were made with GraphPad Prism® software. All figures were constructed with Adobe Illustrator software. RESULTS AAV1.miS1 prevents the development of rotarod deficits in B05 mice We first modified the former rAAV1.miS17 wherein the eGFP reporter expression cassette was replaced with a stuffer sequence. The stuffer sequence ensured appropriate length of the expression cassette required for optimal AAV packaging (Fig 1A). To assess that this modification did not impact the silencing potency of the miRNA we transfected HEK 293 cells with the shuttle plasmid pAAV.miS1.eGFP, pAAV.miS1 or a control plasmid. Compared to control transduced cells, both pAAV.miS1.eGFP and pAAV.miS1 significantly reduced ATXN1 mRNA expression 24 hours post-transfection (Fig 1B); replacing eGFP with stuffer sequence did not alter the potency of the artificial miRNA. We used the B05 model2 for this work as the RNAi trigger expressed from rAAV1.miS1 targets human ATXN1. B05 transgenic mice show progressive disease, with transcriptional changes evident prior to noted behavioral deficits (Fig 1C). To identify the efficacy and toxicity thresholds to prevent disease progression, mice were injected bilaterally into the deep cerebellar nuclei (DCN) with increasing doses of rAAV1.miS1, rAAV1.miC or saline after baseline behavior testing (Table 1). Twenty-four weeks after injection (30 weeks of age) animals were re-assayed by rotarod and then euthanized and tissues collected for post-necropsy analysis (Fig 1C). As seen in Figure 1D, at 30 weeks of age control treated transgenic mice could not remain on the rotarod apparatus after 98.8 ± 22 seconds. B05 mice treated with rAAV1.miS1 at doses of 8×108 and 8×109 vector genomes (vg) performed significantly better than control treated transgenic animals and were not statistically differently than their wildtype littermates. rAAV1.miS1 reduces ATXN1 mRNA in SCA1 mouse in a dose-dependent manner, preventing changes in cerebellar metabolites Semi-quantitative PCR on whole cerebellar lysates confirmed miS1 expression (Fig 2A), with a clear dose-response. Quantitative RT-PCR for mutant human ATXN1 mRNA (Fig 2B) showed a similar dose response that inversely correlated with miS1 levels. B05 mice treated with rAAV1.miC or rAAV1.miS1 at a dose of 8×107 vg had similar levels of ATXN1 mRNA (98 ± 4% and 100 ± 3% respectively) relative to saline-treated animals. B05 mice administered 8×108 or 8×109 vg of rAAV1.miS1 had increasingly reduced levels of ATXN1 mRNA (77 ± 3 and 47 ± 7%, respectively). B05 mice in the high dose group had almost complete reduction of human ATXN1 mRNA levels (4 ± 1) relative to the control treated animals. High field proton magnetic resonance spectroscopy (1H MRS) allows quantitation of biomarkers in SCA1 patients in a non-invasive manner. In 2010, Oz-G and colleagues showed that SCA1 patients have reduced N-acetylaspartate (NAA) levels and elevated inositol levels.11 The same observations have been made in SCA1 mouse models. We therefore assayed metabolite levels in cerebellar lysates from all groups using nuclear magnetic resonance (NMR). Similar to results on untreated B05 mice12, control treated mice had reduced NAA/inositol ratios compared to wildtype littermates (Fig 2C). However, this difference was normalized to wildtype levels in B05 mice treated with 8×109 or 8×1010 vg of rAAV1.miS1 (Fig 2C). rAAV.miS1 at 8×109 vg prevents cerebellar pathology In SCA1, PC dendrites progressively retract, resulting in cerebellar molecular layer (ML) thinning.13 To investigate the potential protective effect of rAAV1.miS1 on this phenotype, brain sections were evaluated by anti-calbindin staining of sagittal sections, and ML widths quantified. In control treated B05 animals, lobules III-IV/V have marked thinning, as do sections from animals injected with 8×108 vg of rAAV1.miS1 compared to wildtype littermates (Fig 3A). However, there was no significant difference between the ML widths of wildtype animals and B05 mice treated with 8×108, 8×109, or 8×1010 vg of rAAV1.miS1. In lobules IV/V-VI, all groups of B05 treated mice, except those treated with rAAV1.miS1 at 8×109 vg, were significantly reduced relative to their wildtype littermates (Fig 3B). Immunohistochemistry for human ATXN1 in PCs of control treated mice showed, as expected, expression of the transgene in B05 but not wildtype mice (Fig 3C). B05 mice treated with increasing doses of rAAV1.miS1 had progressively less ATXN1-positive PCs. At a dose of 8×1010 vg, no ATXN1-positive PCs were detectable. Histological staining for glial fibrillary acidic protein (Gfap, a marker of astroglial activation), revealed enhanced immunoreactivity at the site of injection (the DCN) in all injected animals, and those treated at 8×1010 vg had robust enhancement (Fig 3D). Histological staining for ionized calcium-binding adapter molecule 1 (Iba1), a marker for microglial activation, did not show differences among any experimental groups except for those receiving the highest dose of rAAV1.miS1 (Fig 3E, F). rAAV2/1.miS1 is effective after disease onset Two doses (8×108 and 8×109 vg) were effective and non-toxic in our pre-onset treatment design. Because most patients with SCA1 present to the clinic with some disease manifestations, we tested the effects of miS1 therapy after disease onset. B05 mice have deficits on the rotarod by 10-11 weeks of age (Fig 4A). We baseline tested B05 mice and wildtype littermates on the rotarod at 11 weeks, to confirm deficits (Fig 4B), and then performed dosing studies as before, except that 5 doses (rather than 4) of rAAV1.miS1, or control were injected at 12 weeks of age. Additionally, the doses stepped up by ½ log and the lowest dose in the pre-disease onset treatment paradigm, which resulted in no silencing, was omitted (Table 2). End-study rotarod was conducted at 20 weeks of age (Fig 4C) and 2 weeks later tissue collected for post-necropsy analysis. Nine weeks after injection, wildtype mice performed significantly better than B05 mice receiving saline, rAAV1.miC, and the low and two high dose groups. In contrast to wildtype mice, treated B05 mice in these groups had poorer performance relative to their baseline. However, B05 mice treated with 2.6×109 vg or 8×109 vg of rAAV1.miS1 performed significantly better than they did at 11 weeks of age, and also significantly better than the other B05 treatment groups. Cumulatively, the data support the hypothesis that rAAV1.miS1 delivery into the DCN of symptomatic ataxic mice improves motor symptoms in the B05 model of SCA1. rAAV1.miS1 reduces ATXN1 and improves molecular readouts in symptomatic B05 mice miS1 expression was detected in B05 mice treated with rAAV1.miS1 (Fig 5A), and there was a clear dose-dependent reduction of human ATXN1 mRNA levels in cerebellar lysates (Fig 5B). ATXN1 mRNA levels were not different between B05 mice treated with saline, rAAV1.miC, and 8×108 vg rAAV1.miS1. B05 mice treated with 2.6×109 vg, 8×109, 2.6×1010 or 8×1010 vg of rAAV1.miS1 had progressively greater levels of knockdown relative to saline-treated B05 mice. Evaluation of transcripts from Purkinje cell protein 2 (Pcp2) and the metabotropic glutamate receptor type 1 (Grm1), two transcripts down-regulated in this model were also done.14,15 B05 mice treated with or rAAV1.miC had significantly lower levels of Pcp2 mRNA than wildtype littermates (Fig 5C). Although B05 mice treated with 8×108 or 8×1010 vg of rAAV1.miS1 had significantly lower levels of Pcp2, B05 mice given 8×109 vg of rAAV1.miS1 had Pcp2 levels that were not different from wildtype. Similar to Pcp2, we detected significantly reduced Grm1 mRNA levels in control treated B05 mice or B05 mice treated with rAAV1.miS1 at 8×108 or 8×1010 vg (Fig 5D). Of note, SCA1 mice treated with 8×109 vg of rAAV1.miS1 expressed Grm1 at levels not significantly different from wildtype littermates. Consistent with the results shown earlier (Fig 2C), cerebellar lysates of control treated B05 mice had abnormal NAA/ inositol ratios as measured by NMR that improved with treatment (Fig 5E). B05 mice treated with 8×109 vg of rAAV1.miS1 had a NAA/inositol ratio that was not significantly different from their wildtype littermates. rAAV1.miS1 improves cerebellar pathology in symptomatic B05 mice Sagittal sections were processed to quantify the molecular layer widths in medial cerebellar regions of lobules IV/V and VI. The data show marked thinning in control-treated B05 mice, and mice treated with 8×108 or 8×1010 vg of rAAV.miS1 relative to those regions in wildtype mice (Fig 6A). However, there was no significant difference between wildtype mice and B05 mice treated with 8×109 vg of rAAV1.miS1. ML widths in the caudal medial cerebellar sections between lobules VIII and IX also show significant thinning in control treated B05 mice and B05 mice administered 8×1010 vg rAAV1.miS1 (Fig 6B). B05 mice treated with 8×108 or 8×109 vg of rAAV1.miS1 had ML widths that were not significantly different from wildtype littermates. Similar to the results observed in the pre-symptomatic dosing experiment, B05 mice treated with saline or rAAV1.miC are immunoreactive for human ATXN1 in most PCs. B05 mice treated post-symptomatically with rAAV1.miS1 show decreasing levels of ATXN1-positive PCs that correlate inversely to the dose injected (Fig 6C). B05 mice treated with rAAV1.miS1 at 8×108 vg had fewer ATXN1-positive PCs than control treated mice; whereas those treated with rAAV1.miS1 at 8×109 or 8×1010 have few to no detectable ATXN1-positive PCs. In the DCN, the site of injection, there were similar amounts of Gfap+ immunoreactive cells in all sections, with the exception of enhanced immunoreactivity in B05 mice treated with 8×1010 vg of rAAV1.miS1 (Fig 6D). B05 mice treated with saline or rAAV1.miC showed slightly higher levels of Iba1 immunoreactivity in the cortex and DCN than those treated with 8×108 or 8×109 vg rAAV1.miS1, or wildtype mice. B05 mice treated with rAAV1.miS1 at 8×1010 vg showed elevated Iba1 immunoreactivity in both the cortex and the DCN (Fig 6E, F). Discussion This work provides solid experimental evidence demonstrating that RNAi-mediated suppression of ATXN1 mRNA alters disease progression, reverses symptoms and normalizes cerebellar pathology and disease biomarkers in a SCA1 model. In addition, it identifies doses within the efficacy-toxicity window to guide clinical development of RNAi for the treatment of SCA1. We identified the least effective dose, the toxicity threshold, and several effective doses that could either prevent or improve SCA1 readouts. Importantly, the doses used in prior work6,7 showing the efficacy of the approach for preventing mutant (human or mouse) ataxin-1-induced symptoms, were recapitulated here. Cumulatively, our data in symptomatic mice corroborate and extend earlier work demonstrating that eliminating mutant human ataxin-1 expression is therapeutic, even after cerebellar pathology and neurological deficits are evident.4,16 In earlier studies by Orr and colleagues, mutant ataxin-1 was completely eliminated and aggregates resolved quickly with recovery of cerebellar pathology.4 Our results are similar but contrasting in important ways. The similarities are that RNAi trigger expression, even when initiated after symptom onset, was therapeutic and improved symptomatology. The major difference is that our suppression was partial rather than complete, and mutant ATXN1 was not suppressed in every Purkinje cell. This result is exciting and suggests that i) partial suppression after disease onset can be beneficial, and ii) that limiting coverage of the RNAi therapy to even a portion of the cerebellum, most notably the medial regions, can improve behavioral outcomes. We found that 2.6×109 vg had 48%, and 8×109 vg had ~71% reduction of mutant ATXN1 mRNA, and both provided benefit. rAAV.miS1 not only prevented further disease progression, but also improved disease readouts (e.g. see rotarod studies). At baseline, B05 animals were significantly impaired (Fig 4B, C). After receiving miS1 at doses of 2.6×109 and 8×109 vg, rotarod performance at 20 weeks of age demonstrated a reversal of pre-existing impairment, and they performed no differently from their wildtype littermates. The difference between a 28% reduction in ATXN1 produced by 8×108 vg and a 48% reduction in ATXN1 produced by 2.6×109 vg of rAAV1.miS1 delineates the threshold for reversal of rotarod performance when delivered to post-symptomatic B05 mice. This is the first time, to our knowledge, that delivery of an RNAi vector has been shown to quantifiably reverse disease pathology in B05 SCA1 mice. Of note, pre-symptomatic B05 mice receiving 8×108 vg at 6 weeks of age failed to develop the phenotypic rotarod deficit by 30 weeks of age, suggesting that earlier treatment with less viral load can be beneficial. PC dysfunction occurs prior to cell loss in SCA1 and in SCA1 mice models. One measure of this is a reduction in molecular layer width due to PC dendritic retraction. The anterior lobe (rostral lobules) of the cerebellum is key to maintain balance, and dysfunction causes truncal ataxia.17 It is also a region affected early in the pathogenesis of SCA1.18,19 The posterior lobe (caudal) plays an important role in motor coordination.20 In mice that received 8×108 vg, molecular layer widths were similar in width to wildtype mice in caudal lobules, with measurable thinning in rostral lobules. However mice treated with 8×109 vg of rAAV.miS1 retained molecular layer widths similar to wildtype in both rostral and caudal lobules. This suggests that this dose, with scaling for human use, may provide preservation of both rostral and caudal aspects of the molecular layers lending improved balance and motor coordination respectively, as well as rescue motor symptoms. It is worth noting that in the B05 model, the human transgene is expressed in the PCs only. However, assays for transduction efficiency, molecular readouts of efficacy, and transgene (miS1) levels were performed on whole cerebellar lysates. These data demonstrate the PC-targeting efficiency of this vector system. Molecular indicators of efficacy include Pcp2, the mRNA of which is trafficked to the dendrites,21 and Grm1, a metabotropic glutamate receptor 1 located in the post-synaptic termini of dendrites.21 The latter is critical for coordinated motor function.22 Both Pcp2 and Grm1 deficits were reversed in mice by 67% reduction in ATXN1. It has been previously shown that B05 mice have elevated Iba1+ immunoreactivity and is reversible in the SCA1 conditional model.23 We also noted enhanced Iba1+ immunoreactivity in control treated B05 mice relative to WT animals, and qualitatively more in the 8×1010 vg rAAV1.miS1 treatment group. In B05 mice treated with 8×108 or 8×109 vg, Iba1+ immunoreactivity was reduced. Thus, even a 28% reduction in ATXN1 (8×108 vg dose), which does not result in behavioral rescue, can abate the phenotypic increase in Iba1+ signal. Non-invasive biomarkers will provide critical tools for assessing efficacy in SCA1. High field proton magnetic resonance spectroscopy (1H MRS) indicates that SCA1 patients have lower levels of N-acetylaspartate (NAA), and elevated levels of inositol.11 These data have been recapitulated in transgenic SCA1 mice12 and were reversed in a conditional mouse model of SCA1.16 NAA reduction usually precedes neuronal loss, and is used as a marker of neuronal dysfunction.24 In this work, NAA levels were modestly reduced in control treated SCA1 mice at 20 weeks of age, a time prior to significant PC loss. Importantly, mice treated with 8×109 vg of rAAV.miS1 had a NAA/inositol similar to their wildtype littermates. This, together with previous studies suggests that the NAA/Inositol may be a sensitive, non-invasive measure of efficacy and a possible biomarker in disease-modifying clinical trials for SCA1. Motor deficits quantified by the Scale for Assessment and Rating of Ataxia (SARA) correlate with altered neurochemical levels quantified by MRS.25 We see a similar relationship in our untreated B05 mice, with improved “scores” upon treatment. These data suggest that rAAV1.miS1 could provide therapeutic benefit and prevention of further pathogenesis in SCA1 patients if administered prior to disease onset. Moreover, rAAV1.miS1 could halt or even reverse pre-existing motor deficits in early, symptomatic SCA1 patients. Thus, SARA scores could stabilize or improve with treatment, along with concomitant improvements in neurochemical levels. While the B05 model was useful for assessing the utility of our clinical product, a more genetically relevant model would be a humanized knock-in that would allow testing of miS1. This would allow efficacy testing in a setting more biologically similar to SCA1 patients, as compared to the transgenic model where the transgene is only expressed in PCs. Of note is that RNAi was tested in mice expressing an expanded CAG repeat in mouse ataxin-1,26 with efficacy at the same E9 dose, (using a RNAi trigger that targeted mouse ataxin-1). Whether the doses that reverse disease are similar to what we found in the B05 model remain to be tested, but are important to determine in future work. Additionally, we cannot assume that miS1 (targets human) and miSCA1 (targets mice) are equivalent in safety, as they are different sequences. Nonetheless it is encouraging that similar doses prevented disease in the current models that are available. Although we noted prevention or reversal of disease at several doses, we also noted toxicity at the highest dose tested. The reasons for this are unclear. It could be due to the near complete absence of ATXN1 in transduced cells, although we think this is not likely due the fact that chronic, 100% loss of Atxn1 in mice causes transcriptional misregulation but no noted neuropathology or ataxia. 27,28 A second possibility is that the high level expression of miS1 somehow causes toxicity due to abnormal processing of endogenous miRNAs. This can be evaluated in future work to examine endogenous miRNA processing and miRNA activity. We think this is improbable, however, as we used miS1 in an older vector platform and reversed aberrant miRNA expression in the B05 model.29 A third possibility is that the high capsid dose is toxic. Testing for this could be done using empty capsid preparations as controls at the doses evaluated here. We are investigating the exact mechanisms underlying the toxicity as part of a follow up study. And while this data informs us of a toxicity ceiling and the maximum tolerable dose, understanding the mechanism for that toxicity is important moving forward. In summary, we show that AAV-mediated delivery of RNAi triggers can reverse neuropathological phenotypes, transcriptional changes, and behavioral phenotypes in a mouse model of SCA1. We also identify the minimal effective and maximally tolerated doses that will guide our clinical application for SCA1 therapy. Together with earlier work demonstrating the scalability of our approach to nonhuman primates,8 our studies will guide the initial application to SCA1 and other cerebellar diseases in which PCs, brainstem neurons and the DCN are important therapeutic targets. Acknowledgements The authors would like to thank The Children’s Hospital of Philadelphia Research Vector Core for the viruses used in this work. The authors would also like to thank Suzanne L. Wehrli and The Children’s Hospital of Philadelphia Small Animal Imaging Facility and Matthew Sowada for assistance with behavioral experiments. This work was funded by the NIH, NINDS (UH2NS094355), the National Ataxia Foundation Pioneer Award, and The Children’s Hospital of Philadelphia Research Institute. FIGURE 1 Experimental design and rotarod analysis. (A) Cartoon of therapeutic viral construct. Inverted terminal repeats (ITR) surround murine U6 promoter driving expression of an artificial miRNA targeting human ATXN1 (miS1) followed by a non-coding stuffer sequence. (B) Comparative silencing efficiency of pAAV.miS1.eGFP and pAAV1.miS1 in HEK293 cells (N=4 replicates; ***p < 0.0001). (C) Timeline of disease progression in B05 mice and study design. (D) Rotarod performance over 4 days at 30 weeks of age. Treatment groups consisted of untreated wildtype mice, B05 mice injected with saline, B05 mice injected at 8 × 108 vector genomes (vg) of rAAV2/1.miControl (denoted as miC), B05 mice injected at 8 × 107 vg (denoted as 8E7) of rAAV2/1.miS1, B05 mice injected at 8 × 108 vg (denoted as 8E8) of rAAV2/1.miS1, B05 mice injected at 8 × 109 vg (denoted as 8E9) of rAAV2/1.miS1, B05 injected at 8 × 1010 vg (denoted as 8E10) of rAAV2/1.miS1 (*** denotes p < 0.0001; * p < 0.05; difference from rAAV1.miC and saline treated B05 animals). FIGURE 2 sqPCR, qRT-PCR, and NMR analyses of cerebellar extracts from treated B05 mice and untreated wildtype littermates. (A) Semi-quantitative analysis of miS1 from whole cerebellar extracts. (B) qRT-PCR for human ATXN1 mRNA levels from whole cerebellar extracts (N ≥ 3; ** p < 0.01; *** p < 0.0001; differences from saline injected SCA1 mice). (C) Ratio of NAA/Inositol levels from whole cerebellar extracts (N=3; *** p < 0.0001; differences from control treated B05 mice). FIGURE 3 Cerebellar pathology. (A) Molecular layer widths of lobules III and IV/V from sagittal cerebellar sections 0.5 mm from midline (N ≥ 3; ** denotes p < 0.01; differences from wildtype). (B) Molecular layer widths of lobules IV/V and VI from sagittal cerebellar sections 0.5 mm from midline (N ≥ 3; * denotes p < 0.05; ** denotes p < 0.01; *** denotes p < 0.0001; differences from wildtype). (C) Representative photomicrographs of sagittal cerebellar sections immunostained for human ataxin-1. Scale Bar = 100 μm. (D) Representative photomicrographs of sections from DCN immunostained for Gfap. Scale Bar = 100 μm. (E) Representative photomicrographs of sagittal cerebellar cortices immunostained for Iba1. Scale Bar = 100 μm. (F) Representative photomicrographs of sagittal cerebellar DCN immunostained for Iba1. Scale Bar = 100 μm. FIGURE 4 Experimental design of reversal study and rotarod data. (A) Timeline of disease progression in B05 mice and study design. (B) 11 week old baseline rotarod. Rotarod performance over 4 days at 11 weeks of age (*p < 0.05; ***p < 0.0001). (C) Rotarod performance over 4 days at 11 and 20 weeks of age (*p < 0.05; *** p < 0.0001; difference from rAAV1.miC and saline treated B05 animals). FIGURE 5 sqPCR, qRT-PCR, and NMR analyses of cerebellar extracts. (A) Semi-quantitative expression of miS1 from whole cerebellar extracts. (B) qRT-PCR for human ATXN1 mRNA levels from whole cerebellar extracts (N ≥ 3; ** p < 0.01; *** p < 0.0001; differences from saline injected B05 mice). (C) qRT-PCR for mouse Pcp2 mRNA levels from whole cerebellar extracts (N=3-4; *p < 0.05; ** denotes p < 0.01; ***p < 0.0001; differences from wildtype mice). (D) qRT-PCR for mouse Grm1 mRNA levels from whole cerebellar extracts (N=3-4; *p < 0.05; **p < 0.01; differences from wildtype mice). (E) Ratio of NAA/Inositol levels from whole cerebellar extracts (***p < 0.0001; differences from wildtype mice). FIGURE 6 Cerebellar pathology in mice treated after disease onset. (A) Molecular layer widths of lobule IV/V and VI from sagittal cerebellar sections 0.5 mm from midline (N ≥ 3; ***p < 0.0001 differences from wildtype). (B) Molecular layer widths layers of lobules VIII and IX from sagittal cerebellar sections 0.5 mm from midline (N ≥ 3; **p < 0.01; ***p < 0.0001; differences from wildtype). (C) Representative photomicrographs of sagittal cerebellar sections immunostained for human ataxin-1. Scale Bar = 100 μm. (D) Representative photomicrographs of sagittal DCN immunostained for Gfap. Scale Bar = 100 μm. (E) Representative photomicrographs of sagittal cerebellar cortex immunostained for Iba1. Scale Bar = 100 μm. (F) Representative photomicrographs of sagittal cerebellar DCN immune stained for Iba1. Scale Bar = 100 μm. TABLE 1 Treatment Groups for Preventative Study Genotype Injectate Dose (vg) B05 rAAV1.miS1 8×107 B05 rAAV1.miS1 8×108 B05 rAAV1.miS1 8×109 B05 rAAV1.miS1 8×1010 B05 rAAV1.miC 8×108 B05 Saline Wildtype TABLE 2 Treatment Groups for Reversal Study Genotype Injectate Dose (total vg) B05 rAAV1.miS1 8×108 B05 rAAV1.miS1 2.6×109 B05 rAAV1.miS1 8×109 B05 rAAV1.miS1 2.6×1010 B05 rAAV1.miS1 8×1010 B05 rAAV1.miC 8×108 B05 rAAV1.miC 8×109 B05 Saline Wildtype Author Contributions Study concept and design: M.S.K., A.M.M., R.C., P.G.A., B.L.D.; data acquisition and analysis: M.S.K. R.C., P.G.A., B.L.D.; drafting the manuscript and figures: M.S.K., A.M.M., R.C., P.G.A., B.L.D. Potential Conflict of Interest B.L.D. is a founder of Spark, Inc, a gene therapy company, that has licensed the technology described in this study. B.L.D. is also on the SAB of Intellia Therapeutics and Serepta Therapeutics. 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LICENSE: This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. 8302946 4093 Hepatology Hepatology Hepatology (Baltimore, Md.) 0270-9139 1527-3350 27629435 5115965 10.1002/hep.28817 NIHMS817614 Article CFTR controls biliary epithelial inflammation and permeability by regulating Src tyrosine kinase activity Fiorotto Romina 14 Villani Ambra 1 Kourtidis Antonis 2 Scirpo Roberto 1 Amenduni Mariangela 1 Geibel Peter J. 3 Cadamuro Massimilano 45 Spirli Carlo 14 Anastasiadis Panos Z. 2 Strazzabosco Mario 145 1 Section of Digestive Diseases, Liver Center, Yale University, New Haven, Connecticut, USA 2 Department of Cancer Biology, Mayo Clinic Comprehensive Cancer Center, Jacksonville, Florida, USA 3 Department of Surgery, Yale University, New Haven, Connecticut, USA 4 International Center for Digestive Health, University of Milan-Bicocca, Milan Italy 5 Section of Digestive Diseases, Department of Medicine and Surgery, University of Milan-Bicocca, Milan, Italy Address correspondence to: Mario Strazzabosco, Section of Digestive Diseases, Liver Center, Yale University School of Medicine, Cedar Street 333, New Haven, CT 06511, USA. Phone: 203-737-1451; Fax: 203-785-7273; mario.strazzabosco@yale.edu. 21 9 2016 27 10 2016 12 2016 01 12 2017 64 6 21182134 This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. In the liver, CFTR regulates bile secretion and other functions at the apical membrane of biliary epithelial cells (i.e cholangiocytes). CF-related liver disease (CFLD) is a major cause of death in patients with CF. CFTR dysfunction affects innate immune pathways, generating a para-inflammatory status in the liver, and other epithelia. This study investigates the mechanisms linking CFTR to TLR4 activity. We found that CFTR is associated in a multi-protein complex at the apical membrane of normal mouse cholangiocytes, with proteins that negatively control Src activity. In CFTR-defective cholangiocytes, Src tyrosine kinase self-activates and phosphorylates TLR4, resulting in activation of NF-κB, and increased pro-inflammatory cytokines production in response to endotoxins. This Src/NF-κB-dependent inflammatory process attracts inflammatory cells, but also generates changes in the apical junctional complex and loss of epithelial barrier function. Inhibition of Src decreased the inflammatory response of CF-cholangiocytes to LPS, rescued the junctional defect in-vitro and significantly attenuated endotoxin-induced biliary damage and inflammation in vivo (Cftr-KO mice). Conclusion Our findings reveal a novel function of CFTR as regulator of TLR4 responses and cell polarity in biliary epithelial cells. This mechanism is pathogenetic, as shown by the protective effects of Src inhibition in vivo and maybe a novel therapeutic target in CFLD and other inflammatory cholangiopathies. Cystic Fibrosis TLR4 cytokines cytoskeleton cell polarity Cystic Fibrosis (CF) is a disease of secretory epithelia leading to chronic damage and insufficiency of several organs, including pancreas, lung and liver. CF is caused by mutations in the gene encoding for the cystic fibrosis transmembrane conductance regulator (CFTR), a cAMP-regulated epithelial chloride channel expressed at the apical membrane of most secretory epithelia (1, 2). More than twenty years after its discovery, the understanding of CFTR function(s) is still incomplete. In addition of functioning as a channel, CFTR may also act as a “hub” protein that forms macromolecular complexes with several other proteins at the apical membrane, mostly through PDZ binding motifs (3). Through these interactions, CFTR may be involved in key cellular functions such as regulation of ATP release, membrane protein and vesicle trafficking and inflammation (4, 5). This multi-functional role of CFTR reflects the variety of manifestations associated with its defective function, and the diversity of the pathogenetic mechanisms involved in the target organs of CF, such as lung, pancreas, liver and intestine. Several defective inflammatory responses and altered innate immune pathways have been linked to CFTR deficiency in different organs affected by CF(6-8). In the liver, CFTR is specifically expressed at the apical membrane of the epithelial cells lining the biliary epithelium (cholangiocytes) where it regulates chloride and bicarbonate secretion in response to cAMP/PKA stimulation (9). Defective CFTR function causes impaired biliary secretion of chloride and bicarbonate, and ductal cholestasis (10). A percentage of patients with Cystic Fibrosis develop liver disease (CFLD). CFLD is a chronic inflammatory cholangiopathy that can evolve into sclerosing cholangitis and focal biliary cirrhosis, and is the third leading cause of death in CF (11, 12). Severe CFLD affects only a minority of CF patients, suggesting that ductal cholestasis may be a predisposing factor to liver disease, which progresses only in the presence of a second insult (13, 14). We have previously shown that the CFTR-defective biliary epithelium, when exposed to gut-derived bacterial endotoxins, produces high levels of cytokines/chemokines and attracts inflammatory cells (i.e macrophages and neutrophils) leading to peribiliary inflammation. In CF biliary epithelial cells TLR4/NF-κB-dependent innate immune response to endotoxins is upregulated (14). In CFTR-defective cells, we have also found an increased activity of non-receptor tyrosine kinases belonging to the Src family (SFKs) (14). Src kinases are involved in a variety of signaling pathways including the regulation of inflammatory responses and phosphorylation of the cytoplasmic domain of TLRs (i.e TLR 2, 3, 4 and 5), which is involved in the activation of the downstream signaling cascade (15-17). Members of the SFK family share a common and well-conserved regulatory mechanism. Src is able to self-activate, unless it is negatively regulated by phosphorylation mediated by the C-terminal Src kinase (Csk), a cytosolic protein that anchors to the membrane through the adaptor Cbp (Csk Binding Protein) (18, 19). Cbp is anchored to the cytoskeleton by the PDZ domains of EBP50 (Ezrin-radix-moesin binding protein 50) (20, 21). EBP50 is an adapter protein localized at the apical region of epithelial cells. EBP50 also binds CFTR favoring its association into macromolecular signaling complexes at the plasma membrane (22-24). In this study, we address the hypothesis that CFTR regulates TLR4-dependent inflammatory responses in the biliary epithelium by modulating Src activity. Expression of CFTR at the apical membrane facilitates the assembly of a protein complex able to maintain the kinase inactive. In the absence of CFTR this complex does not assemble, resulting in self-activation of Src and subsequent increase in TLR4 phosphorylation and NF-κB–dependent cytokine production, in response to endotoxins. We also documented that epithelial cell-cell junctions and monolayer barrier function are impaired in CFTR-defective cells as a secondary effect of the NF-κB-dependent inflammatory process. The protective effects of SFKs inhibition in vitro and in vivo demonstrate the pathogenetic relevance of this mechanism and suggest that targeting SFK activity or NF-κB is a potential therapeutic target for CF-liver disease and possibly other cholangiopathies. MATERIALS AND METHODS Reagents and additional methods are detailed in the supplemental materials and methods. Animals and Experimental Protocol All procedures involving animals in this study were performed according to protocols approved by the Yale University Institutional Animal Care and Use Committee. Congenic B6.129P2-Cftrtm1Unc mice, which possess the S489X mutation that blocks transcription of CFTR (25) and ΔF508-CFTR (B6-129-Cftrtm1Kth) (26) mice with targeted mutation corresponding to the ΔF508 mutation in human, were used for in vivo experiments and/or for the isolation of primary cholangiocytes cell lines. Animals were bred in our facility or provided by the CF Core Center Animal Core (Case Western Reserve University, Cleveland, OH) and were maintained as previously described (14, 27, 28). Cftr-KO mice and WT littermates were exposed to DSS (14) alone or in combination with the tyrosine kinase inhibitor PP2 (1mg/Kg body weight/day) by i.p. At the end of the treatment mice were sacrificed and liver tissue was harvested formalin-fixed and paraffin-embedded for histochemical analysis. Cell culture Mouse cholangiocytes were isolated from WT, DeltaF508 and Cftr-KO mice as described (27). After the first passage cells were plated into 25-cm2 tissue culture flasks coated with rat-tail collagen as previously described (14, 27). Before selected experiments cells were cultured in transwell inserts with a 0.4 μm pore semipermeable membrane (Becton, Dickinson, and Co, Franklin Lakes, NJ); in this condition, cells grow as a polarized monolayer that can be accessed from both the apical and basolateral domain distinctly. Establishment of a confluent monolayer was routinely checked, measuring transepithelial resistance and membrane potential difference (Millicell ERS System; Millipore, Billerica, MA). One week after confluence, transepithelial resistance was >1000 Ω·cm2 and cells were ready for analysis. Determination of cytokine secretion Polarized WT and Cftr-KO cholangiocytes were untreated or treated with PP2 (10 μM), LPS (100 ng/ml) or their combination for 12 h. At the end of the treatment, apical and basolateral media were collected and processed for cytokines/chemokines quantification analysis by using the Milliplex Mouse Cytokines/Chemokines Kit EMD Millipore (Billerica,MA) coupled with BioPlex Luminex platform (Bio-Rad Laboratories, Inc, Hercules, CA) following the manufacturer’s instructions. Data were normalized for the cell protein content as previously described (14). Co-immunoprecipitation Polarized WT and Cftr-KO cholangiocytes were lysated in ODG buffer (50 mM Tris-HCl, pH 7.4, 1 mM EDTA, 2% Octyl-D-glucoside, 5mM βmercaptoethanol, 0.25 M NaCl, 1mM Na3VO4, 20 mM NaF, 5% glycerol, 100μl Triton X-100). To immuno-precipitate Csk or Cbp, 3 mg of proteins were incubated with the proper primary antibody for 1 h at 4°C under rotation (see supplemental table 1). Samples were then incubated with 30 μl of Protein A/G PLUS-Agarose for 3 h at 4°C under rotation. After several washing, the beads were resuspended in 50 μl of 4x NuPAGE Lithium Dodecyl Sulphate (LDS) sample buffer. Western blot with antibodies against CFTR, CSK, Cbp or EBP50 was performed on the immune-precipitated lysates (see supplementary table 1). Immunofluorescence and confocal microscopy Polarized WT and Cftr-KO cholangiocytes were processed for immunofluorescence staining. Briefly, cells were fixed with either a) 100% methanol and washed with PBS; b) or 3.7% PFA, washed using PBS/10mM glycine, and permeabilized with PBS/0.2%TritonX-100. Unspecific binding sites were blocked with Normal Horse Serum (1:20) or with 3% non-fat milk for 45 minutes at RT. Cells were incubated overnight at 4°C with specific primary antibody in blocking buffer (supplementary table 1) and for 1 hour at RT with the proper secondary antibody (conjugated with Alexa Fluor 488, 555, 594 or 647 in PBS/BSA/Gly). Cells were then mounted using a Vectashield Kit (Vector Laboratories, Inc, Burlingame, CA) with 4’,6-diamidino-2-phenylindole (DAPI). Confocal analysis was performed using a Zeiss LSM 710 Duo confocal microscope or a Zeiss LSM 510 Meta with x63, 1.4 NA objective. Serial optical sections (0.5 μm thick) were collected for 3D analysis. Proximity ligation assay (PLA) PLA experiments were done using Duolink In Situ reagents (Olink Bioscience). WT and CFTR-KO cholangiocytes seeded on collagen I coated coverslips were fixed with 3.7% PFA, washed using PBS/10mM glycine, and permeabilized with PBS/TritonX-100 0.2%. Cells were incubated with blocking solution (Olink Bioscience) for 30 minutes and then with one (negative control) or two primary antibodies for 1h at RT. Coverslips were then incubated with secondary antibodies linked to PLA oligonucleotide probes PLUS and MINUS (Olink Bioscience) for 1 h at 37 °C. The samples were then incubated with the ligation ligase solution for 30 min at 37 °C to hybridize oligonucleotides tagged on probes. The coverslips were then incubated with the amplification polymerase solution for 100 min at 37 °C to amplify hybridized oligonucleotides and fluorescently label (Alexa-Fluor 488) the amplification products. Cells were then stained with rhodamine conjugate phalloidin for 20 minutes and coverslips were mounted on slides with Duolink In Situ Mounting Medium with DAPI. Imaging was done using a Zeiss LSM 710 Duo confocal microscope. Immunohistochemistry Paraffin-embedded 4 μm liver slides were processed and stained with the cholagiocyte-specific marker K19 to visualize the ductular reaction, with the leukocyte specific marker CD45 and the macrophage marker F4/80 to analyze the inflammatory cell infiltrate. Quantification of the K19, CD45 and F4/80 positive areas by morphometric analysis was performed as described (14). Epithelial permeability assay Epithelial permeability was assessed in polarized monolayers of WT and Cftr-KO cholangiocytes by measuring transepithelial flux of 10-kilodalton FITC-labelled dextrans as previously described (29). Briefly, epithelial monolayers were equilibrated with PBS at 37°C, then the fluorescent marker (400 μl diluted in PBS at a concentration of 200 mg/mL) was added to the apical chamber. Samples were removed at 1-hour intervals for 4 hours. The volume removed (100 μl) was replaced with 37°C PBS. In experiments with SFK or NF-κB inhibitors, PP2 (0.1, 1 or 10 μM) or Bay 11- 7082 (5 μM) were added to the apical chamber for the last 2 hours and epithelial permeability was compared at the end of the 4 hours time point. At the end of the treatment proteins were extracted for Western Blot processing. After sampling, fluorescence intensity (excitation, 485nm; emission, 530nm) was measured on a fluorescent plate reader Sinergy2 (Biotek Instruments, Winooski, VT). Tracer concentrations were determined by linear regression using dilutions of FITC-dextran in PBS. Measurement of trans-epithelial resistance (TER) WT and Cftr-KO cholangiocytes were seeded in transwell inserts with a 0.4 μm pore semipermeable membrane (Becton, Dickinson, and Co, Franklin Lakes, NJ). After four days in culture TER was measured daily for 9 days using a Millicell ERS System (Millipore, Billerica, MA). TER was calculated as ohms/cm2 multiplying it by the surface area of the monolayer (0.33 cm2). Statistics Results are shown as mean ± SD. Statistical comparisons were made using one-way analysis of variance or the Wilcoxon–Mann–Whitney 2-sample rank sum test, where appropriate, using Prism GraphPad. P values less than .05 were considered significant. RESULTS Src activity and TLR4 phosphorylation are increased in CFTR-KO and DeltaF508 mutated cholangiocytes Cholangiocytes isolated from CFTR-null mice (CFTR-KO; Cftrtm1Unc) have higher Src activity and TLR4 phosphorylation at tyrosine 674 (see figure 1A), as previously reported by our group (14). CFLD occurs in patients with severe CFTR mutations (class I-III), ΔF508 being the most frequent (about 80% of CF patients) (30). To understand if Src signaling is enhanced also in the most common mutation, we isolated cholangiocytes from DeltaF508;Cftrtm1Kth mice (corresponding to the ΔF508 mutation in humans) (26) and tested Src activity, measuring the phosphorylation at the tyrosine 419 of the catalytic domain and TLR4 phosphorylation at the tyrosine 674. As shown in figure 1A, similarly to Cftr-KO cholangiocytes, DeltaF508 cells have significant increased Src tyrosine kinase activity (pY419) and increased TLR4 phosphorylation compared to WT cholangiocytes. Increased Src activation in Cftr-KO cholangiocytes is caused by lack of CFTR expression at the membrane To investigate if the increased Src kinase activity depends on the defective CFTR channel function, we treated WT cells for 1h, 6hrs and 24hrs with a specific CFTR blocker (CFTR inh-172, 10 μM), known to alter the channel gating function (31). Abolishment of cAMP-mediated chloride efflux (32) confirmed the effective inhibition of CFTR activity in WT cholangiocytes treated with CFTR inh-172 (Supplementary figure 2). As shown in figure 1B, both basal levels of Src and TLR4 phosphorylation were unaffected, suggesting that the localization of CFTR at the membrane, rather than its channel function is important for the regulation of Src activity. Thus, we hypothesized that the membrane expression of CFTR might be necessary for the assembly and stabilization of a protein complex able to regulate Src. As discussed in the introduction, Csk and Cbp could interact with CFTR through the PDZ domains of the scaffold protein EBP50, to maintain Src in an inactive state. To demonstrate the interaction of the endogenous proteins CFTR-EBP50-Cbp-Csk in a complex, we used three different approaches. Co-immunoprecipitation experiments showed that in WT cholangiocytes, Csk co-immunoprecipitates with Cbp and CFTR, and Cbp co-immunoprecipitates with EBP50 (figure 1C). Interestingly, although by Western blot the expression level of EBP50, Csk and Cbp was comparable in WT and CF cells (figure 1D), we found no co-immunoprecipitation between Cbp, Csk and EBP50 in CFTR-defective cells. By confocal microscopy, we visualized the apical distribution of CFTR, EBP50, Cbp and Csk and their interactions in the polarized monolayer. As shown in panel 2A, in WT cells expressing CFTR, EBP50 staining is restricted to the apical membrane and co-localizes with CFTR, Cbp and Csk at the apical membrane (figure 2B). Csk also appears to be localized in close proximity to TLR4 at the apical membrane (figure 2C). On the contrary, in CFTR-defective cells, EBP50 staining is diffuse and mislocalized in the cytosol (figure 2A). Furthermore, co-localization of Cbp and Csk at the apical membrane is lost (figure 2B). TLR4 on the other hand, appears to be normally expressed at the apical membrane also in Cftr-KO cells (figure 2C), suggesting that the different susceptibility of CF cells to LPS does not depend on an altered membrane distribution of the TLR4 receptor. Using an in-situ proximity ligation assay, based on the formation of fluorescent spots when two proteins of interest are located within a distance of 40nm, we confirmed that EBP50 and Cbp strictly interact in normal cholangiocytes, whereas no signal was detected in Cftr-KO cells (Figure 2D). For negative control, detection was performed in WT and Cftr-KO cells when one of the two antibodies was omitted. Altogether, these results indicate that in WT cells, CFTR physically interacts with Cbp and Csk through EBP50, and that this interaction is missing in CF cells. In CF cells, the negative regulation of Src is lost and the kinase is free to self-activate and to phosphorylate TLR4, increasing its responsiveness to TLR4 agonists. Inhibition of Src activity decreases LPS-induced activation of NF-κB and cytokine secretion in CF cholangiocytes To study if inhibition of Src kinase decreases the response of the CF biliary epithelium to endotoxins, polarized WT and Cftr-KO cholangiocytes were exposed to LPS (100 ng/ml) for 6 hours in the presence or absence of the SFK family inhibitor PP2 (10 μM) (14). PP2 treatment did not alter the PKA signaling as shown by secretin receptor gene expression analysis and intracellular cAMP production (supplementary figure 3). NF-κB activation was assessed by Western blot for the p65 subunit of NF-κB in nuclear fractions and by measuring the levels of phospho-IkBα. As shown in figure 3A, in Cftr-KO cholangiocytes, as compared to WT cells, NF-κB activation was significantly increased, both in basal conditions and after LPS stimulation. In CF cells not exposed to LPS, treatment with PP2 restored NF-κB to levels similar to WT cells. When cells were treated with LPS in the presence of PP2, NF-κB activation was significantly inhibited. Moreover, the levels of phospho-IkBα were decreased after treatment with PP2 correlating with the decreased p65 nuclear expression (supplementary figure 4). A similar experimental approach was used to study the effects of Src inhibition on the secretion of NF-κB-dependent cytokines previously shown to be increased in CF-cholangiocytes (i.e. G-CSF, CXCL1, LIX and CXCL2)(14, 33). The concentration of cytokines was quantified in the apical and basolateral media by Luminex assay in CF-cholangiocytes exposed to LPS and compared with CF-cholangiocytes exposed to LPS and PP2 (10μM). As shown in figure 3B, LPS-stimulated secretion of G-CSF, CXCL1, LIX and CXCL2 was significantly increased in Cftr-KO cholangiocytes as compared to WT. However, secretion of these inflammatory mediators was significantly decreased by treatment with PP2, consistent with the hypothesis that Src controls TLR4/NF-κB response to LPS in CFTR-defective cells. The distribution of apical junction proteins and actin cytoskeleton is altered in Cftr-KO cholangiocytes. While performing the in-situ proximity assay, we noticed significant changes in the actin cytoskeleton in CFTR-defective cholangiocytes that lead us to investigate it further. Phalloidin staining revealed stark differences in the structure of the actin cytoskeleton in CFTR-defective cells both in not polarized (see figure 2D) and polarized culture conditions (figure 4). As shown in figure 4, while cadherin-catenin complexes accumulated normally at areas of cell-cell contact in WT cells, their association with circumferential actin fibers was largely abolished in cells lacking CFTR. Apical actin filaments were still present, but unlike WT cells where the subcortical actin ring co-localized closely with cell-cell junctions, in Cftr-KO cells the actin appeared split in multiple fibers and failed to co-localize with E-cadherin at the adherens junctions. Interestingly, we observed increased actin accumulation at the tricellular junctions (structures where three cells meet). Since actin filaments are directly connected with cell junction structures (34, 35), we investigated if the defective organization of actin filaments reflected a loss of tight junctions (TJs) and adherens junctions (AJs) integrity. Using confocal microscopy, we analyzed the distribution of proteins of the apical junction complex formed by TJs (i.e ZO-1, zona occludens-1) and AJs (i.e afadin). As shown in figure 5A,B while in WT cells ZO-1 and afadin staining are strictly localized at the cellular junctions, in CF cells both proteins appear diffusely distributed in the cytoplasm. The analysis of the fluorescence intensity confirmed a significant increase of the cytoplasmic/junctional ratio in CF as compared to WT cells suggesting a destabilization of the cellular junctions (figure 5C). Barrier function is impaired in Cftr-KO cell monolayer. The apical junction complex is a functional unit formed by tight junctions (TJs), adherens junctions (AJs) and the perijunctional F-actin cytoskeleton that functionally interact to preserve the barrier function of the epithelium. To determine whether the junctional defect affected the barrier function of Cftr-KO cholangiocyte monolayers, we measured the trans-epithelial movement of FITC-labeled dextrans (10 KDa) across the epithelial monolayer over time (29) and the trans-epithelial resistance (TER) in polarized WT and CFTR-defective cholangiocytes. As shown in figure 6A, the passage of FITC-dextrans across the paracellular compartment was significantly increased in Cftr-KO compared to WT monolayers, whereas TER measurements were significantly decreased in Cftr-KO monolayers (figure 6B), indicating that paracellular permeability and barrier function is altered in Cftr-KO cells. Cytoskeletal and paracellular changes are due to Src- and NF-κB-dependent inflammatory responses To test the effects of Src inhibition on the cytoskeletal and paracellular changes, we treated CF cholangiocytes with the Src inhibitor PP2 (0.1,1 and 10μM, not shown). As shown in figure 7A, treatment with PP2 significantly decreased the junctional defect (i.e afadin and ZO-1 cytoplasmic mislocalization) and rescued the single fiber organization of actin. Consistent with the rescue of cell junction defects by Src inhibition, treatment with PP2 significantly influenced the paracellular permeability of Cftr-KO cells with a dose-dependent effect. As shown in figure 7, as PP2 progressively inhibited Src (Y416) phosphorylation (figure 7C), paracellular permeability of Cftr-KO cells decreased (figure 7D). Inhibition of NF-κB using Bay 11-7082 had a similar rescue effect on the actin distribution and the paracellular permeability (supplementary figure 1A,B), suggesting that the apical junction changes are mediated by the increased Src-dependent NF-κB activation in CF cells. Furthermore, to exclude a potential effect of NF-κB on Src activation in Cftr-KO cholangiocytes, we measure Src phosphorylation at the tyrosine 419 of the catalytic domain by western blot in CF cells treated with the NF-κB inhibitor Bay 11-7082 (5 μM). As shown in supplementary figure 1C, phosphorylation level of Src was unchanged by Bay 11-7082 treatment, suggesting that Src activation is upstream of NF-κB. In vivo inhibition of SFK activity reduces biliary damage and inflammation in Cftr-KO mice treated with DSS To validate in vivo the role of Src inhibition and its possible use as a therapeutic target in CFLD, we treated Cftr-KO mice with DSS, in the presence or the absence of the specific SFK inhibitor PP2. It has been previously established (13, 14) that the increased intestinal permeability caused by DSS induced colitis favors the translocation of gut-derived endotoxins to the liver, causing damage and inflammation in the liver of Cftr-KO mice. At the end of the treatment, liver tissues were harvested and stained with K19, to quantify the biliary and progenitor cell compartment expansion as a marker of biliary damage and with CD45, to quantify the amount of infiltrating leukocytes in the portal space as a marker of inflammation. DSS-treated Cftr-KO mice developed the expected biliary damage with expansion of a small cholangiocyte ductular reactive component (36) and portal inflammatory reaction and extensive infiltration of mononuclear cells whereas no toxicity was shown in the group treated with PP2 alone. As shown in figure 8, in Cftr-KO mice treated with DSS in combination with PP2 (1 mg/Kg by i.p. daily), bile duct proliferation (A) and inflammatory cell infiltration (B) were significantly reduced as determined by computer-assisted morphometric analysis of K19 and CD45 positive areas respectively, suggesting a protective effect of Src inhibition. In addition, treatment with PP2 significantly reduced the amount of macrophages in DSS-treated Cftr-KO mice as shown by staining for macrophage marker F4/80 (supplementary figure 5). DISCUSSION Epithelial cells represent the first line of defense against external pathogens thanks to the innate immune system and the presence of a number of pattern recognition receptors (such as Toll-like receptors). This system must be tightly controlled to avoid excessive inflammation and damage that may occur even in the presence of physiological amounts of bacterial components (37, 38). In this study, we demonstrate a novel mechanism by which the protein CFTR controls TLR4 activation and inflammation in secretory epithelia. Our findings provide a mechanistic explanation to the observation that CFTR dysfunction affects innate immune pathways, in the liver, as well as in other epithelia in Cystic Fibrosis (39). We have recently shown that in CFTR-defective cholangiocytes, TLR4 phosphorylation at tyrosine 674 is increased as compared to normal cells (14) and that TLR4 signaling is up-regulated. Tyrosine phosphorylation of TLRs cytoplasmic domain takes part in the recruitment process of cytoplasmic adaptor proteins during activation of TLR4 downstream signaling (15). In immune cells (i.e. macrophages), members of the Src protein tyrosine kinase family (SFK) phosphorylate the TIR domain of TLR4 and increase the recruitment of downstream signal-competent adapter proteins (e.g MyD88) and kinases (e.g. IRAK-4 and IRAK-1). As a counter-regulatory mechanism, TLR4 tyrosine phosphorylation is reduced to avoid uncontrolled inflammation during continuous exposure to LPS (LPS tolerance)(15, 17). In this study we sought to understand whether activation of Src signaling plays a role in the pathologic inflammatory responses seen in CF cholangiocytes and to clarify the mechanism linking CFTR-deficiency to Src activation and cell dysfunction. Our findings indicate that CFTR associates in an apical membrane complex with proteins acting as constitutive negative regulators of Src (i.e Cbp and Csk). In CF, decreased CFTR protein at the membrane prevents the formation of this multiprotein complex, and consequently Src is able to self-activate and to phosphorylate TLR4, thereby sustaining an increased inflammatory response to LPS and other TLR agonists (Fiorotto/Strazzabosco, unpublished data). Interestingly, pharmacologic inhibition of Src in vitro reduces the LPS-induced NF-κB activation and cytokine secretion in CF biliary cells. CFTR is known to interact directly or indirectly with several proteins that regulate its channel activity (i.e AKAP, PKA), integrate signaling pathways (i.e adenosine 2b receptors, β2-adrenergic receptor) or coordinate other transport activities (i.e ENaC, ROMK) (3-5). Here we demonstrate that CFTR independently from its channel activity participates in the regulation of epithelial innate immunity by controlling the activity of Src. In fact, pharmacological inhibition of CFTR channel function in WT cells has no significant effects on Src activation and TLR4 phosphorylation. Conversely, chemical inhibition of Src significantly decreases the activation of NF-κB, downstream to TLR4 signaling and the dependent secretion of cytokines. The finding that inhibition of Src in vivo improves the inflammatory liver phenotype in Cftr-KO mice exposed to gut-derived endotoxins, provides a proof of concept that Src has a pathogenetic role in CF and is a possible target for treatment. In physiological conditions, Src activity is tightly regulated by Csk, (C-terminal Src kinase), a kinase that holds Src in an inactive conformation by phosphorylating its Y529 residue. To inactivate Src, Csk must translocate from the cytoplasm to the plasma membrane and be anchored in close proximity to the kinase, by the membrane adaptor Csk Binding Protein (Cbp)/PAG which resides in the lipid rafts and is anchored to the cytoskeleton through PDZ domains of ezrin-radix-moesin binding protein 50 (EBP50) (18, 19). EBP50 is an adapter protein localized at the apical region of epithelial cells (22, 23). EBP-50 acts as a scaffold protein that binds CFTR and cooperates in the formation of multiprotein complexes (40). Interestingly, CFTR and EBP50 are mislocalized in cholangiocytes of ezrin defective mice, which also present a cholestatic phenotype (41, 42). Co-immunoprecipitation, confocal microscopy and proximity ligation assay experiments show that in normal cholangiocytes, Cbp is physically linked to Csk and CFTR, and EBP50 to Csk and Cbp. These interactions are lost in Cftr-KO cholangiocytes, suggesting that CFTR insertion at the membrane regulates the assembly of a multi-protein complex that controls Src activation. Confocal microscopy experiments confirmed that EBP50 has a clear distribution on the apical membrane in the normal epithelium but is mislocalized and diffusely distributed in Cftr-KO cholangiocytes. This is consistent with the observation that in bile ducts of CF patients, EBP50 immunoreactivity is not localized at the apical membrane, but distributed throughout the cytoplasm (43). In addition to EBP50, also Cbp and Csk are mislocalized in CF cells suggesting a defect of the apical compartmentalization of these proteins. We also found evidence that lack of CFTR affects the apical junction complex of the biliary epithelium. In fact, the subcortical and peri-junctional F-actin cytoskeleton fails to form properly and ZO-1 and afadin, two key members of the tight and adherens junctions respectively, loose their junctional restriction and appear diffusely distributed in the cytoplasm of CFTR-defective cells. Consistent with the presence of junctional defects, epithelial permeability is significantly increased while transepithelial resistance is decreased in monolayers of Cftr-KO cells. In the biliary epithelium, the integrity of the barrier function is essential to prevent the back-diffusion of toxic bile acids that would cause peribiliary inflammation and fibrogenesis and aggravate the cholestasis. Noteworthy, barrier defects have been associated with several human inflammatory diseases, including cholestatic diseases (44, 45). Normal cell polarity requires epithelial barrier function and apical junctions integrity (34, 35). These structures are anchored into cytoskeletal components such as actin and myosin filaments (46). Several studies have shown that inflammation and production of inflammatory mediators affect the epithelial barrier function. Our group has previously shown that treatment with pro-inflammatory cytokines (i.e IL6, TNFα, IFNγ and IL1) increases the paracellular permeability in normal cholangiocytes (29). Here we show that treatment with Src or NF-kB inhibitors restores the F-actin distribution and normalizes trans-epithelial permeability in Cftr-KO cells, suggesting that these structural defects may be secondary to the increased NF-kB-dependent inflammatory response caused by Src activation. Our findings suggest that targeting tyrosine kinase activation and inflammation could be of potential therapeutic value in CF. In fact, administration of an Src inhibitor to our previously used model of CF cholangitis (Cftr-KO mice with DSS-induced colitis and portal endotoxemia (14)), significantly reduces biliary damage and inflammation, as compared to Cftr-KO mice treated only with DSS. In conclusion, this study provides strong evidence that CFTR regulates TLR-mediated responses in secretory epithelia, by controlling the activation of Src tyrosine-kinase. When CFTR is defective, the negative regulation of Src is lost and the tyrosine kinase is free to target TLR4/NFkB and increase its response to endotoxins. Moreover, aberrant TLR4 activation decreases the epithelial barrier function by destabilizing actin microfilaments and cell-junctional complexes (see cartoon in supplementary figure 6). In the biliary epithelium, decreased barrier function would increase the back-diffusion of toxic bile acids, resulting in further peribiliary inflammation and fibrogenesis. Given the effects of PP2 administration in vivo, and the availability of tyrosine kinase inhibitors already approved for use in several other human conditions (47), targeting SFK activity in the liver may prove to be a useful strategy for the treatment of CFLD. Supplementary Material Supp info Acknowledgements We thank Dr. Ruslan Medzithov, Yale School of Medicine, for helpful discussions, Dr. Nadia Ameen, Yale School of Medicine, for the CFTR antibody (AME4991) and Dr. John Riordan, University of North Carolina – Chapel Hill and Cystic Fibrosis Foundation Therapeutics, for the CFTR antibody (A596). Financial support Research reported in this publication was supported by the National Institute of Diabetes and Digestive and Kidney Diseases of the National Institutes of Health under Award Number RO1 DK096096 to MS, P30 DK034989-Silvio O. Conte Digestive Diseases Research Core Centers to MS and RF, R01 NS069753 to P.Z.A. and partially RO1DK101528 to C.S.; by Fondazione Fibrosi Cistica (Grant #18-2012) and by Telethon (Grant #GGP12133) to M.S. and partially supported by PSC Partners Seeking a Cure Foundation (to RF). A.K. is supported by the Jay and Deanie Stein CDA for Cancer Research, Mayo Clinic. List of abbreviations CFTR cystic fibrosis transmembrane conductance regulator CF cystic fibrosis TLR toll-like receptor NF-κB nuclear factor kappa-light-chain-enhancer of activated B cells Src Rous sarcoma oncogene cellular homolog LPS lipopolysaccharide cAMP Cyclic adenosine monophosphate ATP Adenosine triphosphate PKA Protein kinase A CFLD cystic fibrosis-associated liver disease SFK Src family kinases Csk Carboxy-terminal Src kinase Cbp Csk-binding protein/PAG PAG phosphoprotein associated with GEMs PDZ post synaptic density protein (PSD95) EBP50 ERM binding protein 50 G-CSF granulocyte colony-stimulating factor CXCL1 Chemokine (C-X-C motif) ligand 1 LIX LPS-induced CXC chemokine CXCL2 chemokine (C-X-C motif) ligand 2 ZO-1 zona occludens-1 protein AJ adherens junction TJ tight junction TER trans-epithelial resistance DSS dextran sodium sulfate K19 cytokeratin19 TIR toll-IL-1 receptor MyD88 Myeloid differentiation factor 88 IRAK Interleukin 1 receptor-associated kinase 1 AKAP A-kinase anchor protein ENaC epithelial sodium channel ROMK renal outer medullary potassium channel Figure 1 CFTR expression at the membrane is essential to modulate Src activity and TLR4 phosphorylation A) WT, DeltaF508 and Cftr-KO cholangiocytes were cultured in polarized conditions on transwell inserts. Src activity and TLR4 phosphorylation were determined by western blot using antibodies respectively against the active form of Src (pY418) or against the TLR4 tyrosine phosphorylation site (Y674). Bar graphs represent the optical density ratio of p-Src (pY418) vs total Src and p-TLR4 (pY674) vs total TLR4. A statistical significant increase in Src activity and TLR4 phosphorylation is shown in DeltaF508 and Cftr-KO cholangiocytes. Data represent mean ± SD of n=3 independent experiments (*p<0.05 vs WT). Representative western blot images were cropped from the same gel. B) Polarized WT cholangiocytes were treated with CFTR-inh172 for 1, 6 or 24 hours to inhibit the channel function activity. Src activity and TLR4 phosphorylation were determined by western blot. Bar graphs represent the optical density ratio of p-Src (pY418) vs total Src and p-TLR4 (pY674) vs total TLR4. No statistical differences were shown between the different treatments. Data represent mean ± SD of n=4 different experiments. C) Lysates from WT and Cftr-KO cells were immunoprecipitated with antibodies against Csk or Cbp and immunoblotted with specific antibodies against CFTR, Cbp and EBP50. The Western blot analysis shows that CFTR, Cbp, Csk and EBP50 are physically interacting in WT cells but not in Cftr-KO cells. Nuclear fraction lysates were used as negative controls. CFTR input is displayed from a shorter exposure of the same blot. D) Expression of CFTR, Cbp, Csk and EBP50 was evaluated by Western blot in total cell lysates from WT and Cftr-KO cholangiocytes. Figure 2 Proteins involved in Src regulation co-localize at the apical membrane of WT but not Cftr-KO cholangiocytes Confocal images of polarized WT and Cftr-KO cells single stained for EBP50 (A) or co-stained for CFTR-Cbp-Csk (B) or TLR4-Csk (C). A) EBP50 is localized on the apical membrane in WT cells while appears diffused and mislocalized in Cftr-KO cells. B) Z-stack sections show that CFTR, Cbp and Csk co-localize on the apical membrane in WT cells but not in CF cells. C) TLR4 shows the same distribution in WT and CF cells but does not co-localize with Csk in CF cells. D) Confocal imaging of in-situ proximity ligation assay, using EBP50 and Cbp antibodies, indicates interaction of the two proteins (green dots) in WT cells but not in CFTR-KO cells. Phalloidin staining (red) was used to show the localization of the interaction in proximity of F-actin fibers in x-z and y-z images. In the negative control the assay was performed using EBP50 antibody only. Figure 3 Treatment with the SFK inhibitor PP2 decreases LPS-induced NF-κB activation (A) and cytokine secretion (B) in Cftr-KO cholangiocytes Polarized cholangiocytes were treated with PP2 (10 μM), LPS (100 ng/ml) or their combination. A) NF-κB activity was assessed by western blot using an antibody against p65 in nuclear fractions. Histone-3 was used to normalize for the protein content. Bar graphs represent optical density quantification of n=4 experiments. B) Apical and basolateral media were analyzed by Luminex and data were normalized for the cell protein content. Treatment with PP2 significantly inhibited LPS-stimulated cytokine secretion in Cftr-KO cells. The plots represent the means of 5 independent experiments (*p<0.05; **p<0.01). Figure 4 F-actin cytoskeleton defect in Cftr-KO cells Confocal images of confluent monolayers of WT and Cftr-KO cholangiocytes were acquired with the same imaging setting. Distibution of phalloidin (F-actin) staining reveals a defect in the proper formation of the cortical actin ring with accumulation of F-actin at the tri-cellular junctions in Cftr-KO cells compared with WT cells. E-cadherin was used to define the junctional and lateral cell areas. Figure 5 Cell junction defect in Cftr-KO cells Confocal images of confluent monolayers of WT and Cftr-KO cholangiocytes were acquired with the same imaging setting. Staining for ZO-1 (B), a protein of tight-junctions and afadin (C), a protein of adherens junctions, shows that in Cftr-KO cells both proteins have lost their junctional restriction and appear diffusely distributed in the cytoplasm. Quantification of the fluorescence intensity revealed an increased cytoplasmic/junctional ratio in Cftr-KO cells of both proteins. Fluorescence intensity was measured in 10 cells per field and in 3 fields per sample (*p<0.05). P120 (B) and β-catenin (C) were used to define the entire lateral areas of cell-cell contact. Figure 6 Impaired epithelial barrier function in Cftr-KO monolayers A) Polarized monolayers of WT and Cftr-KO cholangiocytes were assayed for paracellular permeability to 10KDa FITC-dextrans. Concentration of dextrans diffused from the apical to the basolateral compartment was determined by linear regression (4-hour assay period) using known standard concentrations. Results represent the mean ± SD of 3 independent experiments in triplicate. B) WT and Cftr-KO cholangiocytes were seeded in transwell inserts. After reaching confluence TER was recorded daily for 9 days. Results represent the mean ± SD of 5 independent experiments. Figure 7 Cytoskeletal and paracellular defects are rescued by Src inhibition in Cftr-KO cholangiocytes A) Confluent monolayers of Cftr-KO cholangiocytes were treated with SFK inhibitor PP2 (0.1-1μM) for 2 hours and stained for ZO-1, afadin and phalloidin (F-actin) and analyzed at the confocal microscope. Images show the re-localization and restriction of ZO-1 and afadin to the junctions and the rescue of the normal subcortical distribution of F-actin after treatment with PP2. B) Quantification of the fluorescence intensity revealed a decreased cytoplasmic/junctional ratio in Cftr-KO cells, after PP2 treatment, of both proteins. Fluorescence intensity was measured in 10 cells per field and in 3 fields per sample (**p<0.01). C) Polarized monolayers of WT and Cftr-KO cholangiocytes were exposed to different concentrations of PP2 that significantly decreased Src activity in Cftr-KO cells as shown by the quantification of p-Src (pY418) vs total Src by Western Blot. D) Bar graph shows the quantification of FITC-dextrans paracellular permeability at the end of the treatment. Results represent the mean ± SD of 4 independent experiments in triplicate; (*p<0.05; **p<0.01). Figure 8 PP2 treatment reduces biliary damage and inflammation in Cftr-KO mice treated with DSS Cftr-KO mice were untreated (n=6) or either treated with DSS (n=5) or with DSS and PP2 (1 mg/Kg by i.p. daily)(n=5). At the end of the treatment, liver tissues were harvested and stained with the cholangiocyte-specific marker K19 (A) or the leukocyte specific marker CD45 (B). Computer-assisted morphometric analysis of K19 and CD45 positive areas shows that PP2 treatment significantly reduced the bile duct proliferation and inflammatory cell infiltration in Cftr-KO mice treated with DSS (*p<0.05 vs DSS only). Bar scale=50 um. Potential conflict of interests: Nothing to disclose Author names in bold designate shared co-first authorship. REFERENCES 1 Colombo C Battezzati PM Liver involvement in cystic fibrosis: primary organ damage or innocent bystander? 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PMC005xxxxxx/PMC5116009.txt
LICENSE: This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. 101170508 30450 J Thromb Haemost J. Thromb. Haemost. Journal of thrombosis and haemostasis : JTH 1538-7933 1538-7836 27546592 5116009 10.1111/jth.13477 NIHMS812350 Article Inorganic polyphosphate promotes cyclin D1 synthesis through activation of mTOR/Wnt/β-catenin signaling in endothelial cells Hassanian Seyed Mahdi 1 Ardeshirylajimi Abdolreza Dinarvand Peyman Rezaie Alireza R. Edward A. Doisy Department of Biochemistry and Molecular Biology, Saint Louis University School of Medicine, Saint Louis, MO Corresponding Author. Alireza R. Rezaie, Ph.D., Edward A. Doisy Department of Biochemistry and Molecular Biology, Saint Louis University School of Medicine, 1100 S. Grand Blvd., St. Louis, MO 63104, Tel: (314) 977-9240; Fax: (314) 977-9205; rezaiear@slu.edu 1 Current address: Department of Medical Biochemistry, School of Medicine, Mashhad University of Medical Sciences, Mashhad, Iran 11 10 2016 5 10 2016 11 2016 01 11 2017 14 11 22612273 This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. Summary Background Inorganic polyphosphate (polyP) elicits intracellular signaling responses in endothelial cells through activation of mTOR complexes 1 and 2. Glycogen synthase kinase 3 (GSK-3) is known to be a negative regulator of mTOR and Wnt/β-catenin signaling pathways. Objective The objective of this study was to investigate the effect of polyP on the expression, degradation and subcellular localization of the Wnt/β-catenin target gene, cyclin D1, in endothelial cells. Methods Regulation of cyclin D1 expression, phosphorylation and subcellular localization by polyP or platelet releasates was monitored in the absence and presence of pharmacological inhibitors and/or siRNA for specific molecules of the upstream mTOR/Wnt/β-catenin signaling network by established methods. Results Both purified polyP and boiled-platelet releasates induced the phosphorylation-dependent inactivation of GSK-3, thereby increasing the expression and nuclear localization, but inhibiting the degradation of cyclin D1. Inhibitors of mTORC1 (PI3K, AKT, PLC, PKC), rapamycin and siRNA for raptor (mTORC1-specific component) and β-catenin, all inhibited polyP-mediated regulation of cyclin D1 expression, phosphorylation and subcellular localization in endothelial cells. The signaling effect of polyP was effectively inhibited by the recombinant extracellular domain of the receptor for advanced glycation end products (RAGE) and/or by the RAGE siRNA. Specific pharmacological inhibitors and siRNA knockdown of ERK1/2 and NF-κB pathways indicated that polyP-mediated cyclin D1 expression and nuclear localization are IKKα- and ERK1/2-dependent, whereas its inhibitory effect on phosphorylation-dependent degradation of cyclin D1 is IKKβ-dependent. Conclusion We conclude that a RAGE-dependent polyP-mediated crosstalk between mTOR and GSK-3/Wnt/β-catenin signaling network can modulate important physiological processes in endothelial cells. Polyphosphate GSK-3 Wnt/β-catenin cyclin D1 mTOR endothelial cells Introduction Inorganic polyphosphates (polyP) are linear polymers of 3 to over 1,000 inorganic phosphate residues, linked together by high-energy phosphoanhydride bonds (1). High levels of medium size polyP polymers (~60–100 phosphate units) are stored in platelets which are known to be released to circulation upon their activation by thrombin or other physiological stimuli during activation of the blood coagulation cascade (2,3). Longer polyP polymers (>1000 phosphate units) may be synthesized by microorganisms under different environmental conditions (1,3). Recent results have established an important role for polyP in regulating numerous physiological processes including coagulation (3–5), tumor metastasis (6,7), proliferation (8), apoptosis (9,10) and inflammation (4,10–12). PolyP is known to activate mammalian target of rapamycin (mTOR) in breast cancer cells (13). We recently demonstrated polyP, upon interaction with the receptor for advanced glycation end products (RAGE) and P2Y1 purinergic receptor, mediates phosphorylation-dependent inactivation of the upstream regulatory tuberous sclerosis complex 1/2 (TSC1/2), thereby activating both mTOR complexes 1 (mTORC1) and 2 (mTORC2) in HUVECs (11,12). It has been established that the key negative regulator of Wnt/β-catenin signaling, glycogen synthase kinase 3β (GSK-3β), through activation of TSC1/2 can inactivate mTOR signaling, suggesting a crosstalk between the two signaling networks modulates metabolic and proliferative signaling responses in HUVECs (14,15). Upon expression and binding of Wnt proteins to the Frizzled family of receptors, GSK-3β is inactivated by phosphorylation, thus leading to activation of both mTOR and Wnt/β-catenin signaling pathways (15,16). GSK-3β is a kinase involved in degradation of β-catenin, thus as a consequence of GSK-3β inactivation, intact β-catenin can translocate into the nucleus, where it binds to specific transcription factors (i.e., T cell factor, TCF) to induce expression of Wnt/β-catenin target genes (16, 17). Cyclin D1 is a Wnt/β-catenin target gene, mainly involved in regulation of the G1 phase of the cell cycle (18). Cyclin D1 accumulates in the nuclei of cells during the G1 phase and exits into the cytoplasm during the S phase (19). It has been demonstrated that GSK-3β through phosphorylation of the nuclear cyclin D1 regulates cytoplasmic distribution and subsequent degradation of the cell cycle protein (20). In this study we investigated the role of polyP-70 in modulating Wnt/β-catenin signaling by analysis of polyP-mediated phosphorylation of GSK-3 and regulation of cyclin D1 synthesis in the absence and presence of siRNA for β-catenin and pharmacological inhibitors of specific signaling pathways. Results suggest that polyP-70, through phosphorylation-dependent inactivation of GSK-3, activates Wnt/β-catenin signaling, thereby regulating expression and subcellular localization of cyclin D1 in HUVECs. Possible physiological significance of these results was demonstrated by findings that platelet releasates exerted similar signaling effects in HUVECs by polyP-dependent mechanisms. Materials and Methods Reagents Wnt/β-catenin inhibitors, iCRT3 and PNU-74654, were from Santa Cruz Biotechnology (Santa Cruz, CA). MG-132, was obtained from Sigma-Aldrich Chemical Co., Inc. (St. Louis, MO). Vectashield mounting medium was from Vector Laboratories Inc. (Burlingame, CA). siRNA for β-catenin was from Dharmacon (Lafayette, CO). Rabbit antibodies to cyclin D1, GSK3α, GSK3β, phospho GSK3α, phospho GSK3β, phospho cyclin D1, eukaryotic initiation factor 4E (eIF4E) and Alexa-conjugated secondary antibodies were from Cell Signaling Technology Inc. (Beverly, MA). Anti-eIF4E (phospho S209) antibody was from Abcam Inc. (Cambridge, MA). Extracellular domain of receptor for advanced glycation end products (sRAGE) was prepared as described (11). All other reagents were provided as described (11,12). Scrambled siRNA was used as negative control for all siRNA experiments as described (11,12). PolyP-70 was a generous gift from Dr. James Morrissey (University of Illinois, Urbana). Platelets releasates were prepared by activation of human platelets with TRAP as described (21). Cell culture Primary human umbilical vein endothelial cells (HUVECs) and immortalized HUVECs (EA.hy926) were grown as described (11,12). Western-blot analysis Cells were treated with stimuli under different conditions (with or without transfection with siRNA and treatment with pharmacological inhibitors) and lysed with Pierce IP lysis buffer as described (12,22). Immunofluorescence staining To examine subcellular localization of cyclin D1, cells (2.5×105) were seeded on glass coverslips and fixed with 4% paraformaldehyde for 10min at room temperature. Next, cells were first incubated in blocking solution (2% BSA, 0.1% tritonX-100 in PBS) and then stained with either anti-cyclin D1 or phospho anti-cyclin D1 (Thr-286) monoclonal antibodies, followed by Alexa-conjugated secondary antibodies (Alexa Fluor 488 and 594 conjugates). Coverslips were mounted on glass slides with Vectashield mounting medium containing DAPI to counterstain cell nuclei. Coverslips were then sealed with a mixture of Vaseline and wax. Stained cells were visualized with a Nikon Optiphot-2 microscope fitted with appropriate fluorescence filters. Results PolyP-70 inactivates GSK-3 and promotes cyclin D1 expression PolyP-70 promoted GSK-3 phosphorylation in HUVECs by a time-dependent mechanism with optimal effect occurring after 15min of treatment (Fig. 1A). GSK-3 is encoded by two genes, GSK-3α and GSK-3β (23). GSK-3α and GSK3-β are inactivated by phosphorylation at Ser-21 and Ser-9, respectively, when Wnt proteins bind to Frizzled receptors to mediate activation of Wnt signaling (24,25). PolyP effectively phosphorylated both isoforms of GSK-3 (Fig. 1A). The Wnt signaling-dependent phosphorylation of GSK-3β inhibits its kinase activity, thereby preventing degradation of β-catenin by GSK-3β (15–17,23). The translocation of intact β-catenin to the nucleus, promotes transcription of Wnt/β-catenin target gene, cyclin D1 (18–20). In quiescent cells, in addition to degradation of β-catenin, GSK-3β is also involved in phosphorylation-dependent degradation of cyclin D1 (18). Results suggested that polyP-mediated inactivation of GSK-3β promotes overexpression of cyclin D1 protein (Fig. 1B), transcript (Fig. 1C) and its nuclear localization (Fig. 1D). PolyP-70 stimulated expression of cyclin D1 in both primary and transformed HUVECs. To provide further support for the hypothesis that polyP-70 activates Wnt/β-catenin signaling, expression of cyclin D1 in polyP-70-stimulated cells was studied with and without transfection of cells with β-catenin siRNA. Efficiency of siRNA knockdown of β-catenin is presented in Fig. 2A. siRNA for β-catenin effectively inhibited polyP-70-mediated up-regulation of cyclin D1 expression (Fig. 2B). Up-regulation of cyclin D1 in polyP-stimulated cells was also investigated in the presence of two different Wnt/β-catenin signaling inhibitors, iCRT3 and PNU-74654 which both bind β-catenin, disrupting the interaction of β-catenin with TCF transcription factor, thereby inhibiting expression of Wnt target genes (26). Consistent with β-catenin siRNA results, both inhibitors inhibited polyP-induced cyclin D1 expression (Fig. 2C,D). These results suggest polyP-70-induced cyclin D1 overexpression in is mediated through activation of Wnt/β-catenin signaling. PolyP-70 activates Wnt/β-catenin signaling by PI3K/AKT- and PLC/PKC/ERK-dependent mechanisms Next, we investigated the role of PI3K/AKT in polyP-mediated Wnt/β-catenin signaling by monitoring expression of cyclin D1 using pharmacological inhibitors of these signaling pathways. Pretreatment of cells with either wortmannin (PI3K inhibitor) or AKT VIII (AKT inhibitor) suppressed up-regulation of cyclin D1 in polyP-70-stimulated cells (Fig. 2E,F). PolyP mediates calcium release from intracellular stores through interaction with P2Y1 (11,12,27). It was found that calcium signaling is required for polyP-mediated Wnt/β-catenin signaling since the Ca2+ chelator, BAPTA-AM, inhibited the effect of polyP-70 on cyclin D1 overexpression (Fig. 2G). Inhibitors of PLC (U-73122) and PKC, bisindolylmaleimide I hydrochloride (BIS), also inhibited polyP-induced overexpression of cyclin D1 (Fig. 2H,I). These results suggest polyP-70 up-regulates cyclin D1 expression through activation of PI3K/AKT and PLC/PKC/Ca2+ signaling cascades. Next, polyP-70-mediated cyclin D1 overexpression was monitored in the absence and presence of siRNA for ERK1/2. Efficiency of gene knockdown was determined 48h post transfection (Fig. 2J). Results demonstrated ERK1/2 siRNA inhibits polyP-mediated up-regulation of cyclin D1 (Fig. 2K). Consistent with these results, pretreatment of cells with ERK1/2 inhibitor, PD-98059, also abrogated polyP-induced cyclin D1 expression (Fig. 2L). Our previous results indicated polyP exerts its modulatory effect through PI3K/AKT- and PLC/PKC/Ca2+-dependent activation of mTOR independent of ERK1/2 (12). Thus in contrast to mTOR activation, polyP-mediated up-regulation of Wnt/β-catenin signaling required ERK1/2 activation. We have demonstrated that none of the inhibitors used in this study has a toxic effect on EA.hy926 cells (12). PolyP-70 regulates phosphorylation and degradation of cyclin D1 GSK-3β phosphorylates cyclin D1 on Thr-286, thereby mediating its cytoplasmic degradation (20). Since polyP-70 inhibits GSK-3α/β, we investigated effect of polyP-70 on phosphorylation and degradation of cyclin D1 in the absence and presence of the proteasome inhibitor, MG-132. In the presence of MG-132, nuclear-localized phospho-cyclin D1 could be visualized by a specific anti-phospho-cyclin D1 antibody (Fig. 3A). However, co-treatment of cells with MG-132 and polyP-70 significantly decreased the phosphorylated form of cyclin D1 (Fig. 3A), suggesting polyP-70 inhibits phosphorylation-dependent degradation of cyclin D1. To further investigate this question, cells were treated with inhibitors of mTOR upstream signaling and phosphorylation of cyclin D1 was analyzed. Results suggest inhibition of PI3K/AKT and Ca2+-signaling abrogates the inhibitory effect of polyP-70 on cyclin D1 phosphorylation (Fig. 3B). In contrast to the suppressive effect of ERK1/2 inhibitor on cyclin D1, the inhibitory effect of polyP-70 on cyclin D1 phosphorylation was independent of ERK1/2 (Fig. 3B, bottom panel). In agreement with results obtained with the ERK1/2 inhibitor, siRNA for ERK1/2 had no effect on polyP-induced inhibition of cyclin D1 phosphorylation (Fig. 3C). Moreover, consistent with the inhibitory effect of PD-98059 (ERK1/2 inhibitor) on polyP-70-induced cyclin D1 overexpression, PD-98059 significantly suppressed nuclear localization of cyclin D1 in polyP-70-stimulated cells (Fig 3D). These results suggest that effects of polyP-70 on cyclin D1 expression and nuclear localization are both dependent on ERK1/2, whereas PolyP-mediated inhibition of cyclin D1 phosphorylation/degradation is independent of ERK1/2. PolyP-mediated cyclin D1 overexpression, localization and degradation are mTORC1- and NF-κB-dependent We recently demonstrated that polyP, through interaction with RAGE and P2Y1, activates both mTORC1 and mTORC2 in endothelial cells (12). GSK-3β through phosphorylation of β-catenin and TSC1/2 inhibits Wnt/β-catenin and mTOR signaling, respectively. Since polyP inactivated GSK-3β, we investigated the role of mTORC1 and mTORC2 in Wnt/βcatenin-dependent regulation of cyclin D1. Results indicated the mTORC1 inhibitor, rapamycin, abrogates polyP-induced up-regulation of cyclin D1 expression (Fig. 4A). Since rapamycin may also inhibit mTORC2 (28,29), this question was analyzed in cells transfected with siRNAs specific for components of either mTORC1 (raptor) or mTORC2 (rictor). Both raptor and rictor siRNAs effectively inhibited their expression (Fig. 4B), however, only siRNA for raptor, inhibited polyP-mediated overexpression of cyclin D1 (Fig. 4C), suggesting polyP-mediated Wnt/β-catenin and mTORC1 signaling are linked pathways. mTORC1 promotes protein synthesis through stimulation of phosphorylation of p70S6K and enhancing expression and phosphorylation-dependent release of eukaryotic initiation factor 4E (eIF-4E) from its inhibitory proteins (30). We previously demonstrated polyP effectively up-regulates phosphorylation of p70S6K through activation of mTORC1 in the absence of serum in endothelial cells (12). Analysis of polyP-70-mediated regulation of eIF-4E indicated polyP has no effect on expression of eIF-4E but promotes its phosphorylation (Fig. 4D). In light of findings that polyP activates NF-κB (10,11) and that there is interplay between mTORC1 and NF-κB pathways in polyP-stimulated cells (12), we investigated the role of NF-κB in Wnt/β-catenin-dependent regulation of cyclin D1 expression in polyP-70-stimulated cells. The IKKα-inhibitor, BAY11-7082, markedly decreased polyP-mediated cyclin D1 overexpression (Fig. 4E) whereas the IKKβ-inhibitor, BMS-345541, had no effect (Fig. 4F). In agreement with inhibitor results, while both IKKα and IKKβ siRNAs effectively inhibited their expression (Fig. 4G), only IKKα siRNA suppressed overexpression of cyclin D1 in the presence of polyP-70 (Fig. 4H). To determine whether polyP-70-mediated cyclin D1 nuclear localization and phosphorylation are NF-κB-dependent, cells were transfected with siRNAs for IKKα and IKKβ and localization and phosphorylation of cyclin D1 were analyzed. Results demonstrated that polyP-mediated nuclear localization of cyclin D1 is IKKα-dependent but the inhibitory effect of polyP on cyclin D1 phosphorylation is specifically dependent on IKKβ (Fig. 4 I,J). Next, involvements of RAGE and P2Y1 receptors in polyP-mediated cyclin D1 synthesis were investigated by both siRNA approaches and competitive binding studies using the extracellular domain of RAGE (sRAGE) (11). Results suggested while siRNA for either RAGE or P2Y1 significantly decreases the ability of polyP to induce cyclin D1, the combination of two siRNAs completely abrogates polyP-mediated cyclin D1 synthesis (Fig. 5A, lane 10), suggesting that similar to polyP-mediated mTOR activation, up-regulation of cyclin D1 synthesis is also mediated through polyP interacting with RAGE and P2Y1. Interestingly, RAGE siRNA by itself resulted in a dramatic decrease in cyclin D1 synthesis (Fig. 5A, lane 1) and in combination with P2Y1 siRNA, no cyclin D1 could be detected in transfected cells (Fig. 5A, lane 9), suggesting a key role for RAGE-signaling in cyclin D1 synthesis. In support of this hypothesis, sRAGE effectively inhibited cyclin D synthesis and polyP-70 did not up-regulate its expression in the presence of sRAGE (Fig. 5B), confirming siRNA results that RAGE is required for cell growth and that polyP induces cyclin D1 synthesis through stimulation of RAGE-signaling. Treatments of cells with polyP for up to 4h did not have any effect on the viability of endothelial cells as determined by the MTT assay as described (12) (Fig. 6A,B). Platelet releasates regulate GSK-3/Wnt/β-catenin signaling Activated platelets secrete polyP with polymer lengths of ~60–100 phosphate units (2,3). Expression, nuclear localization and phosphorylation of cyclin D1 by activated platelet- releasates were monitored employing the same assays described above. It was found that platelet releasates ratio of 0.04 to 0.1 (platelet releasates/total volume, estimated to be ~10 to 25µM, if the polyP concentration was expressed in terms of phosphate monomer) (12), phosphorylates GSK-3α/β by a dose-dependent manner (Fig. 7A). Since platelets were activated with TRAP, the possible stimulatory effect of a small amount of TRAP present in platelet releasates was analyzed. A TRAP concentration of 0.5µM, which exceeds the concentration of TRAP present in the highest platelet releasates ratio of 0.1 (~25µM) (12), did not have any effect on GSK-3 phosphorylation (Fig. 7A), excluding any contribution from trace amounts of TRAP present in platelet releasates. To establish the hypothesis that polyP derived from platelet releasates is responsible for GSK-3 phosphorylation, incubation of platelet releasates with specific polyP inhibitor EcPPXc (polyP-binding domain of Escherichia coli exopolyphosphatase) (31) or alkaline phosphatase (ALP) abrogated the signaling activity of both polyP-70 and platelet releasates (Fig. 7B). Furthermore, boiling platelet releasates for 30min prior to cell treatment did not impact the platelet releasates-mediated expression of cyclin D1, however, boiling releasates followed by treatment with either recombinant EcPPXc or ALP abrogated the signaling effect (Fig. 7B). It has been previously demonstrated that boiling platelet releasates for 30min denatures all proteins without negatively affecting the cofactor function of polyP (21). These results strongly suggest that platelet polyP is responsible for GSK-mediated cyclin D1 overexpression in endothelial cells. In agreement with results obtained with polyP-70, iCRT3, wortmannin, AKT VIII, U-73122, BIS, BAPTA-AM, PD-98059, BAY11-7082 (IKKα-inhibitor) and rapamycin all inhibited the platelet releasates-mediated cyclin D1 overexpression (Fig. 7C). As expected based on results presented above, BMS-345541 (IKKβ-inhibitor) had no inhibitory effect on the platelet releasates-mediated regulation of cyclin D1 expression (Fig. 7C). Similar to results obtained above with 25µM polyP-70, treatment of cells with a 0.1 ratio of boiled platelet releasates (~25µM) enhanced nuclear localization of cyclin D1 and that the effect was eliminated by PD-98059, rapamycin and BAY11-7082 but not by BMS-345541 (Fig. 7D,E). Moreover, consistent with the inhibitory effect of polyP-70 on cyclin D1 phosphorylation, incubation of cells with boiled platelet releasates (0.1 ratio) suppressed cyclin D1 phosphorylation in MG-132-treated cells by mTORC1- and IKKβ-dependent but ERK1/2- and IKKα-independent mechanisms. Taken together, these results suggest that both polyP-70 and platelet-derived polyP regulate GSK-3/Wnt/β-catenin signaling through the same mechanisms in endothelial cells. Discussion We have demonstrated here that polyP inhibits the kinase activity of GSK-3 by phosphorylation of both GSK-3α and GSK-3β isoforms in both primary and transformed HUVECs. The phosphorylation-dependent inhibition of GSK-3 by polyP results in stabilization of β-catenin and its subsequent translocation to the nucleus, thus inducing the expression of the β-catenin target gene, cyclin D1 (16–18). Consistent with this hypothesis, Wnt/β-catenin signaling inhibitors, iCRT3 and PNU-74654, both inhibited polyP-mediated up-regulation of cyclin D1 synthesis. Thus, polyP through inhibition of GSK-3 and stabilization of β-catenin/ cyclin D1 appears to play a key role in regulating metabolic and proliferative signaling responses in both primary and transformed HUVECs. The mechanism by which polyP modulates expression and subcellular localization of cyclin D1 is not known. Nevertheless, our recent results, showing that polyP is an effective stimulator of mTOR in endothelial cells (12), suggest that polyP, through activation of mTOR, may also modulate GSK/Wnt/β-catenin signaling. The polyP-induced mTOR signaling in endothelial cells has been found to be primarily mediated through polyP interacting with RAGE (11), a multi-ligand cell surface receptor involved in numerous pathophysiological processes including cell growth, proliferation, inflammation and cancer (32,33). We recently demonstrated that polyP can bind with high affinity to the RAGE ligands, HMGB1 and histones, and present the nuclear proteins to RAGE, thereby dramatically amplifying proinflammatory signaling responses (11). To determine whether polyP-mediated up-regulation of cyclin D1 expression is mediated through the same receptor signaling system, we used RAGE-specific siRNA to effectively down-regulate expression of RAGE in endothelial cells. Results suggested polyP induces cyclin D1 synthesis through the same mechanism since it was ineffective in up-regulating cyclin D1 expression in the presence of RAGE siRNA. In agreement with previous results that polyP interaction with P2Y1 further stimulates mTOR by inducing calcium signaling (11,12), the combination of RAGE and P2Y1 siRNAs completely inhibited cyclin D1 synthesis. Interestingly, RAGE siRNA by itself dramatically down-regulated cyclin D1 expression independent of polyP, suggesting RAGE signaling is required for cyclin D1 synthesis in endothelial cells during nutrient depletion. Stimulation of cells with polyP in the presence of RAGE siRNA did not produce a significant stimulatory effect on expression of cyclin D1. These results suggest that polyP through RAGE signaling regulates expression of cyclin D1. Further support for RAGE/mTOR-dependent regulation of cyclin D1 signaling was provided by the observation that pharmaceutical inhibitors of the upstream mTOR signaling network (PI3K/AKT and PLC/PKC/Ca2+) all abrogated regulatory effects of polyP on cyclin D1 expression, phosphorylation and subcellular localization. PolyP-mediated up-regulation of the cyclin D1 synthesis was mediated specifically through mTORC1 since siRNA for raptor but not rictor effectively inhibited this process. Results from several studies have indicated that RAGE siRNA arrests a number of human cancer cells in the G1 phase of the cell cycle, thereby inhibiting DNA synthesis, suggesting that RAGE signaling may be involved in promoting cancer growth and metastasis (34–37). Noting that tumor cells can secret significant amounts of HMGB1 and that HMGB1 promotes autophagy (37,38), it has been hypothesized that HMGB1-mediated autophagy through RAGE signaling plays an important role in allowing tumor cells to grow during nutrient depletion (38–41). In this context, we have shown that transformed HUVECs (EA.hy926 endothelial cells) secrete a significant amount of HMGB1 under serum-free growth conditions (42). Thus, it appears that these cells can acquire survival advantage during the serum free culture conditions through HMGB1/RAGE-mediated induction of autophagy, thereby up-regulating cyclin D1 synthesis. In support of this hypothesis, sRAGE, which binds with high affinity to HMGB1, effectively inhibited cyclin D1 synthesis in EA.hy926 cells. We have also demonstrated that polyP can bind to HMGB1 with high affinity and present the nuclear protein to the RAGE, thereby dramatically amplifying proinflammatory signaling responses (11). Several human tumor cell lines are known to synthesize and store a significant amount of polyP in their nuclei and other tissues (1,3,13,43,44). Results presented above raise the possibility that the tumor cell-derived polyP can make a positive contribution to the growth factor-independent proliferation and metastasis of cancer cells by a similar signaling mechanism. Thus, polyP establishes a crosstalk between RAGE, mTOR and Wnt/β-catenin signaling networks that can be critical for survival and regulation of key pathophysiological processes in vascular endothelial cells. The possible physiological significance of these results was demonstrated by findings that boiled human platelet releasates exert similar signaling effects in EA.hy926 endothelial cells by a polyP-dependent mechanism. It is worth noting that the aberrant regulation of both mTOR and Wnt/β-catenin signaling pathways are associated with a number of different tumor developments (16,30,45). A role for platelets in tumor metastasis has also been postulated (46). Thus, it is of interest to further investigate and to determine whether or not polyP, released by activated platelets, in addition to up-regulation of thrombin generation, coagulation and inflammation, can also participate in promoting tumor cell growth and metastasis under certain pathophysiological conditions. It should be emphasized that we monitored HMGB1 expression, RAGE signaling and platelet-releasates experiments only in transformed HUVECs, thus further studies will be required to validate these results in primary endothelial cells. We previously demonstrated that polyP through activation of mTOR also up-regulates the activation of NF-κB, suggesting that the two pathways are interlinked (12). It was interesting to note in the current study that a polyP-mediated crosstalk between NF-κB and Wnt/β-catenin signaling also modulated expression, phosphorylation and subcellular localization of cyclin D1. This is derived from observations that siRNAs for IKKα and IKKβ and their pharmacological inhibitors down-regulated polyP-mediated overexpression of cyclin D1 and/or abrogated the inhibitory effect of polyP on the phosphorylation-dependent degradation of the cell cycle protein. These two kinases appear to exert different modulatory effects on polyP-mediated up-regulation of cyclin D1. This is based on the observation that inhibition of IKKα, but not IKKβ, inhibited polyP-mediated overexpression and nuclear localization of cyclin D1. By contrast, inhibition of IKKβ, but not IKKα, abrogated inhibitory effect of polyP on the phosphorylation-dependent degradation of cyclin D1. These results provide some insight into the nature of an intricate and complex crosstalk between mTOR, GSK-3/Wnt/β-catenin and NF-κB and envision a key role for polyP in RAGE-dependent modulation of these signaling networks in endothelial cells. The mechanism through which polyP activates GSK-3/Wnt/β-catenin signaling is not known. It is however known that the pathway is activated when different Wnt ligands bind to Frizzled family of receptors, thereby inactivating GSK-3β by phosphorylation, thus leading to stabilization of β-catenin, its translocation to the nucleus and transcription of the Wnt/β-catenin target gene, cyclin D1 (15–18). Thus, a mechanism through which polyP can activate GSK-3/Wnt/β-catenin signaling is by up-regulation of the synthesis of Wnt proteins by endothelial cells. However, GSK-3 is also known to be phosphorylated/inactivated by AKT/PKB signaling (30,47), which is a pathway effectively activated by polyP (12). Moreover, we previously demonstrated that polyP, through activation of mTORC1, mediates phosphorylation and stimulation of p70S6 kinase (12), thereby increasing mRNA synthesis and translation of ribosomal proteins which promote protein synthesis during cell growth. In support of a role for polyP in promoting protein synthesis through mRNA translation, we discovered in the current study that polyP also promotes phosphorylation of the mRNA cap-binding protein eIF-4E, which has been shown to be involved in the initiation of translation of a subset of mRNAs (including cyclin D1) required for cell growth (48,49). Indeed, the overexpression of elF-4E in NIH 3T3 cells by transfection studies has been found to be associated with increased cyclin D1 mRNA expression and enhanced translation efficiency of cyclin D1 mRNA in serum-deprived cells (50). These results suggest that polyP can influence GSK-3/Wnt/β-catenin signaling through multiple steps, without requirement for Wnt proteins ligating their specific Frizzled receptors. Based on these results we propose the model presented in Fig. 8 depicting different mechanisms through which polyP may modulate the GSK-3/Wnt/β-catenin signaling. The interaction of polyP with RAGE and P2Y1 activates mTORC1 by PI3K/AKT and PLC/PKC dependent inhibition of TSC1/2 complex as we demonstrated previously (12). PolyP, through interaction with the same receptors, can activate GSK-3/Wnt/β-catenin signaling by at least four different mechanisms: 1) polyP-mediated AKT activation can lead to phosphorylation-dependent inhibition of GSK-3, thereby resulting in stabilization of β-catenin independent of Wnt-mediated Frizzled signaling, 2) polyP-mediated improvement of protein translation can result in augmentation of translation of mRNAs for cyclin D1 and/or Wnt proteins, 3) polyP through activation of IKKα/β can down-regulate GSK-3 activity, thereby stabilizing β-catenin and cyclin D1 independent of a direct Wnt/Frizzled signaling, and finally 4) polyP can directly interact with a Frizzled receptor, thereby activating the pathway by a mechanism similar to RAGE signaling. As indicated above, we have demonstrated that polyP can bind HMGB1 with high affinity to dramatically promote RAGE signaling (11). Thus, we hypothesize that low levels of HMGB1 synthesized by cells under stressed conditions can have a profound effect in modulating these signaling pathways in the presence of polyP (11). Further studies will be required to determine the exact mechanisms through which polyP establishes a crosstalk between mTOR and GSK-3/Wnt/β-catenin signaling network that culminates in elevated expression of cyclin D1 in endothelial cells. We thank Stephanie A. Smith from University of Illinois, Urbana for preparing the platelet releasates and Audrey Rezaie for proofreading the manuscript. Funding Sources This research was partly supported by grants awarded by the National Heart, Lung, and Blood Institute of the National Institutes of Health HL 101917 and HL 62565 to A.R.R. Figure 1 PolyP-70 induces GSK-3 phosphorylation and increases expression and nuclear localization of cyclin D1, in EA.hy926 endothelial cells. (A) Time course of polyP-mediated phosphorylation and inactivation of GSK-3α/β in EA.hy926 cells. (B) Cells were treated with polyP-70 (25 µM) at different time points followed by measuring the expression of cyclin D1. (C) Semiquantitative RT-PCR was performed as described before (22). Results were normalized to expression levels of GAPDH and presented as the fold difference relative to the control group at each time point. The results are shown as mean ± standard deviation of 3 different experiments as determined Student t test. *P<0.05; **P<0.01. (D) The same as B except that the effect of polyP-70 on nuclear localization of cyclin D1 was measured. Cells were stained with DAPI to visualize the nucleus (Blue) and anti-cyclin D1 antibody (Red) and then imaged by confocal microscopy. The scale for the microscopic figure is 20µm. Figure 2 PolyP-70-mediated expression of cyclin D1 in the absence and presence of siRNA or specific inhibitors for signaling molecules. (A) The efficiency of gene knockdown of β-catenin (>75%) was determined 48h post transfection by Western-blotting using a specific antibody. The (B) PolyP-mediated up-regulation of cyclin D1 was monitored after siRNA knockdown of β-catenin in EA.hy926 endothelial cells. (C–D) PolyP-mediated overexpression of cyclin D1 in the absence and presence of increasing concentrations of two different Wnt signaling inhibitors (iCRT3 and PNU-74654). (E) PolyP-mediated up-regulation of cyclin D1 in the absence and presence of increasing concentrations of PI3K inhibitor (wortmannin). (F) PolyP-mediated overexpression of cyclin D1 in the absence and presence of increasing concentrations of AKT inhibitor (AKT inhibitor VIII). (G) PolyP-mediated overexpression of cyclin D1 in the absence and presence of increasing concentrations of intracellular calcium chelator (BAPTA-AM). (H) PolyP-mediated up-regulation of cyclin D1 in the absence and presence of increasing concentrations of PLC inhibitor (U-73122). (I) PolyP-mediated overexpression of cyclin D1 in the absence and presence of increasing concentrations of PKC inhibitor (BIS). (J) EA.hy926 cells were transiently transfected with control siRNA or siRNA for ERK1/2 and the efficiency of gene knockdown (>75%) was determined 48h post transfection by Western-blotting using a specific antibody. (K) The same as J except that polyP-mediated overexpression of cyclin D1 was monitored after siRNA knockdown of ERK1/2. (L) PolyP-mediated overexpression of cyclin D1 in the absence and presence of increasing concentrations of ERK inhibitor (PD-98059). The results are shown as mean ± standard deviation of 3 different experiments. *P<0.05; **P<0.01. Figure 3 PolyP-70 inhibits phosphorylation and degradation of cyclin D1 in EA.hy926 endothelial cells. (A) Cells were treated with MG132 (25 µM) for 4h in the absence or presence of polyP-70 (25 µM) followed by measuring the phosphorylation of cyclin D1 using anti-phospho cyclin D1 antibody. (B) PolyP-mediated inhibition of cyclin D1 phosphorylation was monitored in the presence of specific inhibitors of mTOR upstream signaling pathway. In the presence of each inhibitor, cells were co-incubated with MG132 (25µM) and PolyP-70 (25µM) for 4h. (C) PolyP-mediated inhibition of cyclin D1 phosphorylation was monitored after siRNA knockdown of ERK1/2. (D) PolyP-mediated nuclear localization of cyclin D1 was measured in the absence and presence of ERK1/2 inhibitor (PD-98059). The scale for the microscopic figure is 20µm. Figure 4 PolyP-70-mediated regulation of expression, localization and degradation of cyclin D1 are dependent on mTORC1 and NF-κB signaling pathways. (A) PolyP-mediated overexpression of cyclin D1 was monitored in the presence of different concentrations of mTORC1 inhibitor (rapamycin). (B) EA.hy926 endothelial cells were transiently transfected with control siRNA or siRNA specific for either raptor or rictor and the efficiency of gene knockdown (>75%) was determined 48h post transfection. (C) The same as B except that polyP-mediated up-regulation of cyclin D1 was monitored after siRNA knockdown of either raptor or rictor. (D) The expression and phosphorylation of eIF-4E was monitored in EA.hy926 cells treated with different concentrations of polyP-70. (E) PolyP-mediated overexpression of cyclin D1 was monitored in the presence of different concentrations of IKKα inhibitor (BAY11-7082). (F) The same as D except that polyP-mediated up-regulation of cyclin D1 was monitored in the presence of different concentrations of IKKβ inhibitor (BMS-345541). (G) The same as B except that cells were transiently transfected with control siRNA or siRNA specific for either IKKα or IKKβ. (H) The same as C except that polyP-mediated up-regulation of cyclin D1 was monitored after siRNA knockdown of either IKKα or IKKβ. (I) PolyP-mediated nuclear localization of cyclin D1 was measured in EA.hy926 cells transiently transfected with control siRNA or siRNA specific for either IKKα or IKKβ. (J) The same as H except that polyP-mediated inhibition of cyclin D1 phosphorylation was monitored after siRNA knockdown of IKKα or IKKβ. The scale for the microscopic figure is 20µm. The results are shown as mean ± standard deviation of 3 different experiments. *P<0.05; **P<0.01. Figure 5 PolyP-mediated expression of cyclin D1 in EA.hy926 endothelial cells transfected with siRNAs for RAGE and/or P2Y1 or treated with recombinant soluble RAGE (sRAGE). (A) Cells were transiently transfected with control siRNA or siRNA specific for either RAGE or P2Y1 followed by stimulating cells with polyP-70 (25 µM) and monitoring the expression of cyclin D1. Lane 1, RAGE siRNA alone; lane 2, RAGE siRNA + polyP-70; lane 3, P2Y1 siRNA alone; lane 4, P2Y1 siRNA + polyP-70; lane 5, control siRNA alone; lane 6, control siRNA + polyp-70; lane 7, control (no siRNA, buffer only); lane 8, control + polyP-70; lane 9, RAGE and P2Y1 siRNAs alone combined; lane 10, RAGE and P2Y1 siRNAs combined + polyP-70. (B) Analysis of expression of cyclin D1 treated with sRAGE (2.5 µM). Lane 1, sRAGE alone; lane 2, sRAGE + polyP-70; lane 3, control (buffer only); lane 4, control + polyP-70. The efficiency of gene knockdown was >75% in all cases. The results are shown as mean ± standard deviation of 3 different experiments. *P<0.05 for lane 4 (P2Y1 siRNA + polyP), compared to control siRNA + polyP-70 in panel A. Figure 6 Viability of EA.hy926 cells treated with polyP-70. (A) The time course of cell survival was monitored by treating cells with polyP-70 (25 µM) followed by evaluating the viability by MTT assay as described (22). (B) The same as A except that the polyP-70 concentration-dependence of cell survival was monitored. The percentage of cell viability was calculated by the ratio of the OD540 of wells containing polyP-70 to the OD of the wells lacking polyP-70 × 100. The results are shown as mean ± standard deviation of 3 different experiments. *P<0.05. Figure 7 Platelet releasates regulate expression, localization and stability of cyclin D1 in EA.hy926 cells. (A) Dose response of platelet releasates (30 min) for inducing the phosphorylation of GSK-3α/β in EA.hy926 cells. PolyP-70 is shown as a control in the last lane. (B) Overexpression of cyclin D1 by boiled (30 min) platelet releasates (plt-rel, 0.1 ratio) is inhibited by co-incubation of platelet releasates with EcPPXc (250 µg/ml) and alkaline phosphatase (ALP 2 units/mL). PolyP-70 is shown as a control in the lanes 2–4. (C) Analysis of cyclin D1 overexpression by boiled (30 min) platelet releasates by the inhibitors of mTOR upstream signaling pathway. With all inhibitors, cells were treated with boiled platelet releasates co-incubated with each inhibitor for 8h. (D) Platelet releasates-mediated nuclear localization of cyclin D1 was measured in EA.hy926 cells co-incubated with ERK1/2 inhibitor (PD-98059), mTORC1 inhibitor (rapamycin), IKKα and IKKβ inhibitors (BAY11-7082 and BMS-345541 respectively). (E) The same as D except that platelet releasates-mediated inhibition of cyclin D1 phosphorylation was monitored. The scale for the microscopic figure is 20µm. The results are shown as mean ± standard deviation of 3 different experiments. *P<0.05; **P<0.01. Figure 8 Mechanism of polyP-mediated crosstalk between mTOR and GSK-3/Wnt/β-catenin signaling networks. PolyP, through interaction with RAGE and P2Y1 receptors, activates mTORC1 by PI3K/AKT and PLC/PKC/Ca2+ dependent inhibition of tumor suppressor TSC1/2 complex, thereby augmenting protein translation machinery by phosphorylation of p70S6K and eIF-4E. HMGB1 can dramatically promote these signaling reactions. PolyP by the same mechanism mediates the phosphorylation-dependent activation of IKK-α/β, thereby activating NF-kβ. PolyP can promote the expression of cyclin D1 by several different mechanisms: It can indirectly promote cyclin D1 synthesis by the phosphorylation-dependent inhibition of GSK-3 by either AKT and/or IKK-α/β, thereby preventing the ubiquitin- and proteasome-dependent degradation of β-catenin and cyclin D1 independent of Wnt-Frizzled receptor interaction (dashed blue lines). Alternatively, polyP can promote the translation of cyclin D1 mRNA and/or Wnt mRNAs, thereby leading to up-regulation Wnt proteins and their interaction with and activation of Frizzled receptors (dashed red arrows). Finally, polyP can directly interact with Frizzled (and LRP5/6) receptors to improve the expression of cyclin D1 (solid red arrow). HMGB1, high mobility group box 1; RAGE, receptor for advanced glycation end products; TSC1/2, tuberous sclerosis complex 1/2; GSK-3, glycogen synthase kinase 3; TCF, T cell factor; LRP5/6, Dvl, Dishevelled; LRP5/6, low-density lipoprotein receptor-related protein 5/6, mTORC1, mammalian target of rapamycin complex 1; eIF-4E, eukaryotic initiation factor 4E. Essentials Polyphosphate (polyP) activates mTOR but its role in Wnt/β-catenin signaling is not known. PolyP-mediated cyclin D1 expression (β-catenin target gene) was monitored in endothelial cells. PolyP and boiled platelet-releasates induced the expression of cyclin D1 by similar mechanisms. PolyP establishes crosstalk between mTOR and Wnt/β-catenin signaling in endothelial cells. Addendum S. M. Hassanian designed, performed experiments and wrote the manuscript. A. Ardeshirylajimi and P. Dinarvand performed experiments. A. R. Rezaie supervised the project and wrote the manuscript. Disclosure of Conflict of Interests The authors declare no competing financial interest. Supporting Information The source of reagents can be found in the online version of this article. 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PMC005xxxxxx/PMC5116248.txt
LICENSE: This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. 101240003 32254 Semin Fetal Neonatal Med Semin Fetal Neonatal Med Seminars in fetal & neonatal medicine 1744-165X 1878-0946 27343151 5116248 10.1016/j.siny.2016.06.001 NIHMS797974 Article Necrotizing enterocolitis and preterm infant gut bacteria Warner Barbara B. a Tarr Phillip I. b a Fetal Care Center, Division of Newborn Medicine, Washington University School of Medicine, St Louis, MO, USA b Division of Gastroenterology, Hepatology, Nutrition; Pathobiology Research Unit; Department of Pediatrics, Washington University School of Medicine, St Louis, MO, USA * Corresponding author Address: Fetal Care Center, Division of Newborn Medicine, Washington, University School of Medicine, Campus Box 8116, 660 S, Euclid, St Louis, MO 63110, USA, Tel: +01 314 454 2531. warner_b@kids.wustl.edu (B.B. Warner) 29 6 2016 22 6 2016 12 2016 01 12 2017 21 6 394399 This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. Summary Necrotizing enterocolitis remains an intractable consequence of preterm birth. Gut microbial communities, especially bacterial communities, have long been suspected to play a role in the development of necrotizing enterocolitis. Direct-from-stool nucleic acid sequencing technology now offers insights into the make-up of these communities. Data are now converging on the roles of Gram-negative bacteria as causative agents, despite the dynamic nature of bacterial populations, the varying technologies and sampling strategies, and the overall small sample sizes in these case–control studies. Bacteria that confer protection from necrotizing enterocolitis have not been identified across studies. The beneficial effect of probiotics is not apparent in infants with birth weights <1000 g (these infants are at highest risk of, and have the highest case fatality rate from, necrotizing enterocolitis). Further work should be directed to the modulating gut microbes, or the products they produce, to prevent this devastating complication of preterm birth. Necrotizing enterocolitis Gammaproteobacteria 1. Introduction The newborn gut microbiome is an area of intense and growing interest in perinatology. There is emerging appreciation of the roles played by gut microbes in intestinal health, and, indeed, in lifelong health. Most relevant to preterm infants in neonatal intensive care units (NICUs), several very important disorders are likely to originate from either abnormal proportions of microbial content (dysbiosis), or when a vulnerable host encounters a specific pathogen. In this review, we focus on early-in-life bacterial population assembly in the preterm infant gut, recent data on the biology and ecology of the bacterial community, and the role these microbes play in the development of necrotizing enterocolitis (NEC). Experimental data are mentioned as examples that corroborate or extend observations from the human host. 2. The in-population of the human infant gut by microbes Classic teaching holds that the human gut (i.e., the meconium) contains no bacteria, or at least no viable bacteria, at birth. However, recent data prompt reconsideration of this dogma. Mshvildadze et al. [1] identified bacterial sequences in freshly produced meconium, as have Heida et al. [2], and Ardissone et al. [3]. Stout et al. [4] have identified bacterial bodies on electron microscopy in the basal plate of placentas delivered via cesarean section. Aagaard et al. [5] reported bacterial 16S and metagenomic sequences in placentas, finding similarities between these sequences and those of bacteria resident in the mouth. Additional studies have identified bacterial sequences in amniotic fluid from term pregnancies delivered by elective cesarean section [6]. Notably, these papers rarely present evidence of viable bacteria in specimens putatively colonized based on nucleic acid sequencing (Table 1). The possibility that the fetal gut is colonized by bacteria before maternal membranes rupture is intriguing. However, low grade bacteremia occurs independent of pregnancy in healthy adults after brushing or flossing teeth, or defecation [11]. The finding of bacterial sequences in or on a newborn infant immediately after rupture of membranes may reflect colonization of the newborn while passing through the birth canal or being delivered through the skin. These sequences may also reflect nucleic acid remnants of viable bacteria that circulated in the mother's blood, but which have no replicative potential or relevance to the assembly of the earliest-in-life members of the bacterial community of the infant gut. An additional argument against prenatal colonization of the gut with bacteria acquired in utero is the observation that germ-free animals, which generally require immersion in iodine solution during the derivation process, are generated from mothers (usually mice) who are not free of germs. Iodine immersion would not sterilize the colonized gut, so if the gut is an intergenerational habitat for viable bacteria, we would expect that it would be impossible to derive germ-free animals. Recent publications illuminate rules of assembly for the human infant gut microbiome. Among healthy term and near-term infants, early gut colonization patterns are driven largely by delivery route and feeding patterns [12,13], with emerging data suggesting a role for the gut virome [10]. Infants born very preterm (<32 weeks), however, have a distinct set of exposures compared to those born near term. Parenteral antibiotic use is nearly universal during the first several days of life in preterm infants, feeding tubes are placed early, and enteral nutrition is commenced cautiously. In the days and weeks after birth, preterm infants reside almost exclusively in NICUs. These environments are designed to limit microbial transmission, and contact with bacteria is controlled to the extent possible. Visitors are restricted and often only parents and professional staff are permitted to touch the infant. Hand hygiene is stressed, line care is protocolized, and nutrition is either human breast milk (mother of infant or pasteurized donor pool), or sterilized liquid formula. There is no exposure to pets, or physical contact with other relatives. This microbiologically constrained biosphere offers a rich opportunity to study the transition of the neonatal gut from sterility or near sterility at birth to an organ that houses, for the rest of the life of the host, the greatest density of microbes in the human body. Not unexpectedly, bacterial communities assemble differently in the preterm gut than in the term infant gut. Whereas the in-population of the infant gut with bacteria is a fascinating ecologic event worthy of study in its own right, accumulating experimental data suggest that the earliest-in-life gut bacteria affect the future well-being of their hosts [14]. Hence, the study of these communities in infants is justifiable in order to determine whether the animal data are relevant for humans. However, pertinent to infants born very prematurely, there are additional compelling reasons to study the gut microbiome because of the high frequency with which these infants experience complications of premature birth that are plausibly associated with this biomass. The two most dire consequences in which gut bacteria could play major roles in outcome are NEC and late-onset neonatal bloodstream infections (P.I. Tarr and B.B. Warner, Chapter 4, this issue). The “normal” preterm infant gut microbiome has been characterized among infants born very preterm who were at risk of developing NEC, but who did not experience this event, i.e., controls. Until recently, these analyses used culture-based technology, or polymerase chain reaction amplification of DNA extracted from stool and testing for mobility in a gel. Most recently, advances in sequencing technology, expansion of ribosomal RNA gene databases, and metagenomic capabilities (DNA sequencing not confined to 16S rRNA gene regions) have made feasible the direct-from-stool amplification of extracted bacterial DNA. These approaches provide a less circuitous, and deeper and more economical, portrayal of bacterial populations in polymicrobial substances. In the targeted approach, conserved regions of the 16S ribosomal RNA gene of bacteria are primed and amplified, a technique employed in the NIH-sponsored Human Microbiome Project [15]. This targeted approach enables deep “censusing” of bacterial populations, as all such mass readouts are confined to the regions of the bacterial chromosome that identify the organism from which they are derived. We are aware of six publications from NICUs in eight different centers in which bacterial community assembly in “normal” preterm infants has been interrogated in depth using direct-from-stool sequencing. For the purposes of this review, our criteria for including such studies are those that included at least 100 stools from at least 25 subjects who did not develop NEC, and that the enumeration technology employed 16S rRNA gene or metagenomic sequencing (Table 2). Even though only one of the papers in Table 2 exclusively focused on defining the pattern of progression in children without NEC [20], data supplied in the others [16,18,21] were sufficient to confirm the findings of La Rosa et al. [20]. In that comprehensive study of preterm infants, 16S rRNA gene sequencing demonstrated a remarkably choreographed pattern: namely, the early-in-life gut bacterial content is predominated by Bacilli (despite their name, Bacilli are Gram-positive cocci such as staphylococci, streptococci, and enterococci). Bacilli are soon overtaken by Gram-negative facultative organisms (a diversity of genera and species within the Gammaproteobacteria class). This surge in Gammaproteobacteria is counterbalanced by a gradually increasing abundance of Clostridia (many genera and species) and Negativicutes (predominantly Veillonella). Overall, four bacterial classes (Bacilli, Gammaproteobacteria, Clostridia, and Negativicutes) account for >90% of the taxa present. Compared to the gut content of older children and adults, these preterm infant gut bacterial populations have much higher content of Gammaproteobacteria (one to two orders of magnitude difference), and approximately half the density of obligate anaerobes. There is a convergence on a consensus community structure by the equivalence of 33–36 weeks postmenstrual age (the sum of gestational age at birth, and day of life on which the sample was obtained). The content of this consensus community at this postmenstrual age (but not earlier) is independent of gestational age at birth. In particular, anaerobic bacteria gain abundance more rapidly in the gastrointestinal tracts of infants born least prematurely. This choreographed progression is punctuated unpredictably and substantially by short-lived changes in composition, before the communities self-revert to the choreographed progression. Such abrupt changes have been noted in older children and adults [12,13,15,22]. Unexpectedly, the factors believed to be influential in microbial community assembly (at least in children born after full-term gestation), namely mode of delivery (vaginal vs cesarean section), antibiotic administration in the aggregate, and feeds (breast milk), were either not determinative of bacterial content, or had only minimal or temporary influence on this progression. These non-associations between diverse exposures, each of which could logically be considered to influence bacterial community structure in the gut, prompts us to interpret that in the preterm human infant, the major driver of bacterial population assembly is intrinsic host biology or succession ecology rather than exogenous factors. However, we offer two caveats. First, as described above, the microbial exposures of very preterm infants differ considerably from those of infants born at term, in whom mode of delivery and breast-milk feeding appear to influence gut bacterial population assembly. Second, we wish to note that in a subsequent study of the St Louis Children's Hospital cohort [19], specific antibiotics (meropenem, cefotaxime, and ticarcillin–clavulanate), which were used in few subjects in La Rosa et al. [20], were associated with substantial directional changes in microbial content. It is also noteworthy that when metagenomic sequencing technology was applied [19], bacterial community population characteristics as previously defined by 16S rRNA gene sequencing were recapitulated [20]. 3. The gut microbiome and NEC Multiple lines of circumstantial evidence suggest that NEC is influenced by bacteria in the very preterm infant gut. Most notably, NEC does not occur in utero, and, in fact, rarely occurs before approximately day of life 10, after bacterial populations start to assemble in the newborn gut. Also, NEC is statistically and independently associated with increased antibiotic use, especially prolongation of antibiotics during the first week of life [23–25]. Moreover, H2 blockers, which could affect gut microbial populations by reducing the gastric acid line of defence against bacterial colonization, are associated with increased NEC risk [26]. Multiple studies suggest that probiotics prevent NEC (reviewed in [27]), but this benefit accrues chiefly to infants who weigh <1000 g at birth, and who are at lesser risk of experiencing NEC, and of dying from NEC, than those whose birthweights are <1000 g. Indeed, a recent large and well-conducted multi-center randomized control trial of Bifidobacterium breve BBG-001 failed to demonstrate any protective effect against NEC in a population in which most of the children weighed ≤1000 g at birth [28]. Whereas this failure might represent the use of a single probiotic instead of a combination of probiotics, and though the choice of the probiotic intervention could be subject to debate, it seems unlikely that we will soon identify viable microbes that can exert a profoundly protective effect against NEC, especially among infants whose birth weights are ≤1000 g. A review of the many taxa that have been associated with NEC is beyond the scope of this article. However, the diversity of incriminated species, the overall small numbers of subjects in these studies, and small effect sizes reported (often only in subgroup analysis), cast doubt on the existence of a specific mono-microbial driver of NEC [29]. Nonetheless, as reviewed above, direct-from-stool sequencing of DNA now offers new opportunities to compare cases with NEC to controls, to determine whether microbial populations are associated with this outcome. In the past decade, multiple groups have attempted to apply direct-from-stool sequencing to identify bacteria that might cause NEC. Some such attempts are summarized in Table 3, focusing on studies that utilized 16S rRNA amplification methods rather than culture or gel electrophoresis-based methods. These studies suggest that diverse bacterial taxa are associated with either risk of, or protection from, developing necrotizing enterocolitis among preterm infants. One interpretation is that there are center-specific differences in microbial drivers of NEC, as described for variability in gut microbial populations before the onset of bloodstream infections [35]. An alternative explanation is that the population biology of bacteria in the gut is exceptionally dynamic in the interval during which NEC occurs, which obligates the assembly of exceptionally large cohorts to study this disorder, and the need to interrogate an abundance of specimens prior to the event. Indeed, only one of the studies in Table 3 reported the analysis of >100 pre-NEC specimens. The dynamism of bacterial populations poses immense challenges. In the first 60 days of life, as described above, there is a week-by-week aggregate progression from Bacilli to Gammaproteobacteria predominance, while Clostridia slowly rise in abundance. In reality, the Clostridia class described by La Rosa et al. contains Clostridia and Negativicutes, because Negativicutes (Gram-negative obligate anaerobic bacteria) have recently been assigned their own class [20]. NEC generally does not present until after the second week of life, and risk extends to approximately day of life 60, with infants born most prematurely developing NEC later in this period of vulnerability [29]. To illustrate this challenge, stools from a case occurring on day of life 25 would ideally be compared to stools from a control group of infants produced on day of life 25, these controls having been born after the same gestational duration. However, control specimens for a case of NEC that occurs on day of life 45 would greatly differ in content from controls chosen on day of life 25, even if controlling for gestational age at birth. That is to say, the norm changes throughout the interval of risk, during which NEC can occur at any time. When one also takes into account the additional abrupt changes in populations, it is clear that a substantial number of subjects and specimens must be assembled to characterize the microbial population in children at risk in a case–control study. Notably, the larger studies tend to lean towards a predominance of Gram-negative bacteria as being drivers of NEC. Consensus protective organisms have generally not emerged from these large studies. A final complicating note is that specimens obtained immediately before NEC is apparent may reflect changes of NEC that are already under way before infants become visibly affected. It therefore seems prudent to “censor” sequence data from the hours preceding the onset of clinical NEC if trying to identify signatures well in advance of NEC that could be associated with this disorder. Interestingly, in one study in which specimens were analyzed late (tissue at resection) [30] or early (meconium) [2], anaerobic bacteria were associated with NEC. In the largest study (in terms of numbers of cases and numbers of pre-NEC stools analyzed) reported to date, an overrepresentation of Gammaproteobacteria was associated with NEC, whereas anaerobic bacteria, especially Negativicutes and secondarily Clostridia, were associated with control status (i.e., protection). Gammaproteobacteria risk has been suggested in several smaller studies [16,18,34]. In contrast, however, several publications employing direct-from-stool sequencing have not identified overabundant Gram-negative bacteria as a prelude to NEC [2,33]. Indirect data support that Gram-negative bacteria are causal in NEC pathogenesis. In animal models, toll-like receptor 4, the ligand for lipopolysaccharide, is believed to play a central role in mucosal injury [36], and antibiotics active against Gram-negative bacteria confer protection [37]. Moreover, anaerobic bacteria, in response to microbiota-accessible carbohydrates, generate anti-inflammatory short-chain fatty acids, notably acetate, propionate, and butyrate [38]. Several literature reviews [39,40] have evaluated studies in which infants were administered oral aminoglycosides in attempts to prevent NEC. Aminoglycosides would be active against Gammaproteobacteria in the gut, but not suppress anaerobic bacterial populations. In the aggregate, these studies [41–44] support the use of oral aminoglycosides to prevent NEC. However, because of concerns about selecting for aminoglycoside resistance [45] and of absorption of the oral aminoglycosides from the gut (albeit confined to very early in life before the incidence of NEC increases [46]), enteral antibiotics to prevent NEC are not widely used. It is interesting to note that the oral aminoglycosides were often discontinued in these studies before the time of life at which the most premature infants develop NEC. This timing raises the possibility that the beneficial effects of antibiotics in these studies might have been understated. Bacterial diversity – defined as the number of different taxa present, weighed according to their proportionality – is considered to reflect a healthy luminal microbial community in inflammatory bowel disease and C. difficile infections [47,48]. Even before these associations between lack of diversity and gut inflammation were reported, Claud and Walker proposed the hypothesis that diminished diversity of the premature infant gut could result in NEC [49]. Subsequent studies failed to find an association between lack of bacterial diversity and development of NEC [16–18,31,33,34,50], though again, as for NEC microbial associations, the numbers were limited. However, in a recent study [21], an association between subsequent development of NEC and comparatively lower gut bacterial diversity was noted. The difference appeared to be related to delayed or suppressed maturation of microbial diversity in infants who subsequently developed NEC, compared to those who did not. In other words, diversity slowly increased over the first 60 days of life in the controls but not the cases. However, this association is not straightforward: gut bacterial communities are exceptionally non-complex in preterm infants. Therefore, a change in the proportionality of one taxon is necessarily counterbalanced by a change in one or more of the few other taxa present. With only four dominant taxonomic “degrees of freedom,” it is difficult to attribute NEC to lack of gut bacterial diversity per se, versus an increase or a decrease in one or another taxon. In other words, it cannot be stated that lack of diversity is the driver of risk for NEC, versus an overrepresentation of Gammaproteobacteria, which directly ordains the lack of diversity in these sample sets. The role of bacterial diversity in protecting from NEC remains an intriguing hypothesis, however. 4. Conclusion NEC remains a catastrophic disorder. It is concerning that we have not had meaningful and durable improvements in incidence or outcomes of NEC in the nearly four decades since widespread recognition of this entity permeated neonatology. The finding of a microbial signature prior to development of NEC, and/or a protective signature in the form of obligate anaerobic bacteria, now offers new opportunities to prevent this devastating consequence of preterm birth. Funding sources: This work was supported by NIH Grants UH3AI083265, P30DK052574 (for the Biobank Core) and the Children's Discovery Institute of Washington University and the St Louis Children's Hospital. We are grateful to Ms Maida Redzic for assistance with manuscript preparation. Table 1 Data in support of prenatal colonization of the new-born gut with microbes. Study Subject of study Comments Jimenez et al. [7] Cord blood cultures of term neonates born by elective cesarean section Enterococci, streptococci, staphylococci, and propionibacterium recovered from cord blood Mshvildadze et al. [1] Meconium by 16S rRNA gene sequencing Viable bacteria not sought DiGiulio et al. [8] Amniotic fluid cultures and 16S rRNA gene sequencing in preterm deliveries 16S rRNA gene sequences identified in, and Mycoplasma hominis, Ureaplasma sp., Streptococcus agalactiae, Lactobacillus sp., Prevotella sp., Fusobacterium nucleatum, coagulase-negative Staphylococcus sp., Bacillus sp. (not anthrax), Peptostreptococcus sp., and Gardnerella vaginalis recovered from the amniotic fluid Rautava et al. [9] Bacterial DNA detected in amniotic fluid at time of elective cesarean section by 16S rRNA gene sequencing Viable bacteria not sought Stout et al. [4] Electron microscopy of placenta Bacteria identified in basal plate, no attempt to culture Aagaard et al. [5] 16S rRNA gene sequences and metagenomic sequences Bacterial sequences identified and reflected periodontal microbes, no attempt to culture Lim et al. [10] First in life stool (days 1–4) subjected to 16S rRNA gene sequencing and virome analysis Few bacterial species, many bacteriophages, based on sequence analysis Table 2 Studies of gut bacterial assembly in preterm infants without necrotizing enterocolitis (NEC). Study and location Sequencing technology No. Of subjects without NEC No. of specimens Conclusions about pattern of bacterial community assembly Zhou et al. [16], Brigham and Women's Hospital, Boston, MA, USA 16S rRNA gene sequencing 26 111 Increasing proportion of Clostridia over time, balanced by slowly diminishing proportion of Gram-negative genera, with little effect of antibiotics on this trend Ward et al. [17], Cincinnati, OH, and Birmingham, AL, USA Metagenomic sequencing 89 185 Clostridia class increases over time (specifically veillonella and C. freundii), with consistently high Proteobacteria (specifically E. coli) Shaw et al. [18], St Mary's Hospital, Queen Charlotte's and Chelsea Hospital, London,UKa 16S rRNA gene sequencing 44 369 Bifidobacteria and klebsiella increased in proportionality, and Gram-positive bacteria decreased in proportionality, over time Gibson et al. [19], St Louis Children's Hospital, St Louis, MO, USA Metagenomic sequencing 84 401 Some of these subjects and specimens were also analyzed in La Rosa et al. [21]. Notably, metagenomic sequencing recapitulated the 16S sequence analysis of this cohort in these two companion publications. La Rosa et al. [20], St Louis Children's Hospital, St Louis, MO, USA 16S rRNA Gene sequencing 58 922 Bacterial classes proceed from Bacilli to Gammaproteobacteria to Clostridia in these infants, but these populations are prone to changes in content. When infants near 33–36 weeks postconceptional age (i.e., an interval that is equivalent to the 3rd to the 12th week of age, in view of the wide range of gestational ages in this cohort), the populations converge on a consensus community, with ∼40% of the bacteria being obligate anaerobes (especially Clostridia and Negativicutes), and an equal percentage being Gammaproteobacteria. There was little or no effect of use of postnatal antibiotics, mode of delivery, or breast milk, and the community composition at this point. Warner et al. [21], St Louis Children's Hospital, St Louis, MO; Children's Hospital at Oklahoma University, Oklahoma City, OK; Kosair Children's Hospital, Louisville, KY, USA 16S rRNA gene sequencing 120 2720 Includes the 58 subjects without NEC and their 922 stools in La Rosa et al. [21]. Patterns in NICUs in Oklahoma City and in Louisville recapitulate those in St Louis cohort NICU, neonatal intensive care unit. a Based on data from Supplemental Table 1 in [18]. Table 3 Summary of studies in which DNA sequences obtained directly from stools have been used to associate bacterial risk and development of necrotizing enterocolitis (NEC), listed in ascending order according to number of pre-NEC stools sequenced. Study Sequencing technology No. of subjects without NEC No. of specimens from subjects without NEC No. of subjects with NEC No. of pre-NEC specimens from subjects who subsequently developed NEC Comments Brower-Sinning et al. [30], Pittsburgh, PA, USA 16S rRNA gene sequencing 10 10 9 9 Tissue analysis only, no pre-NEC samples; Proteobacteria, Clostridia associated with risk, as was diminished bacterial diversity Mai et al. [31], three University of Florida-affiliated NICUs, FL, USA 16S rRNA gene sequencing 9 18 9 18 Case stools demonstrated an increase in Proteobacteria, and a decrease in Firmicutes in the second of the paired samples (i.e., week before NEC) McMurtry et al. [32], Louisiana State University Health Sciences Center, Touro Infirmary, East Jefferson General Hospital and Children's Hospital of New Orleans, LA, USA 16S rRNA gene sequencing 74 74 21 21 Bacterial diversity and relative abundance of Clostridia was significantly lower in NEC specimens compared to controls Raveh-Sadka et al. [33] Pittsburgh, PA, USA Metagenomic sequencing 5 34 5 21 No clear association between bacterial content as identified by metagenomics and outcome; no microbiologic evidence of time–space clustering Heida et al. [2], Groningen, The Netherlands 16S rRNA gene sequencing of meconium and subsequent stools 22 57 11 30 Clostridium perfringens and Bacteroides dorei associated with risk, and staphylococi associated with protection. Torrazza et al. [34], Gainseville, FL, USA 16S rRNA gene sequencing 35 77 18 40 Novel sequence matching closest to Klebsiella pneumoniae during week 1 associated with subsequent development of NEC Ward et al. [17], Cincinnati, OH, and Birmingham, AL, USA Metagenomic sequencing 89 185 27 60 Specific sequence types of E. coli associated with NEC Sim et al. [18], St Mary's Hospital, Queen Charlotte's and Chelsea Hospital, London, UK 16S rRNA gene sequencing 44 369 22 88 Klebsiella, clostridium associated with risk; no microbiologic evidence of time–space clustering Zhou et al. [16], Brigham and Women's Hospital, Boston, MA, USA 16S rRNA gene sequencing 26 111 10 88 Age-specific differences identified, with early- and late-onset NEC having an association with Clostridia and Gammaproteobacteria, respectively Warner et al. [23], St Louis Children's Hospital, St Louis, MO; Kosair Children's Hospital, Louisville, KY; Children's Hospital at Oklahoma University, Oklahoma City, OK, USA 16S rRNA gene sequencing 120 2720 46 866 Gammaproteobacteria associated with risk, and Negativicutes associated with protection; lack of diversity is associated with risk NICU, neonatal intensive care unit. Practice points The causes of NEC are unknown. Judicious use of antibiotics and promotion of human milk use might lower the risk of NEC, but these interventions are unlikely to categorically reduce disease incidence, and are justifiable for multiple additional reasons. Research directions How can we anticipate the microbial community changes that lead to NEC? How can we modulate the gut microbial community to reduce bacteria-associated processesthat might lead to NEC? Conflict of interest statement: None declared. This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final citable form. Please note that during the production process errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain. 1 Mshvildadze M Neu J Shuster J Theriaque D Li N Mai V Intestinal microbial ecology in premature infants assessed with non-culture-based techniques J Pediatr 2010 156 20 5 19783002 2 Heida FH van Zoonen AG Hulscher JB A necrotizing enterocolitis-associated gut microbiota is present in the meconium: results of a prospective study Clin Infect Dis 2016 62 863 70 26787171 3 Ardissone AN de la Cruz DM Davis-Richardson AG Meconium microbiome analysis identifies bacteria correlated with premature birth PloS One 2014 9 e90784 24614698 4 Stout MJ Conlon B Landeau M Identification of intracellular bacteria in the basal plate of the human placenta in term and preterm gestations Am J Obstet Gynecol 2013 208 226 e1 7 23333552 5 Aagaard K Ma J Antony KM Ganu R Petrosino J Versalovic J The placenta harbors a unique microbiome Sci Transl Med 2014 6 237ra65 6 Collado MC Rautava S Aakko J Isolauri E Salminen S Human gut colonisation may be initiated in utero by distinct microbial communities in the placenta and amniotic fluid Sci Rep 2016 6 23129 27001291 7 Jimenez E Fernandez L Marin ML Isolation of commensal bacteria from umbilical cord blood of healthy neonates born by cesarean section Curr Microbiol 2005 51 270 4 16187156 8 DiGiulio DB Romero R Amogan HP Microbial prevalence, diversity and abundance in amniotic fluid during preterm labor: a molecular and culture-based investigation PloS One 2008 3 e3056 18725970 9 Rautava S Collado MC Salminen S Isolauri E Probiotics modulate host–microbe interaction in the placenta and fetal gut: a randomized, double-blind, placebo-controlled trial Neonatology 2012 102 178 84 22776980 10 Lim ES Zhou Y Zhao G Early life dynamics of the human gut virome and bacterial microbiome in infants Nature Med 2015 21 1228 34 26366711 11 Nikkari S McLaughlin IJ Bi W Dodge DE Relman DA Does blood of healthy subjects contain bacterial ribosomal DNA? 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PMC005xxxxxx/PMC5116260.txt
LICENSE: This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. 2985117R 4816 J Immunol J. Immunol. Journal of immunology (Baltimore, Md. : 1950) 0022-1767 1550-6606 27799309 5116260 10.4049/jimmunol.1600576 NIHMS821782 Article Lung Cancer Subtypes Generate Unique Immune Responses Busch Stephanie E. * Hanke Mark L. * Kargl Julia *‡ Metz Heather E. * MacPherson David † Houghton A. McGarry *†§ * Clinical Research Division, Fred Hutchinson Cancer Research Center, Seattle, WA † Human Biology Division, Fred Hutchinson Cancer Research Center, Seattle, WA ‡ Institute of Experimental and Clinical Pharmacology, Medical University of Graz, Graz, Austria § Division of Pulmonary and Critical Care, University of Washington, Seattle, WA. Corresponding Author: A. McGarry Houghton, M.D., Clinical Research Division, Fred Hutchinson Cancer Research Center, 1100 Fairview Avenue N. (D4-100), Seattle, WA 98109, Phone: 206.667.3175, Fax: 206.667.5255, houghton@fhcrc.org 21 10 2016 31 10 2016 1 12 2016 01 12 2017 197 11 44934503 This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. Lung cancer – the leading cause of cancer-related deaths worldwide – is a heterogeneous disease comprised of multiple histologic subtypes that harbor disparate mutational profiles. Immune-based therapies have shown initial promise in the treatment of lung cancer patients but are currently limited by low overall response rates. We sought to determine whether the host immune response to lung cancer is predicated, at least in part, by histologic and genetic differences, as such correlations would have important clinical ramifications. Using mouse models of lung cancer, we show that small cell lung cancer (SCLC) and lung adenocarcinoma (ADCA) exhibit unique immune cell composition of the tumor microenvironment. The total amount of leukocyte content was markedly reduced in SCLC compared to lung ADCA, which was validated in human lung cancer specimens. We further identified key differences in immune cell content using three models of lung ADCA driven by mutations in Kras, Tp53, and Egfr. Although Egfr-mutant cancers displayed robust myeloid cell recruitment, they failed to mount a CD8+ immune response. In contrast, Kras-mutant tumors displayed significant expansion of multiple immune cell types, including CD8+ cells, regulatory T cells, IL17A-producing lymphocytes, and myeloid cells. A human tissue microarray annotated for KRAS and EGFR mutations validated the finding of reduced CD8+ content in human lung adenocarcinoma. Taken together, these findings establish a strong foundational knowledge of the immune cell contexture of lung ADCA and SCLC and suggest that molecular and histological traits shape the host immune response to cancer. INTRODUCTION Despite decades of research, small cell lung cancer (SCLC) and non-small cell lung cancer (NSCLC) remain among the world's deadliest diseases (1). SCLC, in which RB1 and TP53 mutations are common (2), accounts for 10-20% of lung cancer diagnoses (3). Over half of NSCLC cases are classified as lung adenocarcinomas (ADCA), in which KRAS, EGFR, and TP53 mutations are the predominant genetic drivers (4, 5). Although patients with EGFR mutations initially respond to targeted therapies, drug resistance typically develops within the first year (6). SCLC and KRAS-mutant ADCA have proven less tractable, as scant progress has been made towards the development of targeted therapeutics for these patients (7). Novel immunotherapeutic strategies have offered new hope for the management of NSCLC (8-10) and SCLC (11), but the clinical success of immunomodulatory agents will depend on a strong foundational knowledge of the cells that comprise the lung tumor microenvironment (TME) in these molecularly and histologically distinct diseases. Inflammation is a key attribute of neoplasia (12). The host immune response to cancer is an intricate web of both pro- and anti-tumorigenic signals (13). CD8+ T cells, also known as cytotoxic T lymphocytes (CTL), are the body's main immunological barrier to cancer, as they are capable of recognizing and killing tumor cells. However, CTL activity is curbed by tumor cells expressing immune checkpoint ligands (e.g. PD-L1), as well as an influx of immune-suppressive cells (i.e. regulatory T cells, macrophages, monocytes, and neutrophils) into the TME (14, 15). Newly developed immune checkpoint inhibitors (ICI; e.g. ipilimumab and nivolumab) seek to reverse this suppression and unleash an anti-tumor response (16). Although some lung cancer patients have experienced remarkable tumor regression upon commencing ICI therapy, overall response rates have peaked around 20% (9, 10). These disparate outcomes may in part be explained by findings that tumor immune cell composition and function vary between anatomical sites and histological origins (17). In lung cancer, for example, squamous cell carcinoma (SCC) patients have exhibited longer progression-free survival with ipilimumab treatment than have ADCA patients (8). However, even within histological subgroups, response rates vary widely, raising the question of what other tumor attributes might predict clinical outcome. The oncogenic functions of mutant RAS and EGFR in cancer include the production of pro-inflammatory cytokines, such as IL8, that help to shape the TME (18-21). TP53 has similarly demonstrated non-cell-autonomous behaviors during tumorigenesis (22, 23). The discrete impact of molecular signatures, such as KRAS, EGFR, TP53, and RB1 mutations, on the immune cell composition of lung cancer nevertheless remains largely undefined. To address this question, we profiled the TME of three genetically engineered mouse (GEM) models of NSCLC – KrasLSL-G12D, KrasLSL-G12D;Trp53Fl/Fl, and EgfrL858R – as well as the Rb1Fl/Fl;Trp53Fl/Fl model of SCLC. Here we show that the molecular and histological subtypes of lung cancer predict immune cell composition and may, therefore, demand specific immunotherapeutic regimens. MATERIALS AND METHODS Mice All animal experiments utilized aged-matched mice on approved IACUC protocols at the Fred Hutchinson Cancer Research Center. TetO-EgfrL858R mice (24) were obtained from the Mouse Models of Human Cancer Consortium on C57BL/6 background. Ccsp-rtTA mice (25) on FVB background were provided by Jeff Whitsett (University of Cincinnati). KrasLSL-G12D (i.e. Kras) (26), Trp53Fl/Fl (p53) (27), RORγtGFP (RORγt) (28), and Tcrd−/− (Tgd) (29) mice were obtained from Jackson Labs on C57BL/6 background. TetO-EgfrL858R;Ccsp-rtTA (Egfr), KrasLSL-G12D;Trp53Fl/Fl (Kp53), KrasLSL-G12D;RORγtGFP (K.RORγt), and KrasLSL-G12D;Tcrd−/− (K.Tgd) mice were generated by simple cross-breeding. Rb1Fl/Fl mice (30) were crossed with Trp53Fl/Fl to generate Rb1Fl/Fl;Trp53Fl/Fl (Rbp53) mice on a mixed C57BL/6x129 background. Egfr and single-transgene control mice (Ccsp-rtTA or TetO-EgfrL858R) were fed 200 mg/kg doxycycline-impregnated food (Harlan, Indianapolis, IN, USA). Kras, Kp53, p53, and wild-type (wt) C57BL/6 animals received an intratracheal dose of 2.5×107 pfu Adenoviral Cre Recombinase (AdCre; University of Iowa Viral Vector Core, Iowa City, IA, USA), as described (31). Each cohort was studied over a time course of 6, 10, and 14-weeks post initiation of doxycycline or infection with AdCre. Additional cohorts of K.RORγt and K.Tgd animals were similarly subjected to AdCre infection (2.5×107 pfu) and examined 14-weeks post initiation or when moribund. RbFl/Fl;Trp53Fl/Fl mice received 1×108 pfu AdCre; given the long latency period, Rbp53 animals were studied 9 months post-induction. CTLA4 antibody, clone 9D9 (MedImmune) or isotype control (mIgG2b) was administered to an additional cohort of Kras mice twice weekly via intraperitoneal injection for a total of four weeks – starting at 8 weeks post AdCre – at a dose of 10mg/kg. Tissue collection and histology Lung tissue specimens were collected and processed as described (32). Briefly, the left lung was ligated and snap-frozen for later analysis. The right lung was inflated with 10% neutral buffered formalin (NBF) at 25 cm H20 pressure before fixing in NBF overnight. 5-μm paraffin-embedded sections were stained for hematoxylin and eosin (H&E) or immunostained for CD45 (BD Bioscience, San Diego, CA, USA), FoxP3 (eBioscience, San Diego, CA, USA), or CD3 (Serotec, Raleigh, NC, USA) using 3,3”-diaminobenzidine development and hematoxylin counter-staining. Global adjustments to white balance, brightness and/or contrast were made to some photomicrographs using Photoshop (Adobe Systems, San Jose, CA, USA). Slides were imaged with an Eclipse 80i microscope (Nikon Instruments Inc., Melville, NY, USA), excluding the whole lobe images presented in Figure 1A, which were collected at 20X magnification with an Aperio digital pathology slide scanner (Leica Biosystems, Buffalo Grove, IL, USA). Total lung and tumor area (μm2) were measured from H&E stained slides using NIS-Elements Advanced Research software (Nikon). Results are expressed as % lung occupied by tumor ((area tumor ÷ area lung) × 100). Each lung was also scored for tumor grade, as described (33). FoxP3 and CD3 stained lung lobes (n = 5 mice/genotype) were scored for the presence or absence of cells within three locations: tumor-associated, tumor-infiltrating, or within a lymphoid aggregate (LA). Lung tissue single cell preparation Single-cell suspensions were generated from saline-perfused mouse lungs using mechanical disruption followed by 1 hr digestion at 37°C in RPMI-1640 containing 10% FCS and penicillin/streptomycin along with 80 U/ml DNase, 300 U/ml Collagenase Type 1 (both Worthington Biochemical Corporation, Lakewood, NJ, USA), and 60 U/ml hyaluronidase (Sigma, St Louis, MO, USA). Digested lungs were sheared through a 19g needle, strained through 70-μm nylon mesh, centrifuged, lysed (RBC), washed, strained through 40-μm mesh, centrifuged, and resuspended in DPBS + 2% FCS. Cell viability was determined using trypan blue staining and a TC20™ Automated Cell Counter (BioRad, Hercules, CA, USA). We obtained two SCLC and five ADCA surgical specimens, each with non-adjacent normal lung tissue, using an approved IRB file in association with FHCRC, University of Washington Medical Center, and Northwest BioTrust. Single-cell suspensions were generated using the above digestion protocol. Flow cytometry Single-cell suspensions were incubated with 1.0 μg/106 cells Mouse TruStain FcX™ or 1.0 μl/106 cells Human TruStain FcX™ (Biolegend, San Diego, CA, USA) prior to immunostaining. Twenty-seven fluorochrome-labeled antibodies were used among four multicolor panels for mouse specimens (all flow antibodies detailed in Supplemental Table I). Immunostaining was performed for 30 min on ice, protected from light. Dead cells were excluded with Fixable Viability Dye eFluor® 780 (FVD; eBioscience), per manufacturer's protocol. Stained cells were washed, fixed with IC Fixation Buffer (eBioscience), and stored at 4°C until analysis. Intracellular cytokine production was assessed using PMA (25 ng/ml), ionomycin (1 μg/ml; both from Sigma), and monensin (1.5 μl/ml; BD Bioscience) stimulation for 5 hr at 37°C, 5% CO2. An unstimulated sample was incubated without PMA and ionomycin. After stimulation, cells were washed, stained with FVD, fixed, and permeabilized with the Transcription Factor Buffer Set (BD) prior to immunostaining. Samples were analyzed on a LSR II flow cytometer with FACSDiva™ software (BD), recording ≥ 1×105 events per sample. Data were compensated and analyzed with FlowJo software (TreeStar, Ashland, OR, USA). Gates were defined by fluorescence-minus-one (FMO) samples and verified with appropriate isotype controls. The unstimulated control was used to define cytokine gates. Total cell content was calculated by multiplying the overall number of live cells recovered from each animal (i.e. the trypan-blue-negative hemacytometer count) by the percentage of live cells for each gated parameter. Cytokine-producing T cell subsets were calculated by multiplying the percent parent gate to the previously determined parent population count. Median fluorescence intensity (Med.F.I.) of NKG2D-BV421 and PDL1-BV421 parameters was calculated in FlowJo, with Med.F.I. of the relevant FMO control being subtracted from all experimental values for normalization. CFSE assay Splenocytes from wild-type mice were labeled with 50 μM CFSE (Molecular Probes, Eugene, OR, USA), per manufacturer's instructions. 1×106 CFSE-labeled splenocytes were transferred to 6-well tissue culture plates coated with anti-CD3/anti-CD28 antibodies (Biolegend). Cells were incubated with 200 μg homogenate – generated from 10-week Egfr, Kras, or wt lungs – at 37°C, 5% CO2 for 4 days. Lymphocyte proliferation was determined by harvesting the cells, staining with CD8a-BV421 (Biolegend) and FVD, and measuring ≥ 1×103 live CD8+ cells on a LSR II flow cytometer. Gene Expression Analysis Total RNA was isolated from frozen mouse lungs using TRIzol reagent (Life Technologies, Carlsbad, CA, USA) and subsequently purified with the RNeasy Mini Kit (Qiagen, Hilden, Germany). cDNA was generated from 2 μg total RNA using SuperScript II Reverse Transcriptase and Oligo(dT) (Life Technologies). The expression of indicated target genes was analyzed using a StepOnePlus Real Time PCR machine and TaqMan primer/probe sets (Applied Biosystems, Foster City, CA, USA), with all reactions run in triplicate. ΔCt values were calculated using Gapdh as the endogenous housekeeping gene. Tissue Microarray A lung ADCA cohort on tissue microarray (TMA), consisting of 135 cases, was obtained from the University of Pittsburgh Cancer Institute. Patient identifiers were removed and the study therefore considered “not human subjects” research (i.e. IRB exempt). Each case was previously annotated as either EGFR mutant (n = 31), KRAS mutant (n = 69), or wild-type for both EGFR and KRAS (n = 35). Formalin-fixed, paraffin-embedded sections were stained with an anti-human CD8 antibody (Abcam #ab4055, Cambridge, MA). Immunohistochemical (IHC)-stained TMA slides were scanned in brightfield at a 20X objective using NanoZoomer Digital Pathology System (Hamamatsu, Hamamatsu City, Japan). Twenty TMA cases (n = 5 EGFR and 16 KRAS) were excluded as lost, non-informative (e.g. poorly stained or non-tumorous), or exhibiting high inter-punch variability (i.e. SEM ≥ 50% of mean). The number of CD8+ cells per TMA core was recorded blind to genotype and normalized to core area. Individual core counts from 2 or more replicates were available for most cases, and CD8+ cell counts/mm2 were averaged across replicates. Cut-off values of low versus high CD8+ cell content were defined by the midpoint. Comparison of TMA cohorts was conducted using the Fisher's exact test with one-tailed P value. Statistical analysis Significant differences between experimental groups were determined in Prism 6 (GraphPad Software, La Jolla, CA, USA) using unpaired t-tests or, for comparing ≥ 3 groups, one-way ANOVA with indicated post-hoc test for correction of multiple comparisons. Incidence of CD3+ and/or FoxP3+ cells per lobe was compared between genotypes using the chi-square test. Unless indicated otherwise, data are presented as mean ± SEM. P < 0.05 was considered statistically significant. RESULTS Egfr- and Kras-driven ADCA induce a strong inflammatory response Lung tumor development and associated inflammation were assessed in TetO-EgfrL858R;Ccsp-rtTA (Egfr), KrasLSL-G12D (Kras) and KrasLSL-G12D;Trp53Fl/Fl (Kp53) mice. To allow for the dynamic assessment of tumor-associated immune responses, lung tumor-bearing animals and appropriate littermate controls were studied over a time course of 6, 10, and 14 weeks post initiation. Consistent with previous studies (24, 26, 34), Egfr, Kras, and Kp53 mice developed neoplastic lesions reminiscent of human disease, from benign hyperplasia and adenomas to malignant ADCA (Fig. 1A-C). Hyperplasia was observed at all time points, although it was less prevalent in Egfr mice than in Kras-mutant mice (data not shown). The introduction of a secondary mutation in Trp53 increased ADCA formation and amplified tumor growth. Accordingly, tumor burden in 10-week Kras mice was significantly less than observed in age-matched Kp53 mice (Fig. 1D; P = 0.0231). Analysis of Kp53 mice at the 14-week time point was precluded by early mortality, but Kras mice remained viable and exhibited 38% lung tumor burden. Body mass measurements, used to non-invasively monitor lung tumor-associated morbidity, correlated with tumor burden for all genotypes (Fig. 1E). Previous investigations of pulmonary inflammation have been largely based on the assessment of bronchoalveolar lavage (BAL) fluid. Although a well-accepted methodology, BAL studies confine analysis to the airway compartment and limit the number of immune cell types that can be identified. Therefore, to more thoroughly investigate the immune cell composition of the TME, we performed flow cytometric analyses on single-cell suspensions generated from whole lung tissues. Using the gating strategy shown in Figure 2A, we identified 13 unique leukocyte populations defined by 16 antibody markers (see Methods and Supplemental Table I). Kras, Kp53, and Egfr mutant mice all display a robust immune response, as evidence by 3 to 5-fold elevations in total CD45+ cell content as compared to normal lung (Fig. 2B-G). Macrophages were by far the most prevalent immune cell type in the lungs of the three murine ADCA models. Ten weeks after starting doxycycline, Egfr mice exhibited 11-fold increases in macrophage content compared to controls (Fig. 2B). Similarly, by 6 weeks post-Cre induction in Kp53 and 10 weeks in Kras animals, total macrophage cell counts had increased 14- and 17-fold (Fig. 2D and F). Of note, macrophage content increased with time only in Kras and Kp53 animals (Supplemental Table II). Since myeloid derived suppressor cells (MDSC) are comprised of monocytic (M-MDSC) and granulocytic (G-MDSC) subsets, we simply defined these cells as monocytes (CD11b+Ly6C+) and neutrophils (CD11b+Ly6G+). We observed small but significant differences in neutrophil content in 10- and 14-week Egfr (Fig. 2B and C) as well as 14-week Kras tumor-bearing lungs (Fig. 2E). By 6- and 10-weeks, tumor-associated neutrophil content increased 2- and 5-fold, respectively, in Kp53 animals compared to control (Fig. 2F and G). Indeed, neutrophil counts in Kp53 lungs were statistically increased compared to all other genotypes at the 10-week time point (Supplemental Table III). However, this neutrophil signature may merely reflect overall tumor burden, as statistical analysis of cohorts with approximately matched tumor area (i.e. 6-week Kp53, 10-week Kras, and 14-week Egfr) failed to identify significant differences in pulmonary PMN content. Impaired natural killer cell function in Kras-driven ADCA Natural killer (NK) cells are lymphocytes of the innate immune system that play an important role in the host defense against inhaled pathogens (35). NK cell counts in non-tumor bearing lungs were comparable to those of macrophages and granulocytes (Fig. 2). Unlike the myeloid cell expansion observed with ADCA development, however, NK populations remained largely unaltered in tumor-bearing lungs. When significant increases were identified (Fig. 2B, D-G), the fold changes were small, and NK cell counts decreased over time in Kras animals (Supplemental Table II). NK cells are required for effective tumor immunosurveillance (36), but cancer cells have developed multiple strategies to escape NK cell-mediated cytotoxicity, including downregulation of the natural killer group 2, member D receptor (NKG2D, also known as CD314) (37, 38). Surface expression of NKG2D on NK cells was significantly decreased in both Kras and Kp53 tumor-bearing animals at all time points, but exhibited no change in Egfr mice (Fig. 2H). Thus, these murine models of Kras-driven lung ADCA recapitulate an immune escape mechanism previously described in human lung cancer (39). Oncogenic drivers dictate lymphocyte recruitment into the ADCA microenvironment The majority of immunotherapeutic approaches are premised on the ability of the adaptive immune system to infiltrate tumors and identify tumor-specific antigens. Therefore, we comprehensively surveyed the lymphocyte subpopulations present within the TME. B cell populations remained unaltered in tumor-bearing Egfr mice (Fig. 2B and C) but increased at least 2-fold in Kras and Kp53 mice at all time points (Fig. 2D-G). CD3+ populations were significantly increased in multiple groups (Fig. 2B, D-H), but T cell counts were demonstrably greater in Kras and Kp53 compared to Egfr mice (Supplemental Table III), even after controlling for tumor burden. CD4+ helper T cell expansion was observed in both Kras-driven tumor models but was limited in Egfr mice (Fig. 3A-F). This pattern was reflected in regulatory T cell (Treg) content, which was significantly lower in tumor-bearing lungs from Egfr mice compared to Kras mice (Supplemental Table III). Interestingly, Treg content increased over time in both Kras and Kp53 animals (Supplemental Table II), the only cell type other than macrophages and neutrophils to exhibit such dynamic behavior. Expression of IFNγ by CD4+ T cells (TH1 cells) and IL17A by CD3+ T cells were also significantly upregulated in Kras and Kp53 animals compared to control at early and late time points (Fig. 3C-F), but exhibited little to no increase in Egfr animals (Fig. 3A and B). Direct comparison of tumor-bearing lungs from all genotypes found higher TH1 and CD3+IL17A+ cell counts in both Kras-driven models compared to the Egfr mice (Supplemental Table III). Despite repeated attempts, we were unable to identify IL4-positive TH2 cells in our animals (Supplemental Fig. 1); it remains unclear whether this deficiency reflects a true biological absence or, more likely, a technical barrier. To assess the spatial relationship between lymphocytes and tumor cells, we performed IHC staining for CD3 and FoxP3 on Egfr, Kras, and Kp53 tumor bearing mice. For each model of lung ADCA, immune cell location was assigned to three categories: 1) tumor-associated (i.e. TA, or peripheral), 2) tumor-infiltrating (TI), or 3) within a neighboring lymphoid aggregate (LA). Examples of each are provided in Figure 3G-J. Staining for CD3 illustrated key differences by genotype, as Egfr mutant mice displayed markedly less tumor-associated CD3+ T cell content than Kras and Kp53 specimens (Fig. 3K, left). Tumor-infiltrating CD3+ cells were identified in all ADCA models, although they were more prevalent in Kp53 mice (Fig. 3K, center). Similarly, CD3+ cells were present in all LAs, but LAs were significantly less common in Egfr mice, whereas they were uniformly present in the other genotypes (Fig. 3K, right). Approximately 15% of lobes from Egfr mice displayed the presence of tumor-associated Tregs, compared to about 40% for Kras mice (Fig. 3L, left). The primary location of Tregs in all genotypes was within LA structures (Fig. 3L, right), with essentially no tumor infiltration observed (Fig. 3L, center). Taken together, the IHC studies confirm the flow cytometry data showing that Egfr mice contain fewer Tregs than the other genotypes and, moreover, demonstrate a paucity of tumor-infiltrating lymphocytes, especially when compared to Kp53 tumors. CD8+ lymphocyte content and function differ by lung ADCA subtype CD8+ T cells are capable of detecting and discriminately eliminating tumor cells (40). Notably, CD8+ cell content differed significantly between models driven by mutant Kras versus Egfr. Expansion of CD8+ cells was observed at all time points in Kras and Kp53 mice but did not occur in the Egfr-mutant cohort (Fig. 3A-F). Even after controlling for tumor burden, Kras-mutant mice displayed greater CD8+ cell content than found in Egfr mice (Supplemental Table III). Therefore, we carried out a number of experiments in attempt to determine the mechanistic basis for this finding and to translate this observation to human disease. Initially, we performed quantitative real-time PCR (qPCR) for key CC and CXC chemokines known to impact immune cell recruitment. Notably, we identified an increase in Cxcl-9 and -10 in Kras mutant lungs compared to Egfr (Figure 3M), which may at least partially explain the differences in lymphocyte content seen between the two lung ADCA models. In order to translate these findings to human disease, we performed immunohistochemical staining for CD8 on a lung ADCA TMA annotated for KRAS (n = 53 cases) and EGFR (n = 26) mutational status. The frequency of KRAS and EGFR mutations present in the cases displaying high versus low CD8 content (the top and bottom 50% of cases, respectively) were assessed, and EGFR mutations were found to be significantly overrepresented in the CD8 low cohort (Fig. 4A). Specifically, 65.4% of EGFR-mutant cases were scored as CD8-low versus 41.5% of KRAS-mutant cases. Thus, similar to the findings in genetically engineered mouse models presented above, EGFR mutant lung adenocarcinomas exhibit reduced CD8+ lymphocyte infiltration in human lung cancers as compared to KRAS mutant lung ADCA. Because CD8+ responses can be blunted by immune checkpoint ligands, we measured PDL1 expression on both macrophages and tumor cells (EpCAM+) by flow cytometry. Interestingly, although PDL1 expression was decreased in tumor-bearing versus control lungs for both Egfr and Kras mice, there was no difference in PDL1 expression between oncogenic subtypes (Figure 4B). Since other tumor microenvironmental factors can perturb lymphocyte function, we assessed whether the TME of Egfr mice was more suppressive to lymphocyte proliferation than that found in Kras mice. Both Egfr and Kras tumor homogenates reduced CD8+ T cell proliferation using CFSE-labeled lymphocytes, but the Egfr homogenates were not found to be more suppressive than Kras (Fig. 4C). As the intriguing lack of CD8+ cell expansion in Egfr mutant tumors suggests a failure of CD8+ cell activation in Egfr mice, we performed a detailed assessment of T cell effector and memory status at the 10 and 14-week time points using the markers CD62L, CD44, and PD1 (Figure 4D). No evidence of CD8+ T cell activation was observed, as evidenced by lack of an increase in CD8+PD1+ cells in tumor bearing Egfr mice (Figure 4E, G). Additionally, the proportion of central memory (CD62L+CD44+) and effector/effector memory (CD62L−CD44+) CD8+ T cells was unchanged, with the majority of these cells still falling into the naïve (CD62L+CD44−) category in Egfr mice. In contrast, and consistent with the small but significant increase in helper T cells shown in Figure 3A-B, CD4+ T cells demonstrated a significant increase in effector/effector memory populations in both 10 and 14-week Egfr mice (Figure 4F, H). Given the robust increase in CD8+ T cell content observed in tumor-bearing lungs from Kras mice compared to control, we elected to assess the status and functionality of the lymphocyte populations in Kras mice using an CTLA4 mIgG2b (clone 9D9) antibody (MedImmune). Although administration of anti-CTLA4 increased the proportion of both CD8+ (Figure 4J) and CD4+ (Figure 4K) effector/effector memory cells, this cellular phenotype failed to translate into an altered tumor burden in Kras mice (Figure 4I). Thus, despite an activated CD8+ T cell response in Kras mutant mice, tumor progression continued unabated. Role of IL17A-producing γδ T cells in Kras-driven lung ADCA Given the robust expansion of IL17A+ T cells in Kras mutant tumor-bearing mice and the known pro-tumor role of TH17 cells in lung ADCA (41), we elected to examine the cellular sources of IL17A in the lungs of our Kras mutant mouse models. Surprisingly, the predominant source of IL17A was found to be γδ T cells rather than CD4+ TH17 cells (Fig. 5A-B). An attempt to interrogate the role of IL17A in lung tumorigenesis by crossing Kras mutant mice to mice lacking the transcription factor for IL17A (i.e. RORγt) (42) was stymied by the frequent occurrence of lymphoid neoplasms in these animals. The spontaneously arising lymphomas exhibited both thymic (Fig. 5C) and splenic (Fig. 5D) involvement as well as diffuse infiltration of the liver (Fig. 5E) and lungs (Fig. 5F). Previous investigations of a related mouse model of RORγt deficiency (43) similarly observed a high incidence of lymphoma but did not indicate the occurrence of the pulmonary metastases that, unfortunately, preclude the use of this model in lung tumorigenesis studies. Further efforts to interrogate the specific role of γδ T cells in Kras mutant lung ADCA revealed that deletion of γδ T cells impacted neither tumor burden (Fig. 5G) nor the immune cell composition of the tumor microenvironment (Fig. 5H). A paucity of tumor-infiltrating leukocytes in murine and human SCLC The immune cell composition present within the SCLC TME has not been previously investigated to any extent. Therefore, we profiled the immune content of SCLC, using cohorts of Rbp53 mice infected with AdCre. As described previously (44), lung tumors of mainly neuroendocrine histology arose within 40 to 50 weeks of AdCre administration (Fig. 6A). Flow cytometric analysis of SCLC tumor-bearing lungs (gated as shown in Fig. 2) identified a small but noteworthy inflammatory presence in Rbp53 mice compared to control (Fig. 6B). The total number of CD45+ leukocytes was increased 2-fold in SCLC, and tumor-associated CD45+ cells were also visible by IHC staining (Fig. 6C). Unlike Kras- and Egfr-mutant animals (Fig. 1A and B), SCLC tumors presented as large, discrete foci, and little hyperplasia was observed. CD45+ cells were consequently clustered at the periphery of the SCLC lesions (Fig. 6D), without the inflammatory “field effect” frequently observed in the ADCA models. Few tumor-infiltrating leukocytes were detected (Fig. 6E). The major immune component of SCLC was found to be CD3+ T lymphocytes (Fig. 6B). This population included a 7-fold increase in the number of γδ T cells and a strong trend toward increased CD4+ helper T cells (P = 0.0698). In marked contrast to the ADCA models, expansion of innate immune cells in SCLC tumor-bearing lungs was minimal, with only a 2-fold increase observed in macrophages and a non-significant increase in neutrophils (P = 0.0886). To further investigate this phenomenon, we compared the ratio of CD3+ T cells to myeloid cells (macrophages, neutrophils, monocytes, and eosinophils) and found a pronounced lymphocyte-dominant signature in SCLC versus all ADCA models (Fig. 6F). Egfr mice presented with the smallest CD3:myeloid ratio and were also significantly different from Kras mice. As part of an ongoing study of the immune composition of human lung cancer, we obtained two surgical specimens with confirmed small cell pathology. Since resecting SCLC is rarely clinically indicated, these two specimens represented a unique opportunity to measure the immune cell composition present within the SCLC TME. Therefore, we performed flow cytometry analyses on single cell suspensions generated from these two cases. Similar to the findings in the GEM models, tumor-associated inflammation was discernibly lower in SCLC compared to five ADCA specimens, as CD45+ cells comprised a mere 16.2% of live cells in the SCLC resections, compared to 81.9% in ADCA (Fig. 6G). DISCUSSION Lung cancer is a heterogeneous disease that can be divided into distinct subtypes based on both molecular and cellular characteristics (45). Herein we tested the hypothesis that these subtypes dictate the inflammatory response to cancer by immune-profiling the lung TME in a mouse model of SCLC and in three molecularly distinct models of NSCLC (summarized in Fig. 6H). We found that Egfr and Kras mutations give rise to distinct immune responses characterized by differential expansion of B cells, CD8+ T cells, Tregs, and IL17A-producing T cell populations. Although loss of Trp53 promoted malignancy, it had minimal effect on immune cell composition within the Kras TME. We further demonstrate that SCLC possesses an overall reduced inflammatory presence compared to NSCLC, and one in which lymphocytes predominate over myeloid lineage cells. Mutational profile and histological origin therefore actively shape the immune contexture of lung cancer, a finding that may have important clinical ramifications. The strong macrophage field responses that occur in mutant Kras- and Egfr-driven mouse ADCA are seldom observed in human lung cancer and represent a potential limitation of these GEM models. In Kras mice, this phenomenon of alveolar macrophages flooding the airspaces has been likened to desquamative interstitial pneumonitis (DIP), a rare interstitial lung disease with similar pathology (46). Moreover, the conditional mouse models studied herein utilize varied induction methodologies, i.e. adenoviral Cre recombinase and doxycycline-regulated transgene expression. Although we cannot exclude potential confounding effects of viral infection or doxycycline consumption on the tumor immune response, we have attempted to correct for these variables by using adenovirus- or doxycycline-exposed wild-type animals for the relevant control cohorts. Few gene-specific investigations of the mouse lung TME have been conducted, and no comprehensive effort has been made to compare and contrast different molecular and histological models of lung cancer. Our results do, however, validate findings from several earlier reports on lung tumor-associated inflammation. We were unsurprised to identify macrophages as the dominant immune cell presence in mouse ADCA given that strong tumor-associated macrophage responses have been previously identified in mutant Egfr (21) and Kras (19, 41, 47) mouse lung tumor models. Likewise, as we describe herein, neutrophils have been shown by others to be a modest but important component of Kras- but not Egfr-driven mouse lung ADCA (19, 21, 41). Since the majority of prior data in this regard relied on BAL cell counts, we employed flow cytometry to better define the quality of the immune response. Using this methodology, we found that recruitment of lymphoid lineage cells varies greatly between ADCA models, as EgfrL858R mice exhibited a paucity of B cells, CD8+ T cells, Tregs, and IL17A-producing T cells when compared to the Kras and Kras;Trp53 lung TME. The most clinically relevant finding in this study is the lack of a CD8+ lymphocyte response in both Egfr mutant mice and EGFR mutant human lung ADCA specimens when compared to KRAS mutant counterparts. Markers of effector/memory status failed to reveal any evidence of CD8+ T cell activation or differentiation in Egfr mice. This suggests that EGFR mutation may not elicit an antigen-driven immune response. Although the same could be said for mutant KRAS, we were able to demonstrate an increase in activated and effector-memory CD8+ cells in the Kras mouse model. Furthermore, tumor-infiltrating lymphocyte (TIL) populations that specifically target mutant KRASG12D have recently been identified in colon cancer (48). Despite the presence of activated CD8+ cells, tumor growth continued in Kras mice even with the addition of an anti-CTLA4 therapeutic antibody. Our interpretation of this data is that increases in activated CD8+ cells within the TME in Kras mutant mice will not impact tumor growth unless they are tumor reactive. Specifically in this case, tumor-derived chemokines, such as Cxcl-10 are likely to increase the number of tumor-associated lymphocytes. Whereas anti-CTLA4 antibody therapy drove an increase in effector T cells, these cells would not be expected to reduce tumor burden if they did not recognize a tumor-associated antigen. It is also possible that anti-CTLA4 monotherapy will prove ineffective but that combined immunotherapeutic regimens (e.g. anti-CTLA4 + anti-PDL1) would prove effective. With respect to human lung ADCA, the association of EGFR mutant cancers with never-smoker status would suggest that these tumors are genetically simplified and, unlike smoking-associated KRAS mutant cancers, may not possess sufficient mutational burden to harbor neo-antigens (49, 50). The mouse models described herein were not exposed to cigarette smoke or other carcinogens, eliminating this proposed explanation for the differential CD8+ responses we observed. At this time, however, we cannot exclude the possibility that KRAS mutant human and mouse lung ADCA have realized the same phenotype of high CD8+ T cell infiltration through different mechanisms of action. Tregs and IL17A+ T cells have emerged as important cell populations in multiple mouse models of cancer (41, 51, 52), and both cell types exhibited notable patterns of expression or localization in the murine ADCA models. Although TGFβ and IL6 generate gradients leading independently to Treg or TH17 differentiation, we observed concurrent increases in both populations in Kras and Kp53 mutant tumor-bearing lungs. Notably, we found the major source of IL17A in Kras mutant ADCA to be γδ T cells and not TH17 cells. Since IL17A deficiency has been previously shown to reduce lung tumor growth (41) and IL17A-producing γδ T cells are known to promote breast (53) and pancreatic neoplasia (52), these findings suggested to us that expansion of a pulmonary IL17A-producing γδ T cell subset might overshadow the tumor-surveillance role traditionally ascribed to γδ T cells (54). However, Kras mutant, γδ T cell-deficient mice displayed equivalent lung tumor burden and strikingly similar immune profiles to their γδ T cell-competent counterparts. Therefore, although IL17A is an important signaling component in the immune landscape of lung ADCA, IL17A+ γδ T cells appear to contribute little to the process of lung tumorigenesis. Tregs, in contrast, appear to play a particularly important role in the Kras mutant lung TME, as they were the only non-myeloid lineage population to expand over the course of tumor development. Moreover, Tregs display a unique anatomic location in lung ADCA. They are rarely associated with the tumor itself but are instead frequently found within lymphoid aggregate structures that are believed to function as a local site of antigen presentation and have been correlated with good clinical outcomes in NSCLC (55). The presence of Tregs in these structures has recently been shown to be detrimental to the generation of an effective immune response in murine lung ADCA (56), highlighting the importance of Treg targeting strategies for the clinical management of lung cancer patients. The immune cell composition of SCLC has not been well studied. Our findings in Rbp53 mice point to a less robust but more lymphocyte-predominant host immune response to murine SCLC than to ADCA. Moreover, when we analyzed the immune cell content of two human SCLC cases, we identified a strikingly similar immune profile of sparse CD45+ cell content. Although we acknowledge the inherent limitations of n = 2 studies, patients diagnosed with SCLC seldom undergo lung resection (57), making access to such specimens exceedingly rare. Solid tumor malignancies demonstrating the best responses to current ICI therapies have been those with high mutational burdens and/or a history of cigarette smoke exposure (e.g. melanoma, head and neck SCC, and urinary bladder cancer), both traits common to SCLC (2). In light of these correlations, it is tempting to speculate that SCLC patients would exhibit good responses to ICI therapy. However, initial reports suggest that success rates to anti-PD1 therapy in SCLC are at best only comparable to NSCLC (58, 59). Our preliminary findings with respect to the immune cell composition in SCLC suggest that the presence of redundant immune suppressive factors would not be a likely source of treatment failure, which is almost certainly an important concept in NSCLC. These findings point to potentially unique features of the SCLC TME (e.g. matrix protein composition) that will require additional study. A robust CD45+ immune response was observed in both the ADCA mouse models and human lung ADCA patients. Leukocytes account for nearly 75% of total cellular content in human ADCA, an even greater proportion than we identified in mice (~55%). With the exception of the aforementioned exaggerated macrophage responses, the robust and diverse immune landscape observed in GEM models of ADCA approximates that seen in human lung cancers (60). Driving mutations, such as in Egfr and Kras, substantially impact the TME through the release of bioactive molecules, which is very well reflected in these GEM models. One potential shortcoming of these models is the genetic simplicity of the tumors, which rely on a single driving mutation. In contrast, human NSCLC harbors an average of ~150 distinct mutations per case (61). Efforts are underway to construct mouse models of cancer that harbor a greater abundance of single nucleotide variations and, thus, potential neoantigens. However, EGFR mutant cancers in non-smokers are typically genetically simplified (5), such that the Egfr mutant mice described herein likely constitute an excellent representation of both the genetic component of the cancer cell and the immune composition of the TME. The emergence of immune checkpoint inhibitors has been a tremendous advance, but unfortunately the majority of lung cancer patients in clinical trials have failed to respond to ICI therapy (8-11). In addition to the PD-1/PD-L1 based drugs currently in use, novel ICI agents are likely to emerge in the near future. Our findings argue that the cellular and molecular characteristics of lung cancer may provide an important framework for patient-targeted immunotherapy. Furthermore, preclinical testing of future immunotherapy agents should be performed in genetically and histologically diverse model systems to enable the assessment of tumor subtype-specific efficacy. Supplementary Material 1 ACKNOWLEDGMENTS The authors thank the FHCRC Experimental Histopathology and Flow Cytometry shared resource facilities, the UW Histology and Imaging Core, and the Viral Vector Core Facility at the University of Iowa Carver College of Medicine. The authors would also like to thank MedImmune for supplying the anti-CTLA4 therapeutic antibody. Financial Support: This work was supported by NIH/NHLBI grant R01 HL108979 to A.M.H., European Commission FP7-PEOPLE-2012-IOF 331255 to J.K., and by the Fred Hutchinson Cancer Research Center. Abbreviations ADCA adenocarcinoma AdCre adenoviral Cre recombinase BAL bronchoalveolar lavage fluid GEM genetically engineered mouse ICI immune checkpoint inhibitor NSCLC non-small cell lung cancer PMN polymorphonuclear cell SCLC small cell lung cancer TMA tissue microarray TME tumor microenvironment Treg regulatory T cell Figure 1 Egfr, Kras and Kp53 mice develop lung tumors and associated inflammation. (A, B) All models chronologically develop atypical alveolar hyperplasia, adenoma, and adenocarcinoma 6, 10, and 14 weeks post tumor induction. Normal lung from a non-tumor bearing wild-type mouse is depicted in the lower right corner. H&E sections, scale bars = 2 mm (A) and 500 μm (B), except lower wild-type panel = 1 mm. (C) Spectrum of disease in murine ADCA models. Data are presented as percent of mice exhibiting ≥ 1 indicated lesion at each time point post-induction (n ≥ 5 mice per group). All genotypes exhibited hyperplasia at all time points examined (not shown). Analysis of 14-week Kras LSL/+;Trp53Fl/Fl mice was precluded by early mortality. (D) Percent tumor area was calculated at the indicated time points in a minimum of at least 3 representative lungs from Egfr, Kras, and Kp53 mice. (E) Body mass of tumor-bearing female mice (n ≥ 5) compared to non-tumor bearing littermate controls (n ≥ 3) at each time point post-induction. Figure 2 Flow cytometric analysis of the inflammatory response to lung tumorigenesis. (A) Representative dot plots demonstrate the strategy used to characterize the mouse lung TME. Single cell gates (not shown) were initially applied to remove doublet cells. All subsequent gating utilized a viability marker followed by gating on the CD45+ population. Ly6G identified neutrophils (PMN), while remaining myeloid cells were classified as macrophage (Mac; SiglecF+CD11c+), eosinophil (Eos; SiglecF+CD11c−) or monocyte (Mono; SiglecFloCD11bhiLy6C+) from the Ly6G− population. A size gate was applied for lymphocyte analysis followed by staining to identify B cells (CD3−CD19+), T cells (CD3+CD19−), and NK cells (CD3−CD19−NK1.1+). T cells were further classified into γδ T cells (γδTCR+), CD4 cells (CD4+CD8−), and CD8 cells (CD8+CD4−). T cell subtypes were identified as TH1 (CD4+IFNγ+), Treg (CD4+CD25+FoxP3+), and IL17A-producing T cells (CD3+IL17A+). Major lung immune cell populations in (B) Egfr mice 10 weeks post tumor induction (n ≥ 6), (C) Egfr at 14 weeks (n ≥ 4), (D) Kras at 10 weeks (n = 14), (E) Kras at 14 weeks (n = 11), (F) Kp53 at 6 weeks (n = 8), and (G) Kp53 at 10 weeks (n ≥ 8), compared to non-tumor bearing control mice (white bars, n ≥ 3). Early and late time points for each genotype are depicted with gray and black bars, respectively. Data for each cell type are displayed as the total number of live cells present within the mouse lung. (H) NKG2D median fluorescence intensity (i.e. Med.F.I.) on NK cells was examined in Egfr, Kras, and Kp53 mutant lungs compared to normal lung controls at indicated time points (n ≥ 3 per group). Asterisks indicate P < 0.05. Figure 3 Oncogenic drivers dictate lymphocyte recruitment into the ADCA microenvironment. CD3+ T lymphocyte subpopulations in (A) Egfr mice 10 weeks post tumor induction (n ≥ 6), (B) Egfr at 14 weeks (n = 6), (C) Kras at 10 weeks (n ≥ 10), (D) Kras at 14 weeks (n = 11), (E) Kp53 at 6 weeks (n = 8), and (F) Kp53 at 10 weeks (n ≥ 6), compared to non-tumor bearing control mice (white bars, n ≥ 4). Data for each cell type are displayed as the total number of live cells present within the mouse lung. (G-J) CD3 immunostaining revealed that tumor-associated T cells (G, arrowheads) were commonly located at the edges of neoplastic lesions. Infiltration of CD3+ T cells into the tumor mass is indicated with arrows (H); note that large clusters of TA CD3+ cells were also present in the periphery of this lesion. CD3+ lymphoid aggregates formed within the vicinity of a tumor (I, dashed line, Tu) and were typically associated with airways and/or blood vessels. Although FoxP3+ Tregs were seldom observed infiltrating tumor masses (J), they constituted a significant portion of cells present in lymphoid aggregates. Scale bar = 250 μm. (K-L) Quantification of immune cell localization in matched tumor burden 14-week Egfr (n = 6), 10-week Kras (n = 5), and 6-week Kp53 (n = 5) mice. Results are expressed as the percent of lung lobes that contained at least one occurrence of (K, left) tumor-associated CD3+ cells, (center) tumor-infiltrating CD3+ cells, (right) CD3+ cells in lymphoid aggregates, or (L, left) tumor-associated FoxP3+ cells, (center) tumor-infiltrating FoxP3+ cells, or (right) FoxP3+ cells in lymphoid aggregates. (M) Expression of cytokine and chemokine genes in tumor-bearing lungs from 14-week Egfr and 10-week Kras mice (n = 4 per genotype). Data are presented as mean 1/ΔCt with 95% CI. Asterisks indicate P < 0.05. Figure 4 CD8+ cell content and function correlates with lung ADCA subtype. (A) The number of CD8+ cells/mm2 was tabulated for each core section present on a TMA of lung ADCA cases annotated for EGFR and KRAS mutational status. Cases were ranked from lowest to highest CD8 content prior to unblinding for genotype. Shown are representative images of EGFR- (left) and KRAS-mutant (right) ADCA. Scale bar = 100 μm. 65.4% (17 of 26) of EGFR-mutant cases were scored as CD8-low versus 41.5% (22 of 53) of KRAS-mutant cases (Fisher's exact test, P = 0.0392). (B) PDL1 Med.F.I. was assessed on pulmonary EpCAM+ epithelial cells and macrophages from 10-week Egfr (n = 5) and 14-week Kras mice (n = 4). Expression compared to normal lung (n ≥ 4) is shown in bottom panels. (C) Splenocytes from non-tumor bearing wild-type mice were labeled with CFSE and incubated with protein homogenate generated from wild-type normal lung (NL) or tumor-bearing lung from 10 week Kras or Egfr mice, or with media alone. The cells were subsequently stained with anti-CD8 and a viability marker and analyzed for CFSE intensity; representative plots are shown. For each genotype (n ≥ 3) the percentage of proliferating CD8+ T cells was determined after normalization to the media control. Statistical differences were assessed by one-way ANOVA with Tukey's post-test. (D) Flow cytometric analysis of T cell function in Egfr mice compared to wild-type control, gated from single, live, CD45+CD3+ parent population. Lymphocytes were gated as CD62L+CD44− (i.e. Naïve), CD62L+CD44+ (TCM, central memory), and CD62L−CD44+ (TEM/Eff, effector memory/effector). PD1 expression was assessed on CD8+ T cells only. CD8+ and CD4+ T cell populations were examined at 10 (E, F) and 14 weeks (G, H) post-induction of mutant Egfr (n = 6 tumor-bearing lungs and n ≥ 3 controls per group), respectively. (I) Percent lung tumor area of Kras mice treated with anti-CTLA4 (n = 7) or isotype (n = 6) with representative H&E sections. Scale bar = 500 μm. (J, K) Flow cytometric analysis of CD8+ and CD4+ T cell populations in anti-CTLA4 and isotype-treated Kras mice (n = 5 per group). Asterisks indicate P < 0.05. Figure 5 IL17A cytokine production and impact in Kras mutant lung ADCA. (A) Representative dot plot demonstrating the relative production of IL17A by γδ T and non-γδ T cells; gated from single, live, CD45+CD3+ parent population. (B) Quantification of IL17A cytokine's cellular source in 14 week Kras tumor-bearing lungs (n = 5). (C-F) Spontaneously arising lymphomas occurred at high frequency in K.RORγt animals, commonly impacting (C) thymus, (D) spleen, (E) liver, and (F) lung tissues. H&E sections, scale bars = 250 μm, except lung panel (F) = 500 μm. (G) Representative H&E images from 14-week Kras and Kras.Tgd mice. Scale bar = 500 μm. (H) Flow cytometric analysis of lungs from tumor-bearing Kras and Kras.Tgd mice (n = 6 each) at 14 weeks post-induction. Data for each cell type are displayed as the total number of live cells present within the mouse lung. Asterisks indicate P < 0.05. Figure 6 Tumor-associated inflammation in SCLC. (A) Rbp53 mice develop SCLC tumors within 1 year of AdCre exposure. H&E section, scale bar = 1 mm. (B) Flow cytometric analysis of lungs from tumor-bearing Rbp53 mice (n = 4) and non-Cre exposed control mice (n = 3), approximately 10 months after tumor induction. IHC staining reveals that CD45+ immune cells are generally located in the SCLC tumor periphery (arrowheads, C), with some clustering of cells into organized lymphoid structures (arrows, D). Some large CD45+ cells, likely macrophages, were observed in alveolar spaces (arrowheads, D) proximal to the tumor. Little to no leukocyte tumor infiltration was observed (E). Scale bars = 1 mm (C) and 100 μm (D, E). (F) The ratio of CD3+ T cells to sum myeloid population in SCLC mice was significantly increased compared to three ADCA models, as assessed by one-way ANOVA with Tukey's post-test. (G) The percentage of CD45+ live cells present in two resected specimens of human SCLC was greatly reduced compared to five human ADCA specimens. (H) Leukocyte population summary of the flow cytometric analyses, shown as percent of live cells, for a representative normal mouse lung, 10-week Egfr, Kras, and Kp53 ADCA and mouse SCLC are displayed. Abbreviations: NL, non-adjacent normal lung; Tu, tumor. Asterisks indicate P < 0.05. 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LICENSE: This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. 9001516 21213 Trends Endocrinol Metab Trends Endocrinol. Metab. Trends in endocrinology and metabolism: TEM 1043-2760 1879-3061 27623245 5116263 10.1016/j.tem.2016.08.003 NIHMS812039 Article Linking the microbiota, chronic disease and the immune system Hand Timothy W. *1 Vujkovic-Cvijin Ivan 2 Ridaura Vanessa K. 2 Belkaid Yasmine 23 1 R.K. Mellon Institute for Pediatric Research, Children’s Hospital of Pittsburgh of UPMC, University of Pittsburgh, Pittsburgh, PA, 15224 2 Mucosal Immunology Section, Laboratory of Parasitic Diseases, NIAID/NIH, Bethesda, Maryland 20892, USA 3 National Institute of Allergy and Infectious diseases (NIAID) Microbiome Program, National Institutes of Health (NIH), Bethesda, Maryland 20892, USA * Correspondence addressed to: Timothy Hand (timothy.hand@chp.edu) or Yasmine Belkaid (ybelkaid@niaid.nih.gov) 23 8 2016 10 9 2016 12 2016 01 12 2017 27 12 831843 This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. Chronic inflammatory diseases are the most important causes of mortality in the world today and are on the rise. We now know that immune-driven inflammation is critical in the etiology of these diseases, though the environmental triggers and cellular mechanisms that lead to their development are still mysterious. Many chronic inflammatory diseases are associated with significant shifts in the microbiota towards inflammatory configurations, which can affect the host both by inducing local and systemic inflammation and by alterations in microbiota-derived metabolites. This review discusses recent findings suggesting that shifts in the microbiota may contribute to chronic disease via effects on the immune system. Microbiota dysbiosis metabolic syndrome inflammasome IMMUNITY, THE MICROBIOTA AND CHRONIC INFLAMMATORY DISEASE In the past decade our knowledge of chronic inflammatory disease (CID) has been transformed by a new understanding of the central role of the immune system in driving pathology. The immune system functions as a ‘rheostat for the entire body; seeking out physiological disturbances, (infectious or otherwise), and rectifying them via both inflammatory immune responses, but also critical repair/regulatory processes such as the clearance of dead cells and the restoration of the physical barrier [1, 2]. Thus, many of the most chronic and debilitating diseases afflicting humankind can be seen as a shift in the immune response away from repair/regulation, and towards immune-driven inflammatory responses. Some of these diseases are also associated with a significant shift in the composition of the microbiota [3–7]. The microbiota is a significant source of both nutritional metabolites and inflammatory innate immune signals [8]. Therefore, compositional shifts in the microbiota are of potential importance as modifiers and triggers of disease, in the context of genetic predisposition and environmental factors. CID can encompass both autoimmune disease, such as systemic lupus erythematosus or rheumatoid arthritis, that are obviously associated with defects in the immune system and responses against self antigens in addition to auto-inflammatory disorders such as metabolic syndrome and cardiovascular disease, that have more recently been associated with immune-driven inflammation and are not dependent upon autoantigen recognition. In this review. we will focus more on links between the microbiota, immunity and the non-autoimmune inflammatory diseases; though a link between the microbiota and many autoimmune diseases is undeniable and reviewed elsewhere [9, 10]. The incidence of many CID is on the rise worldwide, without a clearly defined explanation. It has been hypothesized that this rise in chronic inflammatory and metabolic diseases is due, at least in part, to a significant narrowing of bacterial diversity associated with the evolutionarily recent phenomena of large scale urban living [11]. Antibiotic usage, dietary modifications and infectious diseases all play important roles in causing alterations in the host’s associated microbiota. In this review we will discuss recent evidence linking CID with shifts in both local and systemic immune responses and disease promoting configurations of the microbiota. IMMUNE/MICROBIOTA INTERACTION Humans exist as metaorganisms consisting of host cells in addition to a vast consortium of microbial organisms that live on all of our barrier tissues. The highest density of organisms lives in the intestine, and these organisms provide a tremendous benefit to the host via the enzymatic processing of complex dietary constituents, such as fiber, into metabolites digestible by the host, in addition to many other enzymatic functions. Often these enzymatic pathways can involve multiple genes present in separate bacterial clades [12] and it is perhaps more appropriate to measure those genes that are broadly conserved and critical for function, known as the core metagenome, rather than individual strains of microbes whose maintenance is much more volatile [13]. As a result, a narrowing of organismal diversity may also lead to a loss of components of the metagenome, inducing possible deficits in functionality. Since there is great variation in the composition of the microbiota at lower phylogenetic levels, and significant gaps in our knowledge of the specific function of many strains, ‘dysbiosis’ of the microbiota is sometimes difficult to define and is contextual to the individual and their current state of health. Indeed it has been shown that the glycemic response to any particular nutritional input is unique to the individual and dependent upon the microbiota [14]. This study shows that although we have begun to understand how the host, their diet and their associated microbiota work together to influence health, the details appear to be quite complex and individualized. A microbiota that is ‘dysbiotic’ in one individual may be perfectly healthy in the context of different behavior and genetic predisposition. Without a more fundamental understanding of the core metagenome and how it affects health ubiquitously and comprehensively, describing ‘dysbiosis’ is a difficult task. Therefore, while it is undeniable that the microbiota can shift into states that promote inflammation, (thereby meeting the definition of dysbiosis) whether these states are universal is not clear, and thus we will forgo use of the term dysbiosis, in favor of describing those configurations of the microbiota associated to disease. The microbiome impacts multiple organ systems, including host immunity. The immune system is responsible for maintaining tissue homeostasis in the intestines as it must remain vigilant against invasive microbes while limiting overt inflammatory responses against the vast array of benign organisms that make up the microbiota [15]. To maintain this perilous relationship with the microbiota, the host has developed a series of immune mechanisms that severely limit and regulate the interaction between intestinal epithelia and the microorganisms that reside within the lumen [16]. This series of ‘checks and balances’ is absolutely critical to host health, because a breakdown of the intestine’s barrier function and immune homeostasis can contribute to inflammatory bowel disease (IBD) in addition to many other chronic diseases [6, 7, 17–19]. The host has also evolved multiple products that foster a healthy and diverse microbiota, including the secretion of IgA and bile acids and the fucosylation of the intestinal epithelium [20–22]. The exact mechanisms of these host factors in shaping the microbiota are not clear but are complex in that they both limit growth of some bacteria while benefiting others and are therefore part of a larger effort to maintain health in the microbiome [23]. There are multiple ways in which the immune system surveys the microbiota to detect alterations. One of the primary ways is through tonic sensation via innate immune pattern recognition receptors. Indeed, steady-state innate immune signaling via specific components of Bacteroides spp. have been shown to assist the development of a healthy immune system and antagonize the development of autoinflammatory disorders, such as asthma [24–26]. However, we now understand that the immune system also measures ‘keystone’ metabolites to determine the presence of a functional microbiota. This idea has been best demonstrated by several studies showing that Short-Chain Fatty Acids (SCFAs), which are metabolites derived from the microbiota-dependent breakdown of dietary fiber and are a key energy source for enterocytes, support immune homeostasis in the gastrointestinal tract. Specifically, SCFAs promote the induction and maintenance of regulatory Foxp3+ T cells (Tregs) in the colon and can limit experimentally induced colitis [27–29]. Critically, SCFA can also act systemically, leading to the diminishment of innate cell responses and pathology in a model of asthma [30, 31]. Similarly, a vitamin A metabolite, retinoic acid, whose production has been shown to be partly controlled by the microbiota, also supports immune function in a multitude of ways [32]. Microbiota-derived metabolites have also been shown to modulate the immune response through activation of the inflammasome and the production of IL-18 and anti-microbial peptides from enteric cells [33]. In addition to sensing of microbe-associated molecular patterns (MAMPs) and keystone metabolites, immune cells themselves rely on different metabolites as energy sources for their growth and survival. The most pertinent example of this idea is the preference of adipose tissue and fat metabolism for regulatory T cells (Tregs) and M2 anti-inflammatory macrophages that, as will be discussed in detail, may be critical to the etiology of metabolic syndrome [34]. As the microbiota affects the availability and absorption of nutrients via both their own enzymatic capabilities, and the modification of host products such as bile acids; this is an important and often overlooked effect of the microbiota on the development of disease [35]. THE MICROBIOTA AND CHRONIC DISEASES OF THE MUCOSA The intestine is home to the largest and most metabolically active microbial community in the human body. Therefore, it is perhaps unsurprising that the predominant inflammatory diseases of the gut, Crohn’s Disease (CD) and Ulcerative Colitis (UC) are intertwined with shifts in the microbiota. In both diseases, inflammatory immune responses in the intestine against the microbiota induce shifts towards more aggressive members of the population. The most salient example of this effect is the outgrowth of gram negative Proteobacteria, in particular the family Enterobacteriaceae in a subset of patients with IBD [3]. CD specifically has been associated with the outgrowth of opportunistic ‘Adherent-Invasive’ E. coli that can complicate the disease [36]. Additionally, IBD is also associated with a loss of benign gram positive Clostridia, such as Faecalbacterium prausnitzii, which are associated with health and the provision of metabolites such as SCFA from food [37]. Multiple animal models now show that a transmissible microbiota can predispose to IBD susceptibility [38, 39]. However, given the inconsistent efficacy of fecal transplant and antibiotic treatment for IBD it would be a significant overstatement to suggest that the microbiota is sufficient to induce the disease [19, 40–42]. One view on the etiology of these diseases is that barrier and immune dysfunction leads to an outgrowth of those organisms capable of withstanding the intestinal inflammatory response [43]. Indeed, blooms of E. coli are enabled by their ability to use inflammatory nitrogenous compounds as metabolites [44]. Unfortunately, the modules associated with survival in inflamed environments tend to be found in organisms with invasive capabilities and the outgrowth of these organisms lead to a further exacerbation of immune activation and inflammation [45–47]. For example, Clostridium difficile infection is a common complication of patients with IBD [48]. It stands to reason that the most inflammatory organisms are more likely to induce an IgA antibody response in the intestine [49]. Thus the fact that the IgA bound fraction of intestinal bacteria from IBD patients is sufficient to predispose to disease in a mouse model is excellent evidence for the hypothesis that a shift to an inflammatory configuration contributes to development of the disease [50]. However, interestingly none of the organisms discussed above was enriched in the IgA bound fraction of bacteria from IBD patients, and there was no ‘core’ IgA-bound microbiome, perhaps indicating that a loss of diversity in the ‘core’ microbiome in general is more important than the outgrowth of any particular organism. The model for chronic inflammation at barrier sites, wherein genetic predisposition, immune-driven inflammation and an altered microbiota combine to drive disease, is not unique to the intestine. One clear example is Cystic Fibrosis where defective salt transport leads to thickened mucus, reduced function in lung phagocytes and disrupted mucociliary transport, which allows for the overgrowth of Proteobacteria on all of the patient’s mucosal surfaces, most notably their lungs, leading to chronic inflammation and damage to the alveoli [51]. In addition, Atopic Dermatitis is associated with immune responses against Staphylococcus, explaining perhaps why antibacterial wraps are effective in combating severe cases [52]. THE MICROBIOTA, OBESITY AND METABOLIC SYNDROME Obesity and associated pathologies, including Type II Diabetes (T2D) and dyslipidemia, are a worldwide epidemic and affect an increasing number of people each year. The mechanism of T2D is now believed to be a block in insulin signaling driven by inflammatory cytokines [53]. In lean individuals, the fat is dominated by M2 macrophages, eosinophils, group 2 innate lymphoid cells and Tregs, all of which contribute in their own way to adipose tissue homeostasis [34]. In obese individuals, the adipose tissue is profoundly altered as it becomes invaded by inflammatory M1 macrophages that secrete large amounts of TNFα, IL-1β and IL-6, all of which contribute to an inhibition of PI3K/Akt signaling downstream of the insulin receptor [54]. Blockade of these inflammatory cytokines has shown modest efficacy in restoring insulin sensitivity in these patients, providing further support for this hypothesis [53]. Thus T2D is a metabolic disease whose symptoms are driven by alterations to the immune response, and identifying the underlying stressor would be of tremendous benefit to the development of novel therapeutics. It is undeniable that in most cases, the primary cause of these diseases is increased access to high calorie foods, in particular foods high in fat and simple sugars. Gordon and colleagues have now established that obesity is also associated with a configuration of the microbiota that has an increased fraction of Firmicutes, reduced Bacteroidetes, and is capable of providing additional calories to the host for a given caloric intake [5] (Figure 1). Interestingly, the obese microbiota is both a symptom and a contributor to disease, as transfer of this microbiota to germ-free mice leads to significant increases in adiposity in recipients [55]. Building from these studies, it has been demonstrated that the microbiota of obese patients actually produces significantly less SCFA than that of lean identical twins [56]. Whether these SCFAs are contributing to regulation of inflammation via dampening of the immune response through Tregs and innate immune cells, or via regulating other aspects of metabolism or satiety is not entirely clear, but will be an important area for future research. The microbiota can also block adiposity. Indeed, an additional finding of these studies is that gnotobiotic mice transplanted with the microbiota of obese patients can be invaded by a healthy “lean microbiota”, if the mice are placed on a standard diet low in fat [56]. As well, the presence of mucinophilic bacteria, Akkermansia muciniphila, has been associated with a reduction of inflammation and protection from T2D, in mouse models [57, 58] (Figure 1). Therefore, while the microbiota of patients with obesity resists weight loss, it is amenable to change and as such may represent a potential target for treatment. Beyond nutrient provision, the microbiota can also directly contribute to inflammatory cytokine expression at the core of T2D, via activation of the immune system. In mouse models, this has been clearly shown by the phenotype of TLR5 knockout mice. TLR5 knockout mice show a strikingly increased adiposity, insulin resistance and inflammatory cytokine production, while raised on standard mouse chow [59]. TLR5 is the innate immune receptor for bacterial flagellin, and mice deficient in this receptor have significantly increased populations of Enterobacteriaceae that can transmit many of the phenotypes in wild-type mice via fecal transfer [60] (Figure 1). Interestingly, the outgrowth of Enterobacteriaceae has also been associated with obesity and T2D in humans, though this finding is confounded by the effects of the diabetes medication, metformin [4, 61]. Much like CD, obesity, though not metabolic syndrome specifically, is correlated with reduced microbial diversity [62, 63]. Therefore, a shift towards a more invasive and inflammatory microbiota that induces changes to the immune milieu of the adipose compartment from M2 to M1 macrophage may contribute to the development of metabolic syndrome [64]. Indeed, a number of studies have linked obesity with a ‘leaky gut’, as measured by an increase in serum LPS, and increased intestinal adherence of Enterobacteriaceae [18, 65, 66]. In animal models, provision of a high fat diet and associated affects on the microbiota are sufficient to induce a significant increase in IFNγ expressing Th1 T cells in the small intestine which may traffic to associated adipose depots and directly affect inflammation [67]. The exact mechanism of Proteobacteria outgrowth in obesity and T2D remains unknown and will be an important area for future research. The effect of the microbiota on metabolic disease has also been demonstrated by experiments on animal models of liver disease and cirrhosis. The liver, via the hepatic portal vein, is directly downstream of the small intestine and acts as a barrier to the further trafficking of microbiota-derived products [68]. Mice deficient in components of the inflammasome harbor an altered microbiota with inflammatory potential [69]. When these animals are placed on specific diets associated with non-alcoholic steatohepatitis (NASH) their disease is pronounced and transmissible via the microbiota to co-housed animals [17]. Increased liver damage is dependent upon TLR signaling and TNFα production, and is associated with heightened presence of TLR ligands in the hepatic portal vein. Similar phenomena involving increased translocation of bacterial products may also contribute to other forms of cirrhosis due to alcohol abuse or as a complication of Cystic Fibrosis [70–72]. The microbiota and the immune system may also contribute to dyslipidemia and the cellular composition of the adipose tissue in a metabolically important way. The fat depots exists in at least two distinct states: (i) ‘white’ which functions to store energy, and (ii) brown/beige fat, which is critical for thermogenesis. Brown fat is present at birth, whereas beige fat develops later in life [73]. Instead of storing energy, beige adipocytes metabolize lipids rapidly to create heat and therefore is typically inversely correlated with adiposity throughout the body [74]. Interestingly, the presence of beige fat is supported directly via the local production of IL-4, IL-13, IL-25 and IL-33 from innate lymphoid cells, eosinophils, macrophages and stroma [75–77]. Since inflammation causes such a switch from from M2 to M1 immune cells downstream effects on adipocytes may explain with it is so detrimental to metabolic health. The microbiota does seem to also play a role in the decision to switch on a transcriptional program associated with brown fat in white adipose tissue, in murine models of hypothermia, where fat ‘beiges’ for heat production. Interestingly, the transfer of the microbiota from hypothermic mice is sufficient to induce beige fat in the transplant recipient [78, 79]. However, in this context, it is unclear whether the mechanism of hypothermic beiging is associated with immune cytokine production and adipose tissue inflammatory state. THE MICROBIOTA AND CARDIOVASCULAR DISEASE Cardiovascular disease (CVD) and in particular atherosclerosis is the most common cause of death in high-income countries. The root cause of atherosclerosis is blockages in coronary arteries, which is caused by plaques formed of fat deposits and the development of fat laden macrophages called foam cells. Development of atherosclerosis has long been associated with diets high in animal fats, cholesterol and red meat. Recently, Hazen and colleagues have identified that a chemical derivative of red meat, trimethylamine-N-oxide (TMAO) is a significantly more reliable indicator of risk for CVD than cholesterol, and may drive disease by effects on platelets [80, 81]. TMAO is the product of the bacterial breakdown of meat-derived compounds such as L-carnitine and choline, and the microbiota is absolutely necessary for its production, as germ-free mice are free of TMAO, even when fed a diet high in choline [82]. Plasma levels of TMAO can be correlated with specific taxa of the microbiota, but it will only be through a better understanding of the metagenome of patients suffering CVD that we will be able to understand if there is a particular configuration of the microbiome that contributes to CVD [83]. It is possible that the process of converting compounds to TMAO has some benefit for the microbes that carry it out, and that these organisms would be selected for by a diet high in meat. Indeed, the microbiome of vegans has a significantly reduced ability to convert L-carnitine to TMAO [83]. Chronic HIV infection provides another example of a human disease in which CVD risk is elevated, with a possible contributory role for the gut microbiota. HIV-infected subjects exhibit multiple metabolic symptoms, but critically, a significant increase in the incidence of CVD [84]. HIV infection is associated with an increased abundance of invasive, pro-inflammatory Proteobacteria in the gut microbiota including Enterobacteriaceae, along with a depletion of members of the SCFA-producing Clostridia clade; a microbial profile that superficially resembles that of IBD [85–87]. Possibly related to this shift in the microbiota, HIV-infected subjects also exhibit impaired mucosal barrier function, translocation of microbial products into systemic circulation, and increased markers of innate immune activation associated with risk for the development of CVD [88]. Indeed, the degree to which the HIV-associated gut microbiota profile is observed correlates with markers of circulating LPS as well as inflammatory biomarkers of CVD risk [85, 87, 89–91]. CVD may also be associated with shifts in the oral microbiota. Human periodontitis is characterized by an altered and expanded oral bacterial community [92]. In periodontitis patients, markers of systemic exposure to periodontal bacteria are elevated and correlated with increased risk of CVD across several cohorts [93, 94]. Indeed, mouse models reveal that atherogenesis is accelerated by oral colonization with the periodontitis-associated bacterium, Porphyromonas gingivalis and DNA from oral bacteria has been found in atherosclerotic plaques in mice and humans [95–97]. MODERN LIFE AND CHANGING HOST/MICROBIOTA RELATIONSHIPS As discussed, a multitude of evidence now suggests that shifts in the microbiota towards inflammatory and low diversity states can contribute to chronic disease. One of the primary ways that modern life has changed our relationship with our resident bacteria is the advent of antibiotics. The invention of antibiotics sparked a revolution that fundamentally changed morbidity and mortality associated with bacterial infections. However, it can be argued that antibiotics have been overused as palliatives instead of therapeutics and in agriculture, where they promote rapid weight gain in livestock [98]. Recently, concerns have been raised that the increased use of antibiotics may be contributing to the rise of metabolic syndrome [11]. Essentially, this hypothesis posits that the same effect that induces increased size in cows and pigs is acting on children via constitutive exposure to trace antibiotics present in meat and milk, and early-life administration to combat infection. In support of this idea, mice fed low dose antibiotics early in life grow 10% larger, and the difference is largely due to increases in adipose tissue [99, 100]. These differences in growth could be transferred with the microbiota and seemed to be associated to shifts in the mucosal immune response [100]. Importantly, after cessation of antibiotic treatment, the microbiota, which had deviated significantly from controls, returned to normal, implying that the negative impact of alteration in microbiota can be subsequently sustained by the immune system [100]. Although not formally shown, one might suspect that these immune effects are penetrating beyond the gastrointestinal compartment and acting upon adipose tissue homeostasis. It is not well understood why the microbiota that is resistant to β lactam antibiotics [100], would be more inflammatory and prone to the induction of metabolic issues. One intriguing possibility is that the most inflammatory members of the microbiota tend to be ‘successful colonizers’ with broad host ranges requiring genetic adaptability and therefore may be more accepting to horizontal gene transfer such as antibiotic resistance. Indeed, it has been shown that Enterobacteriaceae of different genera exchange plasmids at a very high rate in vivo under inflammatory conditions [101]. Another fundamental way that those in high-income countries may have developed altered relationship to the microbiota is through diet and exercise. Our ancestors likely ate diets high in fibrous plant material, and had limited access to the saturated fat and simple sugars that represent today the majority of calories in the ‘Western’ diet. As has already been discussed in this review, the Western diet can lead to metabolic syndrome and obesity and these effects are in part due to shifts in the microbiota that control nutrient uptake and inflammation in the adipose tissue. In addition, the western lifestyle, which tends to less physical activity contributes to shifts in the microbiota as well [102]. Western diets might be also selecting away from those organisms that are more closely adapted to the mammalian gut and dependent upon complex carbohydrates [103]. For example, the breakdown of complex carbohydrates to SCFA requires a cascade of enzymes that are not always present in a single organism and can require the cooperation of an ecological community [12]. The Western diet, taken to extremes, presents a situation where there is no selection for cooperative breakdown of complex molecules and only competition for simple sugars and energy rich fats. One could hypothesize that this situation would benefit the more aggressive and inflammatory members of the microbiota, in particular, Proteobacteria, who can divide in as little as twenty minutes and rely heavily on mono and disaccharides as carbon sources [104], and select against organisms that prefer complex carbohydrates as a carbon source. For example, a diet high in milk fat has been shown to favor the outgrowth of Deltaproteobacteria and predispose to significantly exacerbated disease in the IL-10 knockout mouse model of IBD [20]. Thus, the western diet may not only shift the microbiota towards increased provision of calories, but also may benefit those organisms that are least symbiotic and prone to inflammatory outgrowth. Worldwide urban life amongst millions of other human beings is a modern construction that we have not evolved to deal with. One of the primary ways that life has changed because of urbanization is infection. As opposed to our ancestors, who were beset by chronic parasitic infections and intermittent outbreaks of zoonoses [105, 106], our current population sizes and global travel patterns supports multiple endemic pathogens. Fortunately, in the last century the combined efficacy of sanitation, public health, antibiotics and vaccines have largely mitigated the lethal consequences of these pathogens but it is undeniable that the frequency and biological effect of infection has been profoundly changed. A primary example of this effect is the worldwide reduction in enteric helminth infection. Intestinal helminths used to be a ubiquitous of human life, but in high-income countries are now quite rare. ‘De-worming’ has obvious benefits, as infections with high burdens of worms can lead to malnutrition and anemia [107]. However, our immune system evolved in the context of exposure to these organisms and as a part of the ‘Hygiene Hypothesis’ their absence is believed to contribute to the rise of CID [108, 109]. Multiple findings in animal models have shown that co-infection with helminthes can affect the immune system both systemically and locally at the mucosal surface [110]. For example, helminth infection can support the production of Tregs at mucosal surfaces, which may prevent the development of food allergy and temper the immune response to viruses via shifting from type I to type II immunity, limiting immunopathology and aiding the healing process [111, 112]. Helminth infection can also promote immunoregulation via induction of increased SCFA production from the microbiota [113]. Animal models of IBD and chronic diarrhea have shown that transient helminth infection may represent an effective treatment [114, 115]. Trials in human patients with UC have been promising, but the identification of the products that drive regulatory immune functions is critical, because infection with live worms present obvious limitations [116]. Additionally, identifying direct host affects from those that act through the microbiota could also assist in developing the most effective therapeutics. Although improved sanitation has reduced the incidence of enteric infections, they remain a significant burden in high-income countries. For instance, the average child in North America will experience ten diarrheal episodes by their 5th birthday and children in low-income countries are exposed to an even higher number of enteric infections [117, 118] Enteric infection poses an issue for the mucosal immune system, because the microbiota and inciting organisms are not always easily discriminated and it has been hypothesized that infections could be triggering events for CID [119]. Indeed, in many cases bacterial pathogenicity is contextual to the complex relationship between the bacteria, the host and the microbiota. Multiple laboratories have now shown that infection causes a significant shift in the microbiota and in general, these shifts mimic those seen in IBD, characterized by increases in Proteobacteria, specifically Enterobacteriaceae, and a depletion of Firmicutes [45–47, 120]. Given that many enteric infections belong to the same phylogenetic groups as prominent members of the microbiota, a critical question is how the immune system discriminates between opportunistic members of the microbiota and the initiating infectious organism. This is made all the more difficult by the fact that many infections break the epithelial barrier leading to translocation of the microbiota into the host [47, 121, 122]. Recent work indicates that the immune system does not discriminate between the microbiota and the infectious organism and activates microbiota-specific T cells in a comparable manner to those specific to the pathogen [123]. How these microbiota-specific T cells are maintained long-term and possibly contribute to chronic disease is an active area of new research. Infection with enteric pathogens such as Yersinia pseudotuberculosis can also cause damage and induce ‘immunological scarring’, which can chronically affect homeostatic intestinal immune responses by deviating lymphatic traffic away from the lymph nodes and into the fat [124]. Fascinatingly, oral Yersinia infection is also associated to chronic pro-inflammatory shifts in the microbiota, possibly indicating a link with immunological scarring [125]. As well, it is interesting to consider whether this kind of atypical traffic of myeloid cells activated at barrier surfaces into adipose depots is somehow contributing to metabolic disease and IBD. Indeed, CD is characterized by the ‘wrapping’ of the gut with creeping fat, the presence of bacteria within the adipose tissue and the production of inflammatory adipokines [126, 127]. Thus taken together, these three effects of infection; shifts in the microbiota towards more inflammatory organisms, microbiota-specific memory, and immunological scarring, provides a framework within which current or cleared infections can act as the inciting event of a CID [119]. An example in which one or more of these microbiota-dependent factors may be acting, is Environmental Enteropathy (EE) in children. EE is a disease that is prevalent in sub-Saharan Africa and parts of the Indian subcontinent wherein malnutrition and poor sanitation allow for chronic infection leading to a malabsorption syndrome [128]. Recent studies have identified that Enterobacteriaceae and subsequent anti-microbiota immune responses are critical players in the etiology this disease [129, 130]. Fascinatingly, it took two years after restoration of a healthy diet and abatement of chronic enteric infection, for patients with EE to experience full restoration of intestinal absorption, implying that either immune memory against the microbiota and immunological scarring could be maintaining the phenotype [131]. CONCLUDING REMARKS AND FUTURE PERSPECTIVES It is now clear that the microbiota acts as a genetically distinct organ that is critical for the enzymatic digestion of food, promotion of immune homeostasis and prevention of enteric infection. Just like the host-derived organs of the body, the microbiota can be damaged, or, as commonly described, become dysbiotic, leading to a negative impact on dependent host systems. Alterations to the microbiota can certainly contribute to pathology and in cases where these changes include the outgrowth of opportunistic and innately inflammatory bacteria, complicate many diseases (see ‘Outstanding Questions’ and Figure 2). Many studies on the microbiota describe associations to a disease state, and lack clear causative mechanisms. Thus, in order to achieve experimental control, many microbiota studies are carried out in inbred mouse models, which lack both genetic diversity and life history that would fundamentally shape the interaction between the immune system and the microbiota. Additionally, experiments done in germ-free and antibiotic treated mice can be complicated by defects in immune development. This is important because a patient’s history of infection, pathology and treatment may also be critical to understanding their current disease state. Going forward, it is only through a more holistic understanding of the individualized genetic (host and microbial) and environmental triggers of complex diseases that we will be able to cure them. The authors would like to apologize that due to length requirements, not all work in this burgeoning field could be discussed and properly cited. This work was supported by NIAID K22 AI108719 (T.W.H) and the NIH intramural program (V.K.R, I.V-C and Y.B.). The authors would like to thank K. Gopalakrishna and J. Tometich for critical reading of the manuscript. Figure 1 The microbiota affects metabolic syndrome via the immune system a) Obesity is associated with an increase in Firmicutes and a decrease in Bacteroidetes. Firmicutes provide an increased amount of calories to the host by increased harvest of energy from the diet. b) Outgrowth of Proteobacteria is associated with metabolic syndrome and has been shown to increase the frequency of IFNγ-producing T cells in the host, which in turn is associated with increased concentrations of serum LPS. Serum LPS and IFNγ may then drive the development of pro-inflammatory M1 macrophages in the adipose tissue. M1 macrophages express significantly higher amounts of TNFα and IL-1β than the resident M2 macrophages of the gut, and both cytokines contribute to insulin resistance. Beige adipose cells further contribute to health by metabolizing lipids to heat instead of storing them and are supported directly and indirectly by the cytokines IL-4, IL-13, IL-25 and IL-33. c) Mucophilic bacteria Akkermansia combat many of the effects of Proteobacteria outgrowth, including IFNγ production, and can alleviate symptoms associated with metabolic syndrome in animal models. Figure 2 Potential linkages between the environment, microbiota, immune system and chronic inflammatory disease At homeostasis, the microbiota assists the host in converting the diet into metabolites that foster a healthy host/microbiota relationship. These metabolites bolster the barrier between the host and the microbiota, preventing systemic immunity and inflammation. Disruption of the microbiota due to environmental factors (such as diet, infection, antibiotics etc.) or host factors can lead to a narrowing of microbial diversity and a shift in the metabolites derived from the microbiota. Shifts in this relationship can also lead to increased invasion of host tissue by bacteria and bacterial products. Together, a shift in metabolites and increased translocation of microbial products is believed to contribute to immune activation at the core of chronic inflammatory disease (IBD = Inflammatory Bowel Disease; CVD = Cardiovascular Disease; T2D = Type II Diabetes; NASH/NAFLD = Non-alcoholic Steatohepatitis/Non-alcoholic Fatty Liver Disease). OUTSTANDING QUESTIONS Can we define a core metagenome that is associated with health and conversely deficient metagenomes that are dysbiotic in all hosts? Alternatively, is a healthy metagenome also contextual to host genetics and environment and shifting temporally? Can we define those aspects of modern living that are contributing to the increase in chronic inflammatory disease via induction of shifts in the microbiota? Is infection a trigger for chronic inflammatory disease via the modification of the microbiota/host relationship? If the microbiota is a critical contributor to disease, can we modify the microbiota with pre and probiotics to alleviate symptoms exacerbated by inflammatory organisms? If the immune response is critical, can we modulate the immune response downstream of the microbiota to modulate disease phenotypes? Can we catalog the microbiota-derived metabolites that affect the immune response and understand how the balance of these metabolites may allow for assessment of the health of the host/microbiome relationship. Shifts in the microbiota, such as those induced by early life antibiotic use, seem to have a systemic immune memory. Can these ‘memory’ factors be defined and more importantly, can we intervene, to prevent long-term health impacts TRENDS BOX Chronic inflammatory disease is associated with shifts in the microbiota; often towards reduced diversity and increased inflammatory character The immune system can identify shifts in the microbiota both by direct interaction with bacteria in addition to ‘sensing’ of microbiota-derived metabolites Immune activation associated with shifts in the microbiota can have far-reaching systemic effects and contribute to disease The incidence in chronic disease is on the rise and has been linked to a number of environmental factors, including antibiotic use, diet and infection. There is evidence that these factors act on the host via shifting the microbiota This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final citable form. 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PMC005xxxxxx/PMC5116296.txt
LICENSE: This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. 0406041 4668 J Comp Neurol J. Comp. Neurol. The Journal of comparative neurology 0021-9967 1096-9861 27199256 5116296 10.1002/cne.24041 NIHMS788089 Article Patterns of cell death in the perinatal mouse forebrain Mosley Morgan 1 Shah Charisma 1 Morse Kiriana A. 2 Miloro Stephen A. 2 Holmes Melissa M. 3 Ahern Todd H. 2* Forger Nancy G. 1* 1 Neuroscience Institute, Georgia State University, Atlanta, GA 30302 2 Department of Psychology, Center for Behavioral Neuroscience, Quinnipiac University, Hamden, CT 06518 3 Department of Psychology, University of Toronto, Mississauga, Ontario L5L 1C6 * Co-Corresponding authors: Nancy G. Forger, Neuroscience Institute, Georgia State University, Atlanta, GA 30302, Phone: (404) 413-5888, nforger@gsu.edu, Todd. H. Ahern, Department of Psychology, Center for Behavioral Neuroscience, Quinnipiac University, Hamden, CT 06518, todd.ahern@quinnipiac.edu 2 6 2016 13 6 2016 1 1 2017 01 1 2018 525 1 4764 This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. The importance of cell death in brain development has long been appreciated, but many basic questions remain, such as what initiates or terminates the cell death period. One obstacle has been the lack of quantitative data defining exactly when cell death occurs. We recently created a “cell death atlas,” using the detection of activated caspase-3 (AC3) to quantify apoptosis in the postnatal mouse ventral forebrain and hypothalamus, and found that the highest rates of cell death were seen at the earliest postnatal ages in most regions. Here we have extended these analyses to prenatal ages and additional brain regions. We quantified cell death in 16 forebrain regions across nine perinatal ages from embryonic day (E) 17 to postnatal day (P) 11 and find that cell death peaks just after birth in most regions. We find greater cell death in several regions in offspring delivered vaginally on the day of parturition compared to those of the same post-conception age but still in utero at the time of collection. We also find massive cell death in the oriens layer of the hippocampus on P1, and in regions surrounding the anterior crossing of the corpus callosum on E18, as well as the persistence of large numbers of cells in those regions in adult mice lacking the pro-death Bax gene. Together, these findings suggest that birth may be an important trigger of neuronal cell death, and identify transient cell groups that may undergo wholesale elimination perinatally. Graphical Abstract Activated caspase-3 cell death brain development hypothalamus hippocampus nucleus accumbens bed nucleus of the stria terminalis oriens cingulate RRID:AB_231409 RRID:AB_2109645 RRID:AB_2314667 RRID:AB_2298772 Introduction Two waves of cell death shape normal mammalian brain development. The first is confined to the ventricular and subventricular proliferative zones, and eliminates many neural precursor cells within hours of their birth (Blaschke et al., 1996; 1998; Thomaidou et al., 1997; Kuan et al., 2000). The second wave, known as “post-mitotic cell death,” occurs throughout the brain and eliminates roughly 50% of the neurons that have migrated, differentiated, and begun to make axonal connections (Oppenheim et al., 1985; Buss et al., 2006). Post-mitotic cell death sculpts developing circuits, contributes to sex differences in neuronal cell number (Forger, 2009), and may identify a window of vulnerability during which exposure to injuries, infections, or variations in environmental factors have greatest impact (McDonald et al., 1988; Ikonomidou et al., 1989, 1999; Yakovlev et al., 2001; Olney, 2002). Although the importance of cell death in neural development has been appreciated for decades, many surprisingly basic questions remain (see Yamaguchi and Miura, 2015 for a recent review). For the most part, we still do not know what initiates the cell death period, what terminates it, or what accounts for the large regional differences in the magnitude of cell death in the developing brain. The classical view, that developmental neuronal cell death is a cell suicide program triggered by a lack of trophic factors (Purves, 1988; Barde, 1989; Burek and Oppenheim, 1996), is best supported for neurons with axonal connections in the periphery (i.e., motoneurons and ganglion cells), but less well established for the brain. The death of interneurons in the cerebral cortex, for example, may be intrinsically determined (i.e., independent of trophic factors; Southwell et al., 2012), and non-neuronal cells such as microglia may kill otherwise viable neurons in some developing brain regions (e.g., Marin-Teva et al. 2004, Wakselman et al. 2008). One obstacle to resolving basic questions about neuronal cell death is that, with the exception of a few well-studied regions (e.g., cerebellum, substantia nigra pars compacta, and some cortical regions; Jackson-Lewis et al., 2000; Verney et al., 2000; Stankovski et al., 2007; Cheng et al., 2011), systematic data on the timing and magnitude of postmitotic cell death in the mammalian brain has been lacking. We recently addressed this by creating a “cell death atlas of the postnatal mouse brain” (Ahern et al., 2013), comprising brains of male and female C57BL/6 mice collected during the first two postnatal weeks. Postmitotic neuronal cell death is crucially controlled by members of the Bcl-2 family of proteins (Yuan and Yankner, 2000; Roth and D’Sa, 2001), and culminates in the activation of caspases, including caspase-3 (Porter and Jänicke, 1999; Hengartner, 2000). Using immunohistochemical detection of activated caspase-3 (AC3) to detect dying cells, we found the highest density of cell death in the ventral forebrain and hypothalamus at the earliest age(s) examined (postnatal day (P)1 to P3; Ahern et al., 2013). This raised the possibility that “peak” cell death actually occurs earlier – i.e., at P0 or prenatally. Here we examined this possibility by extending the cell death atlas to earlier ages. In addition, we present both pre- and postnatal cell death data from brain regions not included in the previous study. We find that AC3 cell number is very low in most forebrain regions at embryonic day (E)17 and increases over the next few days, with remarkably steep rises in some areas. In most regions examined, the highest rates of cell death are observed just after birth. We also identify several forebrain regions with intense accumulations of AC3-positive cells perinatally, and confirm an excess of neurons in these regions in adult mice lacking the pro-death gene Bax. Taken together, these findings clearly define the period of post-mitotic cell death in many regions of the mouse forebrain, suggest a possible role for parturition in triggering neuronal cell death, and point to the perinatal elimination of several transient cell groups. Materials and Methods Mouse Breeding and Collection of Brains, E17 – P1 Methods throughout followed as closely as possible those used in the generation of the postnatal cell death atlas (Ahern et al., 2013). Wildtype C57BL/6J mice purchased from The Jackson Laboratory (Bar Harbor, Maine) were housed in a 12:12 light:dark cycle (lights on at 0600 h) at 22°C with food and water available ad libitum. All procedures were in accordance with National Institutes of Health animal welfare guidelines and approved by the Georgia State University Institutional Animal Care and Use Committee. The forebrain regions studied here differentiate as discernable nuclei between E15 - E17 in the mouse (Niimi et al., 1962; Creps, 1974; Henderson et al., 1999). We therefore collected brains on E17, E18, E19/P0 and P1, including a one-day overlap with the postnatal atlas (Ahern et al., 2013) to allow us to calibrate our counts with those reported previously. To generate timed pregnancies, males and females were paired overnight. The males were removed the following morning at ~0900 hours and females checked for sperm plugs; this was designated day E0. Both male and female offspring from a total of 17 litters were collected. All fetuses/pups were collected at the same time of day (between 1400–1500 h), and pups from at least three different litters were used for each time point with the exception of E17 (two litters). Fetuses collected on E17 and E18 were removed by Cesarean (C) section after briefly exposing the dam to CO2 (< 1 minute). Fetuses are refractory to CO2 exposure and are relatively unaffected by such short exposure times (Leary, 2013; Pritchett et al., 2005). A large incision was made in the dam’s ventral midline, fetuses were extruded from the uterine horns, and all brains collected within 10 minutes. At the time of collection on the 19th day after conception, some offspring had been born vaginally earlier that day, whereas others were still in utero and were delivered by C-section. In the analyses below, we refer to the combined group as “E19/P0.” When examined separately, the C-sectioned group is referred to as “E19” and the vaginally-born group as “P0.” All pups collected on P1 had been vaginally delivered on day 19 (P0). Fetuses and neonates of both sexes were rapidly decapitated, and brains removed and fixed overnight in 5% acrolein (Alfa Aesar, Ward Hill, MA) in 0.1M phosphate buffer (PB). The tissue was then transferred to 30% sucrose in 0.1M PB and stored at 4°C. Two series of 40µm coronal sections were collected, placed in cryoprotectant (30% sucrose, 1% polyvinylpyrrolidone, 30% ethylene glycol in 0.1M PB), and stored at −20°C until use. Previously Generated Material Postnatal Cell Death Atlas We collected new data from the previously generated postnatal atlas material (Ahern et al., 2013), including data from five hippocampal regions and the core and shell of the nucleus accumbens. In addition, some data from the postnatal cell death atlas that were published previously (Ahern et al., 2013) are reprinted below along with the expanded age range. The previously published data are clearly indicated as such in the figures. Bax +/+ and Bax −/− brains Bax is a pro-death member of the Bcl-2 protein family that is required for the death of developing neurons; virtually all naturally-occurring neuronal cell death is eliminated in mice with a targeted disruption of the Bax gene (White et al., 1998; Ahern et al., 2013). The Bax +/+ and Bax −/− brains examined in this study were drawn from previously collected brains of Bax knockout mice and their wildtype siblings (Forger et al., 2004; Holmes et al., 2009). The Bax deletion was on a C57BL/6 background and mice were adult at the time of sacrifice. For thionin-stained sections, animals were intracardially perfused with formalin, and brains were frozen sectioned at 30µm. For immunocytochemistry, animals were perfused with 4% paraformaldehyde and frozen sectioned at 30µm. Immunohistochemistry Alternate sections from all perinatal animals were immunohistochemically stained for AC3, closely following the protocol of Ahern et al. (2013). Free-floating sections were extensively rinsed in 1X Tris-buffered saline (TBS; pH 7.6), and immersed in 0.05M sodium citrate for 30 minutes. Sections were again rinsed, transferred to 0.1M glycine in 1X TBS for 30 minutes, rinsed, then incubated in a concentrated blocking solution (1X TBS, 20% normal goat serum, 1% hydrogen peroxide, 0.3% Triton-X). Sections were incubated overnight in primary antibody solution (Cleaved Caspase-3, RRID:AB_231409, Cell Signaling, Danvers, MA; 1:20,000 in 1XTBS, 2% normal goat serum, 0.3% Triton), then washed in a dilute blocking solution (1X TBS, 1% normal goat serum, 0.02% Triton-X), incubated for one hour in secondary antibody solution (goat anti-rabbit (Vector Laboratories, Burlingame, CA; 1:250, 1X TBS, 2% normal goat serum, 0.3% Triton-X), followed by rinses in 1X TBS with 0.2% Triton-X, before incubating for one hour in an ABC solution (Vectastain Elite ABC Kit, Vector Laboratories). Reagent A and B of the ABC kit were added to 1X TBS at a dilution of 0.8% based on pilot optimization runs. Sections were incubated for 2–5 minutes in diaminobenzidine-nickel (DAB) solution (Vector Laboratories), followed by rinses in 1X TBS. Sections were mounted onto microscope slides and counterstained with thionin. We also used immunohistochemical detection of the microglial marker, ionized calcium-binding adaptor molecule 1 (Iba1), to examine the distribution of microglia in a subset of animals on E18. Activated microglia with an amoeboid morphology are responsible for the phagocytosis of cell corpses, and accumulate in regions of high cell death (reviewed in Pont-Lezica et al., 2011; Wake et al., 2012). The immunohistochemical procedure followed that described for AC3 above, except that the primary antibody used was anti-Iba1 (RRID:AB_2314667, Wako Chemicals, Osaka, Japan, 1:20,000 in 1X TBS, 2% normal goat serum, 0.3% Triton), and the sodium citrate incubation was increased to one hour. To determine the phenotype of cell groups persisting in Bax −/− mice, we examined Bax+/+ and Bax −/− brains that were processed for double-label immunohistochemistry for NeuN and GFAP, markers of mature neurons and astrocytes, respectively. These brains came from animals in our previous study (Holmes et al., 2009) and were labeled using sequential staining for NeuN [1:1000 mouse anti-NeuN monoclonal antibody (RRID:AB_2298772, Chemicon International, Temecula, CA)] using a DAB reaction (brown reaction product), and GFAP (1:1000 rabbit anti-GFAP polyclonal antibody; RRID:AB_2109645, Chemicon International), using Vector SG (blue reaction product; Vector Laboratories), as described (Holmes et al., 2009). Antibody specificity Details of primary antibodies are given in Table 1. The AC-3 antibody used here recognizes the active fragment of cleaved caspase-3.. It detects a couplet on Western blots of the expected size and does so only when apoptosis-initiating proteases are active (Cheong et al., 2003). It does not cross-react with full-length (inactive) caspase-3 in human or mouse cells (Hu et al., 2000; Sammeta and McClintock, 2010). Moreover, virtually all labeling with this antibody is abolished in the forebrain of newborn mice lacking the pro-death gene Bax (Ahern et al., 2013), supporting its specific detection of dying cells in this material. The specificity of the GFAP antibody was demonstrated in Western blots of rat retina lysate (Chang et al., 2007) where it labeled a band of the expected size (50 kDa); quantification of the labeled band in Western blots also correlated with quantification of immunocytochemical labeling of cells with astrocytic morphology in tissue sections. The Iba1 antibody used here recognizes a single band of 17 kDa on immunoblots, corresponding to the size of Iba1 protein, and does not recognize neurons or astrocytes (Imai et al., 1996; Ito et al., 1998). It has been used extensively as a microglial marker in perinatal mouse brain (e.g., Nilsson et al., 2008; Shrivastava et al., 2012). The mouse monoclonal against neuron-specific nuclear antigen (NeuN) was originally made against cell nuclei purified from mouse brain (Mullen et al., 1992). The antibody does not recognize oligodendrocytes or astrocytes in mouse brain but labels neurons in vivo and in vitro. Western blotting with this antibody shows three bands of 46–48-kDa (Mullen et al., 1992). Digital analysis of AC3-labeled regions of interest All slides were digitally scanned using a NanoZoomer Digital Pathology slide scanner (Hamamatsu Photonics, Bridgewater, NJ) and analyzed using the Aperio ImageScope program (version 12.1.0.5029, Leica Biosystems, Nussloch, Germany) as previously (Ahern et al.; 2013). Digitized slides were coded and analyzed by investigators blind to group membership. We counted AC3+ cells bilaterally in a total of 16 brain regions. Regions were chosen that had clearly identifiable borders at all ages examined. For nine of the regions, AC3+ cells had previously been quantified from P1–P11, and we expanded the age range to E17 here. This included four hypothalamic regions [anteroventral periventricular nucleus (AVPV), medial preoptic nucleus (MPON), paraventricular nucleus (PVN), and suprachiasmatic nucleus (SCN)], the lateral and principal nuclei of the bed nuclei of the stria terminalis (BNSTl, BNSTp), two regions in the amygdala [central amygdala (CeA), and medial amygdala (MeA)], and the lateral septum (LS). In addition, we quantified cell death at nine ages in seven brain regions not previously examined in the postnatal atlas: the core and shell of the nucleus accumbens (NAcc core and NAcc shell) and five hippocampal regions [cornus ammonis (CA)1, CA2/3, CA1 oriens layer, CA2/3 oriens layer, and the dentate gyrus (DG)]. Newly generated data are plotted with solid lines in the figures below, whereas reprinted data are indicated by dotted lines. Most regions were examined in their entirety (i.e., in each section in which they occurred throughout their rostrocaudal extent). For the much larger hippocampal regions, we sampled four sections from the dorsal hippocampus of each animal. In the younger animals (E17-P1) these were four consecutive (alternate) sections, starting with the anterior-most section in which the DG was clearly visible. For older animals with larger hippocampi (~P3–P11), we identified the first section in which the DG was clearly visible (anterior anchor), and the first section in which the lateral extent of the hippocampus begins to dip ventrally (posterior anchor, i.e., Figure 69 in Paxinos et al. 2007); these sections and two additional sections spaced evenly between them were traced and counted. This allowed us to sample approximately the same rostro-caudal extent of the hippocampus in each subject. The NAcc shell could not be distinguished from the NAcc core prior to E18; counts on E17 therefore represent the combined area. An observer blind to the sex or age of the subject traced the outline of each region of interest using Aperio ImageScope, and the cross-sectional area was recorded. Labeled AC3+ cells within the region were counted as in Ahern et al. (2013). The measure “total AC3 cells” is the sum of these counts times two (because alternate sections were processed for AC3 immunohistochemistry). The “density of AC3+ cells” was calculated by dividing the total number of AC3+ cells by the total measured volume of each region, and is expressed as AC3+ cells per mm3. Cell number in the hippocampal oriens of Bax+/+ and Bax−/− mice We quantified the number of cells with a neuronal morphology (large and multipolar) in thionin-stained sections, as well as the number of NeuN+ and GFAP+ cells in immunohistochemically stained sections of the CA1 oriens of adult Bax+/+ and Bax−/− mice (N = 3 of each). Two consecutive sections were counted, and the first section was the most anterior section in which the DG was clearly visible in each animal. Cingulate cortex/indusium griseum and subcallosal sling Two striking clusters of AC3+ cells were visible with the naked eye in AC3-stained sections of late prenatal mice. One was located just dorsal and lateral to the midline crossing of the corpus callosum, in an area approximately corresponding to cingulate cortex area 2/indusium griseum (Cg2/IG; Adamek et al., 1984); the other was just ventral to the corpus callosum and may correspond to the subcallosal sling (Silver et al., 1982). Due to the sheer density of AC3 staining in these two areas, we were unable to individually count labeled cells. Instead, we captured images of the areas and used the thresholding function of ImageJ (Version 1.47; National Institutes of Health) to compare AC3 immunostaining across perinatal ages. The sections analyzed spanned from just anterior to the most rostral crossing of the corpus callosum to the appearance of the forceps major. Each region was outlined in ImageJ and the number of pixels above threshold determined. Threshold was based on background staining of an adjacent brain area with no AC3+ cells and was determined separately for each animal. Total number of pixels above threshold was then divided by the volume sampled, and converted to pixels above threshold per mm3. Photomicrographs For figures including photomicrographs, Adobe Photoshop was used to crop images, adjust brightness, and balance color. Statistical Analysis We included an overlapping day (P1) between analyses performed on the previously generated material (postnatal atlas; Ahern et al., 2013) and the new material (E17-P1), so that we could “calibrate” between the two data sets. Across the 16 brain regions examined, AC3+ cell densities on P1 in the two sets of material were highly correlated, with counts from the previously generated material accounting for 95% of the variance between brain regions in the new material (R2 = 0.95; df = 14, p < 0.0001). The datasets were therefore combined and the values plotted for P1 below represent the P1 animals from both collections. We first performed two-way ANOVAs (sex-by-age) for each brain region. No significant sex differences were found for any of the newly generated data presented here, so counts from males and females were combined and 1-way ANOVAs performed for each brain region. (We note that in the previously published data, there was an effect of sex on AC3+ cell number in the BNSTp only, with more AC3+ cells in females from about P5–P7; Ahern et al., 2013). Planned comparisons using Fisher’s least significant difference were performed only following significant main effects. The number of animals per age group varied from 12 (E17) to 35 (P1; the combined P1 animals from the postnatal atlas and new material). However, a given brain region was not included in the analysis if tissue damage or staining artifacts prevented an accurate count of AC3+ cells. The final median number of animals per age (followed by the range in parentheses) across all brain regions was as follows: E17, 6 (4–12); E18, 9 (6–12); E19/P0, 20 (12–31); P1, 29 (21–35); P3, P5, and P7, 23 (20–24); P9 and P11, 21 (19–22). Two-tailed, independent t-tests were used to compare the number of cells (thioninstained, NeuN+ or GFAP+) in the hippocampal oriens layer of Bax+/+ and Bax−/− mice. Results AC3+ cell density All 16 regions exhibited a significant effect of age on AC3+ cell density between E17-P11 (Table 2). For 13 of the 16 regions, AC3+ cells were very sparse on E17 and increased over the next several days (Figures 1 and 2). Highest AC3+ cell densities were seen between birth and P5, followed by a decline to very low levels in all regions on P9 and P11 (Figure 2). Exceptions to this pattern included the DG, CA1, and PVN: for each of these regions AC3+ cell density was high at E17 and remained high over the next several days (Figure 2E, G); density then declined between E19/P0 and P1 for the PVN (P < 0.0001), and between P1 and P3 for the DG and CA1 (P < 0.0001). The difference in AC3+ cell density between the CA1 and CA2/3 during late prenatal life was striking; this can be seen not only in the quantitative analysis (Figure 2G), but also in photomicrographs (Figure 4). As seen previously (Ahern et al., 2013), there were large differences in the density of AC3+ cells across brain regions. In the CeA, for example, densities were below 600 AC3+ cells per mm3 at all ages examined (Figure 2D), whereas peak densities of >5,000 AC3+ cells per mm3 were seen in the CA1 and CA2/3 oriens (Figure 2H). Total number of AC3+ Cells AC3+ density measures allow for comparisons of the rate of cell death across brain regions of very different overall size, but can obscure changes in the total number of dying cells when brain regions change significantly in size, as they do during perinatal development. Figure 3 presents total AC3+ cells for the 16 brain regions analyzed above; all regions showed a significant main effect of age on total number of AC3+ cell number (Table 1). As was seen for AC3+ cell density, the highest total numbers of AC3+ cells are seen soon after birth. In fact, the pattern is more consistent for total counts than it was for density: even in the regions with high densities of AC3+ cells prenatally (DG, CA1, and PVN), the total number of AC3+ cells is low at E17, with increases over the next several days (Figure 3E, G), followed by a decline to very low levels by P11. Peak total numbers of AC3+ cells were seen “early” (P0, P1) in the PVN, BNSTl, DG, CA1, CA2/3, CA1 oriens and CA2/3 oriens, and “late” (P5) in the BNSTp, AVPV, SCN, LS, MPON, CeA, NAcc core, and NAcc shell. Persistence of cells in the hippocampal oriens layer of Bax knockout mice As noted above, the CA1 and CA2/3 oriens layers of the hippocampus were remarkable for the exceptionally high density of AC3+ cells observed on P1 (~6,000 AC3+ cells per mm3), which was twice that of the next highest brain region (Figures 2H and 3H). Both oriens regions also exhibited abrupt, three- to four-fold increases in AC3+ cell density in the 24h between P0 and P1 (P < 0.0001 for both CA1 and CA2/3 oriens; Figures 2H, 3H and Figure 4). The hippocampal oriens layer is cell sparse in adulthood, and populated mainly by the basal dendrites of CA pyramidal neurons and their afferents (Reznikov, 1991). The very high rate of cell death in the newborn oriens therefore suggested the elimination of a transient cell population. To investigate this further, we examined the oriens layers in adult Bax−/− mice, in which developmental neuronal cell death is nearly completely prevented (White et al., 1998; Ahern et al., 2013). We find a large population of multipolar, neuronal-like cells in the CA1 and CA2/3 oriens layers of thionin-stained sections of Bax−/− mice; quantification indicates 8 times more cells in the CA1 oriens of Bax−/− than of wildtype mice (Figure 5; P < 0.0005). This far exceeds the ~1.5- to 2-fold increases in cell number seen in other brain and spinal cord regions of Bax knockouts (Deckwerth et al., 1996; Sun et al., 2003; Forger et al., 2004; Jacob et al., 2005). Double-labeling for NeuN and GFAP established that the large majority of rescued cells in the Bax knockouts are neuronal: the number of NeuN+ cells in the CA1 oriens of Bax−/− animals was 5.6-fold greater than the number in wild-type controls (Figure 5; P < 0.05), whereas the number of GFAP+ cells did not differ significantly between genotypes (not shown). This supports the existence of a transient layer of neurons in the hippocampal oriens that is eliminated by an explosive period of cell death coinciding with birth. Cingulate cortex area 2/ Indusium griseum and subcallosal sling Next we analyzed two forebrain areas that were not a priori identified as regions of interest, but stood out as having the highest levels of AC3 labeling in any brain region of perinatal animals, visible with the naked eye in stained sections. These cell groups were located just dorsal and ventral to the midline crossing of the corpus callosum and are identified here as Cg2/IG and the subcallosal sling (Figure 6A,B). In both regions we found significant effects of age on AC3+ cell labeling (P < 0.0001 and P = 0.0002 for the Cg2/IG and subcallosal sling, respectively; Figure 7), with the highest density of AC3+ cells seen on E18. The cluster in the Cg2/IG was remarkable for the abrupt increase between E17–E18 and the equally abrupt decrease between E18-E19/P0 (P < 0.0001 in both cases; Figure 7). The subcallosal sling displayed a similar pattern, but with more modest differences in cell death density between E17–E18 and E18–E19/P0 (P = 0.006 and P = 0.04, respectively). Few AC3+ cells were seen in these regions at P3 or later ages (not quantified). The morphology of AC3+ cells in the Cg2/IG could be seen more clearly in high-powered views of sections that were not counterstained (Figure 5C), and processes could be seen projecting into, or perpendicularly through, the corpus callosum in this material (Figure 5C). In support of the interpretation that the intense AC3 staining in the Cg2/IG and subcallosal sling is indicative of cell death, we observed many pyknotic cells in this regions in thionin-stained sections of E18 animals not processed for immunohistochemistry (not shown), as well as a dense accumulations of microglia with an activated morphology (Figure 6C). Examination of adult Bax −/− mice suggests an accumulation of thionin-stained and NeuN+ cells in the Cg2/IG region that far exceeds differences in cell density between Bax −/− and wildtype animals in adjacent regions (Figure 6E–H). As discussed below, the AC3 cells in the perinatal Cg2/IG may represent the elimination of a transient neuronal cell group that pioneers the midline crossing of the corpus callosum or hippocampal commissure. AC3+ density at 19 days post-conception in offspring vaginally born or still in utero Most C57BL/6 dams give birth at 19 days post-conception (e.g., Murray et al., 2010). At our usual collection time between 1400 and 1500 h on E19, some litters had been born vaginally earlier that day (P0 group), whereas others were still in utero (and removed by C-section; E19 group). The pups are combined as the E19/P0 group in the analyses above. When analyzed separately, there was no significant difference for most cell groups. However, we found greater AC3+ cell density in vaginally delivered pups in the suprachiasmatic nucleus (P = 0.033), AVPV (P = 0.013) and the subcallosal sling (P = 0.003) (Figure 7). No brain regions showed the opposite pattern. Body weights between the groups did not differ (1.32 ± 0.02 g and 1.33 ± 0.02 g for E19 and P0 offspring, respectively; two-tailed t-test, P = 0.756). Discussion Despite the fact that the role of cell death in brain development is now textbook material, systematic analyses of cell death in the developing mammalian brain have been lacking. With few exceptions, most previous studies have quantified dying cells in one, or at most a few, brain regions at one or a few ages. Here we present cell death dynamics in 16 forebrain regions across 9 perinatal ages, providing the most comprehensive view to date of the patterning of post-mitotic neuronal cell death in the mouse brain. These data may help guide the search for factors that account for regional differences in the magnitude of cell death or that trigger the onset and termination of the cell death period. Limitations We opportunistically chose to quantify brain regions with clearly defined borders at all ages in the current study and, although we examined a relatively large number of areas, there are obviously many more that we did not. Missing from this analysis, for example, are any thalamic or cortical regions (with the exception of Cg2). Limited data on the timing of cell death in the mouse cortex have previously been published and analyses of multiple cortical areas using the current material are in progress (T. Ahern, unpublished). We believe the regions quantified here to be reasonably representative because the lack of AC3+ cells at the earliest ages examined (E17–E18), and peak rates of cell death during first few days of postnatal life, were clearly widespread phenomena throughout the forebrain based on qualitative assessments of the material. Another limitation of this work is that the identification of cell death relied almost exclusively on the detection of AC3. This could be a concern if some dying cells do not express AC3, or if AC3 immunoreactivity labels cells that are not undergoing apoptosis. Although caspase-independent cell death has been described for neuronal precursor cells or after neuronal injury (Zhan et al., 2001; Rideout and Stefanis, 2001; Cregan et al., 2002), it does not, as far as we know, occur during naturally-occurring death of post-mitotic neurons. The other possibility (non-apoptotic roles for AC3 in our labeled cells) is not likely to be a concern at the ages studied here: although AC3 is involved in dendritic pruning in Drosophila and synaptic plasticity in weanling rats (Li et al., 2010; Hyman and Yuan, 2012), the large majority of cells expressing caspase-3 in the neonatal rodent nervous system also show signs of pyknosis (Srinivasan et al., 1998; Zacharaki et al., 2010; Zuloaga et al., 2011). More important, almost all (>95%) activated caspase-3 (AC3) cells are eliminated throughout the perinatal forebrain in mice lacking the pro-death gene, Bax (Ahern et al., 2013). Double labeling studies are limited in number, but indicate that the majority of AC3+ cells in the perinatal rodent brain are neuronal (Zuloaga et al., 2011), in accord with our observation that many of the AC3+ cells in perinatal animals in the current study had a neuronal morphology. In addition, the “extra” cells in Bax−/− mice were NeuN+ in two brain regions that had high AC3+ cell densities perinatally. Taken together, AC3 immunoreactivity in the late prenatal and neonatal brain is a reliable marker for naturally occurring cell death and primarily labels dying neurons. Does birth orchestrate cell death? The observation that cell death peaks within a few days of birth in most forebrain regions raises the possibility that parturition orchestrates patterns of neuronal cell death. The final stage of mammalian gestation is characterized by major hormonal shifts and a state of sterile inflammation (Soares and Talamantes, 1984; Bernal, 2001; Thomson et al., 1999; Golightly et al., 2011); these are followed by the mechanical stimuli of a vaginal delivery, a transition to breathing air, and marked changes in energy metabolism, feeding, temperature regulation, and new challenges to sensory-motor systems (Turgeon and Meloche, 2009; Hillman et al., 2012). Peri-parturitional events trigger major adaptive changes in peripheral organs that are required for adaptation to ex utero life (e.g., Thilaganathan et al., 1994; Fowden et al., 1998; Jain and Eaton, 2006) and could also influence brain development, including the timing or magnitude of neuronal cell death. Alternatively, cell death may be pre-programmed and occur at a set time after conception regardless of the timing of birth. As far as we know, data are not currently available to discriminate between these two possibilities. Whether birth plays a role in controlling neuronal cell death could be addressed by examining mice in which birth is experimentally advanced or delayed by hormonal or genetic manipulations (Sugimoto et al., 1997; Langenbach et al., 1997; Gross et al., 1998; Jeff et al., 2000; Hashimoto et al., 2010). Similarly, by carefully equating time ex utero after a vaginal or cesarean delivery, one could determine whether mode of birth makes a difference. Both types of studies have the potential to identify novel factors controlling the timing and magnitude of cell death in the mammalian brain. Exceptions to the “rule” Exceptions to the pattern of peak rates of cell death soon after birth were seen in the DG, PVN, and CA1, which all had high densities of AC3+ cells prenatally.; even in these regions, however, total AC3+ cell number conformed to the pattern. Our counts of total AC3+ cells in the DG are in good agreement with those reported previously for perinatal mice (Kim et al., 2009). The DG forms quite late, with the earliest neurons born at E16 (Bayer, 1980; Altman and Bayer, 1990; Stanfield and Cowan, 1979). As would be expected, DG volume increases steeply during the next few days (a nearly 5-fold increase (487%) in volume in the three days between E17 and P1, based on our material; data not shown). Similarly, although many neurons in the CA1 of rodents are born by E16, neurogenesis continues in this region through the last days of gestation and first few postnatal days (Stanfield and Cowan, 1979; Soriano et al., 1989; Bayer, 1980; Bowers et al., 2010). Because regions of neurogenesis are often associated with high cell turnover (Blaschke et al., 1998; Morshead and van der Kooy, 1992; Jabès et al., 2010; Kim et al., 2011), the relatively late histogenesis of the DG and CA1 could explain the high density of AC3+ cells during late prenatal life. The PVN, on the other hand, forms quite early in the mouse (Karim and Sloper, 1980), so late histogenesis cannot explain high rates of cell death prenatally. The PVN is one of the most important autonomic control centers in the brain, and plays a central role in the stress response. Many studies have demonstrated “programming” effects of late prenatal stressors on the hypothalamic-pituitary-adrenal axis and, in particular, long-term changes in PVN function (e.g., McCormick et al., 1995; Hossain et al., 2008; Zohar and Weinstock, 2011). Late prenatal stress also increases apoptosis in the fetal PVN of rats (Fujioka et al., 1999; 2003; Tobe et al., 2005). It is possible that the cell turnover occurring just prior to birth in the PVN of mice contributes to the susceptibility of this brain region to prenatal programming. Unusually high rates of cell death represent the elimination of transient cell groups in the hippocampus, subcallosal sling, and cingulate cortex One unexpected finding of the current study was the large number of AC3+ cells in the oriens layers of the hippocampus (normally a cell-poor region in adulthood). The CA1 and CA2/3 oriens layers of the hippocampus had by far the highest densities of AC3+ cells in any of the brain regions quantified in this or the previous study (Ahern et al., 2013). Also of note were the abrupt changes in the number and density of AC3+ cells in the oriens regions: a 300–400% increase in AC3+ cells between P0 and P1, followed by a return to baseline several days later. Because a population of large neurons persisted in the oriens layers in Bax−/− mice, this suggests the relatively sudden elimination of a transient cell group in the developing hippocampus. The elimination of cell groups that may play a temporary role during development of the vertebrate nervous system has been described previously (e.g., Whitlock and Westerfield, 1998; Reyes et al., 2004; Jung et al., 2008). As far as we can tell, the rapid die-off of a cell group in the hippocampal oriens has not previously been described, although Stanfield and Cowan (1979) noted a decrease in cell density in the stratum oriens and stratum radiatum between E18 and P1 in mice, based on appearance in a Nissl stain. The identity or function of the eliminated cells is not known and is an interesting question for future study. A massive accumulation of AC3+ cells was also seen in the subcallosal sling and (especially) Cg2/IG at E18; in fact, the density of AC3+ cells in these regions was so great that we could not count them individually. Both the subcallosal sling and Cg2/IG have been implicated in the early formation of the corpus callosum (CC) or hippocampal commissure (HC). The subcallosal sling (previously referred to as the “glial sling,” but renamed when it was shown to contain neurons) is present before the first CC axons cross the midline (E15–E16 in the mouse) and may function to guide pioneer axons that grow along its surface (Silver et al., 1982; Shu and Richards, 2001; Shu et al., 2003). The appearance of pyknotic cells just before birth in the subcallosal sling of the mouse has been reported previously (Hankin et al., 1988); our analyses confirm the interpretation that the disappearance of this structure is due to cell death. Niquille et al. (2009) more recently proposed the elimination of a transient population of neurons thought to guide axons crossing the CC. Although the cells they describe were located primarily within the CC itself, we note that some of the AC3+ labeling they observed on P0 (Niquille et al., 2009; Supplemental figure 3) appears ventrolateral to the CC and may also correspond, in part, to what we have identified here as the dying off of the subcallosal sling. Based on work in the rat, cells in the Cg2 region were proposed to be the first cortical neurons to project their axons to the contralateral hemisphere (i.e., to pioneer the CC; Koester and O’Leary, 1994). Prenatally, however, the CC is closely apposed to the slightly more ventral HC, and work in mice suggests that the early projecting cingulate neurons instead enter the HC (Ozaki and Wahlten, 1998). Regardless of which interpretation is correct, it is interesting that both Koester and O’Leary (1994) and Ozaki and Wahlsten (1998) raised the possibility that the Cg2 neurons that pioneer the midline crossing are later eliminated by apoptosis, although neither group favored that explanation. Many AC3+ labeled cell processes in the current study coursed perpendicular to the CC, in accord with the suggestion of Ozaki and Wahlsten (1998) that they projected through the CC to the more ventrally located HC; other AC3+ fibers ran parallel to the CC, however. The fact that so many cells in the Cg2/IG were AC3 labeled, and that this area was also filled with pyknotic cells and amoeboid microglia, suggests that many are eliminated at ~E18, after the CC and HC have been established. Conclusions Much of the recent work on cell death in the developing brain pertains to injury-induced cell death. Many years after its discovery, however, there is clearly much that remains to be learned about the control of naturally-occurring cell death during brain development. The findings presented here, and previously (Ahern et al., 2013), demonstrate that the bulk of developmental cell death occurs within several days of birth. Whether birth (parturition) plays a causative role in timing cell death, although a seemingly basic question, is not known. The signals that trigger the elimination of cells in the Cg2/IG and SCS on E18 or hippocampal oriens cells on P1 also are not known, and are areas for future investigation. Supported by: NIMH R01-068482 (NGF), a Georgia State University Brains and Behavior Seed Grant (NGF), a Quinnipiac University College of Arts & Sciences Seed Grant (THA), and NSERC Discovery Grant 402633 (MMH). Figure 1 Photomicrographs of coronal sections immunohistochemically stained for activated caspase-3 (AC3) show many more dying cells on postnatal day (P) 1 than on embryonic day (E) 17. A, C, and E are from mice on E17; B, D, and F are from P1 mice. A and B are taken at the level of the nucleus accumbens; C and D are taken at the level of the lateral nucleus of the bed nucleus of the stria terminalis; E and F are higher magnification views of the regions indicated by the boxes in C, D. Scale bars = 100 µm in A–D and 25 µm in E,F. Abbreviations: ac, anterior commissure; CC, corpus callosum; LV, lateral ventricle; 3V, third ventricle. Figure 2 Mean (±SEM) density of AC3+ cells in 16 regions of the mouse forebrain from embryonic day 17 (E17) to postnatal day 11 (P11). Filled symbols (E17-P1) represent data from new material generated for this study and open symbols (P1–P11) are data from previously generated material (Ahern et al., 2013). Previously published data from Ahern et al. (2013) are shown by dotted lines (A–D and PVN in E) and reprinted here with the permission of John Wiley & Sons; new data collected from the material generated in Ahern et al., (2013) are plotted in solid lines (DG in E, and F–H). Abbreviations: AVPV, anteroventral periventricular nucleus; BNSTl and BNSTp, lateral and principal nuclei of the bed nuclei of the stria terminalis; CA1, cornus ammonis 1; CA2/3, cornus ammonis 2 and 3; CeA, central amygdala; DG, dentate gyrus; LS, lateral septum; MeA, medial amygdala; MPON, medial preoptic nucleus; NAcc, nucleus accumbens; PVN, paraventricular nucleus of the hypothalamus; SCN, suprachiasmatic nucleus. Figure 3 Mean (±SEM) total number of AC3+ cells in 16 regions of the mouse forebrain from embryonic day 17 (E17) to postnatal day 11 (P11). Filled symbols (E17-P1) represent data from new material generated for this study and open symbols (P1–P11) are data from previously generated material (Ahern et al., 2013). Previously published data from Ahern et al. (2013) are shown by dotted lines (A–D and PVN in E) and reprinted here with the permission of John Wiley & Sons; new data collected from the material generated in Ahern et al., (2013) are plotted in solid lines (DG in E, and F–H). Abbreviations: AVPV, anteroventral periventricular nucleus; BNSTl and BNSTp, lateral and principal nuclei of the bed nuclei of the stria terminalis; CA1, cornus ammonis 1; CA2/3, cornus ammonis 2 and 3; CeA, central amygdala; DG, dentate gyrus; LS, lateral septum; MeA, medial amygdala; MPON, medial preoptic nucleus; NAcc, nucleus accumbens; PVN, paraventricular nucleus of the hypothalamus; SCN, suprachiasmatic nucleus. Figure 4 Photomicrographs of coronal sections through the hippocampus from embryonic day (E) 17 through postnatal day (P) 5. Sections were immunohistochemically stained for activated caspase-3 (AC3) and counterstained with thionin. A: E17, B: E18, C: E19/P0, D: P1, E: P3, F: P5. A peak of cell death in the hippocampus is evident from P1–P3. Although not shown here, few to no AC3+ cells were present in the hippocampus of the older animals (P7, P9, and P11) examined in this study. Scale bars = 100 µm. Figure 5 The elimination of developmental cell death reveals a prominent cell layer in the hippocampal oriens layers. A, C. Photomicrographs of thionin-stained sections of the hippocampus of adult wild-type (Bax+/+) and Bax −/− mice. B, D. Higher magnification views of the boxed areas in A and C. Many large, neuron-like cells are found in the CA1 and CA2/3 oriens of the Bax knockouts. E, F. Photomicrographs of the hippocampal oriens of adult Bax+/+ (E) and Bax−/− (F) mice double-labeled for NeuN and GFAP. An accumulation of NeuN cells is seen in the Bax−/− mice. Scale bars = 200 µm in A, B, E, and F; 25 µm in C and D. Quantification of thionin stained (G) and NeuN+ (H) sections of the CA1 oriens layer indicates many more cells with a neuronal morphology in Bax −/− than Bax+/+ mice. Figure 6 Striking accumulations of AC3+ cells are found in the cingulate cortex 2 / indusium griseum (Cg2/IG) region on E18. A, B. Photomicrographs of sections immunohistochemically stained for activated caspase 3 (AC3) and counterstained with thionin on E17 (A) and E18 (B). Photos in both cases are taken just posterior to the anterior-most crossing of the corpus callosum. Note the sudden increase in AC3+ cells in the Cg2/IG on E18 (B). C. Higher magnification view of the Cg2/Ig on E18 in a section without counterstain. AC3+ labeled cell bodies are seen in the Cg2/Ig (upper left) and several processes of labeled cells can be see running perpendicular to the corpus callosum (arrows). D. Immunohistochemistry for Iba1 on E18, in a section rostral to B, shows an accumulation of amoeboid microglia just dorsal and ventral to the CC in the Cg2/IG and subcallosal sling, respectively (arrows). E, F, G. H. Thionin-stained (E, F) and NeuN/GFAP double-stained (G, H) sections of the Cg2/IG region in adult wild-type (Bax+/+; E, G) and Bax −/− (F, H) mice. Arrows point to an accumulation of cells in the Bax −/− animals that is greatly reduced in the wild-type mice. Arrowhead in (H) points to an accumulation of cells around the lateral ventricle as previously described in Bax−/− animals (Kim et al., 2007). Abbreviations: LV, lateral ventrical; CC, corpus callosum. Scale bars = 100 µm in A and B, 10 µm in C, 200 µm in D; scale bar in E is 50 µm for E and F and scale bar in G is 100 µm for G and H. Figure 7 Quantification of AC3+ labeling in the cingulate cortex area 2/indusium griseum (Cg2/IG) and subcallosal sling (SCS) from embryonic day (E) 17 to postnatal day (P) 1. Highest rates of cell death were seen in both regions on E18. *, significantly different from E17 (p < 0.0001 and p < 0.001 for Cg2/Ig and SCS, respectively). Figure 8 Vaginally delivered E19/P0 pups exhibited significantly higher cell death density than cesarean delivered pups on E19/P0 in the (A) suprachiasmatic nucleus (SCN), (B) anteroventral periventricular nucleus of the hypothalamus (AVPV), and (C) subcallosal sling (SCS). Table 1 Primary Antibodies Antibody Immunogen Manufacturer data Concentration Activated caspase-3 (AC3) Peptide sequence CRGTELDCGIETD, which is adjacent to Asp175 in human caspase-3 Cell Signaling Technology, Cat# 9661, Lot 36, RRID:AB_231409, Polyclonal antibody raised in rabbit 1:20,000 Glial fibrillary acidic protein (GFAP) Purified bovine GFAP Chemicon, Cat# AB5804, Lot 0512018283, RRID:AB_2109645, Polyclonal antibody raised in rabbit 1:1,000 Ionized calcium binding adaptor molecule 1 (Iba1) Synthetic peptide corresponding to C- terminal sequence PTGPPAKKAISELP of Iba1 Wako, Cat# 27030, Lot PDJ0493, RRID:AB_2314667, Polyclonal antibody raised in rabbit 1:20,000 Neuronal nuclei (NeuN) Purified cell nuclei from mouse brain Chemicon, Cat# MAB377, Lot 0601019159, RRID:AB_2298772, Monoclonal antibody raised in mouse 1:1,000 Table 2 Results of ANOVAs examining the effects of age on cell death density and total cell death for 16 regions of interest. All p-values were significant (p < 0.0001). AC3+ CELL DENSITY TOTAL AC3+ CELLS REGION F (df) F (df) AVPV 12.43 (8,165) 15.63 (8,165) BNSTL 53.86 (8,179) 33.12 (8,179) BNSTP 31.18 (8,175) 35.23 (8,175) CA1 48.04 (8,164) 25.21 (8,164) CA1 OR 29.01 (8,165) 27.44 (8,165) CA2/3 30.29 (8,164) 30.03 (8,164) CA2/3 OR 50.79 (8,165) 36.84 (8,165) CEA 17.56 (8,161) 17.72 (8,161) DG 26.15 (8,166) 23.85 (8,166) LS 55.33 (8,143) 24.52 (8,143) MEA 66.99 (8,168) 26.18 (8,168) MPON 34.99 (8,144) 24.62 (8,144) NACC CORE 35.81 (8,150) 32.85 (8,150) NACC SHELL 25.55 (8,150) 41.48 (8,150) PVN 21.93 (8,184) 10.39 (8,184) SCN 19.80 (8,187) 27.38 (8,187) The authors quantify cell death in 16 regions of the mouse forebrain during late prenatal and early postnatal life. They find peak cell death just after birth in most regions. They also describe massive cell death perinatally in regions surrounding the corpus callosum, and the persistence of neurons in those regions in adult Bax knockout mice. Conflict of Interest Statement. The authors have nothing to declare. Role of Authors. Study concept and design: MM, THA, NGF; Acquisition of data: MM, CS, KAM, SAM, THA, NGF; Analysis and interpretation of data: MM, THA, NGF; Drafting of the manuscript: NGF; Critical revision of the manuscript for important intellectual contribution: MM, THA, NGF; Obtained funding: THA, NGF; Administrative, technical, and material support: MM, CS, KAM, SAM; Study supervision: THA, NGF. 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PMC005xxxxxx/PMC5116300.txt
LICENSE: This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. 8805635 27439 Immunol Allergy Clin North Am Immunol Allergy Clin North Am Immunology and allergy clinics of North America 0889-8561 1557-8607 27712766 5116300 10.1016/j.iac.2016.06.008 NIHMS795565 Article Eosinophils and Mast Cells in Aspirin-Exacerbated Respiratory Disease Steinke John W. 1 Payne Spencer C 3 Borish Larry 2 1 Asthma and Allergic Disease Center, Carter Center for Immunology Research, Department of Medicine, University of Virginia Health System Charlottesville, VA 2 Asthma and Allergic Disease Center, Carter Center for Immunology Research, Department of Microbiology, University of Virginia Health System Charlottesville, VA 3 Department of Otolaryngology – Head and Neck Surgery, University of Virginia Health System Charlottesville, VA 2 Corresponding Author: Larry Borish, Asthma and Allergic Disease Center, Box 801355, University of Virginia Health System, Charlottesville, VA 22908, Telephone #: (434)-243-6570; Fax #: (434)-924-5779; lb4m@virginia.edu 17 6 2016 13 9 2016 11 2016 01 11 2017 36 4 719734 This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. Aspirin-exacerbated respiratory disease (AERD) is explained in part by over-expression of pro-inflammatory mediators including 5-lipoxygenase and leukotriene C4 synthase (LTC4S) that results in constitutive over-production of cysteinyl leukotrienes (CysLTs). Mast cells and eosinophils are two cell types that have important roles in mediating many of the effects observed in this disease. Increased levels of both interleukin (IL-4) and interferon (IFN)-γ are present in the tissue of AERD subjects. Previous studies demonstrated that IL-4 is primarily responsible for the upregulation of LTC4S by mast cells. Our studies demonstrate that IFN-γ, but not IL-4 drives this process in eosinophils. We also extend to both IL-4 and IFN-γ the ability to upregulate CysLT receptors. Prostaglandin E2 (PGE2) acts to prevent CysLT secretion by inhibiting mast cell and eosinophil activation. PGE2 concentrations are reduced in AERD and studies confirm that this reflects diminished expression of cyclooxygenase (COX)-2, a process again that is driven by IL-4. Thus, IL-4 and IFN-γ acting on eosinophils and mast cells together play an important pathogenic role in generating the phenotype of AERD. This review will examine the overall role that eosinophils and mast cells contribute to the pathophysiology of AERD. eosinophil mast cell leukotriene cyclooxygenase prostaglandin aspirin-exacerbated respiratory disease arachidonic acid Introduction In 1968, the term Samter’s triad was coined and was defined by the presence of nasal polyps, aspirin sensitivity, and asthma 1, however this disease is now referred to as aspirin-exacerbated respiratory disease (AERD) as asthma is not always present despite reactions to aspirin. AERD comprises as many as 7% of adult-onset asthmatics and up to 12–14% of adult asthmatics with severe asthma 2, 3. This disorder is characterized by the unique intolerance to aspirin and other non-selective cyclooxygenase (COX) inhibitors 4–6. Other characteristics include hypereosinophilia, both in circulation and in the tissue, a tendency to develop de novo in adulthood 5, 7–9 and often an absence of identifiable atopy 5, 7. Sinusitis is present in this disorder, the degree of which is often severe and associated with complete or near complete opacification of the sinus cavity 9. Though not a requirement, when asthma is present it often progresses in severity and is associated with aggressive airway remodeling 10. During aspirin reactions, many mediators are released including cysteinyl leukotrienes (CysLT), tryptase, eosinophil cationic protein (ECP) and prostaglandin D2 (PGD2) suggesting both mast cell and eosinophil activation 11–13. Recently, aspirin was shown to directly activate both of these cell types ex vivo potentiating mediator release 14. A predominant physiological feature of AERD is the robust over-production and over-responsiveness to CysLTs (inflammatory) 12, 15 while at the same time there is under-production and under-responsiveness to the anti-inflammatory lipid mediator PGE2 16–18. These CysLTs have important pro-inflammatory and pro-fibrotic effects that contribute to the asthma severity and to the extensive hyperplastic sinusitis and nasal polyposis 9, 19, 20. And, conversely, the down-regulation of PGE2 pathways reduces the constraints that would normally act to attenuate these pro-inflammatory pathways 21. This review will focus on the role that eosinophils and mast cells play in contributing to these cardinal features of AERD. Eosinophil and mast cell numbers in AERD Chronic sinusitis is now recognized as a collection of disorders that result from inflammation of the sinuses and in many cases can be separated into different types based on the cellular infiltrate. One distinguishing feature in the nasal polyps that often form in association with chronic sinusitis is the presence or absence of eosinophils and amongst eosinophilic polyps a distinction can be made between AERD, allergic fungal sinusitis (AFS) and chronic hyperplastic eosinophilic sinusitis (CHES) 22, 23. Within the eosinophilic polyps, AERD has more than twice the number of eosinophils in the polyp tissue than AFS or CHES, implicating them as important cells in the disease process 23. Examination of bronchial biopsies from AERD subjects also revealed highly elevated eosinophil numbers in comparison to aspirin-tolerant asthmatics and non-asthmatics 24. These eosinophils were in an activated state as evidenced by the presence of secretory ECP 24. We have reported lower numbers of mast cells in nasal polyps from eosinophilic sinus disease as compared to healthy tissue by both toluidine blue and chloroacetate (chymase) staining, and there was no difference between aspirin tolerant and AERD groups 23. This contrasts somewhat with a previous report that found no difference in mast cell numbers in nasal polyps from AERD groups when compared to allergic or non-allergic subjects via tryptase staining 25. The differences in the results of these studies may reflect the use of different markers of mast cells (chymase vs. tryptase) or the stratification of the groups, the latter study not taking into account eosinophilic infiltration into the polyp tissue. Regardless, there do not appear to be more mast cells in nasal polyps in subjects with AERD. However, this result may be erroneous – given the high expression of mast cell-derived mediators – and perhaps reflects the inability to stain for activated, granule-depleted mast cells (so-called “phantom” mast cells). Similarly, when the lungs have been examined, as with NPs, fewer numbers of mast cells have been found in AERD subjects compared to non-asthmatic controls using immunohistochemistry to stain for tryptase positive cells 24. Another study examining the bronchial mucosa found increased numbers of tryptase-positive mast cells only in subjects with non-aspirin sensitive asthma: again, AERD and healthy controls paradoxically had similar numbers 26. Development of Eosinophils and Mast Cells Eosinophils develop from pluripotent hematopoietic stem cells in bone marrow that initially differentiate into eosinophil/basophil progenitors or colony forming units (Eo/B CFU) (Figure 1). Eo/B CFU are mononuclear cells that express CD34, CD35, and interleukin (IL)-5 receptors (CD125) that are capable of responding to appropriate cytokine signals allowing differentiation into mature basophils and eosinophils 27, 28. Eo/B CFU are increased in numbers in both the blood and bone marrow of allergic patients and further increases in their number are observed following allergen exposure 28. These progenitors are also observed in nasal polyp tissue 29. Several transcription factors including GATA-1, PU.1 and C/EBP are induced in response to appropriate cytokine signals and become involved in the development of the eosinophil lineage and eosinophil-associated genes 30–32. In vitro eosinophil differentiation experiments have demonstrated that GATA-1 is the primary transcription factor responsible for this eosinophil lineage specification 33. Three cytokines, IL-3, IL-5 and granulocyte macrophage colony-stimulating factor (GM-CSF) play the most important roles in the regulation of eosinophil development (Figure 1). The function of IL-3 is the broadest as it leads to the expansion of a variety of cell types including monocytes, megakaryocytes, erythrocytes, basophils, neutrophils and eosinophils 27. GM-CSF acts in a similar fashion, albeit with more mature precursor cells, inducing the formation of macrophages, neutrophils and eosinophils 34. IL-5 is the cytokine responsible for selective terminal differentiation of eosinophils 35 and stimulates the release of eosinophils from the bone marrow into peripheral circulation 36. GM-CSF, IL-3 and the chemokines CCL11, CCL24, and CCL26 (eotaxins) are also involved in eosinophil homeostasis and play an important role upon arrival of the eosinophil at a tissue location. In addition, an IFN-γ-induced transcription factor ICSBP can also drive the differentiation of eosinophils 37. As IFN-γ is routinely present in allergic inflammation and, in our studies, was particularly upregulated in AERD 38, this led us to speculate on the role of IFN-γ being able to contribute to eosinophilia. Using an in vitro model with CD34+ hematopoietic progenitors, we demonstrated the capacity of IFN-γ, acting in synergy with IL-5, to promote the survival and differentiation of mature bi-lobed, CCR3- and Siglec-8-expressing eosinophils 38 confirming prior studies 39 regarding the influence of this cytokine on eosinophil-mediated inflammation. As with eosinophils, mast cells are derived from pluripotent hematopoietic CD34+ cells from the bone marrow 40, however mast cells do not fully mature until they reach their final tissue destination with the exception of mast cell leukemia. IL-3 and IL-6 increase early CD34+ progenitor cell numbers and begin the differentiation process, however it is binding of stem cell factor (SCF) to its receptor c-Kit (CD117) that is the master growth and differentiation factor for human mast cells (Figure 1) 41. SCF is produced primarily by stromal cells 42 and it can either be released as a soluble growth factor or expressed on the cell surface of these cells. It is the expression and binding of SCF at tissue sites that cause the CD34+ precursor cells to arrest and terminally differentiate into mast cells. Cysteinyl leukotriene over-production and over-responsiveness in AERD Arguably, the best-characterized molecules associated with AERD are the CysLTs. A unique characteristic of the disease is the over-production of CysLTs in the resting state and a tremendous surge in CysLT production in response to aspirin and other non-selective cyclooxygenase inhibitors that target COX-1 43. Included in this list are the non-selective non-steroidal anti-inflammatory drugs (NSAIDs) as well as other inhibitors of COX-1 44, 45. The high CysLT levels in AERD reflect increased expression of the primary synthesis enzymes 5-lipoxygenase (5-LO) and more importantly leukotriene C4 synthase (LTC4S) (Figure 2). Increased expression of these enzymes is observed in the lungs, sinuses and nasal polyps of AERD subjects with eosinophils and resident mast cells being the primary cells expressing the enzymes 16, 19, 24, 46. Not only do AERD subjects produce more CysLTs, but they also demonstrate an increased sensitivity to CysLTs 47. Initially, two CysLT receptors were identified and were distinguished from each other by their differing potency for the CysLTs: CysLT1 receptors primarily respond to LTD4 whereas CysLT2 receptors respond equally to LTD4 and LTC4. Neither receptor responds well to LTE4. Acting through CysLT1 and inhibited by the CysLT2 receptor, CysLTs induce mast cell proliferation through activation of c-kit and extracellular signal-regulated kinase 48. In AERD sinus tissue, high levels of CysLT1 were found in comparison to healthy tissue and following aspirin desensitization, the CysLT1 levels returned to normal 49. CysLT1 receptors are also prominently expressed on airway smooth muscle 50 and these receptors mediate a portion of the CysLT-induced bronchospasm associated with aspirin challenges or desensitizations 51–54 as demonstrated by the ability of leukotriene receptor antagonists to attenuate much of the bronchospasm that occurs during these procedures. While these findings made it appear that CysLT1 was the only important leukotriene receptor in AERD, several observations suggested they were only partially involved in the pathogenesis of disease. The most abundant leukotriene found in the circulation and airway is LTE4 with C4 and D4 being rapidly converted to E4, thus limiting their duration of action in vivo. Inhalation of LTE4 by asthmatic and AERD subjects potentiates airway hyperresponsiveness to subsequent challenges with histamine, the effect of which could be blocked with indomethacin 47, 55, 56. In the bronchial mucosa of asthmatics, inhalation of LTE4, but not LTD4, causes recruitment of eosinophils, basophils and mast cells into the tissue 57, 58. Mice in which both the CysLT1 and CysLT2 receptors have been deleted show enhanced skin swelling in response to intracutaneous LTE4 in comparison to mice with these genes intact 59. These studies led to the exploration for and ultimate identification of additional CysLT receptors that selectively respond to LTE4 (GPR99 and P2Y12) 59–62. The functional role of these LTE4 receptors in AERD and the utility in targeting them as a therapeutic option are areas of active research, although diminished synthesis of CysLTs and, by extension, of LTE4, could explain the superior efficacy of 5-lipoxygenase inhibitors in treating this disorder 63. Underappreciated role for PGD2 in AERD PGD2 and its metabolites have been found in blood and urine following aspirin challenge 11, 13, 64 and the conventional thought is that it is primarily mast cell derived, however reports demonstrate that eosinophils are also a source 65, 66. Synthesis of PGD2 is regulated by hematopoietic prostaglandin D2 synthase (hPGDS) (Figure 2) and when secreted it binds two receptors CRTH2 (DP2) and DP1 that are expressed on numerous cell types. Activities of PGD2 binding include stimulation of cell migration (including eosinophils and innate lymphoid type 2 (ILC2) cells), bronchoconstriction, vasodilation (flushing), and cellular activation and differentiation 67–70. A role for PGD2 in the pathogenesis of AERD is supported by studies in chronic sinusitis. Expression of hPGDS has been observed in polyps, specifically in eosinophils 66, 71, 72. The degree of hPGDS expression correlated with eosinophil number and severity of disease. These studies did not examine AERD subjects, but given the high levels of eosinophilic infiltrate in AERD tissue, it is likely that hPGDS levels would have correlated as well. Recent work from our lab demonstrated that amongst CRS syndromes, in AERD the highest levels of hPGDS transcripts and proteins expression were observed and with eosinophils being the predominant cell type where expression was localized 66. As discussed in other chapters, aspirin desensitization followed by high-dose aspirin therapy is often used to treat AERD, however not all patients tolerate the desensitization protocol. It has recently been shown that those subjects who cannot be desensitized express higher basal levels of PGD2 (and thromboxane) in their serum and urine 64. During the desensitization procedure, these patients had a surge of PGD2 release but not thromboxane, whereas those who were successfully desensitized had decreased thromboxane and unchanged PGD2 levels 64. In this study, the correlation between PGD2 and eosinophil number in the polyp tissue was not performed. Baseline PGD2 levels may serve as a marker to identify those who will successfully undergo desensitization. PGE2 and PGE2 receptor dysregulation in AERD PGE2 displays both pro- and anti-inflammatory functions reflecting its ability to interact with 4 distinct receptors (EP1-4) each having various activating or inhibitory functions. However, it is the role of PGE2 acting through anti-inflammatory EP2 receptors to block eosinophil and mast cell degranulation that is central to the pathogenesis of AERD. AERD patients constitutively produce low levels of PGE2 16, 73 attenuating the anti-inflammatory constraints provided by this lipid in this basal state. The further reduction of tissue PGE2 concentrations by aspirin and other NSAIDs through COX-1 inhibition precipitates the activation of eosinophils and mast cells in AERD, as demonstrated by the ability of inhaled PGE2 to protect against these reactions 74, 75. This sensitivity of AERD patients to low tissue PGE2 concentrations is amplified by their reduced expression of the anti-inflammatory EP2 receptor 18. Serra-Pages and colleagues demonstrated that the ratio of EP2 to EP3 receptors on the surface of a mast cell influences the activation potential of these cells when the high affinity IgE receptor (FcεRI) is stimulated in a PGE2-containing milieu 76. Through examination of various mast cell lines, the authors found that those with high levels of EP2 could suppress FcεRI activation in the presence of PGE2, but when EP3 levels were high FcεRI activation of mast cells was enhanced. It is likely that the low EP2/EP3 ratio on mast cells and possibly eosinophils in AERD contributes to this disease as any PGE2 that is available would preferentially signal through the EP3 receptor and activate these cells, thus contributing to the pro-inflammatory cascade. Several studies have investigated the mechanism behind the reduced levels of PGE2 in AERD and, perhaps not surprisingly, have correlated this with a decrease in the relevant upstream metabolic enzymes. The production of PGE2 from arachidonic acid (Figure 2) involves the sequential synthesis of PGG2/PGH2 by the two cyclooxygenase enzymes (COX-1 and COX-2) followed by the synthesis of PGE2 by the microsomal PGE2 synthases (mPGES-1, mPGES-2) and cytosolic PGE2 synthase (cPGES). It is mPGES-1 that is most relevant to PGE2 production in inflammatory disorders such as AERD as it is the enzyme primarily functionally coupled to COX-2 77. COX-2 mRNA and protein expression are markedly diminished in AERD 16, 17, 78. Our studies have confirmed this diminished expression of COX-2 79. We found no significant change in COX-1 and a trend towards diminished mPGES-1 expression and that this is driven in part by IL-4. Diminished COX-2 expression and the reduced capacity to synthesize PGE2 contributes to the severity of inflammation observed in AERD and accentuates the sensitivity of these individuals to the further inhibition of PGE2 synthesis associated with aspirin and other NSAIDs. With this relative absence of COX-2, AERD subjects become dependent upon COX-1 for the PGE2 that is necessary to restrain mast cell and eosinophil activation. Thus, most AERD patients tolerate selective COX-2 inhibitors 80, supporting this concept regarding the unique importance of COX-1-derived PGE2. Cytokine expression in AERD Numerous studies have examined the cytokine milieu found in the tissue of eosinophilic sinusitis and AERD. Many of these studies have reported expression of a Th2-like immune profile (IL-4, IL-13 and IL-5), similar to other allergic diseases with eosinophilic infiltrate, though few have specifically focused on AERD 81–88. However, numerous observations suggest that in contrast to eosinophilic sinusitis patients who tolerate aspirin, AERD appears to have a mixed Th2- and Th1-like cytokine milieu characterized by prominent expression of IFN-γ. The first study to suggest this examined non-allergic sinusitis patients and demonstrated enhanced IFN-γ expression in this cohort: a group in which AERD is likely to be over-expressed 89. Since this initial report, high levels of IFN-γ in chronic sinusitis have been reported by other investigators, although AERD subjects were not specifically separated or recruited for the studies 90. One study specifically addressed IFN-γ expression in AERD and found enhanced levels of IFN-γ in circulating CD8+ cells compared to aspirin-tolerant controls 91. The concept that AERD reflects a mixed Th2- and Th1-like cytokine profile was confirmed in our recent study in which NP tissue derived from AERD subjects was contrasted with those obtained from aspirin tolerant and control subjects by their over-expression of IFN-γ mRNA transcripts and protein 38. To our surprise, we found that eosinophils themselves were the most important source for this cytokine, which is consistent with previous studies that demonstrated IFN-γ can be expressed by eosinophils in substantial quantities 92–94. In contrast to our findings, a recent report did not find elevated levels of IFN-γ protein in nasal polyps from AERD subjects, however this group did not perform flow cytometry, immunohistochemistry or quantitative PCR to verify their results 88. Cytokine dysregulation of LTC4S and CysLT receptors Under non-inflammatory conditions, mast cells express moderate levels of LTC4S that can be increased greatly following stimulation by IL-4 (but not by IL-5 or IL-13) 95. It has also been observed that IFN-γ also has the capability of upregulating LTC4S expression in umbilical cord-derived mast cell progenitors (Joshua Boyce, personal communication). While mast cells are capable of synthesizing CysLTs, previous studies 24 have demonstrated that eosinophils are the more important cell type over-expressing LTC4S in AERD. Examining a battery of cytokines (including IL-3, IL-4, IL-5, GM-CSF, IL-1, TNF-α and IFN-γ), we were unable to demonstrate an ability of any of these cytokines to modulate LTC4S expression on circulating eosinophils. This may be due to their terminal differentiation state and short life span. We have also failed to demonstrate the ability of IL-4 to increase LTC4S expression on eosinophils differentiated from progenitors in the presence of IL-3 and IL-5. However, when the progenitors were incubated with IFN-γ during the differentiation stage, a significant increase in LTC4S expression was observed 38. The increase in LTC4S expression translated into increased capacity of these newly differentiated eosinophils to secrete CysLTs upon activation by aspirin 14. Another mechanism of CysLT production involves the transcellular conversion of LTA4 by adherent platelets expressing LTC4S 96. The frequency of platelet-adherent eosinophils, neutrophils and monocytes are markedly elevated in the blood of AERD subjects. Any LTA4 that is released into the extracellular space can be captured by the platelets and converted to CysLTs. It has been estimated that adherent-platelets contribute up to 50% of the total LTC4S activity in blood and thus would represent a significant source of the CysLTs found in AERD 96. CysLT receptor expression is regulated by numerous cytokines including IL-4 and IFN-γ, but also IL-5 and IL-13. IL-4 increases expression of CysLT1 on mast cells 97, 98 and monocytes 99. In our studies, IL-4 also increased the expression of both CysLT1 and CysLT2 on T and B lymphocytes and eosinophils 100. We also demonstrated robust upregulation of CysLT1 and CysLT2 receptors in response to IFN-γ on T cells and eosinophils 100. In recent studies, examination of eosinophils derived from CD34+ progenitors have also demonstrated the ability of IFN-γ to upregulate CysLT1 and CysLT2 receptor expression 38. There have been no reports of cytokine modulation of other CysLT receptors. In summary, in the AERD cytokine environment, both mast cells and eosinophils are primed to produce and respond to the CysLTs that are produced during the disease process. Cytokine dysregulation of PGE2 Synthesis and EP2 Receptors Cytokine regulation of the PGE2 synthesis pathway in AERD has not been thoroughly investigated. However, in other model systems, the influence of IL-4 on COX-2 expression has been reported. Inhibition of COX-2 expression by IL-4 was noted using peripheral blood monocytes, alveolar macrophages and non-small cell lung cancer cells 101–103. We performed studies on nasal polyp-derived fibroblasts and mononuclear phagocytic cells. Monocytes were utilized both as representative inflammatory cells, but also because PGE2 is their dominant prostaglandin product. Similar to other findings, significant inhibition of COX-2 and also mPGES-1 (but not COX-1) mRNA and protein expression was observed following stimulation with IL-4 on both the monocytes and nasal polyp-derived fibroblasts 79. Inhibition of COX-2 and mPGES-1 synergize to result in dramatically less stimulated PGE2 secretion by monocytes 79. IL-13 has been reported to have a similar effect on airway epithelial cells 104. Thus, in addition to enhancing the CysLT pathways, IL-4 and IL-13 contribute to the AERD phenotype through inhibition of the PGE2 pathway. The role of IFN-γ modulation of the prostaglandin pathway is unclear as its action appears to be cell-type specific. IFN-γ can induce COX-2 mRNA in most inflammatory cells 105, 106 whereas it decreases COX-2 expression in placental 107 and intestinal epithelial cancer cells 108. Actions of IFN-γ on other parts of the PGE2 pathway have not been studied in detail. Activation of eosinophils and mast cells by aspirin It was unknown in AERD how aspirin triggered the release of pro-inflammatory mediators. While, as noted, inhibition of COX releases the protective constraints provided by PGE2, this alone does not explain the positive signaling driving cell activation. In a particularly robust murine model of AERD, aspirin sensitivity is induced by the knocking out of the mPGES-1 gene 109. In this model, the positive – activating – signal is provided by allergic inflammation, a mechanism not likely to be relevant in AERD, at least in those AERD patients who are not atopic. We speculated that aspirin and other NSAIDs had the inherent capacity to directly activate eosinophils and mast cells. When tested, both eosinophils and mast cells generated Ca+2 fluxes following stimulation with water soluble lysine aspirin (LysASA) 14. Similar results were observed with eosinophil activation measured by EDN release and eosinophil and mast cell secretion of PGD2 14, 66. To our surprise, when eosinophils from control, aspirin tolerant, and AERD subjects were compared, no differences were observed in levels of mediator release. Our explanation as to why hypersensitivity reactions due to mediator release caused by aspirin/NSAIDs are not observed in these control cohorts reflects alterations in their PGE2 sensitivity, specifically the decreased capacity to produce and respond to this anti-inflammatory mediator observed in AERD. We speculate that the higher expression of PGE2 as well as its anti-inflammatory EP2 receptor acts to prevent the acute reactions to aspirin/NSAIDs in controls and aspirin tolerant asthmatics 21, 74. An additional explanation for the absence of clinical symptoms in these control cohorts is that when activated with aspirin, their circulating eosinophils produced very low levels of CysLTs 14 in contrast to the robust levels found in AERD subjects following aspirin ingestion 43. As mentioned earlier, AERD sinonasal and lung tissue is characterized by high numbers of eosinophilic hematopoietic progenitor (CD34+IL-5Rα+) cells 29, 110. We therefore investigated whether eosinophils differentiated from progenitor cells in the presence of IFN-γ would recapitulate the sensitivity to aspirin displayed by tissue eosinophils in vivo in AERD. After maturation with IFN-γ, the mature eosinophils displayed increased gene expression for both LTC4S and hPGDS 14, 66. Consistent with the increase in LTC4S gene expression, CysLT secretion was dramatically increased upon LysASA activation 14. In addition to increased CysLT production, these IFN-γ matured eosinophils displayed enhanced PGD2 production when stimulated with LysASA 66. Summary: Towards a generalized model for the induction of the AERD phenotype While our understanding that aspirin causes reactions and that AERD is a debilitating disease have been known for many years, the exact mechanisms driving AERD and how to treat it are still largely unknown. Our work and that of others have demonstrated the importance of both eosinophils and mast cells as drivers of the disease leading to increased expression of pro-inflammatory mediators and reflecting the loss of protective PGE2. The ultimate result is constitutive over-production of and over-responsiveness to mediators by eosinophils and mast cells in the basal state in AERD, with the uncontrolled release of mediators when these cells are directly triggered by aspirin. The increased recognition of the cellular components and mechanisms of action in AERD provides an opportunity to develop alternative targeted therapeutic approaches aimed at dampening the severe impacts of this disease. Supported by NIH grants R01AI057438, R56AI120055, and U01AI100799 Abbreviations 5-LO 5-lipoxygenase AERD aspirin exacerbated respiratory disease AFS allergic fungal sinusitis CHES chronic hyperplastic eosinophilic sinusitis COX cyclooxygenase CysLT cysteinyl leukotriene ECP eosinophil cationic protein Eo/B CFU eosinophil/basophil progenitors or colony forming units GM-CSF granulocyte macrophage colony-stimulating factor IFN interferon IL interleukin LT leukotriene LTC4S leukotriene C4 synthase NP nasal polyposis NSAID non-steroidal anti-inflammatory drugs PG prostaglandin PGDS prostaglandin D2 synthase PGES prostaglandin E2 synthase SCF stem cell factor STAT signal transducer and activator of transcription Figure 1 Eosinophil and mast cell development from CD34 progenitor cell Through the actions of IL-3, IL-5 and GM-CSF, CD34 progenitor cells mature into eosinophils. Mast cells develop following stimulation with IL-3, IL-6 and SCF from CD34 progenitor cells. Figure 2 Pathway depicting metabolites of arachidonic acid important in AERD Following conversion to arachidonic acid by phospholipase A2, further processing occurs via either the prostaglandin pathway mediated by COX-1/COX-2 or the leukotriene pathway mediated by 5-lipoxygenase. Red lettering shows genes inhibited by IL-4 and pink lettering show genes stimulated by IL-4 and IFN-γ. Key Points AERD is a disease of overproduction and hyper-responsiveness to lipid mediators. Mast cells and eosinophils are key driver of AERD pathogenesis through production of pro-inflammatory mediators following aspirin stimulation. Due to their involvement, therapies that target mast cells and eosinophils may be useful in providing clinical benefit in AERD. This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. 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PMC005xxxxxx/PMC5116320.txt
LICENSE: This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. 8219232 5883 Neurol Clin Neurol Clin Neurologic clinics 0733-8619 1557-9875 27720002 5116320 10.1016/j.ncl.2016.06.009 NIHMS793069 Article Alzheimer Disease and its Growing Epidemic: Risk Factors, Biomarkers and the Urgent Need for Therapeutics Hickman RA 1* Faustin A 124* Wisniewski T 1234∞ 1 Department of Pathology, New York University School of Medicine, Alexandria ERSP, 450 East 29th Street, New York, NY 10016, USA 2 Department of Neurology, New York University School of Medicine, Alexandria ERSP, 450 East 29th Street, New York, NY 10016, USA 3 Department of Psychiatry, New York University School of Medicine, Alexandria ERSP, 450 East 29th Street, New York, NY 10016, USA 4 Center for Cognitive Neurology, New York University School of Medicine, Alexandria ERSP, 450 East 29th Street, New York, NY 10016, USA ∞ Corresponding author: Thomas Wisniewski, MD, Thomas.wisniewski@nyumc.org * Equally contributed 9 6 2016 4 8 2016 11 2016 01 11 2017 34 4 941953 This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. SYNOPSIS Alzheimer disease represents one of the greatest medical challenges that face this century; the condition is becoming increasingly prevalent worldwide and as yet, no effective treatments have been developed for this terminal disease. Since the disease manifests at a late stage after a long period of clinically silent neurodegeneration, knowledge of the modifiable risk factors and the implementation of biomarkers is crucial in the primary prevention of the disease and pre-symptomatic detection of AD, respectively. This review discusses the growing epidemic of AD and antecedent risk factors in the disease process. Disease biomarkers are discussed and the implications that this may have for the treatment of this currently incurable disease. Alzheimer disease risk factors biomarkers epidemiology INTRODUCTION Alzheimer disease represents one of the greatest medical challenges that face this century; the condition is becoming increasingly prevalent worldwide and as yet, no effective treatments have been developed for this terminal disease. In the United States in 2015, over five million people suffered with AD, costing over 170 billion dollars. Since the disease manifests at a late stage after a long period of clinically silent neurodegeneration, knowledge of the modifiable risk factors and the implementation of biomarkers is crucial in the primary prevention of the disease and pre-symptomatic detection of AD, respectively. This review discusses the growing epidemic of AD and antecedent risk factors in the disease process. Disease biomarkers are discussed and the implications that this may have for the treatment of this currently incurable disease. EPIDEMIOLOGY Alzheimer disease (AD) is the most common dementia in the elderly and is a growing epidemic across the globe. Although the risks associated with developing AD are multifactorial, the greatest risk factor by far is aging1. The age-specific risk of AD dramatically increases as individuals get older; findings from the Framingham study in the early 1990s showed that the incidence doubles every five years up to the ages of 89 years2. Age-dependent increases have been seen in other studies3–5. Unsurprisingly therefore, with global reductions in fertility and extended life expectancies, the number of patients with AD is expected to increase as populations age6. In the United States, it is estimated that approximately 5.3 million people had AD in 2015; 5.1 million people being 65 years and older and approximately 200,000 people under the age of 65 years with early onset AD (EOAD) 7–9. It is estimated that the number of new cases of AD and other dementias will at least double by 2050 and substantially increase the socioeconomic burden worldwide7, 10. In 2010, it was estimated that dementia afflicted 35.6 million people worldwide, many of which will have AD, with the projection that this figure will double every twenty years11. The incidence of AD is generally lower in many less economically developed countries than in North America and Europe, however, sharp rises in prevalence have been predicted and seen in China, India and Latin America12, 13. The effect of this increasing dementia has obvious socioeconomic consequences for each country affected, through costs of hospital care and also of caregivers. In the USA, the total payments were estimated at $226 billion of which Medicare and Medicaid provided 68% 7, 14, whilst out-of-pocket expenses for patients and their families were expected to be $44 billion7. CLASSIFICATION AND STAGING Revised criteria and guidelines by the National Institute on Aging and the Alzheimer Association published in 2011 (NIA-AA) have recognized three stages of Alzheimer disease: preclinical Alzheimer disease, mild cognitive impairment (MCI) due to Alzheimer disease and dementia due to Alzheimer disease8, 15. These are described as follows: Preclinical AD: pre-symptomatic of AD with early AD-related brain changes as detected by neuroimaging or other biomarker studies; Mild cognitive impairment (MCI) due to AD: mild cognitive decline but still able to perform activities of daily living; Dementia due to AD: cognitive decline is more pronounced and interferes with activities of daily living7. With this classification in mind, it follows that the actual number of individuals with active disease are gross underestimates because they are based on approximations of diagnosed symptomatic patients and largely ignores the vast number of individuals who are preclinical, in whom the disease process is active but asymptomatic16. This long pre-clinical phase of AD is characterized by progressive neuronal loss, the formation of neurofibrillary tangles (NFT) and the deposition of amyloid plaques within the brain17–20. Although the exact pathogenesis of AD is debated, the prevailing hypothesis is that the neurodegeneration is the result of the amyloid cascade, in which aberrant digestion and processing of the amyloid precursor protein (APP) results in the accumulation of neurotoxic Aβ oligomeric proteins21–24. These proteins aggregate to form the insoluble amyloid plaques that are seen at microscopic examination of autopsy brains of AD patients. BIOMARKERS It is widely believed therefore that future therapeutics should be introduced during the preclinical and MCI stages of the disease course so as to preserve the existing functioning neural networks7, 25. In order to provide effective recognition of preclinical AD, there will likely need to be widespread implementation of disease biomarkers, such as in national screening programs targeting specific age groups and other high-risk categories. Such screening may prove popular as many patients are keen to know their disease status at an earlier time point26–28. Current disease biomarkers focus on indicators of cerebral amyloidosis or synaptic dysfunction. Markers of brain amyloidosis include reduced CSF Aβ42 concentrations and increased amyloid tracer uptake on positron emission tomography (PET) 29. These changes are followed after a period of time with markers of neuronal injury, notably increased CSF tau levels and brain atrophy on magnetic resonance imaging (MRI) 30, 31. PET tau imaging has great promise as a biomarker and may be able to provide estimates of pathological disease stage32. Validation is needed prior to introduction of these tests into the clinical setting, but would certainly be useful in providing a more complete overview of the current number of patients with AD and also in evaluating pre-clinical therapeutic response. RISK FACTORS The modifiable and non-modifiable risk factors of AD are important because they provide insight into the predispositions of the disease process prior to onset and also provides stratification of individuals who may be at increased risk. Besides aging, which, as discussed previously, is the most significant risk factor; other determinants of AD include genetic risk factors, and non-genetic, modifiable risk factors. NON-MODIFIABLE GENETIC RISK FACTORS Recent genome wide association studies (GWAS) have revealed many new genes that increase the risk of developing AD33. This review, however, considers the most commonly discussed genetic influences on the disease, notably mutations in ApoE, APP and presenilin mutations. ApoE Of all of the mutations identified in AD, genome wide association studies have demonstrated that it is the ε4 allele of the APOE gene that poses the greatest risk for AD34–38. ApoE is a 34 kDa astrocytic protein that is encoded on chromosome 19q13. The apoE gene has three alleles that result in the production of ε2, ε3 and ε4 isoforms. One of its principal functions within the CNS is the delivery of cholesterol to neurons via the ApoE receptor39. ApoE3 is the most common variant, present in approximately 60% of the population and is regarded as having no altered risk in AD7, 35, 36. However, the next most common allele is the ε4 followed by the ε2 allele. ApoE heterozygosity with ApoE4/E3 or ApoE4 homozygosity confers a significantly risk of developing AD, from three-fold to eight-twelve fold, respectively. In approximately 40% of cases of AD, ApoE4 is identified 40. Furthermore, patients with ApoE4 have poorer cognitive performance in childhood and tend to develop the disease significantly earlier than those with ApoE341. In a population based study, patients who had suffered a head injury and carried the ApoE4 allele had a ten times increased risk of developing AD, unlike those without the allele who were at two-fold increased risk42. The MIRAGE study demonstrated that patients who have suffered head injury are at markedly increased risk of developing AD43. Curiously, the ε2 isoform bestows a decreased risk of AD than the ε3 allele36. It comes as no surprise therefore that the ε2 allele is over-represented in centenarians44. Triggering Receptor on Myeloid Cells 2 Discovery of the triggering receptor on myeloid cells 2 (TREM2) allele as a rare genetic predisposition for AD has sparked interest because of its role in inflammation45. TREM2 is a receptor found on microglia that is important in phagocytosis and dampening the CNS immune response46. Mutation in TREM2 is rare, however, the most common receptor mutation (R47H) increases the risk of LOAD by approximately twofold. Furthermore, mutations in TREM2 are associated with more severe degrees of atrophy in AD than those without47. Mutations in TREM2 that increase the risk and severity of AD may result from derangements in neuroinflammation and amyloid clearance. APP and Presenilin Mutations Early onset familial AD (EOAD), which usually begins in patients younger than 65 years of age, represents less than 1% of cases of AD48. EOAD is often caused by autosomal dominant mutations such as mutations in amyloid precursor protein (APP), presenilin-1, and presenilin-2 genes48. Mutations in proteins that are involved in the synthesis of Aβ result in downstream overproduction of the pathological Aβ. APP is encoded on chromosome 21q21.3 and comprises 3 transcript variants, the most common of which protein within the CNS is 695 amino acids long49. Over 30 coding APP mutations have been identified that usually result in an autosomal dominant EOAD because of increased Aβ production, shifts in synthesis of pathologic Aβ1–42, or production of Aβ that may have increased susceptibility to aggregation50. Of interest, not all APP mutations result in AD preponderance; actually, one mutation was found to be protective50. Presenilin is one of the proteins that constitute the active site of γ-secretase and therefore mutations alter the efficacy of this enzyme increasing the amount of Aβ1–42 production. Presenilin mutations account for the majority of cases of familial AD48. Down Syndrome Down syndrome (DS) is the most common chromosomal abnormality with an incidence of 1 per 733 live births and is characterized by trisomy 2149. Since APP is encoded on chromosome 21q21.3, this results in three copies of the APP protein. This increased abundance of APP expression, production of Aβ is considered to be one of the mechanisms as to why many of these patients develop EOAD. Given that the lifespan of patients with Down’s syndrome is now 55–60 years of age, approximately 70% of patients will suffer from AD51. Cardiovascular Health A large body of evidence suggests that cardiovascular disease increases the risk of dementia. Studies that have investigated patients with clinical and subclinical cardiovascular disease have poorer cognitive function than those without52, 53. Cortical ischemic changes can increase the risk of dementia54. However, studying the role of cardiovascular disease and AD is complicated by several issues, notably that extensive cardiovascular disease and dementia may preclude from a clinical diagnosis of AD and may instead favor a diagnosis of multi-infarct dementia55. Studies have shown mixed results with regard to the influence of hypertension and this is in part due to differences in study design54, 56–58. Observational studies however have generally shown that increased hypertension are associated with cognitive decline and an increased likelihood of developing AD, possibly through blood vessel injury, protein extravasation, neuronal injury and subsequent Aβ accumulation59. Diabetes Mellitus Diabetes mellitus (DM) is associated with an increased risk of cognitive decline and AD later in life. Observational studies of type 2 DM (T2DM) have found that T2DM nearly doubles the risk of AD60–62. In the Religious Orders Study, 824 individuals who were older than 55 years of age, were evaluated for cognitive decline and AD and found that those with DM had a 65% increased risk of developing AD after a mean 5.5 year period63. The cognitive decline was found to be mainly in perceptual speed. Several meta-analyses have further confirmed an increased risk of AD in DM. The biological mechanism for this association may relate to competition of Aβ and insulin for insulin degrading enzyme, thereby reducing Aβ clearance. Alternatively, increased Aβ aggregation has been demonstrated through increased age-related glycation end-products that can occur in DM. Anti-diabetic therapies in patients with DM and cognitive impairment and also in patients with AD have shown improvement in cognition, which may be related to the anti-inflammatory properties of these drugs. Traumatic Brain Injury Traumatic brain injury (TBI) is a growing public health concern worldwide because the incidence is rising and it carries a significant healthcare and socioeconomic burden for society64–68. For patients who survive TBI, the average life expectancy is considerably shortened and many cases of TBI suffer chronic neurological and psychological morbidity that reduces quality of life 69–72. More data is now showing that there are ongoing chronic changes within the brain following TBI and that these ensuing processes may result in further damage with possible neurodegenerative sequelae73. The first documentation of a syndrome that directed attention towards a neurodegenerative phenomenon after head injury was ‘punch drunk syndrome’. This syndrome described degenerative changes after repeated episodes of sub-lethal head injuries in professional boxers 74. This condition is now termed chronic traumatic encephalopathy (CTE) and afflicts a diverse range of people including professional and amateur players of contact sports as well as veterans 75–78. CTE has pathological features that overlap with AD and TBI is recognized to shorten the time to onset of AD79. Furthermore, it is now considered that TBI is the most significant environmental risk factor for AD76, 80. Recent data has demonstrated that in both long-standing TBI and AD there is chronic inflammation within the brain parenchyma and this persistent inflammatory milieu within the brain parenchyma could be where the pathophysiology of TBI and AD converge81, 82. Following TBI the amyloid levels increase due to several factors. Firstly, APP expression is noticeably increased post-TBI83, 84. APP is particularly prominent at the axon terminals where there has been axonal transection and axonal transection is known to occur even in mild cases of TBI 85, 86. Secondly, β-secretase and γ-secretase, enzymes that both contribute to the digestion of APP and formation of Aβ are also upregulated87–89. These increases in both substrate and enzymes, results in increased deposition of amyloid at the axon bulbs and offers one explanation as to how the risk of AD is increased after TBI 90. The Influence of Neprilysin and TBI Removal of cerebral amyloid is likely to be multifactorial, involving partly passive diffusion of soluble amyloid, active transport mechanisms and cellular digestion91, 92. The degree of amyloid pathology post-TBI and in AD is particularly influenced by neprilysin. Neprilysin is a membrane zinc metalloprotease that is capable of digesting Aβ peptide and thus has the capability of reducing the amyloid load within the brain93. Neprilysin knockout mice demonstrate increased amyloid burden in a gene-dose dependent correlation94. Johnson and colleagues demonstrated that in post-mortem subjects, the degree of amyloid burden was most in patients who had more than 41 GT repeats in the promoter region of the neprilysin gene, which was considered to be related to defective amyloid clearance 95. Curiously, neprilysin expression increases post-TBI and this may be a mechanism by which Aβ and amyloid plaques are cleared months after injury, despite increased intra-axonal APP and presenilin-1 expression 96. With age-related reduction in neprilysin, the balance between formation of amyloid and its breakdown may shift towards accumulation of amyloid and this may be responsible for the preponderance to AD post-TBI97. There is also likely to be a contribution to amyloid breakdown from microglial activation. Neprilysin, metalloproteinase-9 and several other factors that are released by healthy microglia, digest Aβ98. There is a heightened neuro-inflammatory response following TBI that persists, and the activation of microglia most likely releases factors that will assist in the digestion of Aβ. However, with aging, the efficacy of microglial breakdown is likely to be lost, and may even accentuate the accumulation, thereby causing a gradual shift toward accumulation of amyloid in the dynamic Aβ turnover99. Previous Amyloid Exposure One of the most concerning developments over the past few years has been the accumulation of evidence that suggests infectivity of amyloid in a prion-like fashion. In a recent case series of iatrogenic CJD, a proportion of patients who received homogenized human pituitaries for growth hormone replacement were found to have significant cerebral amyloid angiopathy at autopsy, to an extent that was inconsistent with age100. Given that pituitaries may have amyloid deposits, there is the possibility that amyloid could seed through peripheral injection with proteopathic spread over subsequent decades100, 101. The proteopathic spread of amyloid in the brain has been demonstrated in numerous animal models and in human AD pathological staging102. The main fear that stem from these findings is that iatrogenic infection may occur from re-used surgical instruments, since amyloid is difficult to remove from metal devices103. Further research is needed in this area in order to gauge the significance of these findings on amyloid infectivity. Protective Factors In general, environmental influences that are anti-inflammatory appear to be beneficial at reducing the likelihood of developing AD. Low calorie diets that are sustained for a protracted period of time are associated with reduced free radical production and increased brain neurogenesis and BDNF concentrations, all of which are recognized to promote healthier brain aging44, 104. Data regarding diets that are rich in antioxidants and polyunsaturated fatty acids (PUFA) have proved inconclusive with some studies demonstrating a reduction in the risk of AD, whilst others showing no such association105–107. Other protective influences include cognitive stimulation and a high educational achievement, which improves cognitive reserve108, 109. Physical exercise does appear to reduce the risk of developing dementia and can show improvements in cognition in patients with dementia110–114. Perspectives While the incidence of AD appears to be increasing worldwide, the age-specific risk of developing AD in high income countries may be decreasing. Improvements in diet, exercise, education and management of chronic conditions, such as DM, appear to be improving the individual age-specific risk of AD within the USA115. However, in view of longer life expectancies and worldwide increases in the prevalence of other risk factors, such as obesity and DM, the incidence of AD is most likely set to increase considerably with significant socioeconomic impact. Future work on the development and validation of biomarkers and on the introduction of therapeutics into the preclinical phase of AD has the greatest promise in the effective treatment of this otherwise incurable disease. KEY POINTS Alzheimer disease is increasing in prevalence worldwide Many individuals have preclinical AD without symptoms Biomarkers are currently in development for detecting preclinical AD that may be amenable to novel therapies Addressing modifiable risk factors should also help to reduce the prevalence of AD in the future None of the authors have anything to disclose. This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final citable form. 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PMC005xxxxxx/PMC5116424.txt
LICENSE: This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. 100883691 21720 Cell Microbiol Cell. Microbiol. Cellular microbiology 1462-5814 1462-5822 27206578 5116424 10.1111/cmi.12617 NIHMS794247 Article The Borrelia burgdorferi CheY3 Response Regulator is Essential for Chemotaxis and Completion of its Natural Infection Cycle Novak Elizabeth A. 1*^ Sekar Padmapriya 2^ Xu Hui 1 Moon Ki Hwan 1 Manne Akarsh 1 Wooten R. Mark 2 Motaleb Md. A. 1# 1 Department of Microbiology and Immunology, Brody School of Medicine, East Carolina University, Greenville, North Carolina, USA 2 Department of Medical Microbiology and Immunology, University of Toledo College of Medicine, Toledo, Ohio, USA # Corresponding Author: MD A. MOTALEB, Department of Microbiology and Immunology, East Carolina University Brody School of Medicine, 600 Moye Blvd, Greenville, NC 27834, USA, motalebm@ecu.edu * Current address: University of Pittsburgh School of Medicine, Pittsburgh, PA 15224. ^ E.A. Novak and P. Sekar contributed equally as 1st authors for this reported work 14 6 2016 11 7 2016 12 2016 01 12 2017 18 12 17821799 This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. SUMMARY Borrelia burgdorferi possesses a sophisticated and complex chemotaxis system but how the organism utilizes this system in its natural enzootic life cycle is poorly understood. Of the three CheY chemotaxis response regulators in B. burgdorferi, we found that only deletion of cheY3 resulted in an altered motility and significantly reduced chemotaxis phenotype. Though ΔcheY3 maintained normal densities in unfed ticks, their numbers were significantly reduced in fed ticks compared to the parental or cheY3-complemented spirochetes. Importantly, mice fed upon by the ΔcheY3-infected ticks did not develop a persistent infection. Intravital confocal microscopy analyses discovered that the ΔcheY3 spirochetes were motile, but appeared unable to reverse direction and perform the characteristic backward-forward motility displayed by the parental strain. Subsequently, the ΔcheY3 became “trapped” in the skin matrix within days of inoculation, were cleared from the skin needle-inoculation site within 96 hours post-injection, and did not disseminate to distant tissues. Interestingly, although ΔcheY3 cells were cleared within 96 hours post-injection, this attenuated infection elicited significant levels of B. burgdorferi-specific IgM and IgG. Taken together, these data demonstrate that cheY3-mediated chemotaxis is crucial for motility, dissemination, and viability of the spirochete both within and between mice and ticks. INTRODUCTION Bacterial cells possess sophisticated signal transduction pathways that detect changes in specific parameters of their dynamic external environment, allowing them to respond appropriately to the fluctuating environment (Falke et al., 1997, Skerker et al., 2005). Chemotaxis, the cellular movement in response to chemical gradients (Wadhams et al., 2004), is one behavior that bacteria alter based on their external environment (Wolanin et al., 2002). This movement empowers bacteria to approach and remain in beneficial environments or escape from noxious ones by modulating their swimming behaviors. There are a vast array of signals, including nutrient concentrations, osmolarity, temperature, oxygen, and pH changes, which bacteria integrate together and translate into a specific response (Falke et al., 1997), either benign or pathogenic (Wadhams et al., 2004). Bacterial chemotaxis pathways are regulated by a complex two-component signal transduction system (Falke et al., 1997, Bourret et al., 2010, Hazelbauer, 2012). The system starts with the membrane-bound chemoreceptors—methyl-accepting chemotaxis proteins (MCPs)—that sense external stimuli. The MCPs are coupled (via the coupling protein, CheW) with CheA, a histidine kinase. The catalytic activity of CheA is mediated by a ligand (either attractant or repellant) bound to the MCPs. Once active, CheA utilizes ATP to autophosphorylate and then proceeds to phosphorylate the response regulator, CheY. Phosphorylated CheY (CheY-P) then binds to the flagellar switch proteins FliM and FliN, regulating the direction of rotation of the flagella (Welch et al., 1993, Toker et al., 1997, Djordjevic et al., 1998, Sarkar et al., 2010). Borrelia burgdorferi, the causative agent of Lyme disease (Burgdorfer et al., 1982, Lane et al., 1991), is the most common arthropod-borne disease in the United States and Europe (Mead, 2015). Chemotaxis and motility genes comprise approximately 5–6% of the genome of B. burgdorferi, and we have shown that motility is required for every stage of the infectious life cycle of B. burgdorferi (Sultan et al., 2013, Motaleb et al., 2015, Sultan et al., 2015). In nature, B. burgdorferi cycles between the Ixodes tick vector and a mammalian host (Burgdorfer et al., 1982, Levine et al., 1985, Lane et al., 1991, Tsao, 2009, Brisson et al., 2012). Completion of the enzootic cycle requires that B. burgdorferi traverse through dense and complex tissues within tick and vertebrate hosts; the spirochetes must migrate from the midgut to the salivary glands within the tick to allow transmission to the next host during tick feeding (Dunham-Ems et al., 2009, Radolf et al., 2012, Sultan et al., 2013), as well as navigate through the skin matrix of a vertebrate host after deposition via the tick-bite to reach a multitude of target tissues before migrating back to a feeding tick (Ribeiro et al., 1987, Dunham-Ems et al., 2009, Pal, 2010, Radolf et al., 2012, Sultan et al., 2013). The spirochete must complete these tasks all by simultaneously detecting its current environment, determining its next optimal direction, and evading the immune systems of both hosts. Indeed, a recent global signature-tagged mutagenesis study identified that mutations in chemotaxis and motility genes were most often associated with loss in infectivity of B. burgdorferi, signifying their importance for its enzootic lifecycle (Lin et al., 2012). While chemotaxis has been extensively studied in Escherichia coli and Salmonella enterica (Armitage, 1999, Bren et al., 2000, He et al., 2014), the chemotaxis system of B. burgdorferi is poorly understood and differs greatly from those prototypic systems. The Lyme disease spirochete is relatively long (10 to 20 μm) and thin (0.3 μm) with a distinctive flat-wave morphology, and motility is generated by rotation of the periplasmic flagella (Charon et al., 2012). Between 7 to 11 periplasmic flagella are attached near each cellular pole, causing the motility/chemotaxis behavior of B. burgdorferi and other spirochetes to be unique and complex. Tracking of B. burgdorferi swimming in vitro has described that spirochetes perform run, flex, and reverse swimming modes. Runs occur when the periplasmic flagellar motors at one pole rotate in the direction opposite that of the motors at the other pole (motors at one end rotate in clock-wise whereas motors at other end rotate counter clock-wise). The flex is a non-translational (i.e. no net motility) mode and is thought to be equivalent to the E. coli tumble. During the flex, the motors at both poles rotate in the same direction, i.e. both rotate in clock-wise (CW) or counter clock-wise (CCW). Spirochetal reversal occurs in translating (i.e. motile) cells when the motors at each end reverse their direction of rotation. For spirochetes to swim toward an attractant, the organisms must be able to coordinate the rotation of the motors at the two separate poles of the cell that are located at a considerable distance from one another (often greater than 10 μm). One of the questions related to spirochete chemotaxis is how the organisms are able to achieve this coordination (Li et al., 2002, Motaleb et al., 2005, Motaleb et al., 2011b, Charon et al., 2012, Wolgemuth, 2015). The genome of B. burgdorferi encodes multiple homologs of several chemotaxis genes (e.g. two cheA, three cheW, three cheY, two cheB, and two cheR genes), making it much more complex than E. coli or S. enterica (Fraser et al., 1997, Charon et al., 2012, Motaleb et al., 2015). In several species of pathogenic bacteria, the CheY response regulator has been shown to play an important role in chemotaxis, which is also needed for virulence (Butler et al., 2005, McGee et al., 2005, Antunez-Lamas et al., 2009, Lertsethtakarn et al., 2011). To date, only two studies have shown that chemotaxis—specifically involving the histidine kinase cheA2 and phosphatase enhancer cheD—are essential for the infectious life cycle of B. burgdorferi (Sze et al., 2012, Moon et al., 2016). Amino acid sequence analysis indicates that B. burgdorferi CheY1, CheY2, and CheY3 share 25–37% identity with each other. Moreover, these proteins share 32%, 38%, and 25% amino acid sequence identity with E. coli CheY, respectively (Motaleb et al., 2011b). Importantly, all of the functional residues of the E. coli CheY response regulator were found to be conserved in CheY1, CheY2, and CheY3, suggesting that they all are potential chemotaxis response regulators. Previous reports also indicate that cheY3, but not cheY1 or cheY2, is important for motility and chemotaxis in vitro (Motaleb et al., 2011b). Moreover, the function of cheY3 cannot be substituted by the other cheYs in B. burgdorferi. Importantly, those cheY mutants were constructed in a high-passage, avirulent strain that cannot be evaluated in the tick vector or vertebrate hosts (Motaleb et al., 2011b). We hypothesize that cheY3 is crucial for one or more stages of the enzootic cycle. The goal of this study is to utilize a cheY3-mutated B. burgdorferi generated in a virulent genetic background to delineate the importance of CheY3 for the different host environments encountered by these bacteria. Our findings are significant in describing the deficiencies in motility and chemotaxis abilities exhibited by the ΔcheY3 strain and delineating the essential nature of this gene for every stage of the tick-mouse infection cycle. Based on our data, we propose a model indicating the importance of chemotaxis (and motility) during the enzootic life cycle of B. burgdorferi. RESULTS Construction and confirmation of ΔcheY3 and cheY3+ strains B. burgdorferi genome sequence and transcriptional analyses indicated that the cheY3 gene is located on the large linear chromosome and is transcribed as a polycistronic mRNA using a σ70 promoter (Li et al., 2002). Previous reports also indicate that only cheY3 is essential for chemotaxis (Motaleb et al., 2011b). However, those studies were done in vitro under one condition, using a high-passage, non-infectious clone that cannot be evaluated in the tick-mouse infectious cycle (Motaleb et al., 2011b). To determine the importance of cheY3 in the pathogenic life cycle of B. burgdorferi, we constructed a ΔcheY3 in the low-passage B31-A3 strain using a promoterless kanamycin resistance cassette, Pl-Kan (Figure 1A) (Sultan et al., 2010). PCR data confirmed the deletion of the cheY3 gene (data not shown, see below). The cheY3 gene is located at the end of its operon, thus integration of Pl-Kan in place of the cheY3 gene is unlikely to exhibit a polar effect on the expression of downstream genes. However, we complemented the ΔcheY3 in cis by genomic integration to ensure the phenotype of the mutant was solely attributed to the inactivation of the cheY3 (Figure 1A). Mutation and complementation of cheY3 were confirmed by western blotting as demonstrated by the absence or presence of CheY3 production, respectively (Figure 1B). Since cheY3 is in a polycistronic operon, we verified expression of other gene products (cheX and cheA2) in that operon. As shown in Figure 1B, expression of CheA2 and CheX proteins were not affected in ΔcheY3 bacteria. Furthermore, linear and circular endogenous plasmids of the mutant and complemented clones were verified by PCR and found that all clones retained the plasmids seen in the parental wild-type (WT) cells (data not shown). In vitro phenotypes of ΔcheY3 The growth, motility, and chemotaxis phenotypes of ΔcheY3 were assessed in vitro using various approaches. Dark-field microscopic analysis indicated that WT and cheY3+ cells exhibited run-flex/pause-reverse swimming patterns, whereas ΔcheY3 cells constantly ran in a single direction without reversals or switching their swimming direction. Additionally, semi-solid plating analysis showed that ΔcheY3 formed significantly smaller swarming colonies compared to WT or cheY3+ (Figure 2A). Despite the altered motility and swarming deficiencies, ΔcheY3 had no growth defect in liquid culture relative to WT or the cheY3+ (data not shown). Additionally, the chemotactic response of the ΔcheY3 was measured by using a quantitative capillary-tube chemotaxis assay. As expected, the chemotactic ability of the mutant was significantly reduced when compared to the WT or complemented cells (Figure 2B). The complemented cells exhibited a chemotactic response that was higher than the WT cells. We currently do not understand why this response was enhanced, but we speculate that the cheY3+ cells assessed for this assay were taken from a growth phase that was more chemotactic than the WT cells even though we were careful to collect all clones from the same growth phase. Together, these data are the same as reported previously, which indicate that cheY3 is important for chemotaxis as well as for governing motility in B. burgdorferi in vitro (Motaleb et al., 2011b). ΔcheY3 spirochetes are unable to survive in mice by needle injection To evaluate the ability of the ΔcheY3 to establish infection in a mammalian host, groups of C3H/HeN mice were needle-inoculated with WT, ΔcheY3, or cheY3+, and multiple tissues (i.e. ear, bladder, and joint tissues from each mouse) were collected at 4 weeks post-injection to determine bacterial outgrowth (Table 1). WT and complemented cells were re-isolated from one or more tissues assessed from all mice in those groups, demonstrating that these cells established an infection. Alternatively, ΔcheY3 spirochetes were not re-isolated from any mouse tissues, even when infected with 1×106 bacteria (Table 1). These results indicate that the cheY3 chemotaxis response regulator is essential for B. burgdorferi infection in a mammalian host. ΔcheY3 spirochetes are unable to infect mice by Ixodes scapularis tick bite Tick-mouse-tick infection studies were performed to determine if ΔcheY3 spirochetes are able to colonize, replicate, and transmit from infected ticks to naïve C3H/HeN mice. Since ΔcheY3 were unable to infect mice via needle inoculation, infecting ticks via feeding on infected mice was not feasible. Alternatively, we performed tick-immersion studies in order to artificially infect naïve larvae, and then the ticks were allowed to feed on naïve mice to determine the ability of the spirochetes to transmit from infected ticks to naïve mice. Additionally, the burden of spirochetes per tick was evaluated to determine the replication and survival of the spirochetes within the fed larvae 7 days post-repletion. Immunofluorescence assay using a FITC-conjugated antibody specific for B. burgdorferi demonstrated that spirochetes were intact within fed ticks (data not shown). However, while artificial immersion achieved a 90% infection rate of ticks for all strains (data not shown), the burden of ΔcheY3 spirochetes per tick was significantly less when compared to the WT or the cheY3+ cells, as determined by tick plating (Figure 3A). This result indicates that the non-chemotactic ΔcheY3 has a decreased ability to survive or multiply within fed larvae. Four weeks after tick-feeding, mice were euthanized and animal tissues were cultivated to re-isolate B. burgdorferi in order to determine transmission from tick to mouse. No tissues from mice fed on by ΔcheY3-infected ticks showed bacterial outgrowth whereas 4 out of 5 mice fed upon by WT- or cheY3+-infected larvae showed regrowth (Figure 3B). These assays were also performed using encapsulated artificially immersed nymphs that produced similar results—reduced survivability of the mutants in fed but not in unfed ticks (Figures 4A, B). Moreover, we assessed the skin containing the tick-bite site, as well as ear, joint, and bladder tissues for bacterial outgrowth; PCR was also performed to detect spirochetes genomes. The artificially ΔcheY3-immersed nymphs were unable to establish an infection in any of the mice they fed upon, as the mutant bacteria were not reisolated by outgrowth in culture media or detected by PCR from those tissues, whereas five out of six mice were positive for WT bacteria and three out of six mice were positive for the cheY3+ spirochetes (Figure 4C). Together, these results indicate that chemotaxis is crucial for optimal survival of spirochetes in ticks and infection of mice by tick-bite. Intravital microscopy shows that ΔcheY3 motility behavior within skin is similar to its in vitro phenotype The finding that the ΔcheY3 was unable to infect mice via needle-injection or tick-bite suggested this mutant would demonstrate similar deficiencies in motility/chemotaxis in vivo as observed in vitro. To address this, intravital confocal fluorescence microscopy was used to directly observe GFP-expressing strains of WT and ΔcheY3 within the intact skin tissues of living mice. No notable differences were observed in the shapes of the WT GFP-expressing B. burgdorferi (WT-eGFP) and ΔcheY3-GFP-expressing B. burgdorferi (ΔcheY3-eGFP) spirochetes, suggesting that loss of this chemotaxis protein does not alter the morphology of B. burgdorferi within skin tissues. Assessment of time-lapse images taken at 6 hours post-injection showed that the majority of WT bacteria displayed a back-and-forth (B/F) motion (see Experimental Procedures section for a description of different motility events), with only a few showing directed runs (Figure 5B and Video 1) (Harman et al., 2012). Alternatively, while the majority of the ΔcheY3 mutants appeared non-motile, those that did display translational motility were unable to reverse their direction; even when they did stop moving, they were only able to continue movement in the same direction (Figure 5B and Video 2). Viewing the non-motile ΔcheY3 at a higher magnification showed that the majority of these mutants appeared to be trying to move forward, but could only make a minimal gain as they appeared stuck and were returned to the same spot, resulting in no net movement. This suggests that certain tissue components were hindering B. burgdorferi movement, and since the ΔcheY3 cannot reverse direction to find an unhindered route, they lose translational motility. Based on our described motility patterns (see Experimental Procedures), WT bacteria maintained the B/F motion as the major motility behavior over a period of 48 hours, whereas the majority of the ΔcheY3 bacteria were non-translational by 6 hours and almost all were non-motile at 48 hours (Figure 5C), suggesting the ΔcheY3 mutants are either stuck or become non-motile and/or cleared. Since a significant number of ΔcheY3 bacteria were non-translational by 6 hours, the velocity of bacteria that could translocate (translational, includes both run and B/F) and the ones that could not (non-translating bacteria defined above) were calculated separately. The average velocity of translating WT bacteria was 217.7 μm/min while translating ΔcheY3 bacteria was 183.4 μm/min (Figure 5D). Thus, even though ΔcheY3 were unable to reverse direction, they could still achieve velocities similar to that of the WT bacteria in skin. The velocity of bacteria at later times post-injection was not calculated, since the majority the ΔcheY3 bacteria (>90%) were non-translational after 6 hours post-inoculation. These observations suggest that the loss of cheY3 affects the motility pattern, but not the velocity potential of B. burgdorferi within murine skin. ΔcheY3 bacteria fail to disseminate from the skin injection site to other target tissues and are cleared within 4 days post-injection To determine the persistence of the mutant in mice, ΔcheY3-eGFP and WT-eGFP bacteria were injected intradermally into ear skin and confocal microscopy images were collected at the indicated times post-injection for manual enumeration of the spirochetes in each image. The burden of WT bacteria appeared to initially decrease between 6 hours and 24 hours post-injection, but subsequently increased dramatically between 48 hours and 96 hours post-injection (Figure 6A, right panel). Alternatively, the burden of ΔcheY3 steadily decreased after 6 hours post-injection, such that none of the mutants were visible by 96 hours post-injection, suggesting that the murine immune system cleared the ΔcheY3 from skin tissues within 96 hours post-injection. Although the same number of WT and ΔcheY3 spirochetes was injected, there appeared to be more ΔcheY3 than WT bacteria per viewing field at 6 hours post-injection (Figure 6A). We speculate that these differences are artificial due to more ΔcheY3 spirochetes becoming stuck at the injection site compared to WT spirochetes, since WT are capable of efficiently migrating through skin. These data indicate that loss of cheY3 leads to increased clearance of B. burgdorferi within murine skin tissues. Although the ΔcheY3 appeared to be cleared relatively quickly at the inoculation site, it was still feasible that their limited mobility could allow dissemination to distant tissues via the bloodstream or other routes. To address this, B6 mice were intradermally injected with WT-eGFP or ΔcheY3-eGFP spirochetes and a number of target tissues (e.g. distant back skin, ankles, and heart) were harvested at the indicated times post-injection for bacterial enumeration by qPCR (Figure 6B). ΔcheY3 were cleared from all ear tissues (i.e. the injection site) by 96 hours post-injection, whereas WT spirochetes persisted in ear tissues (Figure 6B; top left), corroborating our intravital microscopy results (Figure 6A). Assessment of all distant tissues (i.e. back skin, heart, and ankles) indicated that WT B. burgdorferi were detected in all tested tissues by day 14–28 post-injection. However, no ΔcheY3 were detected in any of these tissues at any times post-injection, implying that these mutants did not escape the injection site but were instead cleared from the local ear tissues by the murine immune system (Figure 6B). This is consistent with the tick-mouse infection studies (Figure 3C and 4C), where ΔcheY3 spirochetes could not be re-isolated or detected from mouse tissues harvested 4–28 days after infected-ticks fed to repletion. Thus, loss of cheY3 leads to early clearance of B. burgdorferi in mice and an inability to disseminate to distant tissues. Infection with ΔcheY3 is sufficient to elicit B. burgdorferi-specific antibodies Typically during any infection, an immunocompetent vertebrate host initiates a primary antibody response that consists mainly of IgM antibodies. As this initial response starts to wane, the host then generates a stronger secondary antibody response that is primarily comprised of pathogen-specific IgG antibodies. Interestingly, B. burgdorferi infection of both mice and humans elicits a continuously increasing IgM response during an active infection together with an IgG response that is not well-maintained after the infection is cleared (Kalish et al., 2001, Hastey et al., 2012, Elsner et al., 2015). When the antisera from our current experiments were assessed by ELISA, WT bacteria elicited a strong B. burgdorferi-specific IgM response that continued to increase even after 60 days post-injection (Figure 7A), similar to those studies listed previously. Alternatively, ΔcheY3 infection elicited IgM levels similar to WT ≤28 post-injection, but these levels subsequently decrease by day 62 (Figure 7A). B. burgdorferi-specific IgG levels generated in response to the ΔcheY3 were also similar to WT ≤28 post-injection (Figure 7B); however the WT IgG levels continue to increase between days 28 and 62 post-injection, whereas antibody levels against ΔcheY3 did not increase after day 28, but was maintained for the duration of this experiment. Interestingly, the IgG levels against a non-motile ΔmotB (lacks the MotB motor stator), which we previously reported were cleared within 48–72 hours post-injection and elicited a minimal B. burgdorferi-specific antibody response, were lower than both WT and ΔcheY3 at day 62 post-injection (Sultan et al., 2015). Thus, although the IgM response is abbreviated in the ΔcheY3-infected mice, the infection is still sufficient to generate a robust B. burgdorferi-specific IgG response that persists well after bacterial clearance. DISCUSSION The enzootic lifecycle of B. burgdorferi requires that it cycles between a tick vector and a vertebrate host (Burgdorfer et al., 1982, Welch et al., 1993, Toker et al., 1997). This necessitates that the spirochete sense and assess its external environment, and subsequently responds in an appropriate fashion by changing its cellular behavior and/or gene expression accordingly. The chemosensory system of B. burgdorferi would presumably aid in such sensing as well as traversing a path between the tick vector and the mammalian host. Previous results indicate that all of the chemotaxis genes in the flaA-cheA2-cheW3-cheX-cheY3 operon are important for chemotaxis in vitro (Li et al., 2002, Motaleb et al., 2005, Motaleb et al., 2011b, Zhang et al., 2012). Additionally, previous studies have demonstrated that CheA2 is capable of both autophosphorylating and transferring that phosphoryl group to CheY3 (Motaleb et al., 2005). Therefore, it is plausible that CheA2 and CheY3 comprise a two-component system in B. burgdorferi, and that CheA2 is the cognate kinase for CheY3. The in vivo studies with the ΔcheY3 demonstrated that burden of the ΔcheY3 in fed but not unfed ticks was significantly reduced compared to the burden of parental spirochetes (Figure 4A, B). The reason for this observed reduced burden in ticks is unknown. It is possible that since the ΔcheY3 is non-chemotactic and only able to swim in one direction it is easily identified and captured by the innate immune system of the tick or that ingested blood factors more efficiently cleared the mutant organisms (Ribeiro et al., 1990, Kern et al., 2011, Hajdusek et al., 2013). Based on our previous investigations with motility and cyclic-di-GMP mutants, we proposed that back-and-forth motility is crucial to protect the spirochetes in the fed ticks (Sultan et al., 2010, Pitzer et al., 2011, Sultan et al., 2013, Novak et al., 2014, Motaleb et al., 2015, Sultan et al., 2015). The same proposal can be applied here, as the ΔcheY3 spirochetes are unable to reverse their swimming patterns. Nevertheless, further studies are needed in order to determine the cause for the reduced burden of the ΔcheY3 in ticks. The inability of the chemotaxis-deficient ΔcheY3 to establish an infection in mice is not completely understood, but could be due to the inability of the mutant to disseminate to target organs and/or evade the host cellular immune responses, as these mutant cells are not able to relay its CheY3-associated signals to the flagellar motor, and thus would not respond appropriately to certain chemotactic signals within their microenvironment (Table 1 and Figure 3C, 4C). We noticed that the in vivo phenotype of the mutant was partially restored in the cheY3+ cells (Figure 4C) even though we complemented the mutant by genomic reconstitution, and the CheY3 protein expression was restored to WT level (Figure 1). The reason for the partial restoration could be due to the loss of some of the endogenous B. burgdorferi plasmids in part of the population of the cheY3+ cells (Sultan et al., 2013). Nonetheless, our current data suggest that the failure of ΔcheY3 to switch its swimming behavior is causing the mutant to become trapped in the skin tissues. Skin dermis is a meshwork composed of a variety of ECM molecules, including collagen, elastin, and an extrafibrillar matrix made up of glycosaminoglycans (GAGs), proteoglycans, and glycoproteins (Leong et al., 1998, Parveen et al., 2000, Jarvelainen et al., 2009). WT B. burgdorferi appear able to detect barriers in its motility pathway and subsequently reverse or change its direction before taking an adjacent path that might be comprised of less dense tissue. Alternatively, the ΔcheY3 is unable to reverse and adjust its direction, and thus will eventually become trapped after translocating into a dense area, indicating that back-and-forth movement is essential for maneuvering around complex structures in the skin tissue (Moriarty et al., 2008, Norman et al., 2008). This is supported by the significant reduction of ΔcheY3 in skin by 24 hours and complete clearance by 96 hours post-injection (Figure 6A), suggesting that these non-translating spirochetes were quickly recognized and efficiently cleared by innate immune components. There are currently no commercially available vaccines to protect against B. burgdorferi infection. Many of the individual purified proteins tested as vaccines do not confer complete protection (Hanson et al., 1998, Exner et al., 2000, Hagman et al., 2000, Nogueira et al., 2012, Floden et al., 2013). Passive transfer of serum from mice (or humans) injected with WT bacteria or with certain B. burgdorferi proteins seem to provide limited protection (Fikrig et al., 1994, Barthold et al., 1997, Hanson et al., 1998, Fikrig et al., 2000, Hagman et al., 2000, Floden et al., 2013, Small et al., 2014), suggesting that antibodies can provide protection if generated against critical antigens. Attenuated or killed vaccines have been successful in preventing many bacterial and viral infections (Mc, 1948, Mekalanos, 1994, Jin et al., 2015), but there are few studies screening non-infectious B. burgdorferi mutants for potential protective abilities. Immunization with killed or an aflagellar B. burgdorferi mutant conferred protection to naïve mice only if the mice were challenged early with WT bacteria (Johnson et al., 1986, Sadziene et al., 1996). But similar to passive immunization results, the protective ability of these attenuated (or killed) strains was decreased if the mice were challenged late (≥ 90 days post-immunization) (Johnson et al., 1986, Sadziene et al., 1996). One of the reasons surmised for this failure to achieve long-lasting immunity was that these mutants did not persist more than 24 hours post-injection, which is insufficient for generating an effective antibody response, particularly since it theoretically would not provide enough time for the mutants to upregulate critical virulence proteins that are expressed during vertebrate infection. Our observation that the ΔcheY3 survived ≤96 hours post-injection suggested that these mutants might persist long enough to upregulate more vertebrate host-specific virulence factors that could elicit antibodies capable of conferring protection from subsequent challenges. Our studies showed that infection with the ΔcheY3 generated similar levels of spirochete-specific IgM and IgG as WT B. burgdorferi through day 28 post-infection before reaching a significant baseline level that was maintained at least through day 62 post-infection. Notably, these levels were also significantly higher at all times tested than those generated against a non-motile ΔmotB strain that was shown to be cleared within 48–72 hours post-infection (Sultan et al., 2015). This implies that infection with the ΔcheY3 could potentially generate sufficient levels of spirochete-specific antibodies to confer protection against future challenges with fully virulent B. burgdorferi strains. If so, such studies might also allow the identification of individual antigens that can elicit protective antibodies, potentially leading to a vaccine based on recombinant proteins. Further studies are needed to demonstrate that infection with the mutant protects against WT infection. As mentioned, B. burgdorferi contains three homologs of the cheY gene, which are located in separate operons (Motaleb et al., 2011b). However, lack of cheY3 was not compensated for by the other cheY homologs, and evidence suggests that cheY1 and cheY2 are not important for motility and chemotaxis in vitro (Motaleb et al., 2011b). So, what then is the function of these additional cheY genes? Many bacterial genomes contain multiple copies of a chemotaxis cheY gene and at least one of them is shown to be dedicated to control motility, similar to what we report in this communication with cheY3. The function of most of the additional genes is unknown (in any bacterium). There are a few instances in which multiple chemotaxis-like signaling systems appear to have very different roles in the same species and those additional cheY genes may control other cellular non-chemotactic processes (Kato et al., 1999, Szurmant et al., 2004, Whitchurch et al., 2004, Berleman et al., 2005). Consequently, it is plausible that B. burgdorferi CheY2 or CheY1 controls some non-chemotactic cellular processes such as serving as virulence determinants rather than acting as a classical chemotaxis response regulator, like CheY3 (H. Xu et al—manuscript under review; our unpublished observations). In summary, we have shown that the CheY3 response regulator is an essential component of the chemosensory system in B. burgdorferi, and that CheY3 is important for successful completion of the enzootic lifecycle and for continued perpetuation of Lyme disease. Based on our data, we propose that the chemosensory system of B. burgdorferi, and by extension motility, is critical during mammalian infection, dissemination, and possibly transmission from tick to the vertebrate host (Figure 8) (Motaleb et al., 2015). The motility/chemotaxis system is likely to be “active” or “on” during dissemination and persistent infection of the mammalian host, as well as during the tick’s blood-meal to allow navigation from the mouse into the tick and subsequent colonization of the mid-gut. However, after the nutrients from the blood-meal are depleted during the molt, B. burgdorferi must shut down flagellar rotation and chemotaxis to conserve energy, as this (motility/chemotaxis) system is unnecessary during molting (Figure 8) (Motaleb et al., 2015). Motility and chemotaxis must then be turned back “on” during nymphal feeding for subsequent transmission of the spirochetes. Although the latest time point post-injection analyzed by intravital microscopy in this study was 96 hours, we have examined WT-eGFP bacteria constantly swimming in the murine host for >2 years post-injection (R. M. Wooten and M. A. Motaleb, unpublished data). Accordingly, we propose that continuous chemotaxis/motility activities are necessary for persistent mammalian infection and are still required even after B. burgdorferi reaches its target colonization tissues in the mammal host. As outlined in Figure 8, CheY proteins are phosphorylated by CheA-P. CheY3-P then binds to the flagellar switch proteins to alter swimming behavior until it is dephosphorylated by the CheX phosphatase (Motaleb et al., 2005, Pazy et al., 2010). Based on our data, only CheY3 appears to act as a classical response regulator, as it contributes to motility and chemotaxis. Further studies are needed to not only elucidate the environmental signals that trigger the “active/on” or “inactive/off” status of the chemotaxis/motility system, but also the exact molecular components that transduce these signals within the spirochete. EXPERIMENTAL PROCEDURES Ethics statement East Carolina University and University of Toledo are both accredited by the International Association for the Assessment and Accreditation of Laboratory Animal Care. All animal procedures received Institutional Animal Care and Use Committee approvals and were in accordance with federal guidelines for the care and use of laboratory animals. Mouse strains All intravital microscopy experiments were performed utilizing C57BL/6 (B6; National Cancer Institute); all other experiments were completed using C3H/HeN mice (Charles River Laboratories, Raleigh, NC). These mouse strains contain equivalent susceptibilities to infection with B. burgdorferi and have been shown to contain similar bacterial numbers in most tissues during persistent infection, even though they can yield different levels of disease severity (Ma et al., 1998, Brown et al., 1999b, Weis et al., 1999). Bacterial strains and growth conditions Low-passage, virulent B. burgdorferi strain B31-A3 was utilized as the WT clone throughout this study (Elias et al., 2002). This clone was used to infect naïve C3H/HeN mice and then was reisolated from the mouse tissues, subcloned, and used as the parental clone for all of our subsequent studies. The genome of this strain is known to contain 12 linear and 9 circular plasmids, for a total of 21 plasmids, in addition to a 960-kbp linear chromosome (Fraser et al., 1997, Casjens et al., 2000). This strain lacks circular plasmid 9 (cp9), but still maintains its infectivity in tick-mouse infection studies (Elias et al., 2002, Jewett et al., 2009). Amplified genomic DNA from B31-A3 was used as the foundation to construct the ΔcheY3 (explained below). B. burgdorferi cells were grown in liquid Barbour-Stoenner-Kelly (BSK-II) medium, and cells were plated using plating BSK (P-BSK), which was prepared using 0.5% agarose (Motaleb et al., 2007, Stewart et al., 2008b, Sultan et al., 2013). Cells were grown at 35°C in a 2.5% CO2 incubator, as previously described (Elias et al., 2002, Smith et al., 2003, Motaleb et al., 2007). When required, culture and plating medium were supplemented with appropriate antibiotics at the following concentrations: 200 μg/ml kanamycin and 100 μg/ml streptomycin. The endogenous plasmid contents from all B. burgdorferi strains were confirmed before commencing any in vivo study involving ticks or mice. Construction of the ΔcheY3, complement, and green-fluorescent protein (GFP) strains The B. burgdorferi cheY3 gene was identified from the genomic sequence of B. burgdorferi and was annotated as bb0672 (441 bp) (Fraser et al., 1997). Construction of the cheY3-deletion plasmid, electroporation, and plating conditions were described previously (Sultan et al., 2010, Pitzer et al., 2011). Briefly, three pieces of DNA fragments were amplified separately by PCR: cheY3 gene plus adjacent DNA from the 5′-end (1 kb), the promoterless kanamycin resistance cassette, and the 3′-flanking DNA of cheY3 (1 kb). PCR primer sequences are not shown here but can be obtained upon request. These three pieces of fragments were gel purified and then ligated by overlapping PCR, as described in detail (Motaleb et al., 2011a). The PCR product was then ligated into the pGEM-T Easy vector (Promega, Inc.), yielding pCheY3-Pl-Kan-Easy. DNA containing cheY3-Pl-Kan was linearized by NotI restriction digestion to remove the ampicillin marker of the vector and electroporated into competent B31-A3 cells to obtain mutants (Motaleb et al., 2000, Sultan et al., 2013). Transformants were screened by PCR for proper recombination of the cheY3 inactivation cassette. The ΔcheY3 GFP-expressing strain was constructed in the same manner as the ΔcheY3, except the linearized DNA was electroporated into a B31-A3-GFP expressing strain, as described previously (Sultan et al., 2015). In order to complement the cheY3 mutation, the cheY3 and cheX gene were amplified from genomic DNA along with adjacent flanking DNA using the primers (5′-3′): CheY3.FORWARD (TTGGATGCTGCTTCTTCGG) and CheY3.REVERSE (GCTGCTTGCATTGTTAG). The resulting PCR product was ligated into the pGEM-T Easy vector, yielding RCY3-Easy. The PflgB-aadA cassette, which confers resistance to streptomycin (Frank et al., 2003), was similarly amplified with engineered HindIII sites by PCR using the following primers (5′-3′): Flg-F (AAGCTTCCCGAGTTCAAGGAAGAT) and Strep-R (AAGCTTATTATTTGCCGACTACCTTGG). The cassette was then inserted into the unique HindIII site after the cheY3 gene. DNA containing cheX-cheY3-aadA was linearized by restriction digestion and was then electroporated into competent ΔcheY3 cells in order to obtain complemented cells. Transformants were selected with streptomycin. Western blot analysis was used to confirm the inactivation and restoration of CheY3 in the mutant and complemented cells, respectively, and that no disruption of other gene products in the operon had occurred as a result of the genetic manipulation (see below). Linear and circular plasmid contents of all B. burgdorferi transformants were confirmed by PCR using primers described previously (Elias et al., 2002, Sultan et al., 2010, Pitzer et al., 2011). SDS-PAGE and immunoblot analyses Sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) and immunoblotting with an enhanced chemiluminescent detection method (GE Health Inc.) were performed as reported previously (Motaleb et al., 2000). A Bio-Rad protein assay kit determined the concentration of protein in cell lysates. Unless otherwise noted, 5 μg of lysate protein was subjected to SDS-PAGE and immunoblotting using specific antibodies. Antibodies kindly provided by other investigators included the following: anti-DnaK by J. Benach (State University of New York [SUNY], Stony Brook, NY), and polyclonal E. coli anti-CheA by R. Silversmith (University of North Carolina, Chapel Hill, NC). CheY3 and CheX antibodies are described elsewhere (Motaleb et al., 2005, Motaleb et al., 2011b). Mouse serum collected at indicated times post-injection was utilized as the ‘primary antibody’ in western blot analysis to determine the B. burgdorferi-specific antibody response. Dark-field microscopy and swarm plate assays Exponentially growing B. burgdorferi clones (1–3×107 cells/ml) were imaged using a Zeiss Imager M1 dark-field microscope connected to a digital camera to determine morphology and motility. Swarming ability of individual bacterial colonies of each strain was determined by plating no more than 50 cells into a petri dish (95 mm × 15 mm) containing semi-solid P-BSK (0.35% agarose) diluted 1:10 in Dulbecco’s phosphate-buffered saline (Motaleb et al., 2000, Motaleb et al., 2007, Motaleb et al., 2011a). Plates were incubated for three weeks at which time colony diameters were measured. At least 11 colony diameters were measured for each strain in each assay. Capillary tube chemotaxis assay The chemotactic ability of B. burgdorferi was quantitatively determined as previously described (Motaleb et al., 2011b) with slight modifications. Briefly, WT, ΔcheY3, or cheY3 complement (cheY3+) B. burgdorferi were grown to approximately 1×108 cells/ml. Spirochetes were counted using a Petroff-Hausser chamber, and the cells needed for the assay (1×107 cells/ml) were collected by centrifuging for 15 minutes at 1,800 × g at room temperature. The cells were washed with PBS and then gently resuspended in motility buffer (136.9 mM NaCl, 8.10 mM Na2HPO4, 2.7 mM KCl, 1.47 mM KH2PO4, 2% recrystallized BSA (Sigma-Aldrich Co.), 0.1 mM EDTA, pH 7.4) to obtain a final solution of 1×107 cells/ml, 0.5% methylcellulose (400 mesh; Sigma Aldrich Inc.). This suspension (0.2 ml) was added into each 1.5 ml eppendorf tube chemotaxis chamber with a perforated lid. Capillary tubes were filled with control solution (motility buffer) or attractant solution (100 mM N-Acetylglucosamine in motility buffer, 0.22μm filter-sterilized) and sealed on one end with clay. Excess fluids on the outside of the capillary tubes were wiped off, and the capillary tubes were inserted into the appropriate eppendorf tube chemotaxis chambers (one capillary tube per chamber; 3–5 replicates per strain). Tubes were incubated at 35°C for 2 hours, at which point the tubes were carefully wiped off to remove excess liquid on the outside, and the contents was expelled into a clean eppendorf tube. The contents of each chemotaxis tube were plated individually using P-BSK to determine colony-forming units (CFU). The plates were incubated at 35°C for 2–5 weeks (until colonies appeared). Each strain was repeated three times with each repeat containing 3 replicates, and the results are expressed as the average attractant/buffer ratio. An increase in the number of spirochetes equal to or greater than twice that of the buffer control was considered significant. Mouse infection studies using injected B. burgdorferi Six-to-seven weeks old C3H/HeN mice were used for infection studies, as previously described (Elias et al., 2002, Stewart et al., 2008a, Sultan et al., 2013). In order to determine the infectious ability of the spirochetes, mice (n = 5 or 2 per strain) were injected subcutaneously with WT (5×103), ΔcheY3 (5×103 or 1×106), or cheY3+ cells (5×104). The number of spirochetes was determined using a Petroff-Hausser chamber and verified by colony forming units (CFUs) by plating. At four weeks post-injection, mice were euthanized and ear skin, bladder, and tibiotarsal joints were harvested and placed in BSK-II broth for up to 35 days to allow bacterial outgrowth from the animal tissues (Elias et al., 2002, Grimm et al., 2003, Stewart et al., 2008a), which is the direct determination of the ability of spirochetes to infect mice by tick bite and disseminate throughout the body. The presence of spirochetes in the growth medium was determined by dark-field microscopy (Elias et al., 2002, Grimm et al., 2003, Grimm et al., 2004, Sultan et al., 2013). Tick-mouse studies Transmission of spirochetes from infected ticks to naïve mice was assessed using tick-mouse infection assays (Policastro et al., 2003, Battisti et al., 2008, Stewart et al., 2008a). Naïve Ixodes scapularis larvae were purchased from Oklahoma State University. Naïve larvae were artificially inoculated by immersion in equal-density, exponential-phase (5×107 cells/ml) cultures of B. burgdorferi clones, as previously described (Policastro et al., 2003, Battisti et al., 2008, Stewart et al., 2008a). Ticks were subsequently fed to repletion on mice (3 mice per strain; ~200 larvae/mouse). After 5–7 days, fed ticks were collected once they dropped off mice. At 7 days post-repletion, a subset of ticks was individually dissected and the isolated midguts were analyzed by immunofluorescence (IFA; see below) for the presence of spirochetes (Stewart et al., 2008a). A second subset of ticks was surface-sterilized with 3% H2O2 and 70% ethanol, individually crushed in BSK-II medium, and plated in P-BSK to determine the number of viable spirochetes per tick (CFUs). Results are expressed as the spirochete burden per tick, where each dot is representative of a single tick (n = 12). A third subset of ticks was crushed individually and genomic DNA was extracted using the DNeasy blood and tissue kit, according to the manufacturer’s instructions (Qiagen Inc.). The DNA from each tick was then utilized for PCR to determine spirochete-positive ticks. Spirochete burdens in each spirochete-positive tick were determined by using quantitative real-time PCR (qPCR) using primers specific for the B. burgdorferi enolase gene, as described previously (Yang et al., 2004, Zhang et al., 2009, Pitzer et al., 2011). Copies of the B. burgdorferi enolase gene per tick were extrapolated from a standard curve generated using a known amount of plasmid DNA containing the enolase gene as the template. To determine spirochete transmission and infection of the C3H/HeN mice, fed animals were euthanized four weeks post-repletion followed by bacterial outgrowth analysis. The presence of spirochetes in the growth medium was determined by dark-field microscopy (Sultan et al., 2010, Sultan et al., 2011). Transmission of spirochetes to mice by encapsulated nymphs Naïve nymphs were artificially infected by immersion, as described above. Nymphs were allowed to feed on mice using a capsulated system, as previously described (Mulay et al., 2009, Patton et al., 2011, Sultan et al., 2013). Mice were anesthetized and 15–20 nymphs were confined to capsules affixed to the shaved back of a naïve C3H/HeN mouse (n = 3 per strain per assay). The ticks were allowed to feed to repletion and then collected from the capsules. At 7 days post-repletion, spirochete burdens were determined from individually crushed ticks by qPCR, as described above. The results are expressed as mean ± SEM from at least 4 spirochete-positive tick data per clone per assay. At 68 hours or 4 days post-repletion, mice were euthanized and the tick-bite sites were extensively washed. A section of skin comprising the tick-feeding site was excised, rinsed in 70% isopropanol, and cut into equal portions. Part of the tick-bite site skin, ear, bladder, and joint tissues were cultured separately in BSK-II medium for up to 35 days to determine bacterial outgrowth, and the other remaining tissues were processed for PCR to detect B. burgdorferi DNA using enolase gene-specific primers (Pitzer et al., 2011). Immunofluorescence Assay IFAs were set up as previously described (Sultan et al., 2013). Briefly, ticks were individually dissected in phosphate-buffered saline (PBS)-5 mM MgCl2 on Teflon-coated microscopic slides. Dissected tick contents were then 10-fold serially diluted to avoid quenching by hemin in the blood (Policastro et al., 2003, Sultan et al., 2010). The slides were air dried and blocked with 0.75% bovine serum albumin (BSA) in PBS-5 mM MgCl2 for 30 min. The slides were then washed twice with PBS-5 mM MgCl2, and spirochetes were detected using goat anti-B. burgdorferi antisera labeled with fluorescein isothiocyanate (1:100 dilution; Kirkegaard & Perry Laboratories, Inc.). Images were captured using a Zeiss Axio Imager M1 microscope connected to a digital camera. Intravital microscopy Two days prior to an experiment, the outer ear surface of the mice was depilated (Nair), rinsed immediately with H2O, and allowed to rest. Low-passage cultures of WT-eGFP and ΔcheY3-eGFP were counted to contain the desired B. burgdorferi inoculum (106 bacteria) in 10μl BSK-II medium. B6 mice were anesthetized, and the desired numbers of GFP-expressing bacteria were injected intradermally in a 10μl bolus using a 31G insulin syringe via the dorsal ear surface of the mouse. The mice were allowed to rest for 6h and then re-anesthetized for imaging at the indicated times. Imaging was performed using an Olympus FV1000 laser confocal microscope system. For imaging, the mouse was placed on a 37°C heated imaging stage to mount the ear on a coverslip (with the template) with the dorsal surface down. For bacterial enumeration, as well as motility patterns and velocity determination of the bacteria, 2D images were collected using a 20× dry objective with a 2× optical zoom at 1 frame/1100 milliseconds for 66 seconds (60 images) at different times post-injection. At least two time-lapse images were collected for each section of the template (=10 time-lapse images per ear). For bacterial morphology studies, images were collected between 2–6 hours post-injection using a 60× water immersion objective with an additional optical zoom. Image Analysis for intravital microscopy For bacterial enumeration and motility assessment, the first of the 60 images in a dataset was selected and the bacteria in that image were counted and tracked manually. Motility patterns and velocity were calculated for bacteria present in the viewing field since the first frame. For motility patterns, the movement of any bacteria that remained within the viewing field for ≥ 5 seconds was manually assessed and categorized as one of three groups: (1) Run—bacteria continue to move in one direction without reversing or switching the swimming direction throughout the entire time of assessment, (2) Back/Forth (B/F)—bacteria reversed/switched their direction of motion at least once throughout the entire time of assessment, and (3) Non-translational—bacteria had no net movement, which includes both non-motile bacteria and those that could move slightly, but were unable to generate net movement (translocate). Time of assessment of the bacteria was defined as the total time the bacteria were visible in the viewing field, which ranged from 5 seconds minimum up to 60 seconds. For calculating the velocity of the bacteria, all the 60 images of the dataset were assessed using MetaMorph software (Molecular Devices), and every bacterium noted on the first image was tracked through 60 images and the average velocity of the bacterium was calculated. For tracking, one end of the spirochete was chosen and it was followed until that end is not visible for more than 1 frame. Observations for bacteria that stayed in the field of view for less than 5 frames were discarded. Quantitative measurement of B. burgdorferi in murine skin and other target tissues The bacterial numbers in murine tissues were quantified as previously described (Brown et al., 1999a, Morrison et al., 1999). Briefly, naïve anesthetized B6 mice were intradermally injected with 5×104 bacteria per animal via the dorsal ear surface. Multiple tissues including the entire ears, back skin, entire ankle joints, and heart were collected at various times post-injection. The tissues were appropriately processed to isolate DNA, as described (Brown et al., 1999a, Morrison et al., 1999, Sultan et al., 2015). qPCR was performed using a Light Cycler 96 (Roche Diagnostics) and Syber Green detection. Mouse DNA levels were determined by amplifying the nidogen gene and B. burgdorferi DNA was determined by amplifying the flaB gene. Copy numbers for mouse and B. burgdorferi genomes present in each sample were calculated by extrapolation to standard curves using LightCycler software (Roche Diagnostics). Normalizing B. burgdorferi genomes to 1000 mouse genomes represented the final B. burgdorferi numbers. The primers used to detect mouse nidogen were nido.F (5′-CCA GCC ACA GAA TAC CAT CC-3′) and nido.R (5′-GGA CAT ACT CTG CTG CCA TC-3′). The oligonucleotide primers used to detect B. burgdorferi flaB were flaB.F (5′-TTG CTG ATC AAG CTC AAT ATA ACC A -3′) and flaB.R (5′-TTG AGA CCC TGA AAG TGA TGC -3′). B. burgdorferi-specific antibody detection by ELISA from intravital microscopy studies Serum was collected at the indicated times by either retro-orbital bleeding or exsanguination, and immunoglobulin (Ig) content was assessed using previously described methods (Brown et al., 1999a). For detection of B. burgdorferi-specific antibodies, 96-well high-binding ELISA plates (Costar) were coated with B. burgdorferi sonicate or goat anti-mouse total immunoglobulin (IgG+IgM+IgA; Southern Biotech). For B. burgdorferi sonicates, the WT bacteria were grown at 33ºC and then shifted to 37ºC for the final overnight culture (Schwan et al., 2000). This temperature-shifted culture was then resuspended in PBS for sonication within a closed sterile tube using a bath sonicator (Sonifier® Cell Disruptor). The protein content of the sonicated sample was measured by Bicinchoninic acid assay (BCA; Pierce Thermo Scientific) and stored at −80ºC. The B. burgdorferi ELISA plates were made by coating appropriate wells with 5μg/ml of the sonicate (for sample and blank) or goat anti-mouse total Ig (to provide a purified Ig standard) in 0.1M carbonate-bicarbonate Buffer (pH 9.5) overnight. Serial dilutions of individual sera from uninfected or infected mice were added to the B. burgdorferi-coated plates overnight, washed to remove unbound antibodies, and bound murine Ig was detected using goat anti-mouse IgG conjugated to biotin (Southern Biotech). After incubation for 2–3 hours at room temperature, the samples were visualized by adding avidin-conjugated Horseradish Peroxidase (avidin-HRP; Vector Labs) for 30 minutes followed by adding the color solution (0.4mg/ml of O-phenylenediamine and 0.01% H2O2 in citrate buffer, pH 5) and inhibiting the reaction with 1N hydrochloride. The content was quantified by comparison to standard curves constructed using the appropriate purified mouse Ig isotype (Southern Biotech). Statistical analyses The significance difference between the mean values of the groups for each experiment was analyzed as follows. When comparing WT, ΔcheY3, and cheY3+ (either the cheY3+ or ΔmotB) data was checked with D’Agostino-Pearson omnibus normality test to determine if the values come from a Gaussian distribution. The data that passed normality was analyzed via a multiple-comparison analysis using a one-way analysis of variance (ANOVA), followed by a Tukey’s post hoc test; if the data did not pass normality, a multiple-comparison analysis was performed by using a Kruskal-Wallis test, followed by Dunn test. P < 0.05 is considered significant. For all intravital and detection of GFP-expressing bacteria in mice, normality was checked using Shapiro-Wilk normality test. If data was normal than the difference between WT and ΔcheY3 was assessed via an unpaired t-test, whereas non-normal data was assessed via a Mann Whitney test. Supplementary Material Supp Video S1 Video 1. WT B. burgdorferi motility in mouse skin 1×106 WT-eGFP B. burgdorferi were injected intradermally into mouse ear skin and time-lapse images were collected using an Olympus FV1000 laser confocal microscope system at 6 hours post-injection. 2D images were collected using a 20× dry objective with a 2X optical zoom at 1frame/1100 milliseconds for 66 seconds (60 images). The video is sped up two times the “real-time” speed. Supp Video S2 Video 2. ΔcheY3 B. burgdorferi motility in mouse skin 1×106 ΔcheY3-eGFP B. burgdorferi were injected intradermally into mouse ear skin and time-lapse images were collected using an Olympus FV1000 laser confocal microscope system at 6 hours post-injection. 2D images were collected using a 20× dry objective with a 2X optical zoom at 1frame/1100 milliseconds for 66 seconds (60 images). The video is sped up two times the “real-time” speed. We thank Dr. Ruth Silversmith for reagents and the Medical Entomology and Zoonoses Ecology team at Public Health, England for the tick’s illustrations. We also would like to acknowledge John Presloid for technical help in performing the murine infection and imaging studies. This research was supported by National Institute of Allergy and Infectious Diseases grants (1R21AI113014), National Institute of Arthritis and Musculoskeletal and Skin Diseases grant (1R01AR060834), and an American Heart Association Pre-doctoral Fellowship 14PRE20490177 (PS). Figure 1 Construction and complementation of the ΔcheY3 A. WT B. burgdorferi genome arrangement of flaA operon containing cheY3 (labeled as WT chromosome). The Pl-Kan (aph1) cassette was inserted after deleting the cheY3 gene by allelic exchange (ΔcheY3 chromosome). The mutant was complemented in cis by genomic reconstitution by inserting a WT copy of the cheY3 gene flanked by the PflgB-aadA cassette (cheY3+ chromosome). Arrows indicate the direction of transcription. DNAs/Plasmids are not drawn to scale. B. Immunoblot analysis of B. burgdorferi cells probed with the indicated antibodies. The CheY3 protein expression was inhibited in the mutant, but restored in the complemented cheY3+ cells as confirmed by using cell lysates from the indicated clones probed with anti-CheY3. CheY3 protein is approximately 14 kDa. The cheA2 and cheX genes are located in the same operon as the targeted cheY3, however, the expression of those gene products were not altered in the mutant or the complemented cells (see anti-CheA and anti-CheX blots). DnaK was used as a loading control. Figure 2 In vitro phenotypes of the ΔcheY3 A. ΔcheY3 colonies exhibit a significantly reduced swarming ability on semi-solid agar plates when compared to the parental WT or complemented cells (P = 0.0001). Values are mean ± SD from at least 11 individual colonies per strain. Statistical analysis was performed by using ANOVA followed by Tukey’s Multiple Comparisons test. A P<0.05 between strains is considered significant. B. The ΔcheY3 is deficient in chemotaxis as determined by the capillary tube chemotaxis assay using N-Acetylglucosamine as an attractant. A capillary tube filled with buffer without any attractant was used as a control. An increase in the number of spirochetes equal to or greater than twice that of the buffer control was considered “chemotactic”. The numbers on top of each vertical bar is the fold-increase over the buffer control. Results shown are mean ± SEM from three independent studies with three replicates per strain per assay. Figure 3 CheY3 is important for tick-mouse infectious cycle A. The burden of ΔcheY3 was significantly less in fed larval ticks compared to WT or the complemented cheY3+. Naive larval ticks were artificially infected by immersion using in vitro-grown spirochetes. Larvae were crushed individually on day 7 post-repletion, and the spirochetal density per larva was determined by plating on semi-solid growth media followed by counting viable spirochetes (CFU). The p-values were determined using Kruskal-Wallis ANOVA test followed by Dunn Multiple Comparisons test. Results shown are the spirochete burden per larva, where each dot is representative of a single tick (n = 12). The line denotes the mean of the entire group. A P<0.05 between strains is considered significant. B. CheY3 is important for establishing infection in mice by tick-bite. Naïve C3H/HeN mice were fed upon by artificially-infected larvae (~200 larvae/mouse, 3 mice per clone). Four weeks post-repletion, mice were euthanized to determine bacterial outgrowth from ear, joint, and bladder tissues. Figure 4 Mice are not infected by ΔcheY3-infected nymph bite The burden of the mutant was significantly less in fed, but not in unfed nymphs when compared to the parental cells (A, unfed; B, fed nymphs). Naïve nymphs were artificially infected and then allowed to feed on separate naïve mice (n=3 per assay). Seven days after feeding, nymphs (fed and unfed) were processed for PCR analysis to determine spirochete-positive ticks, and subsequently qPCR to determine the number of spirochete genomes using enolase gene-specific primers (five spirochete-positive nymphs per clone). Results shown are mean ± SEM. Statistical analysis was performed using ANOVA test followed by Tukey Multiple Comparisons test. A P<0.05 between strains is considered significant. C. Naïve mice fed by the ΔcheY3-infected nymphs were not able to establish persistent infection. Fifteen infected encapsulated nymphs per mouse were allowed to feed. Four days (or 68h, data not shown) after feeding, mice were euthanized to detect B. burgdorferi DNA from tick bite site skin, ear, joint, and bladder tissues by PCR (one half of each tissue or one joint tissue from each mouse). To validate the PCR data, the other half of each of those tissues was processed for bacterial outgrowth analysis (not shown). WT and cheY3+ spirochetes were detected only in the tick-bite site skin tissues, as expected, at this early time points when B. burgdorferi cells generally do not disseminate to the distant tissues. Figure 5 Comparison of motility patterns in murine ear tissue between ΔcheY3 and WT A. Morphology of WT and ΔcheY3 B. burgdorferi was observed in vivo in ear skin tissue of mouse using intravital microscopy technique. 1×106 WT-eGFP or ΔcheY3-eGFP B. burgdorferi was injected intradermally into ear skin and images were collected between 2-6 hours post-injection. Both WT (i–ii) and ΔcheY3 (iii–iv) bacteria demonstrate similar characteristic flat-wave morphologies in vivo. Scale bar is 5μm. B–C. 1×106 WT-eGFP or ΔcheY3-eGFP B. burgdorferi (Bb) were injected as above and time-lapse images were collected at different times post-injection. B. Representative images of ΔcheY3 (left) and WT (right) motility path tracked at 6h post-injection using MetaMorph. Colored lines (except green) are the tracks of the bacteria. C. For both strains, the % bacteria performing run, back-and-forth (B/F) and no translational motility was calculated. The majority of WT bacteria at all times performed B/F, whereas most of the ΔcheY3 bacteria were non-translational. The translating ΔcheY3 performed mainly runs with occasional stops, rather than B/F. Results show average % motility ± SEM. ## p = 0.003 % run compared to ΔcheY3; $$ p = 0.0026, $$$ p ≤ 0.0003 % B/F compared to ΔcheY3; ** p = 0.0057, *** p ≤ 0.006 % no translational motility compared to ΔcheY3. Statistics were performed using the Mann Whitney test. n ≥ 3 mice. D. The velocity of WT and ΔcheY3 was measured at 6h post-injection using MetaMorph. Results show average ± SEM. ***p<0.0001 compared to the non-translational counterparts; Statistics were performed using the Mann Whitney test. n ≥ 30 bacteria under each bar. Figure 6 Dissemination and persistence of ΔcheY3 in distant target tissues A. Groups of C57Bl/6 mice were injected intradermally in both ears with 1×106 GFP-expressing ΔcheY3 or WT. At the indicated times, ear skin-resident bacteria were visually assessed using confocal fluorescent microscopy. Visual data was processed manually to determine motility patterns. Results shown are mean ± SD. *p = 0.04, **p < 0.0069 ***p < 0.0001 compared to the WT; Results were analyzed using an unpaired t-test; n ≥ 3 mice under each bar. B. Groups of C57Bl/6 mice were injected intradermally in both ears with 5×104 GFP-expressing ΔcheY3 or WT B. burgdorferi. Both ears, back skin, heart, and both ankles tissues were harvested at the indicated time points for DNA isolation. qPCR analysis was performed to quantify spirochete burdens. Values represent the average of B. burgdorferi genomes (flaB) per 1000 copies of mouse genome (nidogen); values of zero were assigned as 0.0001 for representation on a log scale. *p<0.05, **p<0.01, ***p<0.0001 compared to WT; Results were analyzed using the Mann Whitney test. n ≥ 5 mice from two separate experiments. Figure 7 Infection with ΔcheY3 is sufficient to elicit B. burgdorferi-specific antibodies The mice used in the dissemination study (Figure 6) were sacrificed at the indicated time post-injection and sera were collected. B. burgdorferi-specific antibodies were quantified by ELISA analyses using bacterial sonicates as the capture antigen. A. Detection of IgM antibody levels in serum from WT-, ΔcheY3- and ΔmotB-infected mice. ΔmotB spirochetes was used as a control as these bacteria are reported to be non-motile, fail to disseminate from the injection site, and are cleared from the host within 48-72h after injection. **p < 0.01, ***p < 0.0001 as shown in the graph. # p < 0.05 and ### p < 0.0001 as compared to the ΔcheY3. Results were analyzed using the ANOVA test followed by the Tukey-Kramer Multiple Comparisons test. B. Detection of IgG antibody levels in serum from WT-, ΔcheY3- and ΔmotB-infected mice. **p < 0.01, ***p < 0.0001 as shown in the graph. # p < 0.05 as compared to WT. Statistical analyses were performed using ANOVA test followed by Tukey-Kramer Multiple Comparisons test. Figure 8 Model of the B. burgdorferi chemotaxis/motility system during the enzootic cycle A simplistic chemotaxis signaling pathway of B. burgdorferi (wave-like red shapes) is depicted here and is described in the Discussion. We postulate that CheY2 or CheY1 controls some non-chemotactic cellular processes such as serving as virulence determinants rather than acting as a classical chemotaxis response regulator, like CheY3. Tick illustrations were kindly provided by the Medical Entomology and Zoonoses Ecology team at Public Health, England. Table 1 ΔcheY3 lacks infectivity in mice via needle injectiona Strain Dosage (spirochetes/mouse) Number of Mice Infected WT 5 × 103 5/5 ΔcheY3 5 × 103 0/5 1 × 106 0/5 cheY3+ 5 × 104 2/2 a C3H/HeN mice were injected intradermally using the indicated in vitro-grown spirochete clones. Mice were sacrificed four weeks post injection, and infectivity was determined by reisolation or detection of B. burgdorferi genomes by PCR from the murine ear skin, tibiotarsal joint, and bladder tissue samples. Doses shown are the actual number of spirochetes injected in each mouse. 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LICENSE: This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. 0370512 457 Am J Psychiatry Am J Psychiatry The American journal of psychiatry 0002-953X 1535-7228 26046337 5116912 10.1176/appi.ajp.2015.14091185 NIHMS830486 Article Pediatric-Onset and Adult-Onset Separation Anxiety Disorder Across Countries in the World Mental Health Survey Silove Derrick M.D., Ph.D. Alonso Jordi M.D., Ph.D. Bromet Evelyn Ph.D. Gruber Mike M.S. Sampson Nancy B.A. Scott Kate Ph.D. Andrade Laura M.D., Ph.D. Benjet Corina Ph.D. de Almeida Jose Miguel Caldas M.D., Ph.D. De Girolamo Giovanni M.D. de Jonge Peter Ph.D. Demyttenaere Koen M.D., Ph.D. Fiestas Fabian M.D. Florescu Silvia M.D., Ph.D. Gureje Oye Ph.D. He Yanling M.D. Karam Elie M.D. Lepine Jean-Pierre Ph.D. Murphy Sam Ph.D. Villa-Posada Jose M.D. Zarkov Zahari M.D. Kessler Ronald C. Ph.D. Psychiatry Research and Teaching Unit and Ingham Institute, School of Psychiatry, University of New South Wales, Randwick, NSW, Australia; IMIM-Hospital del Mar Research Institute, Parc de Salut Mar, Pompeu Fabra University (UPF) and CIBER en Epidemiología y Salud Pública (CIBERESP), Barcelona, Spain; Department of Psychiatry, Stony Brook University School of Medicine, Stony Brook, N.Y..; Department of Health Care Policy, Harvard Medical School, Boston; Department of Psychological Medicine, University of Otago, Otago, New Zealand; Department/Institute of Psychiatry, University of São Paulo Medical School, São Paulo, Brazil; Department of Epidemiologic and Psychosocial Research, National Institute of Psychiatry Ramón de la Fuente, Mexico City, Mexico; Chronic Diseases Research Center (CEDOC) and Department of Mental Health, Faculdade de Ciências Médicas, Universidade Nova de Lisboa, Lisbon, Portgual; IRCCS St. John of God Clinical Research Centre and IRCCS Centro S. Giovanni di Dio Fatebenefratelli, Brescia, Italy; University of Groningen, University Medical Center Groningen, Groningen, the Netherlands; Department of Psychiatry, University Hospital Gasthuisberg, Katholieke Universiteit Leuven, Leuven, Belgium; Unit of Analysis and Generation of Evidence for Public Health, Peruvian National Institutes of Health, Lima, Peru; National School of Public Health, Management and Professional Development, Bucharest, Romania; Department of Psychiatry, University College Hospital, Ibadan, Nigeria; Shanghai Mental Health Center, Shanghai, the People’s Republic of China; Department of Psychiatry and Clinical Psychology, Faculty of Medicine, Balamand University, Beirut, Lebanon; Department of Psychiatry and Clinical Psychology, St. George Hospital University Medical Center, Beirut, Lebanon; Institute for Development Research Advocacy and Applied Care (IDRAAC), Beirut, Lebanon; Hôpital Lariboisière Fernand Widal, Assistance Publique Hôpitaux de Paris, University Paris Diderot and Paris Descartes Paris, Paris; School of Psychology, University of Ulster, Northern Ireland; Colegio Mayor de Cundinamarva University, Bogota, Colombia; National Center of Public Health and Analyses, Sofia, Bulgaria. Address correspondence to Dr. Silove (d.silove@unsw.edu.au) 17 11 2016 05 6 2015 7 2015 21 11 2016 172 7 647656 This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. Objective The age-at-onset criterion for separation anxiety disorder was removed in DSM-5, making it timely to examine the epidemiology of separation anxiety disorder as a disorder with onsets spanning the life course, using cross-country data. Method The sample included 38,993 adults in 18 countries in the World Health Organization (WHO) World Mental Health Surveys. The WHO Composite International Diagnostic Interview was used to assess a range of DSM-IV disorders that included an expanded definition of separation anxiety disorder allowing onsets in adulthood. Analyses focused on prevalence, age at onset, comorbidity, predictors of onset and persistence, and separation anxiety-related role impairment. Results Lifetime separation anxiety disorder prevalence averaged 4.8% across countries (interquartile range [25th–75th percentiles]=1.4%–6.4%), with 43.1% of lifetime onsets occurring after age 18. Significant time-lagged associations were found between earlier separation anxiety disorder and subsequent onset of internalizing and externalizing DSM-IV disorders and conversely between these disorders and subsequent onset of separation anxiety disorder. Other consistently significant predictors of lifetime separation anxiety disorder included female gender, retrospectively reported childhood adversities, and lifetime traumatic events. These predictors were largely comparable for separation anxiety disorder onsets in childhood, adolescence, and adulthood and across country income groups. Twelve-month separation anxiety disorder prevalence was considerably lower than lifetime prevalence (1.0% of the total sample; interquartile range=0.2%–1.2%). Severe separation anxiety-related 12-month role impairment was significantly more common in the presence (42.4%) than absence (18.3%) of 12-month comorbidity. Conclusions Separation anxiety disorder is a common and highly comorbid disorder that can have onset across the lifespan. Childhood adversity and lifetime trauma are important antecedents, and adverse effects on role function make it a significant target for treatment. Although separation anxiety disorder traditionally has been a diagnosis assigned to children and adolescents, DSM-5 removed the 18-year age-at-onset restriction on diagnosis because studies had found later onset to be common. It is timely therefore to examine key aspects of the epidemiology of separation anxiety disorder as a condition with onsets that span the life course. The importance of adult-onset separation anxiety disorder is indicated by the fact that 20%–40% of adult patients with mood and anxiety disorders have been found to have symptoms of the disorder, and between one-third and one-half of these patients reported onsets after 18 years of age (1–3). Patients with adult separation anxiety disorder experience high levels of functional impairment and show a poor response to conventional treatments used for other anxiety subtypes (4). There is a dearth of epidemiologic data focusing on separation anxiety disorder across the lifespan. A longitudinal study commencing in childhood recorded a 5% lifetime prevalence of separation anxiety disorder by the time the cohort reached early adulthood (5). The National Comorbidity Survey Replication in the United States found a lifetime separation anxiety disorder prevalence of 6.6% after the pediatric age-at-onset requirement was removed, with two-thirds of case subjects having onsets after 17 years of age (6), but comparable data in other samples or populations have yet to be reported. The relationship of separation anxiety disorder with other mental disorders also remains to be clarified. A longstanding theory has posited a specific developmental relationship between childhood-onset separation anxiety disorder and adult panic disorder and/or agoraphobia (7, 8), an association supported by findings from twin and laboratory studies (9, 10). Yet a meta-analysis of community studies has indicated that separation anxiety disorder may represent a generic risk factor for a range of anxiety disorders and other forms of psychopathology in adulthood (11) rather than primarily for panic disorder and/or agoraphobia. Consistent with the principles of attachment theory (12), a recent developmental model has suggested that separation anxiety symptoms may mediate the associations between early family adversity and trauma and subsequent onset of common adult mental disorders (13). Family dysfunction and exposure to major disasters appear to be associated with subsequent onset of separation anxiety in childhood (13–15). Overall, however, data are limited concerning associations involving early adversity, exposure to trauma, onset of separation anxiety disorder, and a range of later psychopathologic outcomes. In the present study, we analyzed data from the cross-national World Health Organization (WHO) World Mental Health surveys (16) to assess the following key aspects of separation anxiety disorder in the general population: 1) lifetime and 12-month prevalence overall and by gender and country income grouping; 2) the proportions of case subjects experiencing childhood and adult onsets; 3) patterns of comorbidity and temporal relationships with onset and persistence of other common DSM-IV disorders; 4) associations of other predictors (sociodemographic variables, childhood adversities, lifetime traumatic events) with separation anxiety disorder onset and persistence; and 5) severity of role impairment associated with 12-month separation anxiety disorder. METHOD Samples Separation anxiety disorder was assessed in 18 World Mental Health surveys: nine in high-income countries (Belgium, France, Germany, Italy, the Netherlands, Northern Ireland, Portugal, Spain, and the United States), five in upper-middle income countries (Brazil, Bulgaria, Lebanon, Mexico, and Romania), and four in low-/lower-middle income countries (Colombia, Nigeria, the People’s Republic of China, and Peru). A total of 38,993 respondents were assessed. All surveys used probability sampling based on multistage area clustered household survey designs with no substitution for nonparticipants. The majority of surveys were based on nationally representative samples, the remainder on samples representative of particular urban areas (Sao Paulo in Brazil, Beijing and Shanghai in the People’s Republic of China), all nonrural areas in the country (Colombia, Mexico), or major regions of the country (Nigeria). Response rates ranged from 45.9% to 90.2% and averaged 70.3%. More details on the World Mental Health Survey sampling are presented elsewhere (17). The World Mental Health Survey interview was administered in two parts to reduce respondent burden. All respondents completed part I, which assessed core disorders. All respondents with a part I disorder plus a probability subsample of other part I respondents were administered part II, which assessed additional disorders and correlates. The part I data were weighted for differential probabilities of selection and to match population distributions on socio-demographic and geographic variables. The part II data were additionally weighted to adjust for differential probabilities of selection from part I into part II. Separation anxiety disorder was typically assessed in part II but in some countries was included in part I. In one-half of the surveys, the assessment of separation anxiety disorder was restricted to respondents in the age range 18–39 or 18–44, while in the other surveys, there was no such age restriction. Measures Overview World Mental Health Survey interviews were conducted face-to-face by lay interviewers. Consistent translation, back-translation, and harmonization procedures were used in adapting the interview for local administration (18). Consistent interviewer training and field quality-control procedures were applied across sites (19). All respondents provided informed consent according to the requirements of local institutional review boards before being interviewed. Diagnostic assessment The diagnostic interview was the WHO Composite International Diagnostic Interview (CIDI) (20), a fully-structured interview that assessed lifetime and 12-month prevalence of DSM-IV mood (major depressive disorder and/or dysthymia, bipolar disorder), anxiety (panic disorder and/or agoraphobia, specific phobia, social phobia, generalized anxiety disorder, posttraumatic stress disorder [PTSD]), and externalizing (intermittent explosive disorder, alcohol and drug abuse with or without dependence) disorders. A special probing strategy shown to yield improved age-at-onset reports of individual disorders was used (21). A blinded clinical reappraisal study using the Structured Clinical Interview for DSM-IV (SCID) (22) as the gold standard found good diagnostic concordance between core CIDI and SCID diagnoses, although the module for separation anxiety disorder was not included (23). The CIDI module for separation anxiety disorder departed from DSM-IV in assessing lifetime onset of symptoms not only as of age 18 but also for onsets that occurred at ages 19 or later (6). A separation anxiety disorder diagnosis required endorsement of at least three of the eight criterion A DSM-IV symptoms, having symptoms for at least 1 month, and experiencing associated clinically significant distress or role impairment. Sociodemographic variables Sociodemographic variables considered here include age at interview (18–34, 35–49, 50–64, and ≥65 years), gender, education (student, and among nonstudents, low, low-average, average-high, and high-level of education based on country-specific distributions), and marital status. Functional Impairment A modified version of the Sheehan Disability Scales (24) was used to assess severity of role impairment associated with separation anxiety disorder in the previous year. Respondents were asked to quantify severity of role impairment in home management, work, social life, and personal relationships using a 0–10 self-anchoring scale with the following response categories: none (0), mild (1–3), moderate (4–6), severe (7–9), and very severe (10). Respondents rated the Sheehan Disability Scales for the month in the previous year when separation anxiety disorder was most severe. Scores for the Sheehan Disability Scales were dichotomized into severe (range 7–10 for any domain of the scales) or not severe (scores lower than 7–10 for all domains). Childhood family adversities World Mental Health Survey respondents were asked retrospectively about exposure to a wide range of childhood family adversities. As reported previously (25), exploratory factor analysis of responses found one factor for experiences indicative of childhood maladaptive family functioning (parental mental illness, substance misuse, criminal behavior, domestic violence, and child physical abuse, sexual abuse, and neglect), while other childhood adversities were combined into a second scale that included parental death, parental divorce, other long separations from a parent, serious illness of a close family member, and family economic adversity. Traumatic events The CIDI assessed 29 lifetime traumatic events aggregated into the seven domains of accidents and natural disasters, war events, intimate and sexual violence, death of a loved one, other interpersonal violence, network events, and other traumas participants decided not to disclose (26). Dichotomous measures were created for one or more events in each of these domains. Analysis Procedures Cross-tabulations were used to estimate lifetime and 12-month separation anxiety disorder prevalence separately for men and women in each survey. Age-at-onset reports were analyzed using the two-part actuarial method to estimate survival curves (27). The proportion of lifetime cases with onsets after age 18 was calculated for each country and country income group. Discrete-time survival analysis with person-year as the unit of analysis and a logistic link function (28) was used to examine cross-lagged associations of temporally primary separation anxiety disorder with subsequent first onset of other disorders and reciprocal associations of other temporally primary disorders with subsequent first onset of separation anxiety disorder. Survival coefficients and standard errors were exponentiated to generate odds-ratios with 95% confidence intervals. The same survival analysis approach was used to estimate associations of sociodemographic variables, childhood adversities, and lifetime traumatic events (28) with first onset of separation anxiety disorder and to examine variation in strength of prediction as a function of age at onset (childhood [up through age 12], adolescence [ages 13–17], early adulthood [ages 18–29] and later onsets [ages ≥30]). The associations of the same predictors with persistence of separation anxiety disorder, defined as 12-month prevalence among lifetime cases, were examined using person-level logistic regression analysis controlling for age at onset and time since onset. Finally, cross-tabulations were used to examine joint associations of country income level, separation anxiety disorder age at onset, and 12-month comorbidities with 12-month severe separation anxiety-related role impairments. Relative fit of additive and interactive models was evaluated using the Akaike information criterion and Bayesian information criterion (29). Standard errors of estimates were based on the Taylor series linearization method implemented with SUDAAN software (30, 31) to adjust for the weighting and geographic clustering of World Mental Health data. Multivariate significance tests were carried out with Wald chi-square tests based on Taylor series coefficient variance-covariance matrices. Statistical significance was evaluated using 0.05-level two-sided tests. RESULTS Prevalence Lifetime prevalence of the expanded CIDI definition of DSM-IV separation anxiety disorder that allowed adult onsets was 4.8% in the total sample but with a much wider interquartile range (25th–75th percentiles: 1.4–6.4) and range (0.2%–9.8%) across countries than previously found for most other DSM-IV/CIDI disorders (32) (Table 1). Lifetime prevalence was higher among women than men in 15 of the 18 countries and significantly so in the total sample (5.6% compared with 4.0%; χ2=4.0, df=1, p<0.05). Twelve-month prevalence was considerably lower than lifetime prevalence (1.0% in the total sample; interquartile range: 0.2%–1.2%; range: 0.0%–2.7%), higher among women than men in 14 of 18 countries and significantly higher among women than men in the total sample (1.3% compared with 0.8%; χ2=12.0, df=1, p<0.001). Age at Onset The age-at-onset distribution of separation anxiety disorder was quite similar across the three country income groups (Figure 1). Median age at onset was in the late teens in high- and upper-middle income countries and in the mid-20s in low-/lower-middle income countries. The interquartile range of the age-at-onset distribution was wider (15–35 years of age in low-/lower-middle income countries; 9–35 in high- and upper-middle income countries) than previously found for most other DSM-IV/CIDI disorders (32). A total of 43.1% of respondents with lifetime separation anxiety disorder had onsets in adulthood (ages ≥18). The proportion of lifetime cases with adult onsets was significantly higher in low-/lower-middle income countries (53.8%) than in upper-middle income countries (39.1%; χ2=98.0, df=1, p<0.001) or high- income countries (41.6%; χ2=52.8, df=1, p<0.001). Although there were only two low/low-middle income countries with sizable numbers of lifetime separation anxiety disorder cases (N=359 in Colombia; N=154 in Peru), the proportion of these cases with adult onsets was comparable in the two surveys (55.7% compared with 51.8%; χ2=1.5, df=1, p=0.22). Persistence Comparison of individual-level age at onset and recency reports showed that the majority of people with lifetime separation anxiety disorder remitted within a decade of onset (Figure 2). However, the recovery curves became much less steep after approximately 10 years. As with age at onset, the distribution of time to remission was quite consistent across country income groups. This relatively rapid remission of separation anxiety disorder is consistent with the low 12-month/lifetime prevalence ratio shown in Table 2. Comorbidity Lifetime separation anxiety disorder was significantly comorbid with 13 of the other 14 DSM-IV/CIDI disorders assessed in the World Mental Health surveys, the exception being substance dependence with abuse. Survival analysis pooled across countries showed that these associations were a result of 1) significant associations between temporally primary separation anxiety disorder and subsequent first onset of 10 other disorders (odds ratios in the range of 1.3–2.8) coupled with 2) significant associations of nine other disorders with subsequent first onset of separation anxiety disorder (odds ratios in the range of 1.3–2.1) (Table 2). The vast majority of cross-lagged odds ratio pairs between separation anxiety disorder and other disorders were reciprocal in significance and comparable in magnitude. The major exceptions were that temporally primary separation anxiety disorder was a significantly stronger predictor of subsequent attention deficit hyperactivity disorder (ADHD) (odds ratio=2.8) than ADHD was of subsequent separation anxiety disorder (odds ratio=1.1) and that there were no significant associations between temporally primary PTSD, generalized anxiety disorder, or agoraphobia and subsequent-onset separation anxiety disorder in contrast to the reciprocal relationships. Disaggregation by country income group (results available upon request from Silove) showed considerable consistency in these patterns, with the vast majority of significant odds ratios in the total sample also significant in at least two of the three country income groups. The associations of other temporally primary disorders with subsequent separation anxiety disorder persistence (i.e., 12-month prevalence among lifetime cases controlling for age at onset and time since onset) were not significant. The same was generally true for the associations of temporally primary separation anxiety disorder with subsequent persistence of other disorders, with the exceptions being that temporally primary separation anxiety disorder was a predictor of persistence of agoraphobia (odds ratio=2.6), and to a lesser extent, PTSD. As with the analyses of first onset, disaggregation by country income group (results available upon request from Silove) showed consistency in the nonsignificance of these reciprocal associations between lifetime comorbidity and persistence. Other Predictors of Separation Anxiety Disorder Onset and Persistence Controlling for lifetime comorbid DSM-IV/CIDI disorders, age, and country, survival analysis showed that lifetime separation anxiety disorder was significantly associated with being female (odds ratio=1.1–1.4), having low through high-average (compared with high) education (odds ratio=1.5–1.7), maladaptive family functioning childhood adversities (odds ratio=1.7–2.8), other childhood adversities (odds ratio=1.2–1.8), and a variety of lifetime traumatic events (odds ratio=1.3–1.6) (Table 3). It is noteworthy that the associations involving maladaptive family functioning childhood adversities and other lifetime traumatic events predicted not only pediatric-onset but also adult-onset separation anxiety disorder, while other childhood adversities predicted only childhood-onset separation anxiety disorder. Disaggregation by country income group (detailed results available upon request from Silove) showed considerable consistency in these patterns, with the vast majority of significant odds ratios in the total sample also significant in at least two of the three country income groups. As with the analysis of comorbidity, the predictors considered here were not significantly related to separation anxiety disorder persistence either in the total sample or in country income groups (detailed results available upon request from Silove). For example, the associations of maladaptive family functioning childhood adversities with separation anxiety disorder persistence were nonsignificant both in the total sample (χ2=2.5, df=5, p=0.78) and in each of the three country income groups (χ2=2.9–10.2, df=5, p=0.07–0.72). In addition, we found that age at onset (defined in categories of childhood <13 years old, adolescence 13–17 years old, young adulthood 18–29 years old, and later adulthood ≥30 years old) was not significantly related to persistence either in the total sample (χ2=4.3, df=3, p=0.23) or in any of the three country income groups (χ2=3.0–5.4, df=3, p=0.15–0.39). Role Impairment of 12-Month Separation Anxiety Disorder More than one-third (35.3%) of respondents with 12-month separation anxiety disorder reported severe separation anxiety-related role impairment in the year before interview (Table 4). The rate of severe role impairment was considerably lower in low-/lower-middle income countries (17.6%) than upper-middle or high-income countries (38.2%–41.4%; χ2=12.6–18.1, df=1, p<0.001) and considerably higher in the presence than absence of 12-month comorbid DSM-IV/CIDI disorders (42.4% compared with 18.3%; χ2=21.6, df=1, p<0.001). Separation anxiety-related role impairment did not differ markedly as a function of separation anxiety disorder age at onset (χ2=2.9, df=3, p=0.40). A model that assumed additive effects of country income level, comorbidity, and age at onset predicted severe separation anxiety-related role impairment with no evidence of significant interaction between the factors. DISCUSSION The findings concerning the prevalence of separation anxiety disorder across countries are summarized in Figure 3. The 4.8% overall lifetime prevalence estimate found in this study suggests that separation anxiety disorder is a relatively common lifetime disorder, although with a much wider range of prevalence across countries (0.2%–9.8%; interquartile range: 1.4–6.4) than found for most other DSM-IV/CIDI disorders assessed in the World Mental Health Surveys (32). Temporally prior separation anxiety disorder was found to be associated with significantly elevated odds of subsequent first onset of a wide range of other disorders, including not only internalizing disorders (major depression, bipolar disorder, specific and social phobias, panic disorder, and/or generalized anxiety disorder) but also externalizing disorders (ADHD, oppositional defiant disorder, and conduct disorder). This finding is consistent with a recent meta-analysis concluding that separation anxiety disorder represents a generic risk factor for a range of common mental disorders (11). Importantly, therefore, our data do not support the hypothesis of an exclusive link between separation anxiety disorder and panic disorder and/or agoraphobia (7, 8), although the existence of a significant association between temporally primary separation anxiety disorder and subsequent persistence of agoraphobia has potential prognostic importance in relation to the latter disorder. We also found reciprocal associations of a similarly wide range of temporally primary disorders with the subsequent onset of separation anxiety disorder, a result that is broadly consistent with the suggestion that these comorbidities are due to common causes more than to direct effects of particular early-onset disorders on particular later-onset disorders (33). Indeed, an earlier World Mental Health Survey analysis found that separation anxiety disorder had a high factor loading on the internalizing factor of a two-dimensional model and that controls for summary internalizing-externalizing dimensions accounted for the significant cross-lagged associations of separation anxiety disorder with most comorbid disorders (34). Questions therefore remain whether separation anxiety disorder has any specificity as a risk factor for onset of particular secondary disorders either in childhood or adulthood (13). Maladaptive family functioning childhood adversities and exposure to traumatic life events were found to be associated with separation anxiety disorder onset but not persistence, both in the total sample and, separately, in low-/lower-middle, upper-middle, and high-income countries. Importantly, these associations were found for separation anxiety disorder onsets across the entire life course. It is possible that more in-depth future analyses will find significant specifications in the associations of particular types of childhood adversities or traumatic events at specific life course stages with subsequent separation anxiety disorder onset. Nevertheless, in such analyses, it will be important to account for more general associations that may exist involving a wide range of childhood adversities and traumatic events as a backdrop against which more specific specifications are considered. The mechanisms responsible for the ongoing liability to separation anxiety disorder and other mental disorders arising from early adversity and trauma, including the possible neurobiological mediators of these effects, are the focus of ongoing inquiry (35, 36). Our findings suggest that separation anxiety disorder is more likely to be seriously impairing in higher-income than low-/lower-middle income countries. The explanation of this specification is unclear, although it is possible that a culture of individuality and independence in higher-income countries results in low personal and social tolerance of separation anxiety, whereas a collectivist culture in low-/lower-middle income countries accepts a degree of separation anxiety as normative or even adaptive. A related unanswered question is why the range of prevalence across countries is so large. Limitations of the study include variation in response rates across countries, use of a fully-structured diagnostic interview that did not allow clinical probing to confirm diagnoses, and a cross-sectional design in which lifetime prevalence, childhood adversities, and lifetime traumatic events were assessed retrospectively. Although we used the DSM-IV 1-month duration requirement rather than the DSM-5 6-month recommended (although not mandated) duration criterion for adults in defining separation anxiety disorder, overestimation of prevalence in relation to the latter diagnostic system is likely to be slight given that the median persistence of disorder was 4–8 years. Recall bias is a more serious concern, since this might have led to an underestimation of lifetime prevalence among remitted cases and an overestimation of persistence, even though the World Mental Health Surveys used special probing strategies designed to improve recall accuracy (21) and in some countries limited duration of recall by assessing separation anxiety disorder only among respondents younger than ages 40–45. If biases exist, however, this means that separation anxiety disorder is an even more prevalent lifetime disorder with an even lower persistence than suggested by the present results. Retrospectively reported age at onset was unrelated to 12-month persistence among lifetime cases, suggesting that there was no tendency for respondents to overstate onset of separation anxiety disorder in adulthood. The high prevalence of adult-onset cases therefore supports the decision to remove the separation anxiety disorder age-at-onset restriction in DSM-5. An issue worthy of further investigation is that the ratio of 12-month/lifetime separation anxiety disorder prevalence is much lower than that of most other World Mental Health disorders (1.0% 12-month prevalence; range: 0.0%–2.7%; interquartile range: 0.2%–1.2%). Our findings have important implications for clinical practice. The results challenge the long-established view that separation anxiety disorder should be reserved for diagnosis among children and adolescents by indicating that adult onset is prevalent across countries and that adult-onset separation anxiety disorder is equally persistent and impairing as the pediatric-onset form of this disorder. Clinicians should be alerted to the need to consider separation anxiety disorder in the differential diagnosis of patients of all ages presenting not only with anxiety but with a wide variety of internalizing and externalizing disorders. As yet, existing psychological and pharmacological treatments used for the other anxiety disorders have proven to be ineffective for adult separation anxiety disorder (4, 37). There is consequently an urgent need to devise and test novel treatments for this disorder, particularly as it manifests in adulthood. The World Health Organization (WHO) World Mental Health Survey Initiative is supported by NIMH (R01 MH070884, R13 MH066849, and R01 MH069864), the National Institute on Drug Abuse (R01 DA016558), the John D. and Catherine T. MacArthur Foundation, the Pfizer Foundation, the Fogarty International Center (FIRCA R03-TW006481), the Pan American Health Organization, Eli Lilly, Ortho-McNeil Pharmaceutical, GlaxoSmithKline, and Bristol-Myers Squibb. None of these funders had any role in the design, analysis, interpretation of results, or preparation of this article. (A complete list of World Mental Health publications is available online [http://www.hcp.med.harvard.edu/wmh/].) The 2007 Australian National Survey of Mental Health and Wellbeing was funded by the Australian Government Department of Health and Ageing. The São Paulo Megacity Mental Health Survey is supported by the State of São Paulo Research Foundation Thematic Project (grant 03/00204-3). The Bulgarian Epidemiological Study of common mental disorders is supported by the Ministry of Health and the National Center for Public Health Protection. The Colombian National Study of Mental Health is supported by the Ministry of Social Protection. The ESEMeD project is funded by the European Commission (contracts QLG5-1999-01042, SANCO 2004123, and EAHC 20081308), the Piedmont Region (Italy), Fondo de Investigación Sanitaria, Instituto de Salud Carlos III, Spain (FIS 00/0028), Ministerio de Ciencia y Tecnología, Spain (SAF 2000-158-CE), Departament de Salut, Generalitat de Catalunya, Spain, Instituto de Salud Carlos III (CIBER CB06/02/0046, RETICS RD06/0011 REM-TAP), and other local agencies and by an unrestricted educational grant from GlaxoSmithKline. The Lebanese National Mental Health Survey (L.E.B.A.N.O.N.) is supported by the Lebanese Ministry of Public Health, WHO (Lebanon), National Institutes of Health/Fogarty International Center (R03 TW006481-01), Sheikh Hamdan Bin Rashid Al Maktoum Award for Medical Sciences, anonymous private donations to IDRAAC, Lebanon, and research grants from AstraZeneca, Eli Lilly, GlaxoSmithKline, Lundbeck, Novartis, Roche, and Servier. The Nigerian Survey of Mental Health and Wellbeing is supported by WHO (Geneva), WHO (Nigeria), and the Federal Ministry of Health, Abuja, Nigeria. The Northern Ireland Study of Mental Health was funded by the Health and Social Care Research and Development Division of the Public Health Agency. The Chinese World Mental Health Survey Initiative is supported by the Pfizer Foundation. The Portuguese Mental Health Study was carried out by the Department of Mental Health, Faculty of Medical Sciences, NOVA University of Lisbon, with collaboration of the Portuguese Catholic University, and was funded by the Champalimaud Foundation, the Gulbenkian Foundation, the Foundation for Science and Technology and Ministry of Health. The Romania World Mental Health study projects “Policies in Mental Health Area” and “National Study regarding Mental Health and Services Use” were carried out by the National School of Public Health and Health Services Management (former National Institute for Research and Development in Health, present National School of Public Health Management and Professional Development, Bucharest), with technical support from Metro Media Transylvania, the National Institute of Statistics-National Centre for Training in Statistics, SC, Cheyenne Services SRL, Statistics Netherlands and were funded by the Ministry of Public Health (former Ministry of Health), with supplemental support from Eli Lilly Romania SRL. The U.S. National Comorbidity Survey Replication is supported by NIMH (U01-MH60220), with supplemental support from the National Institute of Drug Abuse, the Substance Abuse and Mental Health Services Administration, the Robert Wood Johnson Foundation (grant 044708), and the John W. Alden Trust. The de-identified survey data are stored and were analyzed on secure servers at the World Mental Health Data Analysis Coordination Center at Harvard Medical School, Boston. The authors thank Herbert Matschinger for contributions to the World Mental Health Surveys. Dr. Silove receives royalties from Little, Brown Book Group and Oxford University Press; and he has served as a consultant for Counterpart International. Dr. Demyttenaere serves on the speaker’s bureaus and/or advisory panels of AstraZeneca, Eli Lilly, Johnson and Johnson, Lundbeck, Neurex, Servier, Shire, and Takeda and has also received research grants from Eli Lilly and Fonds voor Wetenschappelijk onderzoek Vlaanderen. Dr. Fiestas is an employee of the Peruvian National Institutes of Health. Dr. Kessler has served as a consultant for Hoffmann-La Roche and Johnson and Johnson Wellness and Prevention; he has also served on advisory boards for Johnson and Johnson Services Lake Nona Life Project, the Mensante Corporation, and U.S. Preventive Medicine; and he is a shareholder with DataStat. FIGURE 1 Age at Onset for Respondents With Separation Anxiety Disorder by Country Income FIGURE 2 Speed of Recovery From Separation Anxiety Disorder by Country Income FIGURE 3 Lifetime and 12-Month Prevalence of Separation Anxiety Disorder a Significant difference between males and females for lifetime prevalence (χ2=32.0, p<0.001) and 12-month prevalence (χ2=8.8, p=0.003). TABLE 1 Lifetime and 12-Month Prevalence of Separation Anxiety Disorder Stratified by Gender and Country Income Lifetime Prevalence 12-Month Prevalence Total Male Female Total Male Female Sample Size (N) Country and Country Income % SE % SE % SE % SE % SE % SE Male Female All countries 4.8 0.1 4.0 0.2 5.6* 0.2 1.0 0.1 0.8 0.1 1.3* 0.1 16,869 22,124 Low-/lower-middle income 5.5 0.4 4.5 0.4 6.4* 0.5 1.3 0.2 0.9 0.2 1.7 0.4 2,622 3,472 Colombia 9.8 0.8 8.1 1.1 11.3* 1.2 2.7 0.5 1.9 0.5 3.3 0.9 885 1,496 Nigeria 0.2 0.1 0.2 0.1 0.2 0.2 0.0 0.0 0.0 0.0 0.0 0.0 614 675 People’s Republic of China-Beijing/ Shanghai 1.3 0.5 0.7 0.4 2.1 1.0 0.2 0.1 0.0 0.0 0.4 0.2 326 297 Peru 6.1 0.7 5.6 0.8 6.6 0.9 1.2 0.2 0.9 0.2 1.4 0.3 797 1,004 Upper-middle income 4.7 0.2 4.0 0.3 5.3* 0.3 1.2 0.1 1.0 0.2 1.4 0.2 5,334 7,271 Brazil 7.7 0.4 6.7 0.6 8.6* 0.6 2.0 0.3 1.7 0.4 2.3 0.3 2,187 2,850 Bulgaria 1.4 0.4 1.5 0.8 1.2 0.3 0.4 0.3 0.6 0.5 0.2 0.1 951 1,282 Lebanon 6.9 1.3 4.9 1.5 9.0 1.8 1.9 0.5 1.1 0.5 2.7 0.8 251 365 Mexico 4.5 0.4 3.7 0.8 5.2 0.5 0.9 0.2 0.7 0.2 1.1 0.2 853 1,509 Romania 0.9 0.3 0.9 0.4 0.9 0.3 0.3 0.1 0.2 0.1 0.3 0.2 1,092 1,265 High-income 4.7 0.2 3.7 0.2 5.6* 0.3 0.9 0.1 0.7 0.1 1.0 0.1 8,913 11,381 Belgium 1.4 0.3 0.7 0.3 2.1* 0.4 0.1 0.1 0.0 0.0 0.3 0.2 599 591 France 3.5 0.5 3.1 0.7 3.9 1.0 0.9 0.3 0.4 0.2 1.4 0.7 692 772 Germany 2.0 0.4 1.5 0.4 2.6 0.6 0.4 0.2 0.5 0.3 0.4 0.3 806 912 Italy 1.5 0.4 0.6 0.3 2.3* 0.5 0.0 0.0 0.0 0.0 0.1 0.1 1,171 1,209 The Netherlands 3.0 0.6 2.0 0.8 4.0 1.1 0.6 0.3 0.5 0.3 0.7 0.6 472 637 Northern Ireland 5.1 0.5 5.1 0.8 5.2 0.6 0.4 0.1 0.5 0.2 0.4 0.1 822 1,164 Portugal 6.4 0.8 5.7 1.5 7.2 0.7 1.2 0.3 0.8 0.4 1.5 0.4 759 1,301 Spain 1.2 0.3 1.1 0.4 1.4 0.4 0.3 0.1 0.1 0.1 0.4 0.2 1,210 1,485 United States 9.2 0.4 7.4 0.5 10.8* 0.6 1.9 0.2 1.7 0.3 2.1 0.2 2,382 3,310 * p < 0.05 (two-sided test). TABLE 2 Time-Lagged Associations (Odds Ratios) of Temporally Primary Composite International Diagnostic Interview (CIDI) Separation Anxiety Disorder With the Subsequent Onset and Persistence of Other DSM-IV/CIDI Disorders and of Temporally Primary Other Disorders With the Subsequent Onset and Persistence of Separation Anxiety Disorder Temporally Primary Separation Anxiety Disorder Predicting Subsequent Onset and Persistence of Other Disorders Temporally Primary Other Disorders Predicting Subsequent Onset and Persistence of Separation Anxiety Disorder Onseta Persistenceb Onsetc Persistenced Disorder Odds Ratio 95% CI Odds Ratio 95% CI Odds Ratio 95% CI Odds Ratio 95% CI Internalizing Major depressive disorder 1.4* 1.3–1.6 1.3* 1.1–1.7 1.7* 1.4–2.0 1.4 0.9–2.1 Bipolar disorder 1.8* 1.4–2.3 1.3 0.8–2.2 1.9* 1.4–2.4 1.6 0.9–2.7 Panic disorder without agoraphobia 1.3* 1.0–1.7 1.0 0.6–1.8 1.8* 1.4–2.2 1.4 0.8–2.5 Generalized anxiety disorder 1.5* 1.2–1.9 1.4 1.0–1.9 1.1 0.8–1.6 0.9 0.5–1.6 Posttraumatic stress disorder 1.6* 1.3–2.1 1.8* 1.2–2.6 0.9 0.7–1.2 0.9 0.5–1.6 Social phobia 1.6* 1.2–2.0 1.2 0.8–1.7 1.4* 1.2–1.7 1.3 0.9–2.0 Specific phobia 1.7* 1.2–2.2 1.3 0.7–2.5 2.1* 1.8–2.4 1.0 0.7–1.4 Agoraphobia with or without panic 1.2 0.9–1.6 2.6* 1.4–4.7 1.3 0.9–1.8 1.1 0.6–1.9 Externalizing Attention deficit hyperactivity disorder 2.8* 1.6–4.6 0.8 0.4–1.9 1.1 0.8–1.5 1.2 0.7–2.0 Oppositional defiant disorder 1.6* 1.1–2.6 1.0 0.4–2.3 1.7* 1.3–2.2 1.4 0.8–2.4 Conduct disorder 1.4* 1.0–1.8 0.7 0.3–1.4 1.4* 1.1–1.9 0.8 0.4–1.6 Intermittent explosive disorder 1.3 1.0–1.7 0.7 0.5–1.2 1.3* 1.0–1.7 0.8 0.5–1.4 Substance abuse with or without dependence 1.0 0.8–1.2 1.3 0.9–1.8 1.4* 1.0–1.9 0.8 0.5–1.5 Substance dependence with abuse 1.0 0.8–1.4 1.3 0.8–2.1 1.0 0.7–1.4 1.0 0.4–2.2 a Discrete time survival analysis controlling for demographic variables, prior traumas, and childhood adversities as of age at onset of separation anxiety disorder, country, and person-year. b The data indicate a discrete time survival analysis predicting the prevalence of the disorder controlling for demographic variables, prior lifetime disorders, prior traumas, and childhood adversities as of age at onset of the disorder, country, and person-year. c Logistic regression analysis predicting 12-month prevalence of separation anxiety disorder among lifetime cases controlling for age at onset and time since onset of separation anxiety disorder, prior lifetime disorders as of the age at onset of separation anxiety disorder, prior lifetime trauma as of the age at onset of separation anxiety disorder, and prior childhood adversities and country. d The data indicate a logistic regression analysis predicting 12-month prevalence of the disorder among lifetime cases controlling for age at onset and time since onset of the disorder, prior lifetime disorders as of the age at onset of the disorder, prior lifetime trauma as of the age at onset of the disorder, prior childhood adversities, and country. * p<0.05 (two-sided test). TABLE 3 Predictors of Lifetime DSM–5/Composite International Diagnostic Interview (CIDI) Separation Anxiety Disorder in the Total Sample and by Life Course Stagea Total Sample Childhood (Age 13) Adolescence (Ages 13–17) Early Adulthood (Ages 18–29) Later Adulthood (Ages ≥30) Variable Odds Ratio 95% CI Odds Ratio 95% CI Odds Ratio 95% CI Odds Ratio 95% CI Odds Ratio 95% CI Sex Female 1.3* 1.2–1.5 1.4* 1.1–1.7 1.1 0.8–1.5 1.4* 1.1–1.9 1.1 0.7–1.7 Male (reference) 1.0 – 1.0 – 1.0 – 1.0 – 1.0 – Education b Student 1.2 1.0–1.6 – – – – 1.0 0.6–1.5 Low 1.5* 1.2–2.0 – – – – 1.4 1.0–2.2 2.0* 1.3–3.2 Low-average 1.6* 1.2–2.0 – – – – 1.4 1.0–2.0 2.0* 1.2–3.3 High-average 1.7* 1.4 1.0–1.9 1.8* 1.2–2.7 High (reference) 1.0 – 1.0 – 1.0 – 1.0 – 1.0 – Marital Status c Never married 1.1 0.9–1.4 – – – – 0.9 0.7–1.1 1.2 0.8–1.8 Previously married 1.3 0.9–1.8 – – – – 1.6* 1.1–2.3 1.7* 1.1–2.5 Currently married (reference) 1.0 – 1.0 – 1.0 – 1.0 – 1.0 – Number of maladaptive family functioning childhood adversitiesd, e 1 1.7* 1.4–2.0 1.7* 1.3–2.2 1.2 0.8–1.8 1.6* 1.2–2.1 2.1* 1.2–3.7 2 2.0* 1.6–2.4 2.3* 1.7–3.1 1.4 0.8–2.4 1.7* 1.2–2.3 2.0* 1.1–3.4 3 2.3* 1.8–2.8 2.6* 1.8–3.7 2.1* 1.3–3.4 1.7* 1.2–2.5 2.0* 1.1–3.4 4 2.8* 2.0–4.0 3.0* 1.9–5.0 1.7 0.8–3.6 3.3* 1.6–6.8 1.9* 1.0–3.8 ≥5 2.8* 2.1–3.6 3.7* 2.3–6.0 1.0 0.4–2.5 2.5* 1.3–4.6 3.7* 1.5–9.1 None (reference) 1.0 – 1.0 – 1.0 – 1.0 – 1.0 – Number of other childhood adversities f 1 1.3* 1.1–1.5 1.5* 1.2–1.9 1.3 0.9–1.9 1.0 0.8–1.3 1.1 0.7–1.5 2 1.2 1.0–1.5 1.7* 1.2–2.3 1.2 0.7–2.1 0.8 0.6–1.2 1.0 0.6–1.7 ≥3 1.8* 1.3–2.4 2.8* 1.6–4.9 1.4 0.6–3.6 1.3 0.7–2.3 0.5 0.2–1.5 None (Reference) 1.0 – 1.0 – 1.0 – 1.0 – 1.0 – Lifetime trauma g War 1.1 0.9–1.3 1.6* 1.0–2.5 1.4 0.7–2.5 0.9 0.6–1.3 1.0 0.6–1.5 Violence 1.1 0.9–1.2 2.0* 1.2–3.3 0.8 0.5–1.2 1.2 0.9–1.5 0.8 0.5–1.1 Sexual violence 1.6* 1.3–1.9 2.8 0.6–12.3 3.0* 1.5–5.8 1.6* 1.2–2.1 1.5* 1.0–2.1 Accident 1.4* 1.1–1.6 1.1 0.7–1.7 1.8* 1.2–2.6 1.3* 1.0–1.7 1.5* 1.0–2.3 Family death 1.4* 1.2–1.6 1.7* 1.1–2.5 1.3 0.8–2.0 1.3* 1.0–1.6 1.6* 1.2–2.3 Network events 1.3* 1.1–1.6 1.6 0.9–2.9 1.5* 1.0–2.2 1.3* 1.0–1.7 1.1 0.8–1.5 Other 1.5* 1.2–1.9 1.9* 1.1–3.3 1.7* 1.0–3.00 1.2 0.8–1.8 2.0* 1.3–3.3 a Discrete time-survival analysis controlling for person-year, country, age at interview, and prior lifetime DSM-IV/CIDI disorders as of separation anxiety disorder age at onset. The total sample model was estimated in all person-years, while the models for the various life course stages were restricted to person-years in the ranges indicated. The measures of education, marital status, and lifetime traumas were dated and were treated as time-varying covariates (i.e., coded as being present only as of the respondent’s age when they occurred). b The chi-square test (df=3) statistics for the total sample, early adulthood, and later adulthood are 20.22, 4.01, and 12.60, respectively, with the results for the total sample and later adulthood reaching statistical significance. c The chi-square test (df=2) statistics for the total sample, early adulthood, and later adulthood are 3.13, 10.06, and 5.70, respectively, with the results for early adulthood reaching statistical significance. d Measured using the Maladaptive Family Functioning Scale, which records items for parental mental illness, substance misuse, criminal behavior, domestic violence, physical and sexual abuse, and neglect. e The chi-square test (df=5) statistics for the total sample, childhood, adolescence, early adulthood, and later adulthood are 98.30, 48.08, 10.62, 18.63, and 13.20, respectively, with the results for all age groups except adolescence reaching statistical significance. f The chi-square test (df=3) statistics for the total sample, childhood, adolescence, early adulthood, and later adulthood are 20.23, 23.42, 2.59, 1.89, and 2.01, respectively, with the results for the total sample and childhood reaching statistical significance. g The chi-square test (df=7) statistics for the total sample, childhood, adolescence, early adulthood, and later adulthood are 117.47, 35.25, 44.40, 35.65, and 42.56, respectively, with the results for all age groups reaching statistical significance. * p<0.05 (two-sided test). TABLE 4 Prevalence of Severe Role Impairment Among Respondents With 12-Month DSM–5/Composite International Diagnostic Interview (CIDI) Separation Anxiety Disorder as a Joint Function of Country Income, Separation Anxiety Disorder Age at Onset, and 12-Month Comorbidity With the DSM-IV/CIDI Disorders Assessed in the World Mental Health Surveysa Total With Comorbidity Without Comorbidity Country Income and Age at Onset % SE % SE % SE Total sample 4–12 years old 33.9 5.2 37.3 5.9 8.5 8.2 13–17 years old 42.2 7.5 46.5 8.5 23.7 10.8 18–29 years old 35.7 4.3 45.3 5.3 16.7 5.3 ≥30 years old 31.7 5.8 40.4 7.3 21.2 8.9 Total 35.3 2.5 42.4 2.9 18.3 4.3 Low-/lower-middle income countries 4–12 years old 24.0 12.2 24.7 12.7 0.0 0.0 13–17 years old 14.5 7.9 13.0 8.7 19.4 18.8 18–29 years old 19.8 5.8 32.2 8.5 8.5 5.7 ≥30 years old 9.0 5.4 19.5 10.5 0.0 0.0 Total 17.6 4.1 25.3 6.0 6.9 3.8 Upper-middle income countries 4–12 years old 38.4 10.6 38.5 11.3 36.8 26.3 13–17 years old 30.6 10.7 27.8 13.1 39.3 17.0 18–29 years old 44.6 8.0 47.9 10.5 35.0 12.2 ≥30 years old 35.4 9.1 46.8 10.5 26.0 13.9 Total 38.2 4.1 41.6 4.4 30.6 8.9 High-income countries 4–12 years old 33.6 6.1 40.5 7.0 0.0 0.0 13–17 years old 62.3 10.5 71.1 9.2 0.0 0.0 18–29 years old 39.8 6.4 49.1 7.6 14.7 7.7 ≥30 years old 38.1 10.4 41.6 12.5 28.9 16.9 Total 41.4 3.8 49.3 4.3 14.2 5.7 a Logistic regression models assuming additive associations of country income level, age at onset, and 12-month comorbidity with severe role impairment fit the data better (Akaike information criterion=434.1; Bayesian information criterion=468.1) than models that also included all two-way interactions (Akaike information criterion=438.0; Bayesian information criterion=531.6) or all two-way and three-way interactions (Akaike information criterion=458.1; Bayesian information criterion=561.3). All other authors report no financial relationships with commercial interests. 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PMC005xxxxxx/PMC5116915.txt
LICENSE: This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. 101676030 44856 Cell Chem Biol Cell Chem Biol Cell chemical biology 2451-9456 27341433 5116915 10.1016/j.chembiol.2016.05.014 NIHMS829074 Article Immunization with outer membrane vesicles displaying designer glycotopes yields class-switched, glycan-specific antibodies Valentine Jenny L. 1# Chen Linxiao 1# Perregaux Emily C. 3 Weyant Kevin B. 1 Rosenthal Joseph A. 4 Heiss Christian 5 Azadi Parastoo 5 Fisher Adam C. 2 Putnam David 13 Moe Gregory R. 6 Merritt Judith H. 2 DeLisa Matthew P. 134* 1 School of Chemical and Biomolecular Engineering, Cornell University, Ithaca, NY 14853 USA 2 Glycobia Inc., 33 Thornwood Drive, Ithaca, NY 14850 USA 3 Comparative Biomedical Sciences, Cornell University, Ithaca, NY 14853 USA 4 Department of Biomedical Engineering, Cornell University, Ithaca, NY 14853 USA 5 Complex Carbohydrate Research Center, The University of Georgia, 315 Riverbend Road, Athens, GA 30602, USA 6 Centers for Cancer and Immunobiology and Vaccine Development, Children’s Hospital Oakland Research Institute, Oakland, CA 94609, USA * Address correspondence to: Matthew P. DeLisa, School of Chemical and Biomolecular Engineering, Cornell University, Ithaca, NY 14853. Tel: 607-254-8560; Fax: 607-255-9166; md255@cornell.edu # These authors contributed equally to this work. 11 11 2016 23 6 2016 21 11 2016 23 6 655665 This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. Summary The development of antibodies against specific glycan epitopes poses a significant challenge due to difficulties obtaining desired glycans at sufficient quantity and purity, and the fact that glycans are usually weakly immunogenic. To address this challenge, we leveraged the potent immunostimulatory activity of bacterial outer membrane vesicles (OMVs) to deliver designer glycan epitopes to the immune system. This approach involved heterologous expression of two clinically important glycans, namely polysialic acid (PSA) and Thomsen-Friedenreich antigen (T antigen) in hypervesiculating strains of non-pathogenic Escherichia coli. The resulting glycOMVs displayed structural mimics of PSA or T antigen on their surfaces, and induced high titers of glycan-specific IgG antibodies following immunization in mice. In the case of PSA glycOMVs, serum antibodies potently killed Neisseria meningitidis serogroup B (MenB), whose outer capsule is PSA, in a serum bactericidal assay. These findings demonstrate the potential of glycOMVs for inducing class-switched, humoral immune responses against glycan antigens. Introduction Complex carbohydrates, or glycans, are a ubiquitous feature on the surface of cells from all three domains of life. For example, capsular polysaccharides (CPS) or lipid-linked lipopolysaccharides (LPS) present on the surface of pathogenic bacteria are well known to mediate host-pathogen interactions (Comstock and Kasper, 2006). Alternatively, by displaying glycans that are structurally similar to those of their host, certain pathogens are able to avoid immune recognition (Comstock and Kasper, 2006). In eukaryotes, surface glycans participate in a variety of key biological processes including adhesion, cell-cell recognition, differentiation, and immune recognition (Varki et al., 2009), and are also known to feature prominently in disease (Ohtsubo and Marth, 2006). Indeed, glycans on the surfaces of tumor cells are commonly expressed at atypical levels or with altered structural attributes, and these aberrant structures serve as unambiguous markers of malignancy for a number of cancers (Pinho and Reis, 2015). At present, the study of glycans and their myriad roles remains a daunting task due in large part to their inherent structural complexity and the relative lack of tools for their biosynthesis, analysis, and recognition. Antibodies (Abs) specific for glycan epitopes (glycotopes) are particularly useful clarifying the functions of glycans. Glycan-targeting Abs can be elicited by immunization with carbohydrate antigens, and the resulting Abs can be used to probe the structure and function of glycans (Calarese et al., 2005; Nonaka et al., 2014) or target glycans therapeutically (Luo et al., 2010; Zhang et al., 2010). Nonetheless, the creation of glycan-specific Abs by immunization poses a significant challenge for several reasons. First, it is very difficult to isolate glycan-based immunogens from cells and tissues at purities and quantities that are sufficient for mAb isolation. Glycans and glycoconjugates are almost always a heterogeneous mixture of structures when isolated from natural sources (Raman et al., 2005), which dilutes any potential antigenic response. Total chemical synthesis and chemoenzymatic synthesis can often yield more uniform glycotopes (Wang and Lomino, 2012), however, these techniques are labor intensive, difficult to scale, and exist predominantly in the laboratories of a handful of experts. Second, glycans alone usually elicit weaker T-cell independent immune responses, which are short-lived and lack IgM-to-IgG class switching (Avci and Kasper, 2010). A common strategy for enhancing the immunogenicity of carbohydrates is to covalently couple a glycan to a T-cell dependent antigen. For example, conjugates composed of bacterial CPS or LPS chemically bound to an immunogenic carrier protein induce high-affinity, class-switched mAbs (Astronomo and Burton, 2010; Avci and Kasper, 2010). Unfortunately, production of traditional conjugate vaccines is a complex, multistep process that is expensive, time consuming, and low yielding (Frasch, 2009). A simplified alternative for generating glycoconjugates known as protein glycan coupling technology (PGCT) has been described recently (Cuccui and Wren, 2014; Terra et al., 2012). This approach leverages laboratory strains of Escherichia coli for the expression of recombinant bacterial polysaccharides (e.g., O-polysaccharide antigens), which are conjugated in vivo to a co-expressed carrier protein by the Campylobacter jejuni oligosaccharyltransferase PglB. However, while PGCT has been used to make several novel protein/glycan combinations, it is limited by variable glycan conjugation efficiency as observed for certain heterologous polysaccharide substrates (Cuccui et al., 2013; Ihssen et al., 2015; Ihssen et al., 2010) and a challenging purification of the product antigen. This is particularly pertinent in the context of producing glycoconjugates carrying mammalian-like glycans (Cuccui and Wren, 2014). Here, we sought to develop an efficient method for generating class-switched, anti-glycan Abs that overcomes many of the challenges discussed above. To this end, our approach combined custom glycan biosynthesis with outer membrane vesicle (OMV) formation in laboratory strains of E. coli. OMVs are naturally occurring nanospherical structures (~20–250 nm) produced constitutively by all Gram-negative bacteria. They are composed of proteins, lipids, and glycans derived from the outer membrane and periplasm, and have natural adjuvant properties that strongly stimulate the innate, and more importantly, the adaptive immune response (Alaniz et al., 2007; Baker et al., 2014; Ellis et al., 2010). To expand the immunostimulatory potential of OMVs, genetic engineering techniques have been used to load OMVs with foreign protein antigens by targeting expression to the outer membrane or to the periplasm of an OMV-producing host strain (Chen et al., 2010; Muralinath et al., 2011). These OMV-associated recombinant proteins elicited strong and specific antibody responses following immunization in mice. Building on these earlier observations, we engineered hypervesiculating strains of E. coli (Bernadac et al., 1998) to produce OMVs that displayed foreign glycans on their exteriors. This involved creation of two heterologous pathways for biosynthesis of structural mimics of clinically important carbohydrates, namely poly-α2,8-N-acetyl neuraminic acid (polysialic acid or PSA) and Galβ1-3GalNAcα1 (Thomsen-Friedenreich antigen or T antigen). The resulting glycosylated OMVs (glycOMVs), whose surfaces were remodeled with the custom-designed PSA or T antigen epitopes, induced strong glycan-specific IgG antibody titers following immunization in BALB/c mice. Taken together, our results show that engineered glycOMVs represent an effective strategy for generating functional Abs against structurally defined glycotopes of biomedical importance. Results A bottom-up engineered pathway for biosynthesis of T antigen on the surface of OMVs T antigen is one of many ‘self’ antigens expressed on a variety of malignancies including breast, colon, prostate, and stomach cancer, and Abs recognizing T antigen could have clinical benefit (Astronomo and Burton, 2010; Heimburg-Molinaro et al., 2011). However, the low intrinsic immunogenicity of T antigen poses a barrier to vaccination even after conjugation to a carrier protein (Adluri et al., 1995). Here, we hypothesized that the adjuvanticity of OMVs could be leveraged to overcome the weak immunogenicity of the T antigen epitope. Since LPS is a major component of released OMVs (Baker et al., 2014) and can be engineered to display foreign glycans (Ilg et al., 2010; Valderrama-Rincon et al., 2012), we attempted to remodel the carbohydrate component of LPS with T antigen-containing glycans. Such remodeling involved the lipid carrier undecaprenylpyrophosphate (Und-PP) as an acceptor of engineered glycans, which are flipped to the periplasmic side of the inner membrane and subsequently transferred to lipid A-core by the O-polysaccharide antigen ligase WaaL (Fig. 1a). In most laboratory strains of E. coli, Und-PP is primed with N-acetylglucosamine (GlcNAc) by the enzyme WecA. To elaborate the native Und-PP-GlcNAc with Galβ1-3GalNAc, we expressed two heterologous glycosyltransferases (GTases): the α1,3-GalNAc-transferase (PglA) from Campylobacter jejuni for transfer of GalNAc to Und-PP-GlcNAc (Glover et al., 2005); and the β1,3-galactosyltransferase (WbnJ) from E. coli O86 for stereospecific addition of the terminal galactose residue (Yi et al., 2005). Additionally, the UDP-GlcNAc 4 epimerase (Gne) from the same locus as C. jejuni PglA was added to supply the requisite UDP-GalNAc (Bernatchez et al., 2005). Formation of the T antigen epitope on inner membrane lipids was assessed by introducing plasmid pTF in E. coli K12 strain MC4100 lacking the waaL gene, which causes accumulation of UndPP-linked glycans in the cytoplasmic membrane. Lipid-linked oligosaccharides (LLOs) were extracted from these cells, and the glycan portion was released and purified as previously described (Valderrama-Rincon et al., 2012). MALDI-TOF mass spectrometry (MS) analysis of these glycans identified a major peak consistent with the expected Gal-terminal T antigen structure (m/z = 609) (Fig. 1b). Following treatment of the isolated glycans with β1,3-galactosidase, MS analysis revealed a major peak (m/z = 447) consistent with the removal of a single hexose residue (Fig. 1b), thereby corroborating the linkage of a terminal β1,3 Gal residue. Next, to determine whether the recombinant T antigen could be displayed on the exterior of OMVs, the hypervesiculating E. coli K12 strain JC8031, which overproduces OMVs due to deletion of tolRA (Bernadac et al., 1998), was transformed with the pTF plasmid. OMVs isolated from these cells were subjected to dot blot analysis whereby intact OMVs were spotted directly onto nitrocellulose membranes without any denaturation steps, and membranes were probed with peanut agglutinin (PNA), a lectin that binds the Galβ1-3GalNAc structure of the T antigen (Lotan et al., 1975). Consistent with the observation that outer membrane glycolipids are a major component of OMVs (Baker et al., 2014), we observed a strong signal from the non-denatured OMV fraction derived from JC8031 cells carrying pTF (Fig. 1c). To confirm that this signal was due to incorporation of the recombinant T antigen into LPS structures, we analyzed the OMV fraction from a knockout mutant of JC8031 that lacked waaL (hereafter JC8032), which encodes the O-polysaccharide antigen ligase responsible for transferring engineered Und-PP-linked glycans to lipid A-core (Feldman et al., 2005). As expected, the formation of T antigen on OMVs was blocked in JC8032 cells (Fig. 1c), confirming that display of engineered glycotopes on lipid A-core involved WaaL-dependent assembly. The incorporation of foreign glycotopes into E. coli LPS structures had no visible effect on vesicle nanostructure. For example, the spherical bilayered shape of T antigen-containing OMVs was indistinguishable from control OMVs as evidenced by transmission electron microscopy (TEM) microscopy (Supplementary Fig. 1a). Likewise, analysis by dynamic light scattering (DLS) revealed that the majority of the purified vesicles had a diameter of 20–60 nm (Supplementary Fig. 1b), consistent with the size of E. coli-derived OMVs that were characterized previously (Park et al., 2010). To determine whether recombinant T antigen detected in the pelleted supernatant was associated with intact vesicles, rather than with released outer membrane fragments or other cellular debris, the OMV-containing fraction isolated from JC8031 cells carrying pTF was separated by density gradient ultracentrifugation. Coomassie staining and Western blotting of the resulting fractions revealed that total OMV proteins, the outer membrane protein OmpA, and recombinant T antigen all co-migrated to denser fractions (Supplementary Fig. 2a–c), reminiscent of the gradient profiles seen previously for intact OMVs and OMV-associated proteins (Kim et al., 2008). A bottom-up engineered pathway for biosynthesis of PSA on the surface of OMVs PSA is a CPS that coats the surface of MenB and E. coli K1, and is also expressed in human tissues, most notably on neural cell adhesion molecule (NCAM) (Moe et al., 2009). As a result of this latter point, PSA has proven to be a particularly difficult target for antibody generation. Indeed, PSA is poorly immunogenic even when conjugated to a carrier protein (Krug et al., 2004), possibly because of the similarity to self-antigens. To overcome this barrier, we engineered a hypervesiculating E. coli K12 strain to produce OMVs decorated with recombinant PSA glycans. Since E. coli K12 strains do not produce PSA naturally, this first required the creation of an artificial pathway for PSA biosynthesis. To create the core onto which PSA could polymerize, we generated plasmid pPSA, which enabled heterologous expression of the GTases LgtB from Neisseria gonorrhoeae and CstII from Campylobacter jejuni. These GTases were predicted to catalyze the successive transfer of galactose and sialic acid (N-acetyl neuraminic acid; NeuNAc), respectively, to the Und-PP acceptor. Plasmid pPSA also encoded the neuBACS genes from E. coli K1, which collectively coordinate the formation of precursor CMP-NeuNAc and polymerization of NeuNAc (Fig. 2a). Finally, the neuD gene from E. coli K1, which promotes efficient sialic acid synthesis by enhancing the activity of other proteins (e.g., NeuBAC) in the sialic acid pathway (Daines et al., 2000), was cloned on a separate plasmid named pNeuD. These two plasmids were introduced into a ΔnanA derivative of the hypervesiculating strain JC8031 (hereafter JC8033), which is unable to catabolize free NeuNAc due to absence of the N-acetylneuraminate lyase enzyme, NanA (Priem et al., 2002). LLOs were extracted from JC8033 cells carrying pPSA and pNeuD, and the glycan portion was purified and permethylated. Positive-ion mode MALDI-TOF MS of the permethylated glycans identified a major peak (m/z = 791.4) corresponding to a NeuNAc disaccharide, as well as minor peaks corresponding to tri-, tetra-, and pentasaccharides of NeuNAc (Fig. 2b). A minor peak consistent with a NeuNAc-NeuGc structure was also identified. To determine whether PSA was incorporated in OMVs derived from these cells, membrane vesicles were isolated and subjected to dot blot analysis using SEAM 12, a murine Ab that is cross-reactive with PSA and exhibits potent complement-mediated bactericidal activity against MenB (Granoff et al., 1998). As with the engineered T antigen, we observed a strong signal from the non-denatured OMV fraction derived from JC8033 cells carrying both pPSA and pNeuD (Fig. 2c). This signal was comparable to that obtained by similarly probing intact EV36 cells, a K-12/K1 hybrid E. coli strain that natively expresses PSA on its surface (Fig. 2c) (Vimr et al., 1989). In contrast, no detectable signal was observed from OMV fractions derived from JC8033 cells without any plasmids or carrying either the pPSA and pNeuD plasmid individually (Fig. 2c), indicating that NeuD was required for engineered PSA biosynthesis. Likewise, the absence of LgtB or CstII, or both, resulted in a similar lack of signal in dot blots probed with the SEAM 12 antibody (Fig. 2c). It is noteworthy that nearly identical signals were observed using a commercial anti-polysialic acid-NCAM antibody (Millipore) that recognizes α2,8-linked PSA. Density gradient ultracentrifugation of the OMV fraction from JC8033 carrying pPSA and pNeuD revealed that PSA co-migrated with total OMV proteins and OmpA (Supplementary Fig. 2d–f), and thus appeared to be associated with intact vesicles. It is also noteworthy that incorporation of foreign PSA glycan into E. coli LPS structures had no visible effect on vesicle nanostructure (Supplementary Fig. 1a), with vesicle size again ranging from 20–60 nm in diameter (Supplementary Fig. 1b). To confirm whether PSA was produced on the Und-PP acceptor, we analyzed the OMV fraction from the waaL knockout mutant of JC8033 (hereafter JC8034) carrying the pPSA and pNeuD plasmids. Unlike the case of T antigen biosynthesis above, the display of PSA on the exterior of OMVs was not dependent on WaaL (Fig. 2d). Likewise, PSA display was still observed in JC8033 cells lacking wecA (hereafter JC8035), which transfers GlcNAc to Und-PP and forms the hypothesized Und-PP-GlcNAc acceptor for LgtB (Fig. 2d). In light of these results, we hypothesized an alternative mechanism for incorporation of recombinant PSA into LPS structures involving direct conjugation of foreign saccharides to lipid A-core structures (Ilg et al., 2010). The basis for this hypothesis stems from the following: in E. coli K-12 strains, lipid A-core contains glucose residues that might serve as substrates for heterologously expressed LgtB, a promiscuous biocatalyst that can transfer galactose to a variety of different glucose- and glucosamine-containing acceptors (Blixt et al., 2001). To test this hypothesis, we generated a hypervesiculating derivative of E. coli ClearColi, a K-12 strain that produces truncated LPS structures, called lipid IVA, that lack saccharide acceptors for our heterologously expressed GTases (e.g., LgtB) (Mamat et al., 2008). This was accomplished by deleting the nlpI gene that is known to increase vesiculation on par with tolRA mutants (Kim et al., 2008; McBroom et al., 2006), resulting in strain ClearColi-ves. OMVs produced from ClearColi-ves cells carrying pPSA and pNeuD were indeed blocked for PSA display (Fig. 2d). In contrast, OMVs derived from the parental strain MG1655, also lacking nlpI (MG1655-ves) and carrying the pPSA and pNeuD plasmids, were decorated with PSA at a level that rivaled JC8033 carrying the same PSA pathway plasmids (Fig. 2d). These results support the notion that PSA was incorporated in LPS structures by direct conjugation to saccharides in lipid A-core. Immunization with glycOMVs elicits glycan-specific antibodies We next sought to assess the immunological potential of glycOMVs displaying the T antigen and PSA epitopes. Specifically, BALB/c mice were immunized via subcutaneous (s.c.) injection with either T antigen- or PSA-containing glycOMVs, after which blood was collected at regular intervals. Controls included ‘empty’ OMVs from plasmid-free JC8031 or JC8033 cells, LOS extracted from MenB strain S3446 (NmBLOS), and phosphate buffered saline (PBS). To determine whether glycOMVs generated glycan-specific Abs, the total T antigen- and PSA-specific IgG titers at the endpoint were measured by ELISA using the model glycoprotein carrier protein scFv13-R4 with a C-terminal glycosylation motif (Valderrama-Rincon et al., 2012) bearing the T antigen or native LOS from MenB, respectively, as immobilized antigen. In the case of the T antigen epitope, glycOMVs elicited a significantly higher (p < 0.01) level of glycan-specific IgGs compared to both the empty OMV and PBS control groups (Fig. 3a). Similarly, the total PSA-specific IgG titers were significantly increased (p < 0.01) for the group immunized with PSA glycOMVs compared to all other immunized groups (Fig. 3b). It is particularly noteworthy that the IgG titers for the group immunized with native MenB LOS were not significantly different (p > 0.2) than those measured in the PBS group, consistent with the weak immunogenicity of glycans alone. Hence, the immunogenicity of engineered carbohydrates was boosted by display on the exterior of OMVs. IgG titers were further broken down by analysis of IgG1 and IgG2a titers, wherein mean IgG1 to IgG2a antibody ratios served as an indicator of a Th1- or Th2-biased immune response. Mice immunized with T antigen and PSA glycOMVs showed a significant (p < 0.05) increase in mean titers of glycan-specific IgG1 and IgG2a in comparison to all other groups (Supplementary Fig. 3a and b). The similar levels observed for IgG1 versus IgG2a titers suggested no measurable Th1/Th2 bias. T antigen-specific antibodies detect target antigen in Western blot format To determine the diagnostic potential of these glycan-specific Abs, we performed Western blot analysis using sera generated through glycOMV immunization. As expected, Abs generated by immunization with T antigen glycOMVs cross-reacted exclusively with the model carrier protein scFv13-R4 bearing the T antigen, generating a signal that was on par with that obtained using PNA lectin (Fig. 4a). In contrast, when the membrane was probed with Abs generated by immunization with empty OMVs, there was no visible binding to either glycosylated or aglycosylated scFv13-R4 (Fig 4a). PSA-specific antibodies exhibit complement-mediated bactericidal activity We next investigated whether the serum Abs produced by glycOMV immunization were immunologically relevant. For this, we performed a complement-mediated serum bactericidal activity (SBA) assay using the sera collected from mice immunized with PSA glycOMVs. SBA is an established method by which the activity of Abs against N. meningitidis is measured, and it correlates with protection for all serogroups of the pathogen (Martin et al., 2005). Here, we hypothesized that PSA-specific Abs generated by glycOMV immunization would bind to capsular PSA on the surface of MenB and, in the presence of components of the human complement system, would mediate bacteriolysis of the pathogen. In the group immunized with PSA glycOMVs, 50% SBA was observed at over 100-fold dilutions of the serum, a level that was on par with the anti-MenB antibody, SEAM 12 (Fig. 4b). In contrast, no killing was observed for sera collected from any of the control groups, or for the control anti-MenC antibody, over the dilutions tested (Fig. 4b). Complete killing was observed in immunized groups at dilutions as high as 10-fold, indicating that the Abs present in serum from glycOMV-immunized mice were immunologically functional. Discussion We have developed a new approach for generating class-switched, anti-glycan Abs that leverages the immunostimulatory properties of OMVs (Alaniz et al., 2007; Chen et al., 2010; Ellis et al., 2010; Sanders and Feavers, 2011) to boost the immune response to glycan epitopes, which are notoriously weak antigens (Astronomo and Burton, 2010; Avci and Kasper, 2010). An important first step involved converting laboratory strains of E. coli into factories for glycosylated OMV production by combining bacterial vesiculation with engineered pathways for designer glycan biosynthesis. We anticipate that this strategy could be generalized to create many other structurally diverse and biomedically relevant glycotopes on the exterior of OMVs for both diagnostic and therapeutic applications. It is worth noting that compared to the expression of protein antigens in OMVs, expression of glycans is a more elaborate undertaking. For protein antigens, expression in OMVs simply requires targeting the antigen of interest either to the periplasmic space by genetic fusion of an N-terminal export signal or to the cell surface by genetic fusion to an outer membrane carrier protein (Baker et al., 2014). Following vesiculation, the periplasmic- or outer membrane-targeted proteins become constituents of the OMV lumen or exterior, respectively. In contrast, display of carbohydrate antigens on OMVs requires the coordinated expression of multiple heterologous glycosyltransferases for directing the synthesis of desired glycans onto bacterial lipid carriers that subsequently localize to the outer membrane and become constituents of released OMVs. Despite the challenges, several groups including ours have used glycoengineering as a tool to remodel the bacterial outer membrane with mammalian glycotopes of interest including ganglioside GM3 (Ilg et al., 2010), Lewis Y (LeY) antigen (Yavuz et al., 2011), and trimannosyl core N-glycan (Valderrama-Rincon et al., 2012). Presumably, expression of these different cell surface glycans in a hypervesiculating host strain would yield uniquely glycosylated OMVs, although this remains to be shown. Importantly, once new glycan structures are created, however, production of glycOMV immunogens is significantly less complicated, less time consuming, less expensive, and more scalable than conventional approaches for producing glycoconjugates. It requires only one cultivation step to generate the final product, which can be easily and economically isolated by a single ultracentrifugation step (Chen et al., 2010). Moreover, the clinical translation of OMVs has also been established recently by Bexsero, a four component vaccine against N. meningitidis serogroup B that has been approved in the U.S. for preventing infection caused by this serogroup. The active components of this vaccine are three recombinant proteins identified by reverse vaccinology combined with detergent extracted OMVs prepared from a naturally occurring epidemic strain (Gorringe and Pajon, 2012). While engineered OMVs such as the ones we described herein have not yet found their way into the clinic, Bexsero represents a first important step in that direction. The ability of T antigen- and PSA-modified glycOMVs to elicit class-switched, glycan-specific IgGs in mice is significant in light of the low intrinsic immunogenicity that has been observed for these glycans, even when conjugated to a carrier protein (Adluri et al., 1995; Krug et al., 2004). The poor immunogenicity of these glycans has been attributed to immunologic tolerance that arises due to their resemblance with structures present in human and murine hosts (i.e., self antigens). Hence, our observation that glycOMVs triggered high titers of class-switched IgGs represents a significant advance in the pursuit of Abs against glycotopes of interest. While a molecular-level understanding of how OMVs boost the immune response to these glycans remains to be determined, we suspect that it stems from the potent adjuvanticity afforded by OMVs which: (i) are readily phagocytosed by professional antigen-presenting cells; (ii) carry pathogen-associated molecular patterns (PAMPs) within their structure that can stimulate both innate and adaptive immunity; and (iii) possess strong proinflammatory properties (Alaniz et al., 2007; Ellis et al., 2010; Sanders and Feavers, 2011). The fact that PSA and T antigen are self antigens of humans and a potential cause of immunopathology has hindered their development as vaccines. However, there are reasons to believe that many tumor-specific carbohydrate antigens including T antigen and PSA have a number of attributes that make them viable targets for vaccine development, most notably their widespread and high expression in several different cancers and their low or cryptic expression on normal cells (Astronomo and Burton, 2010; Heimburg-Molinaro et al., 2011). Interestingly, in the case of PSA, Miller and colleagues recently published an essay in which they reviewed the data on PSA as a self antigen and concluded that (2→8)-α-Neu5Ac conjugates will be as safe and effective as the polysaccharide protein conjugate vaccines for the other four meningococcal serogroups (Robbins et al., 2011). Aside from the potential immunotherapeutic applications enabled by glycOMVs, their ability to elicit glycan-specific Abs can be exploited to produce high-affinity reagents for glycobiology and glycomedicine. Currently, carbohydrate-binding lectins are the primary means to detect glycans in numerous analytical assays; however, lectins are limited by their poor sensitivity and binding affinity as well as lack of specificity towards less common glycan structures (Haab, 2012). Our demonstration that polyclonal serum from immunization with T antigen glycOMVs can be used for immunodetection of glycans illuminates the diagnostic potential of serum Abs elicited by glycOMVs and ensures that these Abs will find use even in cases where vaccine-induced autoimmunity proves to be an insurmountable obstacle. The potent bactericidal activity of the PSA glycOMV-stimulated serum Abs against N. meningitidis serogroup B in the presence of human complement further confirmed the authenticity of the engineered glycotope mimics as well as the full functionality of the Abs they elicited. To our surprise, vaccinations using empty OMV controls elicited measurably higher IgG titers in mice as compared to titers measured for the PBS control mice; however, none of these serum Abs were bactericidal. It should also be noted that the PSA-specific IgG titers for the empty OMV-immunized groups were still significantly (p < 0.01) less than those generated from the PSA glycOMV-immunized groups. Nonetheless, we attribute these unexpected ELISA signals to the presence of serum Abs against other components in the OMVs, which cross-reacted with similar components present in the NmBLOS. Indeed, when ELISA plates were instead coated with a synthetic PSA-ADH derivative (Granoff et al., 1998), the signal from the empty OMV group was notably lower. Overall, the results of this study reveal that glycOMVs are a reliable and robust method for generating class-switched Ab responses to glycan epitopes of interest. Compared to current approaches for achieving the same goal, glycOMVs represent a solution that is considerably less complicated and significantly more scalable. By rewiring the glycan biosynthetic pathway, it should be possible to generate glycOMVs displaying a wide array of biomedically relevant glycotopes found on the surfaces of bacteria and human cells, as we demonstrated here with T antigen and PSA. Moreover, the ability of OMVs to overcome immunologic tolerance by eliciting strong immune responses to glycans characterized as self antigens should further expand the palette of glycans that can be targeted by this approach. There also exist opportunities to couple glycOMVs with emerging techniques for Ab discovery such as immune repertoire mining (Lavinder et al., 2015), which could provide unprecedented access to a renewable source of high-quality, glycan-binding affinity reagents for interrogating the glycomes of living organisms or treating human disease. And since immunization with PSA glycOMVs yielded Abs that were fully functional (i.e., bactericidal), it stands to reason that glycOMVs themselves might eventually find use in a therapeutic context. Experimental Procedures Bacterial strains and plasmids A description of all bacterial strains and plasmids used in this study, including those that were constructed herein, is provided in the Supplementary Methods, along with a complete list in Supplementary Table 1. Briefly, unless otherwise stated, most strains used herein are based on E. coli strain JC8031, a tolRA mutant strain that is known to hypervesiculate (kindly provided by Roland Lloubes, Centre national de la Recherche Scientifique) (Bernadac et al., 1998). Cell growth and OMV preparation OMVs were prepared as described previously (Chen et al., 2010). Briefly, cells were freshly transformed with plasmids for T antigen or PSA biosynthesis and selected on medium supplemented with the appropriate antibiotic. An overnight culture of a single colony was subcultured into 100–200 mL of Luria-Bertani (LB) medium. The culture was grown to mid-log phase, at which time protein expression was induced with L-arabinose (0.2%) and/or IPTG (0.1 mM), if necessary. Cell-free culture supernatants were collected 16–20 h post-induction and filtered through a 0.2 μm filter. Vesicles were isolated by ultracentrifugation (Beckman-Coulter; TiSW28 rotor; 141,000xg; 3 h; 4°C) and resuspended in PBS. OMVs were quantified by the bicinchoninic-acid assay (BCA Protein Assay; Pierce) using BSA as the protein standard. OMVs were further separated by density-gradient ultracentrifugation as previously described (Kim et al., 2008). Briefly, OMVs were prepared as described above but resuspended in a 50 mM HEPES (pH 6.8) solution. This solution was adjusted to 45% (v/v) Optiprep (Sigma) in 1.5 mL. All other Optiprep layers were prepared using the same 50-mM HEPES (pH 6.8) solution. Optiprep/HEPES gradient layers were added to a 12-mL ultracentrifuge tube as follows: 0.33 mL of 10%, 0.33 mL of 15%, 0.66 mL of 20%, 0.66 mL of 25%, 0.9 mL of 30%, 0.9 mL of 35%, 1.5 mL of 45% containing the prepared OMVs, and enough 60% to nearly fill the tube. Gradients were centrifuged (Beckman-Coulter; TiSW41 rotor; 180,000xg; 3 h; 4°C), then, a total of ten fractions of 0.5 mL each were removed sequentially from the top of the gradient. These fractions were analyzed by Western blot and dot blot analyses as described below. Glycoprotein expression and purification E. coli MC4100 ΔwaaL::kan was co-transformed with plasmid pTrc99A-ssDsbA-scFv13-R4DQNAT (Valderrama-Rincon et al., 2012) and either pTF or empty vector control pMW07. An overnight culture was used to inoculate 100 mL of LB medium containing ampicillin and chloramphenicol. Cultures were grown to an OD600 of ~ 2.0, and induced overnight with 0.2% arabinose and 0.1 mM IPTG. Cells were harvested after which glycosylated or aglycosylated scFv13-R4 proteins were purified using Ni-NTA spin columns (Qiagen) according to manufacturer’s instructions. Proteins were buffer exchanged to PBS and the concentration adjusted to 1 mg/mL. Western blot and dot blot analysis OMV and LPS samples were prepared for SDS-PAGE analysis by boiling for 15 min and cooling to room temperature in the presence of loading buffer containing β-mercaptoethanol. OMV samples were normalized by total protein concentration, which was quantified using the BCA method as detailed above. Samples were run on Any kD polyacrylamide gels (BioRad, Mini-PROTEAN® TGX) and transferred to a PVDF membrane. After blocking with Carbo-Free blocking solution (Vector Labs), membranes with T antigen samples were probed first with biotinylated peanut agglutinin (Vector Labs) and then with streptavidin-HRP (Abcam). Similarly, after blocking with a 5% milk solution, membranes with PSA samples were probed first with SEAM 12 primary antibody specific against N. meningitidis B CPS (Granoff et al., 1998) and then with the corresponding anti-mouse HRP-conjugated secondary antibody (Promega). Membranes from density-gradient samples were also probed with an OmpA-specific antibody (kindly provided by Wilfred Chen, University of Delaware) and then with anti-mouse HRP-conjugated secondary antibody (Promega). Signal was visualized using HRP substrate and either an X-ray film developer or a ChemiDoc Imaging System (BioRad). Western blot analysis of glycosylated and aglycosylated scFv13-R4 was performed according to standard protocols. Briefly, protein-containing samples were separated by SDS-PAGE and transferred to PVDF membranes. Membranes were then probed with either: biotinylated PNA (Vector labs) and then with streptavidin-HRP (Vector Labs); immunized sera (from either empty OMV or T antigen glycOMV groups) at a concentration of 1:1000, followed by anti-mouse IgG HRP (VWR); or anti-His-HRP (Sigma). Signal was visualized using HRP substrate and imaged using a ChemiDoc Imaging System (BioRad). For dot blot analysis, OMV samples were normalized by total protein concentration, which was quantified using the BCA method as detailed above, and spotted directly onto a nitrocellulose membrane. Alternatively, OMVs were boiled for 10 min and cooled to room temperature prior to spotting on the membrane. After blocking with a 5% milk solution, membranes with PSA samples were probed first with SEAM 12 and then with HRP-conjugated anti-mouse IgG. For the T antigen, membranes were blocked with Carbo-Free blocking solution (Vector Labs), and then probed with biotinylated peanut agglutinin (Vector Labs) and subsequently streptavidin-HRP (Abcam). Signal was visualized using HRP substrate and either an X-ray film developer or a ChemiDoc Imaging System (BioRad). Electron microscopy Structural analysis of vesicles was performed via transmission electron microscopy as previously described (Chen et al., 2010). Briefly, vesicles were negatively stained with 2% uranyl acetate and deposited on 400-mesh Formvar carbon-coated copper grids. Imaging was performed using a FEI Tecnai F20 transmission electron microscope. MALDI-TOF MS analysis For structural characterization of T antigen, LLOs were extracted from MC4100 ΔwaaL::kan cells carrying pTF. An overnight culture of a single colony was subcultured into LB medium. Cultures were grown at 30°C and induced when optical density at 600 nm (OD600) reached ~2.0. Cultures were then harvested after 20 h. Cell pellets were collected, resuspended in methanol and lysed via sonication. Material was then dried at 60°C and subsequently resuspended in 2:1 chloroform:methanol solution (v/v, CM) via sonication and washed two times with the CM solution. The pellet was then washed in water. Lipids were extracted with 10:10:3 chloroform:methanol:water (v/v/v, CMW) followed by methanol. Extracts were then loaded into a DEAE cellulose column and eluted with 300 mM NH4OAc in CMW. The LLOs were extracted with chloroform and dried. Glycans released from LLOs were dried and resuspended in dH2O. 10-μL β-1,3-galactosidase (NEB) reactions were prepared using supplied buffer and incubated at 37°C. Reaction products were monitored by MALDI/TOF-MS. For structural characterization of PSA, the carbohydrate was isolated from the cells following a published procedure (Willis et al., 2013), except that the cells were disrupted by French press and that the gel-filtration step was omitted. The yield of carbohydrate was about 1 mg. Next, the samples were permethylated as described (Anumula and Taylor, 1992) and analyzed by MALDI/TOF-MS in reflector positive-ion mode on a ABISciex 5800 MALDI/TOF-TOF using α-dihyroxybenzoic acid (DHBA, 20 mg/mL solution in 50% methanol:water) as matrix. Mouse immunizations Three groups of four or five BALB/c female mice aged six- to eight-weeks old (The Jackson Laboratory) were each immunized s.c. with either PBS alone (control) or 100 μL of PBS containing: 10 μg of OMVs from JC8031 cells carrying no plasmid (empty OMVs) or 10 μg of OMVs from JC8031 cells harboring pTF (T antigen glycOMVs). Separately, four groups of five or six BALB/c female mice aged six- to eight-weeks old (The Jackson Laboratory) were each immunized s.c. with either PBS alone (control) or 100 μL of PBS containing: 2 μg of native LOS from N. meningitidis serogroup B (NmBLOS), 10 μg of OMVs from JC8033 cells carrying no plasmid (empty OMVs), or 10 μg of OMVs from JC8033 cells harboring pPSA and pNeuD (PSA glycOMVs). NmBLOS was prepared from MenB strain S3446 identically as described previously (Apicella et al., 1997). PSA content of the PSA glycOMV and NmBLOS doses were similar and determined via reactivity to the SEAM 12 antibody (Granoff et al., 1998). All PBS used was at pH 7.4. Each group of mice was boosted with an identical dosage of antigen 28 days and 56 days after the priming dose. Blood was collected from each mouse from the mandibular sinus immediately before and 14 days after the first immunization, immediately before and 14 days after the first boosting dose, immediately before the second boosting dose, and at 14 days and 28 days after the second boosting dose. The protocol number for the animal studies (2009-0096) was approved by the Institutional Animal Care and Use Committee at Cornell University. Statistical analysis was performed using one-way analysis of variance (ANOVA) followed by the post-hoc Tukey-Kramer test for multiple comparisons. Enzyme-linked immunosorbant assay (ELISA) Glycan-specific Abs produced in immunized mice were measured via indirect ELISA using a modification of a previously described protocol (Chen et al., 2010). Briefly, sera were isolated from the collected blood draws after centrifugation at 2,200xg for 10 min. 96-well plates (Maxisorp; Nunc Nalgene) were coated with E. coli-derived LPS containing T antigen or NmBLOS (2 μg/mL in PBS pH 7.4) and incubated overnight at 4°C. For comparison, ELISAs were also performed using a synthetic PSA-adipic acid dihydrazide (ADH) derivative, which was prepared as described (Granoff et al., 1998) and used to coat microtiter plates at a concentration of 20 μg/ml in PBS (pH 7.4). The next day, plates were washed 3 times with PBST (PBS, 0.05% Tween-20, 0.3% BSA) and blocked overnight at 4°C with 5% nonfat dry milk (Carnation) in PBS. Samples were serially diluted, in triplicate, between 1:100-1:12,800,000 in blocking buffer and added to the plate for 2 h at 37°C. Plates were washed 3 times with PBST and incubated for 1 h at 37°C in the presence of one of the following horseradish peroxidase-conjugated Abs: goat anti-mouse IgG (1:5000; Abcam), anti-mouse IgG1 (1:5000; Abcam), or anti-mouse IgG2a (1:5000; Abcam). After 3 additional washes with PBST, 3,3′-5,5′-tetramethylbenzidine substrate (1-Step Ultra TMB-ELISA; Thermo Scientific) was added and the plate was incubated at room temperature for 30 min. The reaction was halted with 2M H2SO4. Absorbance was quantified via microplate spectrophotometer (Molecular Devices) at a wavelength of 450 nm. Serum antibody titers were determined by measuring the lowest dilution that resulted in signal three standard deviations above background. Statistical significance was determined using Tukey-Kramer post hoc honest significant difference test and compared against the PBS control case. Complement-mediated bactericidal assay Bactericidal assays were conducted similar to a previously published protocol (Moe et al., 1999). Briefly, MenB strain H44/76 was grown overnight on chocolate agar plates (Remel). Single colonies were used to inoculate a culture in Franz media starting at an OD620 ~0.15 and grown at 37°C, 5% CO2 to OD620 ~0.6. The bacteria were diluted in Dulbeccos PBS with Ca2+ and Mg2+ (DPBS), containing 1% human serum albumin (Sigma-Aldrich). Approximately 300–400 CFU meningococci were incubated with 20% human serum (from a healthy adult with no detectable anticapsular antibody to group B polysaccharide) that had been depleted of IgG with a Protein G column and serum collected from mouse immunizations. Percent survival was calculated as the CFU/mL after 60 min incubation of bacteria compared to baseline CFU/ml at time zero determined by average bacterial growth in buffer alone, with heat-inactivated complement, with active complement, or a mixture of heat-inactivated and active complement. Murine antibodies SEAM 12 and anti-MenC were used as positive and negative controls, respectively. Supplementary Material Supplemental We thank Roland Lloubes for strain JC8031, Eric Vimr for strain EV36, and Wilfred Chen for anti-OmpA antibody used in this work. This material is based upon work supported in part by The Jennifer Leigh Wells Family (G.R.M.), NSF Grants CBET 1159581 and CBET 1264701 (both to M.P.D.), an NSF GK-12 “Grass Roots” Fellowship (to L.C.), and the following NIH Grants: T32GM008500 (to E.C.P.), GM088905-01 (to M.P.D.), EB005669-01 (to D.P. and M.P.D.), R56AI114793-01 (to D.P. and M.P.D.), R43AI091336-01 (to A.C.F.), R43GM093483 (to A.C.F.), R44GM093483-02 (to J.H.M.), and P41GM10349010 (to P.A.). We also acknowledge the New York State Office of Science, Technology and Academic Research (NYSTAR) Distinguished Faculty Award (to M.P.D.), the Cornell Center for Materials Research Shared Facilities, which are supported through the NSF MRSEC program (DMR-1120296), and the Chemical Sciences, Geosciences and Biosciences Division, Office of Basic Energy Sciences, U.S. Department of Energy grant DE-FG02-93ER20097 (to P.A.). Figure 1 Expression of recombinant T antigen glycotope on OMVs (a) Schematic of recombinant T antigen biosynthesis, which begins with glycan assembly on endogenous Und-PP-GlcNAc structure in the inner membrane and involves the coordinated action of heterologously expressed GalE epimerase and the glycosyltransferases PglA and WbnJ (shown in red). Trisaccharide glycan is flipped into the periplasmic space by Wzx where it is subsequently transferred onto lipid A core by WaaL and translocated to the outer membrane. (b) MALDI-MS profile of glycans released from LLOs by acid hydrolysis. LLOs were extracted from E. coli MC4100 ΔwaaL::kan cells carrying plasmid pTF. Glyans released from LLOs were dried and resuspended in dH2O. The major signal at m/z 609 corresponded to HexHexNAc2. Following digestion of glycans with β-1,3-galactosidase at 37°C, the major signal at m/z 447 corresponded to HexNAc2. (c) Dot blot analysis of OMV fractions, generated from plasmid-free JC8031 cells (empty), JC8031 cells carrying pTF, and JC8032 cells, which lacked waaL, carrying pTF. Blots were probed with peanut agglutinin to confirm presence or absence of T antigen on exterior of OMVs. Fetuin and asialofetuin served as negative and positive controls, respectively. Figure 2 Expression of recombinant PSA glycotope on OMVs (a) Schematic of PSA biosynthesis pathway, which involves NeuABCD for the formation of CMP-NeuNAc and NeuS for its polymerization into PSA. (b) Positive-ion MALDI-TOF spectrum of permethylated PSA. Glycolipids were extracted from JC8033 cells carrying plasmids pPSA and pNeuD. The major signal at m/z 791.4, with additional significant peaks at m/z 1152.6, 1513.7, and 1874.9 corresponding to tri, tetra, and penta NeuNAc structures. The predominance of the dimer seen here is consistent with preliminary NMR analysis of the same material. (c) Dot blot analysis of non-denatured OMV fractions generated from plasmid-free JC8033 cells (−) or JC8033 cells carrying either pNeuD, pPSA, or pPSA/pNeuD together. Also shown are OMV fractions from JC8033 cells carrying PSA/pNeuD where the pPSA plasmid lacked cstII (pPΔC), lgtB (pPΔL), or both (pPΔCL). Strain EV36 served as a positive control. (d) Dot blot analysis of non-denatured OMV fractions generated from plasmid-free JC8033 cells (−) or the following strains each carrying pPSA/pNeuD: JC8033; JC8034, which lacked waaL; and JC8035, which lacked wecA. Also shown are OMV fractions from hypervesiculating versions of MG1655 and ClearColi (MG1655-ves and ClearColi-ves, respectively) carrying pPSA/pNeuD. Blots were probed with SEAM 12 antibody to confirm the presence or absence of PSA on exterior of OMVs. Figure 3 GlycOMVs boost production of glycan-specific IgG antibodies Median antigen-specific IgG titers of individual mice immunized with (a) T antigen glycOMVs or (b) PSA glycOMVs in endpoint (day 54 and 84, respectively) serum. For the T antigen epitope, three groups of BALB/c mice were immunized s.c. with: 10 μg OMVs from plasmid-free JC8031 cells (empty), 10 μg OMVs from JC8031 cells carrying pTF (T antigen glycOMVs); or PBS. Glycosylated scFv13-R4 bearing T antigen was used as immobilized antigen. For the PSA epitope, four groups of BALB/c mice immunized s.c. with: 10 μg OMVs from plasmid-free JC8031 ΔnanA cells (empty); 10 μg OMVs from JC8031 ΔnanA cells carrying pPSA and pNeuD (PSA glycOMVs); 2 μg MenB LOS; or PBS. NmBLOS was used as immobilized antigen. Mice were boosted on day 28 and 56 with same doses. Asterisk (*) represents statistical significance (p < 0.01; Tukey-Kramer Post-Hoc HSD) versus all other groups. Figure 4 Diagnostic and therapeutic potential of glycan-specific antibodies (a) Western blot analysis of scFv13-R4 glycosylated with T antigen (+) or aglycosylated scFv13-R4 (−). Blots were probed with PNA, polyclonal sera from groups immunized with T antigen glycOMVs or empty OMVs, or anti-His-HRP antibody. (b) Representative killing activity of antibodies in the serum of mice immunized with: PBS, empty OMVs, and PSA glycOMVs. Survival data is derived from standard serum bactericidal assay (SBA) where dilutions of serum from immunized mice were tested against MenB strain H44/76 in the presence of human complement. Murine antibodies against MenB (SEAM 12) and MenC (anti-MenC) served as positive and negative controls, respectively. The SBA curves for PBS and empty OMVs are representative of all mice in the group (n = 6) and three of six PSA glycOMV that had the highest response to the vaccine. Author Contributions. J.L.V. and L.C. designed research, performed research, analyzed data, and wrote the paper. E.C.P., K.B.W., and J.A.R. performed research and analyzed data. C.H. and P.A. performed structural analysis, analyzed the corresponding data, and wrote the paper. A.C.F., D.P., and G.R.M. wrote the paper. J.H.M. and M.P.D. conceptualized project, designed research, analyzed data, and wrote the paper. Competing financial interests. J.H.M. is an employee of Glycobia, Inc. A.C.F., J.H.M. and M.P.D. have a financial interest in Glycobia, Inc. 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PMC005xxxxxx/PMC5117188.txt
LICENSE: This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. 8809954 8282 J Evol Biol J. Evol. Biol. Journal of evolutionary biology 1010-061X 1420-9101 27500505 5117188 10.1111/jeb.12939 NIHMS801610 Article Rise and Fall of Vector Infectivity During Sequential Strain Displacements by Mosquito-Borne Dengue Virus Andrade Christy C. 13* Young Katherine I. 1 Johnson William L. 14 Villa Maria E. 1 Buraczyk Cynthia A. 1 Messer William B. 2 Hanley Kathryn A. 1 1 Department of Biology, New Mexico State University, Las Cruces, NM, USA 2 Department of Molecular Microbiology and Immunology and Division of Infectious Diseases, Department of Medicine, Oregon Health and Sciences University, Portland, OR, USA 3 Current address: Biology Department, Gonzaga University, Spokane, WA, USA 4 Current address: Colorado School of Public Health, Colorado State University, Fort Collins, CO, USA * Corresponding author contact information: Biology Department, Gonzaga University, 502 E. Boone Avenue, Spokane, WA 99258; phone: (509) 313-6638; fax: (509) 313-5804; andradec@gonzaga.edu 21 7 2016 8 8 2016 11 2016 01 11 2017 29 11 22052218 This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. Each of the four serotypes of mosquito-borne dengue virus (DENV-1-4) comprises multiple, genetically-distinct strains. Competitive displacement between strains within a serotype is a common feature of DENV epidemiology and can trigger outbreaks of dengue disease. We investigated the mechanisms underlying two sequential displacements by DENV-3 strains in Sri Lanka that each coincided with abrupt increases in dengue hemorrhagic fever (DHF) incidence. First, the post-DHF strain, displaced the pre-DHF strain in the 1980s. We have previously shown that post-DHF is more infectious than pre-DHF for the major DENV vector, Aedes aegypti. Then, the ultra-DHF strain evolved in situ from post-DHF and displaced its ancestor in the 2000s. We predicted that ultra-DHF would be more infectious for Ae. aegypti than post-DHF but found that ultra-DHF infected a significantly lower percentage of mosquitoes than post-DHF. We therefore hypothesized that ultra-DHF had effected displacement by disseminating in Ae. aegypti more rapidly than post-DHF, but this was not borne out by a timecourse of mosquito infection. To elucidate the mechanisms that shape these virus-vector interactions, we tested the impact of RNA interference, the principal mosquito defense against DENV, on replication of each of the three DENV strains. Replication of all strains was similar in mosquito cells with dysfunctional RNAi, but in cells with functional RNAi, replication of pre-DHF was significantly suppressed relative to the other two strains. Thus differences in susceptibility to RNAi may account for the differences in mosquito infectivity between pre-DHF and post-DHF, but other mechanisms underlie the difference between post-DHF and ultra-DHF. dengue virus competitive displacement Aedes mosquito vector trade-off RNA interference INTRODUCTION Mosquito-borne dengue virus (DENV, genus Flavivirus) is the agent of dengue disease, which ranges in severity from subclinical infection to classical dengue fever to severe dengue disease characterized by intravascular leakage, hemorrhage and hypovolemic shock (WHO, 2009), referred to as dengue hemorrhagic fever (DHF) and dengue shock syndrome (DSS) (Simmons et al., 2012). DENV is composed of four antigenically- and genetically-distinct serotypes (DENV-1-4), each serotype in turn comprises multiple genotypes, which differ by > 6% nucleotide identity, and genotypes include multiple, distinct lineages that differ by ≤ 6% nucleotide identity, which have been termed strains, clades, lineages or groups (Rico-Hesse, 2003, Weaver & Vasilakis, 2009), and here will be called strains. In the decades since World War II, the geographic range and incidence of all four DENV serotypes has increased steadily (Guzman et al., 2010); at present an estimated 390 million people are infected with DENV annually across the tropical and subtropical zones annually, of whom 96 million experience some form of dengue disease (Bhatt et al., 2013). While a dengue vaccine (Dengvaxia®), was recently approved in Mexico, Brazil, El Salvador, and the Philippines, it has limited efficacy and will not be given to children aged <9 years old (Hadinegoro et al., 2015). There are no licensed antiviral therapies to curb transmission of DENV. DENV genetic diversity shapes epidemiology and disease risk in a complex fashion. Infection with a given serotype is thought to result in homotypic protection against infection with all genotypes in that serotype (Rothman, 2011, Snow et al., 2014), but also primes the host for higher levels of viral replication (Pozo-Aguilar et al., 2014) and severe disease (DHF/DSS) upon heterotypic infection with a different serotype (Guzman et al., 2013). Moreover, strains and genotypes within serotypes may differ significantly in their tendency to cause DHF/DSS (Rico-Hesse, 2010). For example, the Southeast Asian genotype of DENV-2 is responsible for multiple dengue disease outbreaks characterized by high levels of DHF, whereas the American DENV-2 genotype has rarely been implicated in a case of DHF (Rico-Hesse, 2007). As a consequence of the increasing global mobility of humans, DENV strains are often moved from the site in which they originally evolved to new locations (Allicock et al., 2012). An increasingly common feature of DENV epidemiology is the invasion of a region by a genotype or strain of a given serotype, either through introduction from another region or in situ evolution, and replacement of the native genotype or strain of that same serotype (dos Santos et al., 2011, Carrillo-Valenzo et al., 2010, Drumond et al., 2012, Duong et al., 2013b, Duong et al., 2013a). Worryingly, it is often strains with a predilection for causing DHF that successfully invade, displacing strains with lower virulence (i.e. a lower tendency to cause DHF, for the purposes of this study) (Rico-Hesse, 2003, Rico-Hesse, 2010). Although some within-serotype strain replacements appear to be the result of passive, stochastic turnover during population bottlenecks (Teoh et al., 2013, Myat Thu et al., 2005), there is strong evidence that many others are due to active competitive displacement. As DENV replicates in two hosts, the mosquito and the human, competitive advantage may be achieved by enhanced infection of either or both (Althouse & Hanley, 2015, Lourenco & Recker, 2010). Investigations of DENV displacement (summarized in Table 1) have typically shown that the displacing genotype or strain was significantly more infectious for Ae. aegypti than the displaced genotype or strain when mosquitoes fed on artificial infectious bloodmeals at similar titers. In the one exception to this pattern, there was no difference between the displacing and displaced strain in mosquito infection, but the displacing strain produced higher viral titers in patient blood samples compared to the displaced strain. In previous work as well as the current study, we have sought to elucidate the mechanisms driving a series of DENV strain displacement events that occurred in Sri Lanka where, despite co-circulation of all four DENV serotypes, severe dengue disease was uncommon until 1989, when the nation experienced a sudden increase in DHF cases (Messer et al., 2003, Messer et al., 2002). Phylogenetic analysis demonstrated that this spike in DHF was associated with invasion of DENV-3 genotype III B strain and displacement of the native DENV-3 genotype III A strain (Messer et al., 2003); for simplicity we have subsequently renamed these strains the post-DHF and pre-DHF strains, respectively (Hanley et al., 2008). We have previously shown that the post-DHF strain replicates to higher titers and disseminates more efficiently in Ae. aegypti than pre-DHF (Table 1), providing one mechanism for the competitive displacement. In 2000, Sri Lanka experienced yet another abrupt surge in DHF incidence, and phylogenetic analysis revealed that this rise in DHF coincided with the appearance and spread of a new DENV-3 genotype III strain: strain SL post-2000, which we here term the ultra-DHF strain (Kanakaratne et al., 2009). The ultra-DHF strain evolved from and replaced the post-DHF strain (Kanakaratne et al., 2009). The rapidity of this replacement, and the absence of evidence for any interruption of DENV transmission that might have facilitated a population bottleneck, suggests that the post-DHF to ultra-DHF transition was the result of competitive displacement rather than drift. Here we tested the prediction that ultra-DHF would, like most other successful DENV invaders (Table 1), have an advantage over the post-DHF strain and pre-DHF strain in mosquito infection. Using multiple isolates from each of the competing DENV strains, we investigated potential differences in transmission efficacy, extrinsic incubation period (EIP; the time between acquisition of an infectious bloodmeal and ability to transmit that bloodmeal (Christofferson & Mores, 2011)), and response to RNA interference, an important mediator of the mosquito immune response (Blair, 2011). MATERIALS AND METHODS Viruses and Cell lines Three isolates of the pre-DHF strain (DENV-3-3002, DENV-3-3009, DENV-3-3011, (Hanley et al., 2008)), 3 isolates of the post-DHF strain (DENV-3-3001, DENV-3-3006, DENV-3-3010, (Hanley et al., 2008)) and 5 isolates of the ultra-DHF strain (DENV-3-3050, DENV-3-3053, DENV-3-3054, DENV-3-3055, DENV-3-3060) were generously provided to the Hanley laboratory by the de Silva laboratory at the University of North Carolina, Chapel Hill. Details on passage history and the nomenclature used in previously published studies of these viruses are provided in Table 2. Isolation of viral genomes, reverse transcription of amplicons including the C, prM and E genes (nucleotides 95 - 2413) and sequencing were conducted, essentially as previously described (Durbin et al., 2001), for each of the isolates listed above. Two cell lines derived from Ae. albopictus, a secondary vector of DENV, were utilized to dissect the impact of RNAi on virus replication kinetics: C6/36 cells lack a functional RNAi response (Brackney et al., 2010) while U4.4 cells possess a functional RNAi pathway (Schnettler et al., 2012, Leger et al., 2013). Additionally, C6/36 cells were used for generation of virus stocks and for titrations of stock viruses as well as infected mosquitoes. C6/36 cells were maintained in minimum essential medium (MEM) supplemented with 10% heat-inactivated fetal bovine serum (FBS), 2mM L-glutamine, 2mM non-essential amino acids (Gibco, Life Technologies, Grand Island, NY), and 0.05 mg/ml gentamycin (Invitrogen, Life Technologies, Grand Island, NY). U4.4 cells were maintained in Mitsuhashi & Maramorosch medium (Himedia, VWR, Sugar Land, TX) supplemented with 20% FBS (Gibco, Life Technologies, Grand Island, NY), 0.13% sodium bicarbonate (Gibco, Life Technologies, Grand Island, NY), and 0.05 mg/ml gentamycin (Invitrogen, Life Technologies, Grand Island, NY). Both cell types were maintained at 32°C, 80% relative humidity (RH) with 5% CO2. Quantification of viral titer Virus titer was determined using serial dilutions of virus cell culture supernatant or homogenized mosquito samples in either C6/36 or U4.4 cells as previously described (Hanley et al., 2008). Briefly, confluent monolayers of designated cells in 24-well plates were inoculated with serial ten-fold dilutions of sample in cell culture medium and incubated at 32°C for 2 hours. Cells were then overlaid with 1% methylcellulose in OptiMem media (Invitrogen) supplemented with 2% FBS, 2mM L-glutamine (Gibco, Life Technologies, Grand Island, NY), and 0.05 mg/ml gentamycin (Invitrogen, Life Technologies, Grand Island, NY) and incubated 5 days at 32°C. When mosquito body and head samples were titered, the overlay was additionally supplemented with 5 μg/ml Fungizone (Gibco, Life Technologies, Grand Island, NY). Viral infection foci (hereafter termed plaques as in (Hanley et al., 2008)) were visualized by immunostaining with DENV-3-specific antibody. Mosquitoes and Mosquito Infection Eggs of Ae. aegypti from the National Institutes of Health (NIH) colony, described in Hanley et al. (2008), were hatched following standard procedures (Pal, 1967, Wattam & Christensen, 1992) and larvae were transferred to water-filled pans and maintained at 27°C with 80% RH. Larvae were fed daily on dry commercial cat food (Special Kitty Original Formula, Bentonville, AR). Pupae were relocated to water cups within a mesh-screened cage at 27°C with 80% RH. Adults were offered 10% sucrose solution ad libitum. Bloodmeals were prepared as previously described (Hanley et al., 2008). Briefly, 2 ml of washed red blood cells prepared from fresh, defibrinated rabbit blood (Hemostat, Dixon, CA) supplemented with 10% sucrose was spiked with 1mL of freshly-thawed stock virus. Sealed cartons of mosquitoes starved of sugar for 24-48 hours were placed under water-jacketed parafilm-covered membrane feeders (Lillie Glass, Smyrna, GA) for 20 minutes. Samples of the infectious bloodmeal were collected after feeding to quantify titer on C6/36 cells as described. Mosquitoes were then cold-anesthetized for 2 minutes at −20°C; engorged mosquitoes were separated on a chilled tray, transferred into new cartons, incubated for a specified time period at 27°C, 80% RH on a 12:12 hour light:dark cycle with ad libitum access to 10% sucrose. At the end of the incubation period, mosquitoes were cold-killed and stored at −80°C until dissection and homogenization. After a competent Ae. aegypti has imbibed an infectious bloodmeal, dengue virus infects the midgut. Midgut infection can occur as early as 2 days post engorgement, though 5 -10 days is more common (Salazar et al., 2007, Hardy et al., 1983). Viruses then replicate in the midgut and disseminate to and infect other tissues in the mosquito including the salivary glands. It typically takes 10-14 days post engorgement for virus to reach the salivary gland, however this can happen in as few as 3 days (Salazar et al., 2007). To quantify infection and dissemination, bodies (as a measure of infection) were separated from heads (as a measure of dissemination) and each was separately homogenized using motorized pestle in 250μl Hanks Balanced Salt Solution (Gibco) supplemented with 10% FBS, 250 μg/ml amphotericin B (Gibco), 1% ciprofloxacin, 150 μg/ml clindamycin, and stored at −80°C until virus titer was determined as described with C6/36 cells. In the first infection experiment, mosquitoes were fed on bloodmeals containing one of multiple virus isolates from each of the post-DHF and ultra-DHF strains (Table 2) and incubated for 14 days. To assess the time course of mosquito infection for each viral strain, mosquito infections were carried out as described above and subsets of mosquitoes were cold-killed on days 2, 6, 10 and 14 post-engorgement. Mosquitoes were then assayed for infection and dissemination as described above. Viral replication kinetics in cell culture To assess the impact of RNAi on viral replication, the replication curve of each of the 11 viral isolates in Table 2 was measured in C6/36 and U4.4 cells as previously described (Troyer et al., 2001). Replication curves are a common and sensitive measure of viral fitness in a cultured cell line (Andrade et al., 2011, Ciota et al., 2007). Briefly, triplicate 25 cm2 flasks of a particular cell line were infected with each virus isolate at a multiplicity of infection (MOI, ratio of plaque-forming units to cells) of 0.01 based on viral titer determined in the matching cell line. Diluted virus was added in a total volume of 1 ml and cells were incubated for 2 hours at 32°C with gentle rocking every 20 minutes. Cells were then washed twice with 1X PBS (Gibco) to remove unadsorbed virus and replenished with 5 ml of cell culture media. One ml of cell culture supernatant was harvested immediately post-wash (time 0) and 1 ml of appropriate medium was added back to each flask. Collected supernatants were stabilized in 1X SPG (2.18 mM sucrose, 38 mM potassium phosphate [monobasic], 72 mM potassium phosphate [dibasic], 60 mM L-glutamic acid), clarified by centrifugation, aliquoted and stored at −80°C. Samples were collected daily for a total of 7 days following the same procedure. Viral titer was quantified as described above in the same cell type in which the replication kinetics assays were performed. RESULTS Endpoint infectivity of post-DHF and ultra-DHF DENV-3 for Ae. aegypti To test the hypothesis that ultra-DHF displaced post-DHF because it is more infectious for Ae. aegypti than post-DHF, we fed mosquitoes on artificial bloodmeals containing one of 3 isolates of the former or 5 isolates of the latter and assayed bodies for virus, as a measure of infection, and heads, as a measure of dissemination, 14 days post-feeding. Percentage infection data were arcsin-square root transformed to render them normal; all transformed data were checked to ensure that they did conform to the normal distribution. Contra our hypothesis, the ultra-DHF strain of DENV-3 infected, on average, a significantly lower percentage of Ae. aegypti (mean ± 1 SE: 16% ± 4%) than the post-DHF strain (37%± 3%) (Fig. 1 and Table 3; t6 = 3.29, P = 0.017). There was no significant difference between the two strains in the mean virus titer in infected bodies (Table 3, t6 = 2.32, P = 0.06), total dissemination (Table 3, t6 = 0.94, P = 0.38), dissemination when the analysis was limited to only infected mosquitoes (Table 3, t6 =1.57, P = 0.17) or the mean titer of virus in infected heads (Table 3, t6 = 1.66, P = 0.15). Average bloodmeal titer did not differ significantly between the two strains either before or after feeding (P > 0.12 for both comparisons). Bloodmeal titers did decline over the course of feeding, and although most mosquitoes fed within the first few minutes after the bloodmeal was offered, we nonetheless conducted a logistic regression that included post-feeding bloodmeal titer as an independent variable as the most conservative comparison between the strains. This analysis, which used virus isolate nested within virus strain and post-feeding bloodmeal titer of each virus isolate as independent variables and infection or dissemination of each mosquito as the dependent variable did not show a significant effect of virus nested within strain (χ25 = 9.81, P = 0.08), but a significant effect of post-feeding bloodmeal titer (χ21 = 13.46, P = 0.0002) on the percentage of mosquitoes infected. This analysis found no effect of either virus strain (χ25 = 5.47, P = 0.36) or bloodmeal titer (χ25 = 2.65, P = 0.10) on percent disseminated infections. Infection time course of displaced and displacing dengue virus strains in Ae. aegypti To test the hypothesis that the ultra-DHF strain displaced post-DHF due to a shorter EIP by the displacing strain, mosquitoes were fed on bloodmeals containing isolates of both strains, as well as the pre-DHF strain, and infection was measured at days 2, 6, 10 and 14 post-feeding. Titer data from day 2 post-feeding were sporadically elevated and this was most likely due to contamination from undigested bloodmeal, as has been previously observed by others (Turell, 1988); consequently analysis was limited to days 6, 10 and 14 post-feeding (Table 4, Table 5, and Fig. 2). Bloodmeal titers (Table 4) were not significantly different among the three strains prior to feeding (F2= 1.8, P = 0.23) or after feeding (F2= 2.8, P = 0.12). We first compared each pair of displacing-displaced strains (post-DHF versus pre-DHF and ultra-DHF versus post-DHF) at day 14 post-feeding to determine whether the differences detected previously, i.e. greater dissemination in post-DHF compared to pre-DHF and greater infectivity in post-DHF compared to ultra-DHF, were repeatable. As we showed previously (Hanley et al., 2008), the pre-DHF strain disseminated in a lower percentage of Ae. aegypti than the post-DHF strain (respective mean ± 1 SE : 19% ± 16%, 62% ± 16%), however in this study at day 14 post-infection this difference was not significant (t4 = 1.92, P = 0.13). The percent dissemination by each strain did not differ significantly between the two studies (P > 0.3 for each comparison). We attribute the lack of significance to the higher dissemination by pre-DHF strain 3009 in the current study compared to the previous one. For the 3002 and 3011 pre-DHF strains, percent dissemination was remarkably similar between the two studies (0% and 5% for 3002 and 3% and 8% for 3011), but for 3009 percent dissemination increased from 25% in our previous study to 50% in the current one. Consistent with the patterns described in the previous section of this paper, in the timecourse experiment ultra-DHF infected a lower percentage (25% ± 9%) of mosquitoes than post-DHF (64% ± 17%); this difference was significant by a one-tailed t-test (t6 = −2.11, P = 0.04). To detect differences in EIP, we compared the infection dynamics in the three strains with a two-factor ANOVA including strain and day post-feeding as factors; a significant interaction between day and strain would indicate differences in infection dynamics. However there was no significant interaction between day post-feeding and virus strain on the percentage of mosquitoes infected (Table 4 and Fig. 2; F4,24 = 0.68, P = 0.61). Additionally, there was no significant main effect of virus strain on the percentage of mosquitoes infected (F2,24 = 2.62, P = 0.09), or day post feeding (6, 10 and 14), on the percentage of mosquitoes infected (F2,24 = 0.44, P = 0.65). Similarly, there was no significant interaction between day post-feeding and virus strain on the percentage of mosquitoes with a disseminated infection (Table 5 and Fig. 2, F4,24 = 1.39, P = 0.27). Neither virus strain (F2,24 = 3.00, P = 0.07) or day post-feeding (F2,24 = 2.97, P = 0.07) had a significant effect on the total percentage of mosquitoes with a disseminated infection. It is noteworthy that in analysis of both infection and dissemination, the impact of virus strain approached significance and the trend for the post-DHF strain to reach higher percentages of infection and dissemination than the other two strains was consistent with the previous experiments in this paper and previous studies (Hanley et al., 2008). Small sample sizes precluded the analysis of virus titer in the bodies and heads (Table 4 and Table 5). Impact of RNAi on pre-DHF, post-DHF and ultra-DHF DENV-3 To test the effect of RNAi on the three DENV-3 strains, we quantified their replication kinetics in one Ae. albopictus cell line that has a functional RNAi response (U.4.4) and one that has a dysfunctional RNAi pathway (C6/36) (Fig. 3). Repeated measures ANOVA revealed a significant time × strain interaction among the three strains in C6/36 cells (Fig. 3 (top); F14 = 2.4, P = 0.004) but a Tukey-Kramer post-hoc test showed that none of the strains differed from each other in overall replication (P>0.05 for all pairwise comparisons). In U4.4 cells (Fig. 3 (top)), in contrast, there was a highly significant interaction of time × strain (F14= 9.2, P < 0.0001) and a Tukey-Kramer post-hoc analysis showed that the pre-DHF strain replicated to a significantly lower level than the post-DHF or ultra-DHF strain (P < 0.05), whereas the post- DHF and ultra-DHF strains did not differ from each other (P > 0.05). We have repeated the experiment in U4.4 cells infected with all three strains for a period of 5 days and find qualitatively similar results (data not shown). Sequence variation in the structural proteins of pre-DHF, post-DHF and ultra-DHF DENV-3 DENV possesses a positive-sense, single-segment RNA genome that encodes three structural proteins (capsid (C), pre-membrane (prM) and envelope (E)) which together form the virion and seven non-structural proteins that facilitate infection (Hanley & Weaver, 2010). Table 6 shows those nucleotide and amino acid variants that distinguished viral strains, i.e. those variants that were conserved within each strain but differed between at least one strain and the other two. The single non-synonymous variant was a serine at amino acid 124 of the envelope gene (numbering from the start of the protein) in the pre-DHF strain but a proline at the corresponding position in post-DHF and ultra-DHF isolates. DISCUSSION Competitive displacement among strains of DENV (Table 1) as well as other arthropod-borne viruses (arboviruses) (Moudy et al., 2007, Schuh et al., 2014) is frequently mediated by differences in vector infectivity between the displacing and displaced strain. We have previously shown that the post-DHF strain of DENV-3, which invaded Sri Lanka and displaced the native pre-DHF DENV-3 strain was more infectious for Ae. aegypti than the pre-DHF strain (Hanley et al., 2008). Subsequently, Kanakaratne et al. (2009) reported that the post-DHF strain had been displaced by its evolutionary offshoot, the ultra-DHF strain. We predicted that this displacement too would be associated with greater mosquito infectivity, a prediction that we tested in the current study. To our surprise, we found instead that the ultra-DHF strain was significantly less infectious than the post-DHF strain. This apparent contradiction could be resolved if the loss in total infection by the ultra-DHF strain were coupled to a gain in the rapidity with which the virus reached this endpoint, i.e. a reduction in the extrinsic incubation period (EIP). Vectorial capacity is negatively related to duration of EIP, and thus a reduction in EIP confers a large fitness gain for arboviruses (Ciota & Kramer, 2013, Christofferson & Mores, 2011). For example, the displacement of the NY99 strain of West Nile virus in North America by the WN02 strain has been attributed to the difference between the two strains in EIP, which is as much as 4 days shorter in WN02 than NY99 (Moudy et al., 2007). Similarly, Quiner et al. (2014) reported that a DENV-2 clade displacement in Nicaragua was associated with a replicative advantage of the invading strain in native mosquitoes that was only observed at 7 days post feeding but not at 14 or 21 days. However in the current study we did not find a difference in the time course of infection among the three strains. All three strains showed relatively low mean percent infection and dissemination on day 6 post feeding; these averages rose substantially for the post-DHF strain but not for the pre-DHF or ultra-DHF strains on day 10 post-feeding. Thus there is no evidence that the displacement of the post-DHF strain by the ultra-DHF strain is due to a shorter EIP in the latter. The decline in vector infectivity by the ultra-DHF strain may be attributable to other evolutionary trade-offs that ultimately enhance transmission but are more difficult to quantify in the laboratory. First, there may be a trade-off between infectivity and pathogenicity of DENV for its vector. By conventional evolutionary wisdom, arthropod-borne pathogens should be benign for their vectors, on which they depend for transmission ((Ewald, 1993), but see (Elliot et al., 2003)). In particular, vector-borne pathogens should not reduce the longevity of their vectors, which must exceed the EIP if the pathogen is to be transmitted at all. The evidence for an impact of DENV on longevity of Ae. aegypti is mixed. Carrington et al. (2015) reported that Ae. aegypti that acquired a dengue infection by feeding on hospitalized dengue patients, the most natural route of infection, did not show a difference in survival compared to mosquitoes that were not infected for a period of 12 days post-feeding. In contrast, a meta-analysis by found that horizontally-transmitted arboviruses, including DENV, did reduce survival of their vectors. However this analysis included studies in which DENV infection was established via intra-thoracic inoculation of mosquitoes, and the relevance of this route of infection is questionable. Second, efficacy of horizontal transmission, as measured by infection after feeding on a bloodmeal, may be inversely related to efficacy of vertical transmission to eggs. While vertical transmission of DENV certainly occurs, recent reviews of the literature determined that it is unlikely to be a significant factor in the epidemiology of the virus ((Lequime & Lambrechts, 2014, Grunnill & Boots, 2015), see also (Adams & Boots, 2010)). However, in situations where a high proportion of the population is immune, it remains possible that vertical transmission could rescue a viral lineage from extinction until a sufficiently large susceptible population had accumulated. Third, the reduced mosquito infectivity of the ultra-DHF strain of DENV-3 may reflect a trade-off between decreased replication in the vector with increased replication in the human host. It has long been hypothesized that the arbovirus cycle of alternation between vertebrate hosts and arthropod vectors imposes trade-offs that prevent optimization of fitness in either host (Ciota & Kramer, 2010, Coffey et al., 2013). Variation among DENV strains in viremia levels in the human host may be mediated by variation in fundamental rates of virus replication or by variation in the proclivity for antibody-mediated enhancement during secondary infection (OhAinle et al., 2011); either mechanism could confer a competitive advantage on the strain with greater replication. In Vietnam the invasive Asian 1 DENV-2 strain caused significantly higher viremia in pediatric patients than the displaced Asian/American strain, but the two strains showed no differences in infectivity for mosquitoes when spiked at constant titer into artificial bloodmeals (Table 1). DENV generally infects more Ae. aegypti as virus titer in human blood increases (Carrington & Simmons, 2014, Duong et al., 2015), though Duong et al. have recently reported that, for any particular level of viremia, people with asymptomatic or presymptomatic dengue infections are significantly more infectious to feeding mosquitoes than people with a symptomatic infection (Duong et al., 2015, Nguyet et al., 2013, Whitehorn et al., 2015), revealing that the relationship between viremia and transmission is more complex than previously thought. Thus higher replication of ultra-DHF than post-DHF in the human host could confer a transmission advantage even if it came at the cost of decreased mosquito infectivity sensu stricto – that is decreased infectivity of ultra-DHF compared to post-DHF when virus titer is held constant. Finally, the decrease in ultra-DHF infectivity could have been driven by mutations that enabled immune escape at the cost of decreased vector infectivity. The paradigm for DENV immunity has long been that infection with any strain in a particular serotype generates cross-immunity to all other strains within that serotype (Katzelnick et al., 2016), whereas antibodies against that strain will not neutralize strains in the other three serotypes and often enhance their replication. However recent studies suggest that there is variation in cross-immunity among DENV strains within a serotype (Wahala et al., 2010, Flipse & Smit, 2015, Katzelnick et al., 2015, Katzelnick et al., 2016, Waggoner et al., 2016, Forshey et al., 2016). Thus it was reasonable to hypothesize that the decrease in ultra-DHF mosquito infectivity could have been due to mutations in the structural proteins that enabled escape from antibodies raised against other strains of DENV-3 or against neutralization by heterologous antibody generated by other serotypes. During invasion in Vietnam, the Asian 1 DENV-2 strain acquired mutations at amino acid 160 in the envelope protein from K to either Q or M. Wang et al. (2015) tested whether the mutations at this site provided protection from heterologous antibodies (those raised against other DENV serotypes). They found, to their surprise, that these mutations actually increased neutralization by heterologous antibodies. In the current study, we found a change from serine to proline at amino acid 124 in the envelope protein between the pre-DHF and post-DHF strains, suggesting that the two strains may differ in their susceptibility to either homologous or heterologous immunity. This position has previously been identified as an informative (i.e. variable) site in DENV-3 (Wahala et al., 2010) and this region of E has been implicated in differential infectivity in tissue culture ((Lee et al., 2006), for example). However, we found no consistent difference in the amino acid sequence of the structural proteins between the post-DHF and ultra-DHF strains, thus ruling out immune escape as an explanation for the ascendancy of the ultra-DHF strain. Generally, the strains showed a high ratio of synonymous to non-synonymous variants (23:1), typical of arboviruses generally and dengue virus in particular, signaling the action of strong purifying selection on these viruses (Hanley & Weaver, 2008). In addition to documenting the pattern of mosquito infectivity in this system, we sought to discern mechanisms by which these strains of DENV may shape their interaction with their mosquito vector. Recent studies have shown that viruses can self-regulate tropism for specific host tissues and levels of replication within those tissues through interaction with RNAi (Guo & Steitz, 2014). RNAi is triggered by the presence of double-stranded RNA (dsRNA) within cells (Kingsolver et al., 2013) and serves as the major defense for mosquitoes against arboviruses (Blair, 2011). As a rule arboviruses possess RNA genomes that produce long dsRNA during replication (Westaway et al., 1999) as well as secondary structures, particularly in the untranslated regions (UTR) (Romero et al., 2006), that form regions of dsRNA. Changes in the genome sequence could potentially modify secondary structures and thereby alter stimulation of RNAi. Moreover, DENV possesses mechanisms to suppress RNAi. Schnettler et al. (2012) have shown that the DENV sfRNA, an approximately 400 nt subgenomic fragment encompassing the 3’ terminus of the 3’ UTR (Schnettler et al., 2012), downregulates RNAi. Additionally, Kakumani et al. (2013) have recently reported that the DENV non-structural 4B (NS4B) is a viral suppressor of RNAi. Thus mutations in the nucleotide or amino acid sequence of the 3’ UTR or NS4B, or elsewhere in the genome, could alter viral regulation of RNAi. We found that while the pre-DHF, post-DHF and ultra-DHF all replicate with similar dynamics in mosquito cells that lack RNAi, the replication of pre-DHF was significantly suppressed, relative to the other two strains, in mosquito cells with a functional RNAi pathway. These findings indicate that pre-DHF either stimulates RNAi more strongly or suppresses it less effectively than the other two strains, a distinction currently being investigated in our lab. This difference likely explains the greater mosquito infectivity of post-DHF compared to pre-DHF. However, post-DHF and ultra-DHF did not differ in their interaction with RNAi, suggesting that the difference in mosquito infectivity between these two strains was mediated by mechanisms other than RNAi. There is an important caveat to the conclusion that the DENV-3 strains studied here underwent a rise and fall in vector infectivity over the course of sequential competitive displacements. We utilized a colonized strain of Ae. aegypti rather than local Sri Lankan mosquitoes, because we were unable to obtain mosquitoes from Sri Lanka. It is well known that rates of mosquito infection by DENV are determined by interactions between host genotype and virus genotype (Lambrechts et al., 2013, Lambrechts, 2011, Lambrechts et al., 2009). However local adaptation of DENV strains to co-occurring mosquito populations has not been demonstrated, suggesting that colonized strains may serve as a useful model for wild populations. Moreover we also detected a significant difference in replication in the pre-DHF and post-DHF strains in U4.4 cultured cells derived from an entirely different vector species, Ae. albopictus, suggesting that the differences observed between the two in infection of NIH colony Ae. aegypti can be generalized. A more trivial limitation to the study is the use of artificial bloodmeals to infect mosquitoes. While arboviruses are less infectious when vectors imbibe an artificial meal rather than blood from a living host (Althouse & Hanley, 2015), there is no reason to suppose that the use of artificial bloodmeals, as opposed to human bloodmeals, influences relative infectivity of different arbovirus strains. In sum, the studies reported here have revealed that the displacement of the pre-DHF strain of DENV-3 by the post-DHF strain was likely mediated by greater infectivity of the latter for Ae. aegypti, that this difference in infectivity is associated with a difference in the interaction of the two strains with RNAi, the major mosquito defense against arboviruses, but that the two strains do not differ in EIP. In contrast, the ultra-DHF strain displaced the post-DHF strain despite a lower infectivity for Ae. aegypti. EIP and interaction with RNAi were similar between the two strains; moreover there were no differences in the coding sequence for the structural proteins between the two, indicating that the success of the ultra-DHF strain was not attributable to immune escape. This suggests that the ultra-DHF strain gained its competitive advantage over post-DHF from differences in the effects of the two strains on mosquito longevity or differences in replication in humans. We have reported that the replication of pre-DHF and post-DHF DENV-3 do not differ in human hepatoma cells (Hanley et al., 2008), but this finding cannot be generalized to replication in humans. Unfortunately there are at present no animal models that adequately recapitulate DENV replication and dengue disease (Cassetti et al., 2010). Thus it will be necessary in future to sample viremic humans and mosquitoes in dengue-endemic areas and employ whole-genome sequencing and phylogenetic analysis to further probe the role of hosts and vectors, as well as the trade-off between the two, in displacements among strains of this important pathogen. Acknowledgments The authors have no conflict of interest to declare. This work was supported by grants from the National Center for Research Resources (5P20RR016480-12) and the National Institute of General Medical Sciences (8 P20 GM103451-12) of the NIH, by NIH grant 1R15AI113628-01, and by the Howard Hughes Medical Institute Undergraduate Research Scholars program at NMSU (grants 52006932 and 52008103). We are extremely grateful to the lab of Aravinda de Silva at University of North Carolina for providing the virus isolates used in this research and to Dr. Stephen Whitehead at the National Institute of Allergy and Infectious Disease, NIH for providing antibodies, other reagents, and advice. Figure 1 Isolates of the post-DHF DENV-3 strain (black, solid) infected a significantly higher percentage of Aedes aegypti mosquitoes than isolates of the ultra-DHF DENV-3 strain (red, hatched) 14 days after engorgement with bloodmeals containing designated dengue virus isolates. Sample size (N) is reported in parentheses below isolate name. See text for statistical analysis. Figure 2 Mean percentage (plus or minus one standard error) of Aedes aegypti mosquitoes infected with (top panel) and generating a disseminated infection of (bottom panel) pre-DHF (blue squares), post-DHF (black circles), and ultra-DHF (red triangles) strains of DENV-3 at days 6, 10, and 14 after feeding on bloodmeals containing isolates of each strain. See text for statistical analysis. Figure 3 Replication kinetics of pre-DHF (solid blue square, circle and upright triangle), post-DHF (solid black diamond, crossed lines, and inverted triangle), and ultra-DHF (open, red symbols) strains in C6/36 (top panel) and U4.4 (bottom panel) cells. Note that y-axes are at different scales to enhance clarity. See text for statistical analysis. Table 1 Summary of studies to date that have investigated the relative fitness of displaced and displacing dengue virus strains in either mosquito vectors or human hosts following documented competitive displacements among strains of the same serotype. Geographic Region DENV Serotype Displacing genotype or strain Displaced strain Impact of displacement on disease Relative infectivity for Aedes aegypti Differences in other phenotypes Reference Thailand 1 genotype I New strain genotype Early strain None New > Early Not investigated (Lambrechts et al., 2012) South America 2 Southeast Asian genotype American genotype Increase in DHF Southeast Asian > American Replication of Southeast Asian genotype > American genotype in human monocytes and dendritic cells (Anderson & Rico-Hesse, 2006, Armstrong & Rico-Hesse, 2001, Armstrong & Rico-Hesse, 2003, Cologna et al., 2005, Rico-Hesse, 2010) Nicaragua 2 Southeast Asian genotype strain NI-2B Southeast Asian genotype strain NI-I Increase in severe disease NI-2B > NI-I Replication of NI-2B > NI-I in Ae. albopictus (C6/36) cells and human dendritic cells (Quiner et al., 2014, OhAinle et al., 2011) Vietnam, Cambodia and Thailand 2 Asian I genotype Asian/American genotype None Asian 1 = Asian/American Asian I associated with higher viremia than Asian/American in patient blood samples (Vu et al., 2010) Sri Lanka 3 genotype III post-DHF strain genotype III pre-DHF strain Increase in DHF post-DHF > pre-DHF Replication of post-DHF = pre-DHF in African green monkey kidney (Vero) cells and Ae. albopictus (C6/36) cells (Hanley et al., 2008) Table 2 Description of virus isolates utilized in the study DENV-3 isolates used in this study Isolate name used in previous studies Genotype/Clade Strain Passage History‡ 3002 83SriLan2*,SK0087† III/A Pre-DHF C6/36 (p5) 3009 89SriLan2*,SK0396† III/A Pre-DHF C6/36 (p4, p5) 3011 85SriLan*,073† III/A Pre-DHF C6/36 (p4) 3001 89SriLan1*,SK0389† III/B Post-DHF C6/36 (p4, p5) 3006 97SriLan1 III/B Post-DHF C6/36 (p6) 3010 93SriLan1*,SK0693† III/B Post-DHF C6/36 (p6) 3050 Not applicable III/SL-Post2000 Ultra-DHF C6/36 (p4) 3053 Not applicable III/SL-Post2000 Ultra-DHF C6/36 (p4) 3054 Not applicable III/SL-Post2000 Ultra-DHF C6/36 (p4) 3055 Not applicable III/SL-Post2000 Ultra-DHF C6/36 (p4) 3060 Not applicable III/SL-Post2000 Ultra-DHF C6/36 (p4) * Messer et al. (2003) † CDC ‡ in cases in which two passages were used, the passage in italics was used for the initial comparison of post-DHF and ultra-DHF and the remaining experiments utilized the other passage. Table 3 Infection and dissemination of designated isolates of the post-DHF and ultra-DHF strains of dengue virus serotype 3 in Aedes aegypti mosquitoes 14 days after engorgement on an artificial bloodmeal containing designated titers of virus. Strain Isolate No. Fed Bloodmeal titer pre-feeding* Bloodmeal titer post-feeding* % (No.) Infected Mean titer ± 1 SE† in infected bodies % (No.) Total dissemination % (No.) dissemination from infected bodies only Mean titer ± 1 SE† in infected heads Post-DHF 3001 24 7.5 7.0 38 (9) 2.6±0.3 8 (2) 22 (2) 1.9±0.8 3006 27 7.0 7.3 41 (11) 3.3±0.3 30 (8) 73 (8) 1.7±0.3 3010 25 7.2 7.0 32 (8) 2.8±0.3 20 (5) 63 (5) 2.6±0.2 Ultra-DHF 3050 25 7.0 6.0 8 (2) 3.0±0.1 8 (2) 100 (2) 2.2±0.3 3053 25 7.0 6.3 8 (2) 4.1±0.2 4 (1) 50 (1) 4.1±0.0 3054 18 7.3 6.7 22 (4) 3.6±0.4 11 (2) 50 (2) 3.3±0.6 3055 14 7.5 6.9 29 (4) 3.7±0.2 29 (4) 100 (4) 3.0±0.6 3060 27 7.0 7.1 11 (3) 3.4±0.6 11 (3) 100 (3) 2.1±0.4 * log10 PFU/ml † log10 PFU/mosquito Table 4 Infection of designated isolates of pre-DHF (blue text), post-DHF (black text) and ultra-DHF (red text) strains of dengue virus serotype 3 in Aedes aegypti mosquitoes at 6, 10 and 14 days after engorgement on an artificial bloodmeal containing designated titers of virus. 6 Days post feeding 10 Days post feeding 14 Days post feeding Strain Isolate Bloodmeal titer pre-feeding* Bloodmeal titer post-feeding* No. fed % (No.) Infected Mean titer ± 1 SE† in infected bodies No. fed % (No.) Infected Mean titer ± 1 SE† in infected bodies No. fed % (No.) Infected Mean titer ± 1 SE† in infected bodies Pre-DHF 3002 7.0 6.3 4 0 (0) - 5 0 (0) - 9 0 (0) - 3009 7.3 7.2 26 62 (16) 2.9 ± 0.2 33 61 (2) 3.0 ± 0.2 50 56 (28) 3.5 ± 0.2 3011 7.2 6.8 11 27 (3) 2.8 ± 0.6 12 8 (1) 4.0 ± 0.0 13 8 (1) 2.9 ± 0.0 Post-DHF 3001 7.1 7.0 4 50 (2) 3.0 ± 0.1 16 56 (9) 3.5 ± 0.4 16 63 (10) 4.2 ± 0.2 3006 7.4 7.0 6 67 (4) 2.3 ± 0.3 7 71 (5) 3.3 ± 0.5 11 36 (4) 3.0 ± 0.2 3010 7.5 7.2 6 0 (0) - 9 89 (8) 3.5 ± 0.3 18 94 (17) 3.6 ± 0.1 Ultra-DHF 3050 6.8 6.7 8 25 (2) 3.0 ± 1.0 8 50 (4) 2.9 ± 0.9 11 0 (0) - 3053 6.5 6.2 5 0 (0) - 7 43 (3) 2.6 ± 0.2 11 9 (1) 3.5 ± 0.0 3054 7.6 6.8 6 33 (2) 2.4 ± 0.4 7 29 (2) 2.1 ± 0.5 8 38 (3) 3.7 ± 0.3 3055 7.3 6.6 5 0 (0) - 5 20 (1) 3.2 ± 0.0 11 36 (4) 3.8 ± 0.5 3060 6.8 6.6 7 71 (5) 3.5 ± 0.6 6 33 (2) 3.0 ± 0.8 9 44 (4) 3.9 ± 0.3 * log10 PFU/ml † log10 PFU/mosquito Table 5 Dissemination of designated isolates of the pre-DHF (blue text), post-DHF (black text) and ultra-DHF (red text) strains of dengue virus serotype 3 in Aedes aegypti mosquitoes at 6, 10 and 14 days after engorgement on an artificial bloodmeal containing designated titers of virus. 6 Days post feeding 10 Days post feeding 14 Days post feeding Strain Isolate Bloodmeal titer pre-feeding* Bloodmeal titer* No. fed % (No.) Total dissemination Mean titer ± 1 SE† in infected heads No. fed % (No.) Total dissemination Mean titer ± 1 SE† in infected heads No. fed % (No.) Total Dissemination Mean titer ± 1 SE† in infected heads Pre-DHF 3002 7.0 6.3 4 0 (0) - 5 0 (0) - 9 0 (0) - 3009 7.3 7.2 26 31 (8) 1.9 ± 0.3 33 36 (12) 2.2 ± 0.2 50 50 (25) 2.4 ± 0.2 3011 7.2 6.8 11 18 (2) 1.4 ± 0.8 12 8 (1) 2.6 ± 0.0 13 8 (1) 2.0 ± 0.0 Post-DHF 3001 7.1 7.0 4 0 (0) - 16 38 (6) 2.3 ± 0.5 16 56 (9) 2.9 ± 0.3 3006 7.4 7.0 6 33 (2) 1.0 ± 0.1 7 57 (4) 2.8 ± 0.3 11 36 (4) 2.2 ± 0.6 3010 7.5 7.2 6 0 (0) - 9 78 (7) 2.5 ± 0.3 18 94 (17) 2.5 ± 0.2 Ultra-DHF 3050 6.8 6.7 8 13 (1) 1.6 ± 0.0 8 25 (2) 2.5 ± 1.5 11 0 (0) - 3053 6.5 6.2 5 0 (0) - 7 0 (0) - 11 9 (1) 3.1 ± 0.0 3054 7.6 6.8 6 0 (0) - 7 14 (1) 1.4 ± 0.0 8 68 (3) 2.8 ± 0.8 3055 7.3 6.6 5 0 (0) - 5 20 (1) 1.4 ± 0.0 11 36 (4) 2.8 ± 0.9 3060 6.8 6.6 7 57 (4) 2.2 ± 0.3 6 17 (1) 2.0 ± 0.0 9 44 (4) 3.3 ± 0.4 * log10 PFU/ml † log10 PFU/mosquito Table 6 Nucleotide and amino acid variants in each of the three structural genes of the dengue virus genome that distinguish the pre-DHF, post-DHF and ultra-DHF strains of dengue virus serotype 3; viral strain, i.e. those variants that were conserved within each strain but differed between at least one strain and the other two. Gene Nucleotide Position* Nucleotide Difference Amino acid Difference† Pre-DHF Post-DHF Ultra-DHF Capsid 243 a g g None pre-Membrane 408 t c c None 471 a g g None 558 g a a None 600 c t t None 654 t c c None 771 t c c None 784 t t c None 807 c t c None Envelope 883 t c c None 915 t c c None 924 t g g None 1083 c t t None 1210 t c c Ser – Pro 1371 t a a None 1620 a c c None 1803 a g g None 1842 t t c None 1845 c c t None 2055 a a g None 2091 c t t None 2130 g a a None 2217 c t c None 2307 c t t None * Nucleotides numbered from the start of the genome † Amino acids numbered from the start of the specified protein References Adams B Boots M How important is vertical transmission in mosquitoes for the persistence of dengue? Insights from a mathematical model Epidemics 2010 2 1 10 Allicock OM Lemey P Tatem AJ Pybus OG Bennett SN Mueller BA Phylogeography and population dynamics of dengue viruses in the Americas. 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PMC005xxxxxx/PMC5117189.txt
LICENSE: This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. 2985193R 5098 J Org Chem J. Org. Chem. The Journal of organic chemistry 0022-3263 1520-6904 26360634 5117189 10.1021/acs.joc.5b01703 NIHMS819262 Article Synthesis of Naamidine A and Selective Access to N2-Acyl-2-aminoimidazole Analogues Gibbons Joseph B. † Salvant Justin M. † Vaden Rachel M. † Kwon Ki-Hyeok † Welm Bryan E. ‡ Looper Ryan E. *† † Department of Chemistry, University of Utah, 315 South 1400 East, Salt Lake City, Utah 84112, United States ‡ Immunobiology and Cancer Program, Oklahoma Medical Research Foundation, 825 Northeast 13th Street, Oklahoma City, Oklahoma 73104, United States * Corresponding Author: r.looper@utah.edu 2 11 2016 24 9 2015 16 10 2015 21 11 2016 80 20 1007610085 This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. A short and scalable synthesis of naamidine A, a marine alkaloid with a selective ability to inhibit epidermal growth factor receptor (EGFR)-dependent cellular proliferation, has been achieved. A key achievement in this synthesis was the development of a regioselective hydroamination of a monoprotected propargylguanidine to deliver N3-protected cyclic ene-guanidines. This permits the extension of this methodology to prepare N2-Acyl analogues in a fashion that obviates the troublesome acylation of the free 2-aminoimidazoles, which typically yields mixtures of N2- and N2,N2-diacylated products. Graphical abstract INTRODUCTION Marine sponges from the Leucetta family have produced a wealth of natural products comprising highly functionalized 2-aminoimidazoles (2-AIs).1 This family of alkaloids effects a number of diverse biological activities (Figure 1). Naamine D (1), for example, has been shown to be a moderate inhibitor of iNOS, an isozyme scrutinized for its involvement in a number of diseases.2 Naamine D was also shown to be active against the opportunistic pathogen in AIDS patients, Cryptococcus neoformas (MIC = 6.25 μg/mL). N,N-Dimethylnaamine D (2) was active against an antimicrobial panel consisting of Escherichia coli, Staphylococcus aureus, Bacillus subtilis and Candida albicans.3 Kealiinine B (3) was recently reported to show antiproliferative activity (IC50 ~ 10 μM) against the breast cancer cell line T47D, while other kealiinine analogues have displayed modest activity against MCF-7 proliferation.4,5 Isonaamine C (4) was found to be cytotoxic to a variety of cell lines,6 while leucettamine A was found to be a leukotriene B4 (LTB4) antagonist.7 These examples clearly demonstrate that the 2-aminoimidazole, bearing a variety of substitution patterns, serves as an important heterocyclic scaffold for small-molecule drug discovery. Our interest in this family stems from the selective cytotoxicity of naamidine A (6). Studies by Ireland and co-workers determined 6 to be a selective inhibitor for EGF-mediated growth in epidermal growth factor receptor (EGFR) transfected NIH3T3 cells (IC50 = 11.3 μM) yet displayed a 21-fold decrease in potency against insulin-mediated growth (IC50 = 242 μM).8 This particular selectivity prompted in vivo studies, where nude mice xenografts of EGF-overexpressing A431 epidermal carcinoma displayed 87.4% tumor growth inhibition when treated with 6 at 25 mg/kg. Although many compounds affect EGFR signaling, 6 is the first known example to stimulate phosphotransferase activity of extracellular regulated kinases ERK1/2.9 This sustained increase in MAPK activity has been shown to be a result of naamidine A-induced expression of p21, leading to inhibition of cyclin-dependent kinase activity and activation of caspases 3, 8, and 9.10 Since the EGFR signaling pathway is overexpressed in many human tumors, the ability to selectively inhibit EGFR-mediated proliferation represents an important strategy for new chemotherapeutics. Herein, we report the synthesis of 6, as well as related analogues via regioselective construction of cyclic ene-guanidines. RESULTS AND DISCUSSION The structural novelty of 6 and other highly substituted 2-AI scaffolds has generated interest in several synthetic laboratories.11–16 We previously reported the synthesis of naamine A (8) via an addition–hydroamination–isomerization sequence utilizing the propargylcyanamide 7 (Scheme 1).17 Analogous to the syntheses of 6 by Ohta and Watson, we were able to add the N-Me-dehydrohydantoin selectively to N2 via silylated N-methylparabanic acid (Scheme 1).11,12 However, the transamination reaction of the piperidinone to the free 2-aminoimidazole proved problematic on larger scales. We had also simultaneously discovered the tandem addition–hydroamination sequence that was reported by Van der Eycken employing N,N-di-Boc guanidines. Removal of the Boc groups with TFA in this sequence presented problems, as cleavage of electron-rich groups at N1 was quite facile under acidic conditions (e.g., those needed for the synthesis of isonaamine C). Furthermore, while trying to access simplified naamidine A analogues, exemplified by the reaction of 9 with 2-fluorobenzoyl chloride, we obtained an unfavorable 1:2 mixture of mono-acylated and diacylated N2 products (10/11). A recent report by Jiang and co-workers identified the same problem, requiring forcing conditions or extra protecting group manipulations to obtain the monoacyl-2-aminoimidazoles in low to moderate yields, reinforcing the need for a high-yielding and selective strategy to access monosubstituted N2-Acyl-2-aminoimidazoles.18 These shortcomings necessitated a revised synthesis of 6 that would allow for (a) reproducible and scalable procedures, (b) the presence of acid labile groups, and (c) differential protection of N2/N3 for selective functionalization. Our attempts to address these issues are presented in the synthesis of naamidine A (Scheme 2). Cu(I)-mediated A3-coupling of the required amine, alkyne, and aldehyde gave 12 (Scheme 2).19 Deallylation with Pd(0) gave the secondary propargylamine (13) in good yield.10 Instead of installing the di-Boc guanidine,14 we prepared the monoacylguanidine 14 using the activated Cbz-cyanamide potassium salt guanylation conditions previously developed in our laboratory.20,21 It is important to note that four pathways are operable in the cyclization of 14: N3- versus N2-cyclization and 5-exo-dig versus 6-endo-dig cyclization. We knew that monoacylguandines prefer the tautomeric form in which the imino tautomer is directly conjugated with the acyl group and the other nitrogen forms a hydrogen bond to the carbonyl (as depicted in 10). This would suggest that the unconjugated nonbonding lone pair on N3 would initiate cyclization. We also knew that the Ag(I)-catalyzed cyclization proceeds preferentially in a 5-exo-dig fashion; however, with an electron-rich alkyne substituent, selectivity can be significantly diminished. For example, when unsubstituted at C5, p-MeOPh-substituted propargylguanidines cyclize with only modest 5-exo-dig selectivity of ~2:1.14 To our delight, treatment of 14 with AgNO3 in CH2Cl2 provided a single isomer (15) in 87% isolated yield. The regioselectivity of this process was ultimately supported by X-ray crystallography of the intermediate 18b (Figure 2). Importantly, this leaves N2 open for subsequent functionalization. The Cbz group is readily cleaved under standard hydrogenolysis conditions. Fortunately, isomerization of the exocyclic alkene provides the 2-aminoimidazole nucleus before it can be reduced. The benzyl ether is also cleaved during this step to provided naamine A in quantitative yield. Again the N-Me-hydantoin can be installed by Ohta’s method to provide naamidine A in good yield. This sequence has proven to be robust and scalable, delivering gram quantities of naamidine A in six steps and 33% overall yield. With the ability to control the regioselectivity of the monoacylpropargylguanidine cyclization, we returned our attention to generating N2-substituted analogues (Scheme 3). We envisioned 15 as an ideal intermediate for selective N2-Acylation, as N3 is protected and the imino tautomer is forced C2=N2 and should yield only monoacylation products. Indeed, both electron-rich and electron-poor aryl chlorides gave the N2-monoacylguanidines 16a–d in excellent yields (Scheme 3). Alkanoyl chlorides are also reactive to give 16e,f. Most notably, hydrogenation conditions that cleaved the Cbz group, isomerized the ene-guanidine, and cleaved the phenolic benzylether in the preparation of 8 resulted in no reaction in the conversion of 16a → 17a. More forcing conditions (elevated H2 pressures) could initiate reductive cleavage of the Cbz group and isomerization, but the benzyl ether was surprisingly difficult to cleave. Ultimately, a nonsupported Pd(II) catalyst was successful, providing the fully deprotected targets 17a–f in excellent overall yields. To complement our focused library, the same methodology was involved in the construction of C5-phenyl and C4-benzyl analogues (Scheme 4). The same synthetic sequence accessing 15 was also employed to prepare substrates 18a and 18b.19 Acylation of these intermediates gave N2-substituted precursors 19a–h in excellent yields. Hydrogenation over palladium on carbon, with 60 psi H2, was sufficient to effect the deprotection with isomerization and deliver the 2-aminoimidazole analogues 20a–h. Confirmation of N2-selective acylation was confirmed by X-ray crystallography of 20h. Again, 18b was characterized by X-ray crystallography, confirming that the initial hydroamination proceeds to give the N3-protected intermediates (Figure 2). The fact that the acylation/deprotection with isomerization sequence yields the mono-N2-substituted 2-aminoimidazoles was ultimately confirmed by X-ray crystallography of product 20h. This structure shows that even in the now aromatized amino-imidazole nucleus, the exocyclic N2-imino tautomer is preferred with H bonding between N3 and the N2-Acyl group with a C2–N3 imino bond length of 1.33 Å. Studies to evaluate the cytotoxicity of 17a–e and 20a–i revealed that 20h was effective against metastatic tumor cells derived from a chemoresistant breast cancer patient (PE1007070 cells) with an EC50 = 8.8 μM.22 Moreover, 20h did not significantly affect the viability of immortalized, nontumorogenic mammary tissue (hTERT-HMEC cells), suggesting a cancer-specific mechanism of action. The effect of 20h on cell viability was also measured in a breast cancer cell line (MCF-7) and an untransformed mammary epithelial cell line (MCF-10A) (Figure 3). As with the patient-derived cells, 20h was found to significantly reduce the viability of MCF-7 cells (EC50 = 1.4 μM) while having no significant effect on the untransformed mammary cell line. Despite the reported selectivity of naamidine A (6) to inhibit proliferation in EGFR transfected NIH3T3 cells, no selectivity was observed in the antiproliferative activity of MCF-7 versus MCF-10A cells (EC50 = 5.9 and 8.1 μM, respectively). Taken together, these results suggest that the natural-product-inspired N2-Acyl-2-aminoimidazoles can exploit cancer-selective mechanisms to cause cell death. Studies to further understand this mechanism and evaluate its therapeutic potential are underway. CONCLUSION In summary, we have shown that monoacylguanidines preferentially adopt the N-acylimino tautomer, and that this can be reliably used to predict reactivity. Thus, the hydroamination of monoacylpropargylguanidines can be effected regioselectively to generate N3-acyl-2-aminoimidazoles and subsequently free 2-aminoimidazoles after deprotection with isomerization of the Cbz-protected variants. This strategy further exploits the confined N2-imino tautomer to allow selective N2-Acylation and deliver these analogues without contamination from the diacylated derivatives. The effectiveness of this approach was demonstrated by completing a gram-scale synthesis of both naamine A and naamidine A. The discovery of 20h as a more selective antiproliferative agent than naamidine A highlights the necessity to efficiently prepare mono-N2-Acyl-2-aminoimidazoles to further study this selectivity. EXPERIMENTAL SECTION General Considerations All reactions requiring anhydrous conditions were performed under a positive pressure of nitrogen using flame-dried glassware. Acetonitrile (MeCN), dichloromethane (CH2Cl2), and toluene (PhMe) were degassed with nitrogen and passed through activated alumina. Methanol (MeOH) and triethylamine (Et3N) were distilled from CaH2 immediately prior to use. Reactions were monitored to completion by TLC and visualized by a dual short-/long-wave UV lamp and stained with an aqueous solution of potassium permanganate and/or organic solution of phosphomolybdic acid. Flash chromatography was performed on silica gel Siliaflash P60 (40–63 μm). Infrared spectra were recorded as thin films, and absorptions are reported in cm−1 relative to polystyrene (1601 cm−1); HRMS mass spectra were determined by ESI/APCI-TOF. 1H NMR and spectra were recorded on 500 and 300 MHz spectrometers as indicated. The chemical shifts (δ) of proton resonances were reported relative to the deuterated solvent peak (7.26 ppm for CDCl3, 3.31 for CD3OD, and 2.50 ppm for DMSO-d6) using the following format: chemical shift [multiplicity (s = singlet, d = doublet, t = triplet, q = quartet, m = multiplet), coupling constant(s) (J in Hz), integral; 13C NMR spectra were recorded at 125 and 75 MHz. The chemical shifts (δ) of carbon resonances were reported relative to the deuterated solvent peak (77.2 ppm for CDCl3 and 39.5 for DMSO-d6). Procedures for the Synthesis of Naamidine A N-Allyl-1-(4-(benzyloxy)phenyl)-4-(4-methoxyphenyl)-N-methylbut-3-yn-2-amine (12) To a 500 mL pressure flask equipped with a stir bar were added 4-methoxyphenylacetylene (5.35 mL, 40.5 mmol), N-allylmethylamine (3.46 mL, 36.4 mmol), p-OBn-phenylacetaldehyde (9.2 g, 40.5 mmol), CuBr (0.52 g, 3.6 mmol), acetonitrile (140 mL), and 1 g of oven-dried 4 Å molecular sieves. The flask was heated at 80 °C for 24 h and then allowed to cool to room temperature. The mixture was filtered through Celite and rinsed with EtOAc (500 mL). The organic layer was washed with aqueous solutions of saturated NaHCO3 (500 mL) and brine (500 mL). The organic layer was dried over Na2SO4. After filtration, the organic layer was concentrated and purified via flash chromatography using 4:1 hexanes/EtOAc to give 8 as a dark red oil (10.8 g, 65%): Rf = 0.35 (4:1 hexanes/EtOAc); 1H NMR (CDCl3, 300 MHz) δ 7.37−7.27 (m, 4H), 7.24 (d, J = 8.8 Hz, 2H), 7.24 (overlapped, 1H), 7.15 (d, J = 8.3 Hz, 2H), 6.84 (d, J = 8.8 Hz, 2H), 6.73 (d, J = 8.8 Hz, 2H), 5.78 (ddt, J = 6.4, 10.7, 17.1 Hz, 1H), 5.14 (dd, J = 1.5, 17.1 Hz, 1H), 5.05 (dd, J = 2.0, 10.3 Hz, 1H), 4.95 (s, 2H), 3.72 (dd, J = 6.4, 8.8 Hz, 1H), 3.70 (s, 3H), 3.15 (dd, J = 5.9, 13.7 Hz, 1H), 3.03 (dd, J = 7.3, 13.5 Hz, 1H), 2.27 (s, 3H) ppm; 13C NMR (CDCl3, 75 MHz) δ 159.2, 157.4, 137.2, 136.0, 133.0 131.2, 130.4, 128.5, 127.8, 127.4, 117.6, 115.5, 114.5, 113.8, 88.5, 85.0, 69.9, 58.4, 58.2, 55.2, 39.5, 37.7 ppm; IR (thin film) 2954, 1606, 1508, 1454, 1420, 1381, 1289, 1243, 1173, 1106, 1026, 921, 831, 807, 791, 732, 696 cm−1; HRMS (ESI+) calcd for C28H30NO2 m/z (M + H) 412.2277, found 412.2278. 1-(4-(Benzyloxy)phenyl)-4-(4-methoxyphenyl)-N-methylbut-3-yn-2-amine (13) To a 500 mL round-bottom flask equipped with a stir bar were added 12 (10.7 g, 26.0 mmol), thiosalicylic acid (8.0 g, 52 mmol), Pd(PPh3)4 (0.6 g, 0.5 mmol), and CH2Cl2 (260 mL). The reaction was allowed to stir at room temperature under N2 overnight. The reaction mixture was concentrated and redissolved in EtOAc (200 mL). The organic layer was washed with saturated NaHCO3 (200 mL) and brine (200 mL). The organic layer was dried over Na2SO4. After filtration, the organic layer was concentrated and purified via flash chromatography using 100% EtOAc (with 0.5% Et3N) to give 13 as an orange oil (6.6 g, 91%): Rf = 0.35 (100% EtOAc); 1H NMR (CDCl3, 500 MHz) δ 7.45 (d, J = 7.3, 2H), 7.40 (t, J = 6.8 Hz, 2H), 7.34 (d, J = 8.8 Hz, 3H), 7.27 (d, J = 8.3 Hz, 2H), 6.95 (d, J = 8.8 Hz, 2H), 6.83 (d, J = 8.8 Hz, 2H), 5.06 (s, 2H), 3.80 (s, 3H), 3.72 (t, J = 6.4 Hz, 1H), 2.98 (dd, J = 2.4, 9.4 Hz, 2H), 2.55 (s, 3H) ppm; 13C NMR (CDCl3, 125 MHz) δ 159.4, 157.7, 137.2, 133.0, 130.8, 128.7, 128.0, 127.6, 115.5, 114.7, 88.7, 84.6, 70.1, 55.3, 53.9, 41.3, 34.2 ppm; IR (thin film) 2933, 1606, 1508, 1454, 1441, 1380, 1289, 1244, 1173, 1107, 1027, 831, 737, 697, 668 cm−1; HRMS (ESI+) calcd for C25H26NO2 m/z (M + H) 372.1964, found 372.1966. N-Cbz-1-(1-(4-(benzyloxy)phenyl)-4-(4-methoxyphenyl)but-3-yn-2-yl)-1-methylguanidine (14) To a 250 mL round-bottom flask equipped with a stir bar were added TMSCl (1.65 mL, 13.0 mmol), benzyloxycarbonylcyanamide potassium salt (2.58 g, 12.0 mmol) and 50 mL of acetonitrile. The reaction mixture was allowed to stir for 10 min under N2. A solution of 13 (4.8 g, 13 mmol) in acetonitrile (15 mL) was added to the suspension, and the reaction was allowed to stir for 1 h. The reaction mixture was concentrated to approximately one-quarter of the original volume and then diluted with EtOAc (100 mL). The organic layer was washed with aqueous solutions of saturated Na2CO3 (100 mL) and brine (100 mL). The organic layer was dried over Na2SO4. After filtration, the organic layer was concentrated and purified via flash chromatography using 1:1 hexanes/EtOAc to give 14 as a yellow foam (5.9 g, 90%): Rf = 0.42 (1:1 hexanes/EtOAc); 1H NMR (CDCl3, 500 MHz) δ 7.44 (d, J = 7.3 Hz, 4H), 7.42−7.27 (m, 8H), 7.20 (d, J = 8.8 Hz, 2H), 6.90 (d, J = 8.3 Hz, 2H), 6.83 (d, J = 8.8 Hz, 2H), 6.02 (br s, 2H), 5.16 (d, J = 2.4 Hz, 2H), 5.03 (s, 2H), 3.80 (s, 3H), 3.04 (dd, J = 7.3, 13.2 Hz, 1H), 2.95 (dd, J = 6.4, 13.2 Hz, 1H), 2.90 (s, 3H) ppm; 13C NMR (CDCl3, 125 MHz) δ 173.1, 164.0, 160.7, 159.8, 157.9, 137.8, 137.1, 133.2, 130.7, 129.1, 128.7, 128.4, 128.0, 127.9, 127.7, 114.8, 114.0, 86.1, 84.9, 70.1, 66.8, 55.4, 50.2, 39.7 ppm; IR (thin film) 2934, 1642, 1589, 1536, 1508, 1440, 1378, 1280, 1244, 1172, 1152, 1107, 1026, 909, 831, 799, 732, 696 cm−1; HRMS (ESI+) calcd for C34H34N3O4 m/z (M + H) 548.2549, found 548.2556. Benzyl (Z)-4-(4-(Benzyloxy)benzyl)-2-imino-5-(4-methoxybenzylidene)-3-methylimidazolidine-1-carboxylate (15) To a 25 mL round-bottom flask equipped with a stir bar were added 14 (0.51 g, 0.91 mmol), AgNO3 (0.02 g, 0.09 mmol), and dichloromethane (9.1 mL). The flask was wrapped with aluminum foil, and the reaction was allowed to stir at room temperature under N2 overnight. The reaction mixture was concentrated and purified via flash chromatography using 5% MeOH in CH2Cl2 to give 15 as a light yellow foam (0.43 g, 87%): Rf = 0.28 (5% MeOH in CH2Cl2); 1H NMR (CDCl3, 300 MHz) δ 7.46−7.20 (m, 8H), 6.97 (d, J = 8.7 Hz, 2H), 6.94−6.87 (m, 4H), 6.74 (d, J = 4.3 Hz, 2H), 6.71 (d, J = 4.0 Hz, 2H), 5.39 (s, 1H), 4.99 (s, 2H), 4.92 (d, J = 11.5 Hz, 1H), 4.29 (d, J = 12.0 Hz, 1H), 4.08 (dd, J = 4.2, 6.6 Hz, 1H), 3.77 (s, 3H), 3.08 (s, 3H), 2.99 (dd, J = 4.2, 13.7 Hz, 1H), 2.73 (dd, J = 7.3, 13.7 Hz, 1H) ppm; 13C NMR (CDCl3, 125 MHz) δ 158.7, 157.9, 154.0, 151.2, 137.1, 134.2, 131.1, 129.5, 128.8, 128.7, 128.5, 128.4, 128.3, 128.1, 127.5, 114.8, 113.8, 113.4, 70.0, 68.6, 65.0, 55.4, 37.8 ppm; IR (thin film) 2923, 2851, 1734, 1607, 1510, 1454, 1382, 1299, 1247, 1178, 1033, 830, 738, 698 cm−1; HRMS (ESI+) calcd for C34H34N3O4 m/z (M + H) 548.2549, found 548.2555. 4-((2-Amino-4-(4-methoxybenzyl)-1-methyl-1H-imidazol-5-yl)-methyl)phenol (Naamine A, 8) To a 10 mL round-bottom flask equipped with a stir bar were added 15 (0.25 g, 0.46 mmol), Pd(OH)2 on carbon (20 wt %, 0.032 g, 0.046 mmol), and MeOH (4.6 mL). A H2 balloon was attached, and the reaction was allowed to stir overnight. The reaction mixture was filtered through Celite and rinsed with dichloromethane. The reaction mixture was concentrated to a pale yellow solid (0.12 g, 84%, mp = 182 °C) and used without further purification to give 8 as naamine A: 1H NMR (CD3OD, 500 MHz) δ 7.08 (d, J = 8.3 Hz, 2H), 6.84 (d, J = 8.3 Hz, 2H), 6.76 (d, J = 8.3 Hz, 2H), 6.64 (d, J = 8.8 Hz, 2H), 3.76 (s, 2H), 3.72 (s, 3H), 3.69 (s, 2H), 3.08 (s, 3H) ppm; 13C NMR (DMSO-d6, 125 MHz) δ 168.5, 157.8, 156.2, 148.9, 134.5, 132.4, 130.6, 130.1, 129.5, 120.3, 115.8, 114.0, 55.6, 32.7, 29.4, 28.6 ppm; IR (thin film) 2923, 2852, 1610, 1511, 1457, 1369, 1245, 1175, 1035, 814, 773, 668, 652 cm−1; HRMS (ESI+) calcd for C19H22N3O2 m/z (M + H) 324.1712, found 324.1714. Preparation of Naamidine A (6) To a 50 mL round-bottom, two-neck flask equipped with a stir bar and reflux condenser were added 1-methylparabanic acid (2.04 g, 15.9 mmol) and acetonitrile (14.5 mL). Bis(trimethylsilyl)acetamide (4.9 mL, 20.0 mmol) was added via syringe, and the reaction mixture was allowed to reflux for 2 h. Without exposing the reaction flask to the open atmosphere, the solvent was removed under reduced pressure. The reaction mixture was placed under N2 and diluted with PhMe (10.5 mL). The solution was transferred via cannula to a 50 mL round-bottom, two-neck flask equipped with a stir bar and reflux condenser containing 8 (1.03 g, 3.2 mmol, mp = 188 °C) under a N2 atmosphere. The reaction mixture was allowed to reflux for 16 h. The reaction was allowed to cool to room temperature, diluted with EtOAc (10 mL), then transferred to a 100 mL round-bottom flash to be concentrated. The mixture was purified via flash chromatography using 85:15 PhMe/MeOH with 1% Et3N to give 6 as a bright yellow solid (1.10 g, 76%): Rf = 0.4 (85:15 PhMe/MeOH with 1% NEt3); 1H NMR (CDCl3, 500 MHz) δ 7.11 (d, J = 8.8 Hz, 2H), 6.83 (d, J = 7.8 Hz, 2H), 6.81 (d, J = 8.8 Hz, 2H), 6.73 (d, J = 8.8 Hz, 2H), 3.87 (s, 4H), 3.77 (s, 3H), 3.40 (s, 3H), 3.17 (s, 3H) ppm; 13C NMR (CDCl3, 125 MHz) δ 163.3, 158.5, 157.0, 155.2, 146.7, 134.7, 131.3, 129.5, 129.3, 128.7, 127.0, 115.0, 114.3, 55.5, 32.1, 30.0, 28.8, 25.0 ppm; IR (thin film) 3335, 1789, 1736, 1665, 1612, 1569, 1512, 1486, 1445, 1392, 1303, 1247, 1174, 1153, 1035, 821, 776, 727, 606 cm−1; HRMS (ESI+) calcd for C23H24N5O4 m/z (M + H) 434.1828, found 434.1840. General Procedure A: Acylation of 15 To Give 16a–f Benzyl-2-(benzoylimino)-4-(4-(benzyloxy)benzyl)-5-((Z)-4-methoxybenzylidene)-3-methylimidazolidine-1-carboxylate (16a) To a 25 mL round-bottom flask equipped with a stir bar were added 15 (498 mg, 0.91 mmol), Et3N (0.25 mL, 1.8 mmol, 2.0 equiv), benzoyl chloride (0.16 mL, 1.4 mmol, 1.5 equiv), and dichloromethane (9.1 mL). The reaction was allowed to stir for 1 h. The reaction mixture was concentrated and purified via flash chromatography using 1:1 hexanes/EtOAc to give 16a as a light yellow foam (545 mg, 92%): Rf = 0.43 (1:1 hexanes/EtOAc); 1H NMR (CDCl3, 300 MHz) δ 8.12 (d, J = 7.0 Hz, 2H), 7.51−7.11 (m, 13H), 7.08 (d, J = 8.8 Hz, 2H), 6.98 (d, J = 8.7 Hz, 2H), 6.78 (d, J = 8.7 Hz, 2H), 6.75 (d, J = 8.9 Hz, 2H), 5.45 (s, 1H), 5.01 (s, 2H), 4.80 (d, J = 19.8 Hz, 1H), 4.42 (d, J = 19.8 Hz, 1H), 4.08 (dd, J = 4.2, 6.6 Hz, 1H), 3.77 (s, 3H), 3.14 (s, 3H), 3.03 (dd, J = 4.2, 13.5 Hz, 1H), 2.78 (dd, J = 7.6, 13.5 Hz, 1H) ppm; 13C NMR (CDCl3, 75 MHz) δ 175,6, 158.7, 157.9, 151.9, 149.1, 137.3, 137.0, 134.5, 131.4, 131.1, 129.7, 129.3, 128,7, 128.6, 128.2, 128.1, 128.0, 127.8, 127.5, 127.1, 117.4, 114.8, 113.7, 70.0, 68.7, 64.6, 55.3, 37.9, 31.0 ppm; IR (thin film) 3033, 2933, 1746, 1647, 1607, 1511, 1455, 1379, 1315, 1282, 1248, 1178, 1075, 1037, 1024, 866, 826, 739, 713, 697 cm−1; HRMS (ESI+) calcd for C41H37N3O5Na m/z (M + Na) 674.2631, found 674.2632. Benzyl-4-(4-(benzyloxy)benzyl)-2-((2-fluorobenzoyl)imino)-5-((Z)-4-methoxybenzylidene)-3-methylimidazolidine-1-carboxylate (16b) Prepared according to the general procedure A with 2-fluorobenzoyl chloride, with purification on silica gel eluting with 1:1 hexanes/EtOAc to give 16b as a yellow oil (540 mg, 89% yield): Rf = 0.42 (1:1 hexanes/EtOAc); 1H NMR (CDCl3, 300 MHz) δ 7.91 (dt, J = 2.0, 7.8 Hz, 1H), 7.44−7.01 (m, 11H), 6.97 (d, J = 8.8 Hz, 4H), 6.85 (t, J = 8.8 Hz, 2H), 6.77 (d, J = 8.8 Hz, 2H), 6.66 (d, J = 8.8 Hz, 2H), 5.46 (s, 1H), 5.00 (s, 2H), 4.82 (d, J = 19.5 Hz, 1H), 4.33 (d, J = 19.5 Hz, 1H), 4.11 (dd, J = 3.4, 7.5 Hz, 1H), 3.76 (s, 3H), 3.15 (s, 3H), 3.00 (dd, J = 4.4, 13.7 Hz, 1H), 2.78 (dd, J = 7.5, 13.7 Hz, 1H) ppm; 13C NMR (CDCl3, 75 MHz) δ 172.7, 161.3 (d, JCF = 253.8 Hz), 158.7, 158.0, 151.8, 149.1, 137.0, 134.4, 132.6, 132.3 (d, JCF = 9.0 Hz), 131.0, 129.5, 128.7, 128.7, 128.2, 128.2, 127.7, 127.5, 127.0, 123.6 (d, JCF = 3.5 Hz), 117.3, 116.4 (d, JCF = 23.0 Hz), 114.9, 113.6, 70.1, 68.9, 64.6, 55.3, 37.9, 31.0 ppm; IR (thin film) 3033, 2930, 1743, 1598, 1510, 1483, 1452, 1407, 1379, 1314, 1282, 1246, 1177, 1116, 1029, 909, 862, 817, 756, 733, 696 cm−1; HRMS (ESI+) calcd for C41H36N3O5FNa m/z (M + Na) 692.2537, found 692.2545. Benzyl-4-(4-(benzyloxy)benzyl)-2-((4-methoxybenzoyl)imino)-5-((Z)-4-methoxybenzylidene)-3-methylimidazolidine-1-carboxylate (16c) Prepared according to the general procedure A with 4-methoxybenzoyl chloride, with purification on silica gel eluting with 2:1 hexanes/EtOAc to give 16c as a yellow oil (78 mg, 88% yield): Rf = 0.48 (2:1 EtOAc/hexanes); 1H NMR (CDCl3, 300 MHz) δ 8.08 (d, J = 8.7 Hz, 2H), 7.44−7.28 (m, 5H), 7.24−7.04 (m, 5H), 6.98 (d, J = 8.4 Hz, 2H), 6.89 (d, J = 9.0 Hz, 2H), 6.83−6.71 (m, 6H), 5.44 (s, 1H), 5.00 (s, 2H), 4.80 (d, J = 20.0 Hz, 1H), 4.43 (d, J = 20.0 Hz, 1H), 4.06 (dd, J = 4.1, 7.1 Hz, 1H), 3.84 (s, 3H), 3.76 (s, 3H), 3.12 (s, 3H), 3.02 (dd, J = 4.1, 13.5 Hz, 1H), 2.77 (dd, J = 7.1, 13.5 Hz, 1H); 13C NMR (CDCl3, 75 MHz) δ 175.3, 162.5, 158.9, 158.0, 151.6, 149.3, 137.1, 134.7, 133.7, 131.8, 131.2, 130.2, 129.8, 129.5, 128.8, 128.7, 128.3, 128.2, 128.0, 127.6, 127.4, 117.4, 114.9, 113.8, 70.1, 68.6, 64.7, 55.6, 55.4, 38.1, 31.1; IR (thin film) 3033, 2933, 2837, 1743, 1598, 1509, 1454, 1378, 1281, 1236, 1176, 1163, 1110, 1074, 1027, 907, 861, 844, 826, 726, 696 cm−1; HRMS (ESI+) calcd for C42H39N3O6Na m/z (M + Na) 704.2737, found 704.2742. Benzyl-4-(4-(benzyloxy)benzyl)-5-((Z)-4-methoxybenzylidene)-3-methyl-2-((3-(trifluoromethyl)benzoyl)imino)imidazolidine-1-carboxylate (16d) Prepared according to the general procedure A with 3-trifluoromethylbenzoyl chloride, with purification on silica gel eluting with 2:1 EtOAc/hexanes to give 16d as a yellow oil (61 mg, 94% yield): Rf = 0.66 (2:1 EtOAc/hexanes); 1H NMR (CDCl3, 300 MHz) δ 8.41 (s, 2H), 8.35 (d, J = 7.5 Hz, 1H), 8.30 (d, J = 8.0 Hz, 1H), 7.96 (d, J = 8.0 Hz, 1H), 7.72 (t, J = 7.5 Hz, 2H), 7.50 (t, J = 8.0 Hz, 1H), 7.42−7.29 (m, 4H), 7.22−7.11 (m, 4H), 7.00 (d, J = 8.5 Hz, 2H), 6.80 (d, J = 9.0 Hz, 2H), 6.77 (d, J = 8.0 Hz, 2H), 5.53 (s, 1H), 5.00 (s, 2H), 4.78 (d, J = 12.0 Hz, 1H), 4.41 (d, J = 12.0 Hz, 1H), 4.13 (dd, J = 4.5, 7.3 Hz, 1H), 3.77 (s, 3H), 3.18 (s, 3H), 3.04 (dd, J = 4.5, 13.8 Hz, 1H), 2.84 (dd, J = 7.3, 13.8 Hz, 1H); 13C NMR (CDCl3, 75 MHz) δ 173.9, 160.9, 158.9, 158.0, 152.9, 149.0, 138.0, 137.0, 134.2, 133.8, 132.9, 131.9 (q, JCF = 33.4 Hz), 131.3 (q, JCF = 3.8 Hz), 131.0, 130.4, 130.2 129.9, 129.5, 129.7 (q, JCF = 3.8 Hz), 129.2, 128.7, 128.5, 128.2, 128.1 127.5, 126.8, 125.4, 124.4, 123.2, 122.3, 117.7, 114.8, 113.7, 70.0, 68.9, 64.6, 55.2, 37.8, 30.9; IR (thin film) 2935. 1797, 1743, 1606, 1511, 1455, 1379, 1332, 1313, 1300, 1275, 1249, 1226, 1167, 1124, 1070, 1033, 996, 908, 858, 818, 789, 729, 693 cm−1; HRMS (ESI+) calcd for C42H37N3O5F3 m/z (M + H) 720.2685, found 720.2689. Benzyl-4-(4-(benzyloxy)benzyl)-2-(isobutyrylimino)-5-((Z)-4-methoxybenzylidene)-3-methylimidazolidine-1-carboxylate (16e) Prepared according to the general procedure A with isobutyryl chloride, with purification on silica gel eluting with 1:1 EtOAc/hexanes to give 16e as a yellow oil (49 mg, 87% yield): Rf = 0.32 (1:1 hexanes/EtOAc); 1H NMR (CDCl3, 500 MHz) δ 7.64−7.37 (m, 10H), 7.28 (d, J = 8.8 Hz, 2H), 7.15 (d, J = 8.8 Hz, 2H), 7.08 (d, J = 7.8 Hz, 2H), 6.96 (d, J = 8.8 Hz, 2H), 5.60 (s, 1H), 5.21 (s, 2H), 5.07 (d, J = 19.5 Hz, 1H), 4.71 (d, J = 19.5 Hz, 1H), 4.20 (dd, J = 4.2, 7.1 Hz, 1H), 3.97 (s, 3H), 3.24 (s, 3H), 3.18 (dd, J = 4.2, 13.5 Hz, 1H), 2.93 (dd, J = 7.1, 13.5 Hz, 1H), 2.84 (sept, J = 6.8 Hz, 1H), 1.44 (d, J = 6.8 Hz, 3H), 1.39 (d, J = 6.8 Hz, 3H) ppm; 13C NMR (CDCl3, 75 MHz) δ 188.0, 158.7, 157.9, 150.3, 149.2, 137.0, 134.6, 131.0, 129.5, 129.4, 128.7, 128.6, 128.2, 128.0, 127.9, 127.4, 127.2, 117.0, 114.8, 113.7, 70.0, 68.6, 64.6, 55.2, 38.6, 37.9, 30.8, 20.1 ppm; IR (thin film) 3033, 2964, 2929, 1745, 1663, 1607, 1455, 1379, 1273, 1249, 1179, 1123, 1077, 1037, 923, 864, 826, 738, 697 cm−1; HRMS (ESI+) calcd for C38H39N3O5Na m/z (M + Na) 640.2787, found 640.2775. Benzyl-4-(4-(benzyloxy)benzyl)-5-((Z)-4-methoxybenzylidene)-3-methyl-2-((2-methylbutanoyl)imino)imidazolidine-1-carboxylate (16f) Prepared according to the general procedure A with 2-methylbutyryl chloride, with purification on silica gel eluting with 1:1 EtOAc/hexanes to give 16f as a yellow oil (28 mg, 85% yield): Rf = 0.44 (1:1 hexanes/EtOAc); 1H NMR (CDCl3, 500 MHz) δ 7.44−7.17 (m, 8H), 7.08 (d, J = 8.7 Hz, 2H), 6.94 (d, J = 8.5 Hz, 2H), 6.86 (d, J = 7.3 Hz, 2H), 6.75 (d, J = 8.4 Hz, 2H), 5.39 (d, J = 5.8 Hz, 1H), 5.00 (s, 2H), 4.88 (dd, J = 4.0 Hz, 20.5 Hz, 1H), 4.51 (dd, J = 4.0 Hz, 20.5 Hz, 1H), 3.99 (p, J = 3.7, 1H), 3.75 (s, 3H), 3.03 (s, 3H), 2.97 (dd, J = 4.4, 13.5 Hz, 1H), 2.72 (m, 1H), 2.46 (ddq, J = 6.9, 5.6, 7.0 Hz, 1H), 1.83 (m, 1H), 1.51 (m, 1H), 1.18 (dd, J = 6.9, 7.0, 3H), 0.97 (dt, J = 4.0, 7.6 Hz, 3H) ppm; 13C NMR (CDCl3, 75 MHz) δ 187.5, 158.9, 158.0, 151.1, 150.7, 149.4, 137.2, 134.7, 131.2, 129.7, 128.8, 128.7, 128.4, 128.2, 128.0, 127.6, 127.4, 127.3, 117.2, 114.9, 113.8, 70.1, 68.8, 64.8, 55.4, 45.9, 45.5, 38.1, 31.1, 27.7, 27.5, 17.2, 16.4, 12.2, 12.0; IR (thin film) 2963, 2931, 2873, 1746, 1653, 1607, 1511, 1456, 1378, 1249, 1179, 1119, 1077, 1039, 827, 741, 696 cm−1; HRMS (ESI+) calcd for C39H41N3O5Na m/z (M + Na) 654.2944, found 654.2941. General Procedure B: Deprotection with Isomerization of 16 to 17 N-(5-(4-Hydroxybenzyl)-4-(4-methoxybenzyl)-1-methyl-1,3-dihydro-2H-imidazol-2-ylidene)benzamide (17a) To a 5 mL round-bottom flask equipped with a stir bar were added 16a (52 mg, 0.08 mmol), PdCl2 (25 mg, 0.18 mmol), and methanol (0.9 mL). The reaction was allowed to stir until completion under a H2 atmosphere balloon. The reaction mixture was filtered through 0.45 μM PTFE syringe filter and rinsed with additional methanol and CH2Cl2. The solvent was removed, and the product was triturated with diethyl ether. The solid was isolated to give 17a as an off-white solid (34 mg, 92%, mp = 135 °C): Rf = 0.40 (5% MeOH in CH2Cl2); 1H NMR (DMSO-d6, 500 MHz) δ 9.41 (s, 1H), 8.10 (d, J = 7.3 Hz, 2H), 7.63 (t, J = 7.33 Hz, 1H), 7.53 (t, J = 7.8 Hz, 2H), 7.20 (d, J = 8.8 Hz, 2H), 6.88 (d, J = 8.3 Hz, 2H), 6.86 (d, J = 8.8 Hz, 2H), 6.69 (d, J = 6.4 Hz, 2H), 4.03 (s, 2H), 4.00 (s, 2H), 3.69 (s, 3H), 3.15 (s, 3H) ppm; 13C NMR (DMSO-d6, 125 MHz) δ 158.5, 156.7, 133.3, 130.4, 130.0, 129.5, 129.0, 128.9, 127.0, 116.0, 114.4, 55.6, 49.0, 31.7, 28.7, 27.4 ppm; IR (thin film) 3926, 2932, 1688 1612, 1510, 1474, 1453, 1408, 1363, 1301, 1246, 1174, 1104, 1033, 908, 818, 731, 706 cm−1; HRMS (ESI+) calcd for C26H26N3O3 m/z (M + H) 428.1974, found 428.1973. 2-Fluoro-N-(5-(4-hydroxybenzyl)-4-(4-methoxybenzyl)-1-methyl-1,3-dihydro-2H-imidazol-2-ylidene)benzamide (17b) Prepared according to the general procedure B with 16b, with purification via trituration with diethyl ether to give 17b as a waxy solid (23 mg, 88% yield): Rf = 0.30 (1:1 hexanes/EtOAc); 1H NMR (DMSO-d6, 300 MHz) δ 9.29 (s, 1H), 7.80 (s, 1H), 7.43 (s, 1H), 7.19 (d, J = 8.1 Hz, 4H), 6.89 (d, J = 8.1 Hz, 2H), 6.84 (d, J = 8.4 Hz, 2H), 6.67 (d, J = 8.1 Hz, 2H), 3.89 (s, 4H), 3.71 (s, 3H), 3.20 (s, 3H) ppm; 13C NMR (DMSO-d6, 125 MHz) δ 157.8, 155.9, 131.3, 129.9, 129.7, 129.4, 128.3, 116.7 (d, JCF = 22.8 Hz), 115.8, 114.2, 55.4, 29.5, 27.7 ppm; IR (thin film) 1686, 1581, 1512, 1478, 1441, 1305, 1247, 1173, 1156, 1105, 904 cm−1; HRMS (ESI+) calcd for C26H24N3O3FNa m/z (M + Na) 468.1699, found 468.1700. N-(5-(4-Hydroxybenzyl)-4-(4-methoxybenzyl)-1-methyl-1,3-dihydro-2H-imidazol-2-ylidene)-4-methoxybenzamide (17c) Prepared according to the general procedure B with 16c, with purification via trituration with diethyl ether to give 17c as an off-white solid (50 mg, 95% yield, mp = 178 °C): Rf = 0.30 (1:1 hexanes/EtOAc); 1H NMR (DMSO-d6, 300 MHz) δ 9.44 (s, 1H), 8.07 (d, J = 9.3 Hz, 2H), 7.21 (d, J = 8.8 Hz, 2H), 7.10 (d, J = 8.8 Hz, 2H), 6.89 (d, J = 8.3 Hz, 2H), 6.87 (d, J = 8.3 Hz, 2H), 6.69 (d, J = 8.3 Hz, 2H), 4.06 (s, 2H), 4.01 (s, 2H), 3.85 (s, 3H), 3.72 (s, 3H), 3.43 (s, 3H) ppm; 13C NMR (DMSO-d6, 75 MHz) δ 162.8, 157.8, 155.9, 130.4, 129.6, 129.2, 128.8, 126.2, 115.2, 113.7, 64.6, 55.3, 54.8, 31.5, 27.8, 26.6, 14.9 ppm; IR (thin film) 2929, 1605, 1585, 1569, 1510, 1465, 1367, 1303, 1248, 1166, 1101, 1030, 906, 843, 815, 770, 728, 692, 668 cm−1; HRMS (ESI+) calcd for C27H28N3O4 m/z (M + H) 458.2080, found 458.2083. N-(5-(4-Hydroxybenzyl)-4-(4-methoxybenzyl)-1-methyl-1,3-dihydro-2H-imidazol-2-ylidene)-3-(trifluoromethyl)benzamide (17d) Prepared according to the general procedure B with 16d, with purification via trituration with diethyl ether to give 17d as an off-white solid (58 mg, 92% yield, mp = 237 °C): Rf = 0.40 (2:1 EtOAc/hexanes); 1H NMR (DMSO-d6, 300 MHz) δ 9.32 (s, 2H), 8.38 (s, 2H), 7.79 (d, J = 7.8 Hz, 1H), 7.64 (t, J = 7.5 Hz, 2H), 7.21 (d, J = 8.7 Hz, 2H), 6.91 (d, J = 8.4 Hz, 2H), 6.85 (d, J = 8.7 Hz, 2H), 6.69 (d, J = 8.4 Hz, 2H), 3.93 (s, 4H), 3.71 (s, 3H), 3.29 (s, 3H) ppm; 13C NMR (DMSO-d6, 75 MHz) δ 157.8, 155.9, 132.2, 129.5, 129.0, 124.5, 115.4, 113.9, 55.1, 28.9, 27.1 ppm; IR (thin film) 1564, 1532, 1512, 1483, 1383, 1322, 1277, 1248, 1170, 1153, 1113, 916 cm−1; HRMS (ESI+) calcd for C27H25N3O3F3 m/z (M + H) 496.1848, found 496.1850. N-(5-(4-Hydroxybenzyl)-4-(4-methoxybenzyl)-1-methyl-1,3-dihydro-2H-imidazol-2-ylidene)isobutyramide (17e) Prepared according to the general procedure B with 16e, with purification via trituration with diethyl ether to give 17e as an off-white solid (20 mg, 98% yield, mp = 196 °C): Rf = 0.17 (1:1 hexanes/EtOAc); 1H NMR (DMSO-d6, 300 MHz) δ 7.09 (d, J = 8.8 Hz, 2H), 6.82 (d, J = 8.3 Hz, 2H), 6.75 (d, J = 8.8 Hz, 2H), 6.64 (d, J = 8.3 Hz, 2H), 3.86 (s, 2H), 3.80 (s, 2H), 3.72 (s, 3H), 3.16 (s, 3H), 2.63 (sep, J = 6.8 Hz, 1H), 1.19 (d, J = 6.8 Hz, 6H) ppm; 13C NMR (DMSO-d6, 75 MHz) δ 176.3, 157.6, 155.8, 136.3, 130.0, 129.1, 128.7, 126.3, 125.5, 115.1, 113.5, 54.7, 33.5, 31.0, 28.0, 26.5, 18.6, ppm; IR (thin film) 3274, 2968, 2472, 1670, 1611, 1510, 1465, 1404, 1301, 1244, 1174, 1102, 1032, 973, 816 cm−1; HRMS (ESI+) calcd for C23H28N3O3 m/z (M + H) 394.2147, found 394.2138. N-(5-(4-Hydroxybenzyl)-4-(4-methoxybenzyl)-1-methyl-1,3-dihydro-2H-imidazol-2-ylidene)-2-methylbutanamide (17f) Prepared according to the general procedure B with 16f, with purification via trituration with diethyl ether to give 17f as an off-white solid (16 mg, 99%, mp = 102 °C): Rf = 0.33 (1:1 hexanes/EtOAc); 1H NMR (DMSO-d6, 300 MHz) δ 9.40 (s, 1H), 7.17 (d, J = 8.7 Hz), 6.87 (d, J = 8.2 Hz, 2H), 6.84 (d, J = 8.7 Hz, 2H), 6.67 (d, J = 8.5 Hz, 2H), 3.98 (s, 2H), 3.94 (s, 2H), 3.71 (s, 3H), 3.36 (s, 3H), 2.89 (sextet, J = 6.6 Hz, 1H), 1.61 (m, J = 7.4 Hz, 1H), 1.43 (m, J = 6.8 Hz, 1H), 1.10 (d, J = 6.8 Hz, 3H), 0.88 (t, J = 7.4 Hz, 3H) ppm; 13C NMR (DMSO-d6, 75 MHz) δ 176.1, 157.9, 156.1, 136.7, 130.5, 129.5, 129.1, 126.8, 125.9, 115.4, 113.9, 55.1, 31.3, 28.5, 26.9, 26.4, 16.9, 11.5 ppm; IR (thin film) 3357, 2965, 2483, 2076, 1670, 1653, 1635, 1612, 1558, 1510, 1458, 1405, 1301, 1245, 1175, 1118, 1033, 971, 816 cm−1; HRMS (ESI+) calcd for C24H30N3O3 m/z (M + H) 408.2303, found 408.2286. Preparation of Compound 18a N-(1,3-Diphenylprop-2-yn-1-yl)-N-methylprop-2-en-1-amine (S1a) In a 250 mL high-pressure flask containing a magnetic stir bar were added benzaldehyde (3.1 g, 29.0 mmol), phenylacetylene (2.95 g, 28.9 mmol), N-allylmethylamine (1.88 g, 26.3 mmol), oven-dried molecular sieves (grade 564, 3 Å, 8–12 mesh) (ca. 2 g), and acetonitrile (200 mL). The flask was sealed and placed in a preheated 80 °C oil bath for 24 h. The reaction flask was removed from the oil bath and allowed to cool to room temperature. CuBr (0.38 g, 2.6 mmol) was added, and the flask was sealed and returned to the preheated 80 °C oil bath for 48 h. The reaction tube was removed from the oil bath and allowed to cool to room temperature. The reaction mixture was filtered through Celite and rinsed with EtOAc (50 mL). The filtrate was concentrated under reduced pressure. The crude product was purified via flash chromatography, eluting with 9:1 hexanes/EtOAc to give S1a as a dark orange oil (5.3 g, 88%): Rf = 0.78 (2:1 hexanes/EtOAc); 1H NMR (CDCl3, 300 MHz) δ 7.65 (d, J = 6.9 Hz, 2H), 7.56−7.53 (m, 2H), 7.40−7.26 (m, 6H), 5.93 (ddt, J = 6.6 Hz, 10.4 Hz, 17.1 Hz, 1H), 5.32 (dd, J = 17.1 Hz, 1.5 Hz, 1H), 5.18 (dd, J = 10.4 Hz, 1.2 Hz, 1H), 4.99 (s, 1H), 3.89 (s, 3H), 3.19 (d, J = 5.1 Hz, 2H), 2.23 (s, 3H); 13C NMR (CDCl3, 75 MHz) δ 138.9, 136.3, 131.9, 128.5, 128.4, 128.3, 127.7, 123.4, 117.8, 88.5, 84.9, 59.8, 57.9 ppm; IR (thin film): 3061, 3030, 2978, 2945, 2844, 2788, 1598, 1489, 1448, 1324, 1273, 1196, 1155, 1127, 1070, 1023, 994, 963, 917, 754, 726, 689 cm−1; HRMS (ESI+) calcd for C19H19N m/z 262.1590 (M + H), found 262.1572. N-Methyl-1,3-diphenylprop-2-yn-1-amine (S2a) In a 250 mL round-bottom flask containing a magnetic stir bar were added Pd(PPh3)4 (1.3 g, 1.1 mmol), thiosalicylic acid (7.0 g, 45.0 mmol), and CH2Cl2 (100 mL). A solution of S1a (5.3 g, 22.7 mmol) in 15 mL of CH2Cl2 was added, and the reaction mixture was allowed to stir at room temperature under N2 for 12 h. The solvent was then removed under reduced pressure, and the crude product was redissolved in Et2O (10 mL). The organic layer was washed with aqueous solutions of saturated NaHCO3 (50 mL) and brine (50 mL) and then dried and filtered over Na2SO4. The crude product was purified via flash chromatography, eluting with 4:1 hexanes/EtOAc to give S2a as a dark orange oil (3.1 g, 73%): Rf = 0.22 (2:1 hexanes/EtOAc); 1H NMR (CDCl3, 300 MHz) δ 7.61−7.31 (m, 10H), 4.76 (s, 1H), 2.57 (s, 3H), 1.47 (s, 1H) ppm; 13C NMR (CDCl3, 75 MHz) δ 140.3, 131.8, 128.6, 128.4, 128.2, 127.9, 127.7, 123.2, 89.1, 85.7, 56.4, 33.9 ppm; IR (thin film) 3060, 3029, 2933, 2850, 2793, 1653, 1598, 1559, 1540, 1489, 1473, 1449, 1306, 1214, 1177, 1098, 1071, 1027, 915, 755, 691 cm−1; HRMS (ESI+) calcd for C16H16N m/z 222.1259 (M + H), found 222.1288. Benzyl (Z)-5-Benzylidene-2-imino-3-methyl-4-phenylimidazolidine-1-carboxylate (S3a) In a 100 mL round-bottom flask containing a magnetic stir bar were added potassium benzyloxycarbonylcyanamide (0.65 g, 3.0 mmol), TMSCl (0.34 g, 3.1 mmol), and acetonitrile (15 mL). The solution was stirred at room temperature for 10 min. A solution of S2a (0.46 g, 2.4 mmol) in acetonitrile (3.5 mL) was then added, and the reaction mixture was allowed to stir at room temperature for 1 h. The solvent was removed under reduced pressure, and the crude product was dissolved in EtOAc (150 mL). The organic layer was washed with aqueous solutions of saturated NaHCO3 (50 mL) and brine (50 mL) and then dried and filtered over Na2SO4. The crude product was purified via flash chromatography, eluting with 1:1 hexanes/EtOAc to give S3a as a dark brown oil (0.75 g, 85%): Rf = 0.48 (1:1 hexanes/EtOAc); 1H NMR (CDCl3, 300 MHz) δ 7.58−7.23 (m, 15H), 5.18 (s, 2H), 2.83 (s, 3H) ppm; 13C NMR (CDCl3, 75 MHz) δ 164.3, 161.3, 158.0, 137.2, 132.1, 128.9, 128,8, 128.6, 128.3, 128.2, 127.9, 127.6, 122.7, 87.0, 85.1, 67.1, 51.4, 30.1 ppm; IR (thin film) 3331, 3031, 2939, 1736, 1646, 1596, 1534, 1491, 1450, 1379, 1153, 1050, 1028, 801, 757, 696 cm−1; HRMS (ESI+) calcd for C25H24N3O2 m/z 398.1869 (M + H), found 398.1877. (Z)-Benzyl 5-Benzylidene-2-imino-3-methyl-4-phenylimidazolidine-1-carboxylate (18a) In a 50 mL foil-wrapped round-bottom flask containing a magnetic stir bar were added S3a (0.75, 2.0 mmol), AgNO3 (35 mg, 0.20 mmol), and CH2Cl2 (20 mL). The solution was stirred at room temperature for 6 h. The solvent was then removed under reduced pressure, and the crude product was redissolved in EtOAc (50 mL). The organic layer was washed with aqueous solutions of saturated NaHCO3 (15 mL) and brine (15 mL) and then dried -and filtered over Na2SO4. The crude product was purified via flash chromatography, eluting with 1:1 hexanes/EtOAc to give 18a as a dark brown oil (0.53 g, 71%): Rf = 0.31 (1:1 hexanes/EtOAc); 1H NMR (CDCl3, 300 MHz) δ 7.43−7.12 (m, 11H), 7.08 (d, J = 7.0 Hz, 2H), 6.90 (d, J = 7.5 Hz, 2H), 5.52 (d, J = 3.0 Hz, 1H), 5.00 (d, J = 3.0 Hz, 1H), 4.79 (d, J = 19.5 Hz, 1H), 4.37 (d, J = 19.5 Hz, 1H), 2.81 (s, 3H) ppm; 13C NMR (CDCl3, 75 MHz) δ 154.1, 151.4, 137.6, 136.3, 34.4, 129.2, 129.1, 128.7, 128.5, 128.4, 128.2, 127.4, 127.1, 113.4, 68.4, 67.6, 30.2 ppm; IR (thin film) 3346, 3031, 1734, 1684, 1652, 1495, 1426, 1386, 1303, 1249, 1197, 1161, 1047, 1026, 957, 797, 696 cm−1; HRMS (ESI+) calcd for C25H24N3O2 m/z 398.1869 (M + H), found 398.1876. Preparation of Compound 18b N-(1-(4-Methoxyphenyl)-3-phenylprop-2-yn-1-yl)-N-methylprop-2-en-1-amine (S1b) Prepared according to the A3-coupling procedure of S1a using p-anisaldehyde, n-allylmethylamine, and phenylacetylene, with purification on silica gel eluting with 2:1 hexanes/EtOAc to give a dark orange oil (12.7 g, 65%): Rf = 0.78 (2:1 hexanes/EtOAc); 1H NMR (CDCl3, 300 MHz) δ 7.59−7.53 (m, 4H), 7.37−7.26 (m, 3H), 6.49 (d, J = 8.7 Hz, 2H), 5.92 (ddt, J = 6.6 Hz, 10.5 Hz, 17.4 Hz, 1H), 5.33 (dd, J = 17.4 Hz, 2.0 Hz, 1H), 5.19 (dd, J = 9.3 Hz, 2.0 Hz, 1H), 4.94 (s, 1H), 3.83 (s, 3H), 3.19 (d, J = 6.6 Hz, 2H), 2.24 (s, 3H); 13C NMR (CDCl3, 75 MHz) δ 159.1, 136.3, 131.9, 131.1, 129.7, 128.4, 128.2, 123.4, 117.7, 113.6, 88.3, 85.3, 59.3, 57.8, 55.4, 37.8 ppm; IR (thin film) 2948, 2834, 2786, 1642, 1609, 1583, 1507, 1488, 1441, 1301, 1244, 1169, 1126, 1107, 1033, 994, 962, 916, 850, 807, 778, 754, 689, 583, 524 cm−1; HRMS (ESI+) calcd for C20H21NO m/z 292.1701 (M + H), found 292.1699. 1-(4-Methoxyphenyl)-N-methyl-3-phenylprop-2-yn-1-amine (S2b) Prepared according to the Pd(0)-deallylation procedure with S1b, with purification on silica gel eluting with 2:1 hexanes/EtOAc to give S2b a dark orange oil (2.1 g, 44%): Rf = 0.22 (2:1 hexanes/EtOAc); 1H NMR (CDCl3, 300 MHz) δ 7.54−7.48 (m, 4H), 7.33−7.31 (m, 3H), 6.9 (d, J = 8.7 Hz, 2H), 5.18 (s, 1H), 3.81 (s, 3H), 2.56 (s, 3H), 1.81 (s, 1H) ppm; 13C NMR (CDCl3, 75 MHz) δ 159.2, 132.4, 131.7, 128.8, 128.3, 128.1, 123.1, 113.8, 89.2, 85.5, 55.6, 55.3, 33.7 ppm; IR (thin film) 2953, 2834, 2790, 1609, 1584, 1508, 1488, 1462, 1440, 1301, 1243, 1171, 1095, 1031, 956, 913, 829, 754, 727, 703, 689, 573, 547, 524 cm−1; HRMS (ESI+) calcd for C17H17NONa m/z 274.1208 (M + Na), found 274.1213. Benzyl (Z)-5-Benzylidene-2-imino-4-(4-methoxyphenyl)-3-methylimidazolidine-1-carboxylate (S3b) Prepared according to the guanylation procedure of S2b, with purification on silica gel eluting with 1:1 hexanes/EtOAc to give a dark orange oil (2.97 g, 82%): Rf = 0.48 (1:1 hexanes/EtOAc); 1H NMR (CDCl3, 300 MHz) δ 7.51−7.43 (m, 6H), 7.36−7.25 (m, 7H), 6.9 (d, J = 6.3 Hz, 2H), 5.18 (s, 2H), 3.80 (s, 3H), 2.80 (s, 3H); 13C NMR (CDCl3, 75 MHz) δ 164.1, 160.9, 159.4, 137.6, 131.9, 129.0, 128.7, 128.6, 128.4, 128.0, 127.7, 122.2, 113.9, 86.6, 85.2, 66.9, 55.3, 50.6, 29.7 ppm; IR (thin film) 3403, 2932, 1646, 1584, 1532, 1508, 1488, 1440, 1376, 1273, 1246, 1121, 1150, 1110, 1027, 908, 845, 799, 775, 755, 729, 690, 647, 586, 552 cm−1; HRMS (ESI+) calcd for C26H26N3O3 m/z 428.1974 (M + Na), found 428.1979. (Z)-Benzyl 5-Benzylidene-2-imino-4-(4-methoxyphenyl)-3-methylimidazolidine-1-carboxylate (18b) Prepared according to the Ag(I) cyclization procedure, with purification by silica gel eluting with 1:1 hexanes/EtOAc to give a dark brown oil (1.2 g, 87%): Rf = 0.18 (1:1 hexanes/EtOAc); 1H NMR (CDCl3, 300 MHz) δ 7.28−7.16 (m, 9H), 7.10−7.08 (m, 2H), 6.92−6.88 (m, 4H), 5.47 (d, J = 2.1 Hz, 1H), 4.92 (d, J = 2.1 Hz, 1H), 4.82 (d, J = 19.5 Hz, 2H), 4.33 (d, J = 19.5 Hz, 2H), 3.81 (s, 3H), 2.75 (s, 3H) ppm; 13C NMR (CDCl3, 75 MHz) δ 106.1, 153.5, 151.4, 136.5, 135.1, 134.4, 129.7, 129.6, 128.7, 128.4, 127.4, 127.0, 114.5, 113.0, 62.2, 67.0, 55.4, 30.1 ppm; IR (thin film) 3404, 2932, 1646, 1548, 1532, 1508, 1488, 1440, 1376, 1273, 1246, 1171, 1150, 1110, 1027, 908, 845, 799, 779, 755, 728, 690, 647, 586, 552 cm−1; HRMS (ESI+) calcd for C26H26N3O3 m/z 428.1974 (M + Na), found 428.1979. General Procedure C: Acylation of 18 To Give 19 Benzyl-2-(benzoylimino)-5-((Z)-benzylidene)-3-methyl-4-phenylimidazolidine-1-carboxylate (19a) In a 10 mL round-bottomed flask containing a magnetic stir bar were added 18a (73 mg, 0.18 mmol), benzoyl chloride (0.032 mL, 0.28 mmol, 1.5 equiv), triethylamine (0.051 mL, 0.37 mmol, 2.0 equiv), and dichloromethane (2 mL) under N2. The reaction was stirred at room temperature for 2 h. The solution was concentrated under reduced pressure, and the crude material was dissolved in EtOAc (20 mL). The organic layer was washed with aqueous solutions of saturated NaHCO3 (15 mL) and brine (15 mL). The organic layer was dried over Na2SO4, and the resulting material was purified via flash chromatography (3:2 hexanes/EtOAc) to yield 19a as a light brown foam (86 mg, 93%): Rf = 0.22 (3:2 hexanes/EtOAc); 1H NMR (CDCl3, 300 MHz) δ 8.21−8.18 (m, 2H), 7.51−7.32 (m, 8H), 7.25−7.11 (m, 8H), 6.8−6.78 (m, 2H), 5.77 (d J = 2.0 Hz, 1H), 5.16 (d, J = 2.0 Hz, 1H), 4.70 (d, J = 12.0 Hz, 2H), 4.63 (d, J = 12.0 Hz, 2H), 2.93 (s, 3H) ppm; 13C NMR (CDCl3, 75 MHz) δ 178.8, 151.8, 149.3, 137.1, 136.8, 135.4, 134.5, 133.9, 131.6, 129.7, 129.4, 129.3, 127.8, 127.5, 116.9, 68.8, 67.0, 30.6 ppm; IR (thin film) 3060, 3029, 1744, 1557, 1494, 1448, 1404, 1377, 1315, 1277, 1226, 1173, 1144, 1080, 1036, 1020, 976, 909, 856, 794, 752, 727, 696, 668 cm−1; HRMS (ESI+) calcd for C32H27N3NaO3 m/z (M + Na) 524.1950, found 524.1963. Benzyl 2-(Benzoylimino)-5-((Z)-benzylidene)-4-(4-methoxyphenyl)-3-methylimidazolidine-1-carboxylate (19b) Prepared according to general procedure C using 18b and benzoyl chloride, with purification using silica gel eluting with 3:2 hexanes/EtOAc to give 19b as a light brown foam (96 mg, 80%): Rf = 0.22 (3:2 hexanes/EtOAc); 1H NMR (CDCl3, 500 MHz) δ 8.18 (d, J = 8.0 Hz, 2H), δ 7.50−7.21 (m, 14H), δ 6.91 (d, J = 8.5 Hz, 2H), δ 6.80 (d, J = 7.0 Hz, 2H), δ 5.74 (d, J = 1.8 Hz, 1H), δ 5.13 (d, J = 1.8 Hz, 1H), δ 4.72 (d, J = 12.0 Hz, 1H), δ 4.24 (d, J = 12.0 Hz, 1H), δ 3.82 (s, 3H), δ 2.90 (s, 3H) ppm; 13C NMR (CDCl3, 125 MHz) δ 175.2, 160.5, 151.9, 149.4, 137.3, 135.6, 134.7, 134.6, 134.4, 131.7, 129.8, 129.4, 128.7, 128.5, 128.4, 128.3, 128.2, 127.6, 116.8, 114.9, 69.0, 66.8, 55.6, 30.7 ppm; IR (thin film) 3404, 2932, 1646, 1548, 1532, 1508, 1488, 1440, 1376, 1273, 1246, 1171, 1150, 1110, 1027, 908, 845, 799, 779, 755, 728, 690 cm−1; HRMS (ESI+) calcd for C33H29N3NaO4 m/z (M + Na) 554.2056, found 554.2066. Benzyl 5-((Z)-Benzylidene)-2-((4-methoxybenzoyl)imino)-3-methyl-4-phenylimidazolidine-1-carboxylate (19c) Prepared according to general procedure C using 18a and 4-methoxybenzoyl chloride, with purification using silica gel eluting with 3:2 hexanes/EtOAc to give 19c as a light brown foam (0.12 g, 95%): Rf = 0.19 (3:2 hexanes/EtOAc); 1H NMR (CDCl3, 500 MHz) δ 8.16 (d, J = 9.0 Hz, 2H), 7.41−7.37 (m, 3H), 7.33−7.30 (m, 2H), 7.26−7.12 (m, 8H), 6.93 (d, J = 9.0 Hz, 2H), 6.81 (d, J = 7.5 Hz, 2H), 5.72 (d, J = 2.0 Hz, 1H), 5.13 (s, 1H), 4.71 (d, J = 12.3 Hz), 4.65 (d, J = 12.3 Hz), 3.86 (s, 3H), 2.92 (s, 3H) ppm; 13C NMR (CDCl3, 125 MHz) δ 175.0, 162.6, 151.5, 149.5, 137.1, 135.6, 134.8, 134.2, 131.8, 130.1, 129.5, 129.4, 1283, 127.9, 127.6, 116.9, 113.4, 68.9, 67.2, 55.6, 30.8 ppm; IR (thin film) 3058, 2951, 1745, 1652, 1597, 1507, 1456, 1427, 1249, 1227, 1177, 1162, 1022, 974, 863, 843, 731, 693 cm−1; HRMS (ESI+) calcd for C33H29N3NaO4 m/z (M + Na) 554.2056, found 554.2061. Benzyl 5-((Z)-Benzylidene)-3-methyl-4-phenyl-2-((3-(trifluoromethyl)benzoyl)imino)imidazolidine-1-carboxylate (19d) Prepared according to general procedure C using 18a and 3-trifluoromethylbenzoyl chloride, with purification using silica gel eluting with 3:2 hexanes/EtOAc to give 19d as a light brown foam (0.12 g, 87%): Rf = 0.31 (3:2 hexanes/EtOAc); 1H NMR (CDCl3, 500 MHz) δ 8.47 (s, 1H), 8.37 (d, J = 8.0 Hz, 1H), 7.74 (d, J = 8.0 Hz, 1H), 7.55 (t, J = 7.5 Hz, 1H), 7.42 (m, 4H), 7.34 (m, 2H), 7.26 (m, 3H), 7.19 (d, J = 7.0 Hz, 2H), 7.15 (t, J = 7.5 Hz, 2H), 6.78 (d, J = 7.0 Hz, 2H), 5.80 (s, 1H), 5.20 (s, 1H), 4.69 (d, J = 11.8 Hz), 4.64 (d, J = 11.8 Hz), 2.95 (s, 3H) ppm; 13C NMR (CDCl3, 125 MHz) δ 173.6, 155.1, 144.3, 138.1, 136.7, 135.4, 134.4, 133.9, 133.1, 130.6 (q, JCF = 32.4 Hz), 128.8, 128.7, 128.5, 128.5, 128.4, 128.3, 128.2 (q, JCF = 2.8 Hz), 128.0, 127.7, 126.8 (q, JCF = 3.6 Hz), 124.3 (q, JCF = 270.5 Hz), 117.4, 69.2, 67.3, 30.8 ppm; IR (thin film) 1699, 1652, 1616, 1325, 1259, 1166, 1121, 1070, 998, 920, 855, 817, 758, 692 cm−1; HRMS (ESI+) calcd for C33H26F3N3NaO3 m/z (M + Na) 592.1824, found 592.1821. Benzyl 5-((Z)-Benzylidene)-2-(isobutyrylimino)-3-methyl-4-phenylimidazolidine-1-carboxylate (19e) Prepared according to general procedure C using 18a and isobutyryl chloride, with purification using silica gel eluting with 3:2 hexanes/EtOAc to give 19e as a light brown foam (38 mg, 92%): Rf = 0.34 (3:2 hexanes/EtOAc); 1H NMR (CDCl3, 500 MHz) δ 7.42−7.35 (m, 3H), 7.29−7.15 (m, 10H), 6.86 (d, J = 7.0 Hz, 2H), 5.72 (d, J = 2.0 Hz, 1H), 5.07 (d, J = 2.0 Hz, 1H), 4.74 (d, J = 12.3 Hz), 4.69 (d, J = 12.3 Hz), 2.81 (s, 3H), 2.71 (m, 1H), 1.26 (d, J = 7.0 Hz, 6H) ppm; 13C NMR (CDCl3, 125 MHz) δ 187.6, 150.2, 149.5, 137.1, 135.6, 134.7, 134.1, 129.5, 128.6, 128.4, 128.3, 127.8, 127.6, 116.6, 68.8, 67.1, 38.8, 30.6, 20.0 ppm; IR (thin film) 3030, 2966, 2360, 2340, 1743, 1653, 1598, 1494, 1455, 1403, 1378, 1345, 1261, 1175, 1121, 1080, 1023, 977, 919, 847, 820, 752, 730, 695, 668, 634, 598, 557 cm−1; HRMS (ESI+) calcd for C29H29N3NaO3 m/z (M + Na) 490.2107, found 490.2103 (M + Na). Benzyl 5-((Z)-Benzylidene)-3-methyl-2-((2-methylbutanoyl)-imino)-4-phenylimidazolidine-1-carboxylate (19f) Prepared according to general procedure C using 18a and 2-methylbutyryl chloride, with purification using silica gel eluting with 3:2 hexanes/EtOAc to give 19f as a light brown foam (57 mg, 70%): Rf = 0.39 (3:2 hexanes/EtOAc); 1H NMR (CDCl3, 500 MHz) δ 7.42−7.12 (m, 13H), δ 6.86 (d, J = 7.5 Hz, 2H), 5.72 (d, J = 2.0 Hz, 1H), 5.08 (d, J = 2.0 Hz, 1H), 4.77−4.66 (m, 2H), 2.81 (s, 3H), 2.53 (m, 1H), 1.87 (m, 1H), 1.55 (m, 1H), 1.23 (d, J = 7 Hz, 3H), 1.01 (t, J = 6.5 Hz, 3H) ppm; 13C NMR (CDCl3, 125 MHz) δ 186.8, 150.6, 149.6, 137.3, 137.1, 135.6, 134.7, 134.3, 134.1, 129.5, 129.4, 128.5, 128.4, 128.3, 127.9, 127.8, 127.5, 116.4, 68.8, 45.8, 30.7, 27.6, 16.8, 12.1 ppm; IR (thin film) 3031, 2963, 2931, 2873, 1744, 1653, 1597, 1494, 1456, 1403, 1375, 1264, 1175, 1113, 1080, 1039, 978, 908, 752, 730, 695, 668, 633, 588 cm−1; HRMS (ESI+) calcd for C30H31N3NaO3 m/z (M + Na) 504.2263, found 504.2275. Benzyl 5-((Z)-Benzylidene)-2-((2-fluorobenzoyl)imino)-3-methyl-4-phenylimidazolidine-1-carboxylate (19g) Prepared according to general procedure C using 18a and 2-fluorobenzoyl chloride, with purification using silica gel eluting with 3:2 hexanes/EtOAc to give 19g as a light brown foam (120 mg, 95%): Rf = 0.28 (3:2 hexanes/EtOAc); 1H NMR (CDCl3, 500 MHz) δ 7.99 (t, J = 8.0 Hz, 1H), 7.50−7.34 (m, 4H), 7.34−7.29 (m, 2H), 7.21−7.07 (m, 8H), 6.99 (d, J = 8.0 Hz, 2H), 6.84 (d, J = 7.0 Hz), 5.71 (d, J = 2.0 Hz, 1H), 5.17 (d, J = 2.0 Hz, 1H), 4.75 (d, J = 11.8 Hz), 4.54 (d, J = 11.8 Hz), 2.93 (s, 3H) ppm; 13C NMR (CDCl3, 125 MHz) δ 172.3, 161.3 (d, JCF = 423.0 Hz), 151.5, 149.3, 136.7, 135.2, 134.4, 133.9, 132.6, 132.5, 134.4, 129.4, 128.7, 128.4, 128.3, 128.0, 127.9, 127.5, 125.9 (d, JCF = 16.6 Hz), 123.8 (d, JCF = 6.6 Hz), 117.2, 116.5 (d, JCF = 38.4 Hz), 69.0, 67.9, 30.5 ppm; IR (thin film) 3031, 1745, 1596, 1483, 1404, 1378, 1316, 1280, 1263, 1223, 1179, 1157, 1111, 1081, 1023, 974, 909, 866, 782, 755, 732, 696, 655 cm−1; HRMS (ESI+) calcd for C32H26FN3NaO3 m/z (M + Na) 542.1856, found 542.1865. Benzyl 5-((Z)-Benzylidene)-2-((2-fluorobenzoyl)imino)-4-(4-methoxyphenyl)-3-methylimidazolidine-1-carboxylate (19h) Prepared according to general procedure C using 18b and 2-fluorobenzoyl chloride, with purification using silica gel eluting with 3:2 hexanes/EtOAc to give 19h a light brown foam (0.98 g, 83%): Rf = 0.25 (3:2 hexanes/EtOAc); 1H NMR (CDCl3, 300 MHz) δ 7.99 (t, J = 6 Hz, 1H), 7.44 (m, 1H), 7.24−7.05 (m, 10H), 6.99−6.83 (m, 5H), 5.69 (d, J = 1.8 Hz, 1H), 5.15 (d, J = 1.8 Hz, 1H), 4.77 (d J = 19.8 Hz), 4.64 (d, J = 19.8 Hz), 3.82 (s, 3H), 2.89 (s, 3H) ppm; 13C NMR (CDCl3, 125 MHz) δ 161.3 (d, JCF = 253.4 Hz), 160.4, 151.5, 149.4, 135.3, 134.4, 134.3, 132.7, 132.6, 129.4, 128.8, 128.4, 128.3, 128.0, 127.5, 123.8 (d, JCF = 4.0 Hz), 117.1, 116.5 (d, JCF = 23.0 Hz), 114.8, 69.0, 66.6, 55.4, 30.4 ppm; IR (thin film) 2933, 2834, 2790, 109, 1584, 1508, 1488, 1462, 1440, 1301, 1243, 1171, 1095, 1031, 956, 913, 829, 783, 754, 727, 689, 660, 634, 618, 573, 547, 524 cm−1; HRMS (ESI+) calcd for C33H28FN3NaO4 m/z (M + Na) 572.1962, found 572.1980. Benzyl 5((Z)-benzylidene)-4-(4-methoxyphenyl)-3-methyl-2-((3-(trifluoromethyl)benzoyl)imino)imidazolidine-1-carboxylate (19i) Prepared according to general procedure C using 18b and 3-trifluoromethylbenzoyl chloride, with purification using silica gel eluting with 3:2 hexanes/EtOAc to give 19i as a light brown foam (95%): Rf = 0.25 (3:2 hexanes/EtOAc); 1H NMR (CDCl3, 1 MHz) δ 8.46 (s, 1H), 8.36 (d, J = 9.5 Hz, 1H), 7.73 (d, J = 9.0 Hz, 1H), 7.55 (t, J = 10.0 Hz, 1H), 7.27−7.10 (m, 10), 6.93 (d, J = 10.5 Hz, 2H), 6.78 (d, J = 9.5 Hz, 2H), 5.77 (s, 1H), 5.18 (s, 1H), 4.70 (d, J = 14.5 Hz), 4.62 (d, J = 14.5 Hz), 3.89 (s, 3H), 2.92 (s, 3H) ppm; 13C NMR (CDCl3, 125 MHz) δ 173.3, 160.4, 152.8, 149.1, 137.9, 135.3, 134.0, 132.8, 130.3 (q, JCF = 24.7 Hz), 129.3, 128.5, 128.3, 128.3, 128.2, 128.1, 127.9, 127.5, 126.5 (q, JCF = 2.9 Hz), 124.2 (q, JCF = 203.2 Hz), 117.0, 114.7, 68.9, 66.7, 55.4, 30.4 ppm; IR (thin film) 1775, 1739, 1670, 1608, 1514, 1383, 1323, 1252, 1172, 1127, 1072, 1030, 770 cm−1; HRMS (ESI+) calcd for C34H28F3N3NaO4 m/z (M + Na) 622.1930, found 622.1927. General Procedure D: Deprotection with Isomerization of 19 to 20 N-(4-Benzyl-1-methyl-5-phenyl-1H-imidazol-2(3H)-ylidene)benzamide (20a) In a 5 mL test tube containing a magnetic stir bar were added 19a (84 mg, 0.17 mmol), Pd/C (10% w/w, 9 mg), and distilled MeOH (2 mL) under a stream of N2. The reaction tube was then sealed in a pressure vessel and purged with H2 three times. The pressure vessel was then charged with H2 at 60 psi, and the reaction was stirred at room temperature for 24 h. After releasing the H2 from the pressure vessel, the solution was filtered with a nonpolar syringe filter followed by addition of 5 mL of hot methanol to wash the filter. The filtrate was concentrated via rotary evaporation under reduced pressure, and the resulting material was purified via flash chromatography (3:2 hexanes/EtOAc) to yield 20a as a light brown foam (44 mg, 72%): Rf = 0.47 (3:2 hexanes/EtOAc); 1H NMR (CDCl3, 500 MHz) δ 8.28 (d, J = 8.5 Hz, 2H), 7.51−7.46 (m, 8H), 7.36−7.26 (m, 2H), 7.18−7.09 (m, 3H), 3.80 (s, 2H), 3.50 (s, 3H) ppm; 13C NMR (CDCl3, 125 MHz) δ 170.9, 137.9, 137.2, 132.8, 132.6, 130.6, 130.2, 129.7, 129.4, 129.2, 128.9, 128.6, 128.5, 127, 34.6, 31 ppm; IR (thin film) 1695, 1653, 1601, 1560, 1494, 1472, 1452, 1379, 1314, 1269, 1025, 765, 742, 700, 658 cm−1; HRMS (ESI+) calcd for C24H22N3O m/z (M + H) 368.1763, found 368.1768. N-(4-Benzyl-5-(4-methoxyphenyl)-1-methyl-1H-imidazol-2(3H)-ylidene)benzamide (20b) Prepared according to general procedure D using 19b, with purification using silica gel eluting with 3:2 hexanes/EtOAc to give 20b as a light brown foam (9.7 mg, 84%): Rf = 0.47 (3:2 hexanes/EtOAc); 1H NMR (CDCl3, 500 MHz) δ 8.27 (d, J = 7.0 Hz, 2H), 7.45−7.40 (m, 3H), 7.32−7.27 (m, 4H), 7.22 (m, 1H), 7.15 (d, J = 7.5 Hz, 2H), 7.01 (d, J = 9.0 Hz, 2H), 3.86 (s, 3H), 3.83 (s, 2H), 3.49 (s, 3H) ppm; 13C NMR (CDCl3, 125 MHz) δ 160.5, 138.7, 131.9, 130.8, 129.2, 128.9, 128.4, 128.1, 127.2, 124.5, 120.0, 114.8, 55.7, 32.4, 31.0 ppm; IR (thin film) 3061, 2933, 1675, 1636, 1566, 1541, 1494, 1464, 1453, 199, 1350, 1288, 1246, 1174, 1108, 1025, 1004, 906, 832, 718, 709, 645, 593 cm−1; HRMS (ESI+) calcd for C25H23N3NaO2 m/z (M + Na) 420.1688, found 420.1698. N-(4-Benzyl-1-methyl-5-phenyl-1,3-dihydro-2H-imidazol-2-ylidene)-4-methoxybenzamide (20c) Prepared according to general procedure D using 19c, with purification using silica gel eluting with 3:2 hexanes/EtOAc to give 20c as a light brown foam (46 mg, 62%): Rf = 0.29 (3:2 hexanes/EtOAc); 1H NMR (CDCl3, 500 MHz) δ 8.30 (d, J = 9.0 Hz, 2H), 7.48−7.44 (m, 3H), 7.31−7.27 (m, 2H), 7.10−7.02 (m, 3H), 7.00−6.95 (m, 4H), 3.85 (s, 3H), 3.60 (s, 2H), 3.48 (s, 3H) ppm; 13C NMR (CDCl3, 125 MHz) δ 163.3 137.8, 131.4, 130.5, 129.7, 129.3, 128.9, 128.4, 127.3, 126.9, 113.9, 55.7, 32.9, 30.8 ppm; IR (thin film) 2858, 1678, 1603, 1573, 1514, 1494, 1453, 1401, 1348, 1311, 1176, 1027, 846, 766 cm−1; HRMS (ESI+) calcd for C25H23N3NaO2 m/z (M + Na) 420.1688, found 420.1688. N-(4-Benzyl-1-methyl-5-phenyl-1,3-dihydro-2H-imidazol-2-ylidene)-3-(trifluoromethyl)benzamide (20d) Prepared according to general procedure D using 19d, with purification using silica gel eluting with 3:2 hexanes/EtOAc to give 20d a light brown foam (123 mg, 87%): Rf = 0.76 (3:2 hexanes/EtOAc); 1H NMR (CDCl3, 500 MHz) δ 8.55 (s, 1H), 8.43 (d, J = 7.5 Hz, 1H), 7.68 (d, J = 7.5 Hz, 1H), 7.53−7.48 (m, 4H), 7.40−7.37 (m, 2H), 7.32−7.29 (m, 2H), 7.26−7.24 (m, 1H), 7.15 (d, J = 8.0 Hz, 2H), 3.87 (s, 2H), 3.54 (s, 3H) ppm; 13C NMR (CDCl3, 125 MHz) δ 173.3, 150.8, 139.5, 137.3, 132.1, 120.5, 129.5, 129.3, 129.2, 128.5, 128.4, 127.7, 127.3, 127.2 (q, JCF = 3.8 Hz), 125.9 (q, JCF = 3.8 Hz), 124.8, 120.6, 95.0, 30.8, 30.3 ppm; IR (thin film) 3062, 1598, 1568, 1471, 1362, 1315, 1276, 1216, 1162, 1117, 1084, 1067, 907, 795, 763, 726 cm−1; HRMS (ESI+) calcd for C25H21N3OF3 m/z (M + H) 436.1637, found 436.1639. N-(4-Benzyl-1-methyl-5-phenyl-1H-imidazol-2(3H)-ylidene)-isobutyramide (20e) Prepared according to general procedure D using 19e, with purification using silica gel eluting with 3:2 hexanes/EtOAc to give 20e as a light brown foam (24 mg, 74%): Rf = 0.50 (3:2 hexanes/EtOAc); 1H NMR (CDCl3, 500 MHz) δ 7.42−7.39 (m, 3H), 7.33 (d, J = 8.0 Hz, 2H), 7.24−7.20 (m, 3H), 7.13 (d, J = 8.0 Hz 2H), 3.83 (s, 2H), 3.31 (s, 3H), 2.49 (m, 1H), 1.13 (d, J = 7.0 Hz, 6H) ppm; 13C NMR (CDCl3, 125 MHz) δ 140.3, 130.2, 129.7, 129.0, 128.6, 128.5, 128.4, 126.2, 35.7, 32.9, 31.8, 19.8 ppm; IR (thin film) 3028, 2968, 2873, 1653, 1602, 1540, 1506, 1494, 1466, 1456, 1437, 1399, 1383, 1312, 1221, 1190, 1156, 1098, 1014, 950, 910, 867, 725, 697 cm−1; HRMS (ESI+) calcd for C21H23N3O m/z (M + Na) 356.1739, found 356.1743 (M + H). N-(4-Benzyl-1-methyl-5-phenyl-1H-imidazol-2(3H)-ylidene)-2-methylbutanamide (20f) Prepared according to general procedure D using 19f, with purification using silica gel eluting with 3:2 hexanes/EtOAc to give 20f as a light brown foam (33 mg, 80%): Rf = 0.44 (3:2 hexanes/EtOAc); 1H NMR (CDCl3, 500 MHz) δ 7.42−7.39 (m, 3H), 7.29 (d, J = 8.0 Hz, 2H), 7.24−7.20 (m, 3H), 7.05 (d, J = 8.0 Hz 2H), 3.77 (s, 2H), 3.30 (s, 3H), 2.43 (m, 1H), 1.69 (m, 1H), 1.41 (m, 1H), 1.10 (d, 7.0 Hz, 3H), 0.87 (t, J = 7.0 Hz, 3H) ppm; 13C NMR (CDCl3, 125 MHz) δ 139.9, 130.3, 129.1, 128.8, 128.6, 128.5, 42.8, 32.3, 27.2, 17.7, 11.1 ppm; IR (thin film) 2835, 1609, 1583, 1508, 1488, 1442, 1419, 1301, 1244, 1169, 1126, 1107, 1069, 1033, 994, 962, 917, 850, 807, 778, 754, 690, 584 cm−1; HRMS (ESI+) calcd for C22H25N3O m/z (M + H) 348.2076, found 348.2082 (M + H). N-(4-Benzyl-1-methyl-5-phenyl-1H-imidazol-2(3H)-ylidene)-2-fluorobenzamide (20g) Prepared according to general procedure D using 19g, with purification using silica gel eluting with 3:2 hexanes/EtOAc to give a light brown (7.1 mg, 89%): Rf = 0.82 (3:2 hexanes/EtOAc); 1H NMR (CDCl3, 500 MHz) δ 8.08 (dt, J = 2.0, 8.0 Hz, 1H), 7.49 (m, 3H), 7.38 (m, 3H), 7.28 (m, 2H), 7.21 (m, 2H), 7.16 (m, 2H), 7.10 (m, 1H), 3.85 (s, 2H), 3.49 (s, 3H) ppm; 13C NMR (CDCl3, 125 MHz) δ 161.7 (d, JCF = 252.4 Hz), 137.8, 132.4 (d, JCF = 8.1 Hz), 131.9, 130.5, 129.4, 129.3, 129.1, 128.5, 128.0, 127.1, 125.6, 123.9 (d, JCF = 3.6 Hz), 116.7 (d, JCF = 23.2 Hz), 113.3, 31.2, 30.8 ppm; IR (thin film) 3029, 1683, 1560, 1494, 1452, 1350, 1286, 1259, 1222, 1135, 1127, 1075, 1054, 1030, 1014, 967, 817, 755, 725, 696, 643 cm−1; HRMS (ESI+) calcd for C24H21FN3O m/z (M + H) 386.1669, found 386.1677. N-(4-Benzyl-5-(4-methoxyphenyl)-1-methyl-1H-imidazol-2(3H)-ylidene)-2-fluorobenzamide (20h) Prepared according to general procedure D using 19h, with purification using silica gel eluting with 3:2 hexanes/EtOAc to give a light brown foam (13 mg, 81%): Rf = 0.41 (3:2 hexanes/EtOAc); 1H NMR (CDCl3, 500 MHz) δ 8.07 (t, J = 8.0 Hz, 2H), 7.34 (m, 1H), 7.32−7.27 (m, 4H), 7.21 (t, J = 8.5 Hz, 1H), 7.19−7.16 (m, 3H), 7.08 (t, J = 9.5 Hz, 1H), 7.00 (d, J = 8.5 Hz, 2H), 3.86 (s, 3H), 3.81 (s, 2H), 3.44 (s, 3H) ppm; 13C NMR (CDCl3, 125 MHz) δ 171.8, 162.5 (d, JCF = 253.4 Hz), 160.2, 148.7, 137.8, 131.8, 131.7 (d, JCF = 1.9 Hz), 131.6, 128.8, 128.2, 126.8, 126.4, 124.8, 123.6 (d, JCF = 3.8 Hz), 119.9, 116.5 (d, JCF = 22.9 Hz), 114.5, 55.4, 31.0, 30.1 ppm; IR (thin film) 2929, 2360, 2340, 1684, 1569, 1511, 1494, 1455, 1401, 1339, 1290, 1248, 1176, 1032, 834, 815, 757, 731, 696, 667 cm−1; HRMS (ESI+) calcd for C25H22FN3NaO2 m/z (M + Na) 438.1594, found 438.1601. N-(4-Benzyl-5-(4-methoxyphenyl)-1-methyl-1H-imidazol-2(3H)-ylidene)-3-(trifluoromethyl)benzamide (20i) Prepared according to general procedure D using 19i, with purification using silica gel eluting with 3:2 hexanes/EtOAc to give a light brown foam (99 mg, 53% yield): Rf = 0.76 (3:2 hexanes/EtOAc); 1H NMR (CDCl3, 300 MHz) δ 8.54 (s, 1H), 8.42 (d, J = 7.8 Hz, 1H), 7.67 (d, J = 7.2 Hz, 1H), 7.50 (t, J = 8.4 Hz, 1H), 7.32−7.23 (m, 5H), 7.15 (d, J = 6.9 Hz, 2H), 7.03 (d, J = 9.0 Hz, 2H), 3.87 (s, 3H), 3.84 (s, 2H), 3.50 (s, 3H) ppm; 13C NMR (CDCl3, 125 MHz) δ 173.0, 160.3, 150.5, 139.4, 137.3, 131.9, 131.6, 130.1 (q, JCF = 32.2 Hz), 129.0, 128.2, 128.1, 127.0, 126.9 (q, JCF = 3.8 Hz), 125.7 (q, JCF = 3.8 Hz), 124.3 (q, JCF = 270.4 Hz), 120.0, 119.4, 114.6, 55.4, 30.5, 29.9 ppm; IR (thin film) 1569, 1512, 1466, 1363, 1317, 1278, 1249, 1217, 1165, 1121, 1069, 1034, 906, 834, 768, 725 cm−1; HRMS (ESI+) calcd for C26H22F3N3NaO2 m/z (M + Na) 488.1562, found 488.1559. Supplementary Material SI R.E.L. thanks the NIH, General Medical Sciences (R01 GM090082, P41 GM08915), Cu̅rza, Amgen, and Eli Lilly for financial support. B.E.W. thanks the NIH, National Cancer Institute (R01 CA140296), for funding. We thank Dr. Atta Arif (U. of U. Chemistry) for help with X-ray crystallography studies. We thank John Sullivan and Richard Nkansah for exploratory work on this project. Figure 1 Representative Leucetta alkaloids. Figure 2 X-ray structures of 18b and 20h. Figure 3 Antiproliferative effects of naamidine A and 20h. Scheme 1 First Generation Synthesis of Naamidine A and Analogues Scheme 2 Synthesis of Naamidine A (6) Scheme 3 Generation of N2-Acyl Naamidine A Analogues Scheme 4 Generation of N2-Acyl-2-aminoimidazoles Supporting Information The Supporting Information is available free of charge on the ACS Publications website at DOI: 10.1021/acs.joc.5b01703. X-ray data for 18b (CIF) X-ray data for 20h (CIF) X-ray crystallography data for compounds 18b and 20h. 1H and 13C NMR spectra for all compounds (PDF) Elemental composition report (PDF) Notes The authors declare no competing financial interest. 1 (a) Sullivan JD Giles RL Looper RE Curr Bioact Compd 2009 5 39 78 (b) Koswatta PB Lovely CJ Nat Prod Rep 2011 28 511 528 20981389 (c) Roué M Quévrain E Domart-Coulon Bourguet-Kondracki M-L Nat Prod Rep 2012 29 739 751 22660834 2 Dunbar DC Rimoldi JM Clark AM Kelly M Hamann MT Tetrahedron 2000 56 8795 8798 3 Crews P Clark DP Tenney K J Nat Prod 2003 66 2 177 182 12608847 4 Gibbons JB Gligorich KM Welm BE Looper RE Org Lett 2012 14 4734 4737 22966873 5 Das J Bhan A Mandal SS Lovely CJ Bioorg Med Chem Lett 2013 23 6183 6187 24076171 6 Gross H Kehraus S Konig GM Woerheide G Wright AD J Nat Prod 2002 65 1190 1193 12193030 7 Chan GW Mong S Hemling ME Freyer AJ Offen PH DeBrosse CW Sarau HM Westley JW J Nat Prod 1993 56 116 121 8383730 8 Copp BR Fairchild CR Cornell L Casazza AM Robinson S Ireland CM J Med Chem 1998 41 3909 3911 9748366 9 James RD Jones DA Aalbersberg W Ireland CM Mol Cancer Ther 2003 2 747 751 12939464 10 LaBarbera DV Modzelewska K Glazar AI Gray PD Kaur M Liu T Grossman D Harper MK Kuwada SK Moghal N Ireland CM Anti-Cancer Drugs 2010 20 425 436 11 Ohta S Tsuno N Nakamura S Taguchi N Yamashita M Kawasaki I Fujieda M Heterocycles 2000 53 1939 1955 12 (a) Aberle NS Lessene G Watson KG Org Lett 2006 8 419 421 16435849 (b) Aberle N Catimel J Nice EC Watson KG Bioorg Med Chem Lett 2007 17 3741 3748 17462892 13 Ermolat’ev DS Bariwal JB Steenackers HPL De Keersmaecker SCJ Van der Eycken EV Angew Chem, Int Ed 2010 49 9465 4968 14 Gainer MJ Bennett NR Takahashi Y Looper RE Angew Chem, Int Ed 2011 50 684 687 15 Das J Koswatta PB Jones JD Yousufuddin M Lovely CJ Org Lett 2012 14 6210 6213 23215346 16 Su Z Peng L Melander C Tetrahedron Lett 2012 53 1204 1206 17 Giles RL Sullivan JD Steiner AM Looper RE Angew Chem, Int Ed 2009 48 3116 3120 18 Zhang N Zhang Z Wong ILK Wan S Chow LMC Jiang T Eur J Med Chem 2014 83 74 83 24952376 19 For leading references, see: (a) Wei C Li Z Li CJ Synlett 2004 1472 1483 (b) Zani L Bolm C Chem Commun 2006 4263 4275 (c) Li CJ Acc Chem Res 2010 43 581 590 20095650 (d) Koradin C Polborn K Knochel P Angew Chem, Int Ed 2002 41 2535 2538 (e) Gommermann N Koradin C Polborn K Knochel P Angew Chem, Int Ed 2003 42 5763 5766 20 Genêt JP Blart E Savignac M Lemeune S Lemaire-Audoire S Bernard JM Synlett 1993 1993 680 682 21 (a) Looper RE Haussener TJ Mack JBC J Org Chem 2011 76 6967 6971 21732649 (b) Kwon K Haussener TJ Looper RE Org Synth 2015 92 91 102 27812231 22 Gligorich KM Vaden RM Shelton DN Wang G Matsen CB Looper RE Sigman MS Welm BE Breast Cancer Res 2013 15 4 R58 23879992
PMC005xxxxxx/PMC5117190.txt
LICENSE: This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. 8610640 104 J Bone Miner Res J. Bone Miner. Res. Journal of bone and mineral research : the official journal of the American Society for Bone and Mineral Research 0884-0431 1523-4681 24839202 5117190 10.1002/jbmr.2282 NIHMS788576 Article IGFBP-2 directly stimulates osteoblast differentiation Xi Gang Ph.D. 1 Wai Christine B.S. 1 DeMambro Victoria M.S. 2 Rosen Clifford J M.D. 2 Clemmons David R M.D. 1* 1 Department of Medicine, University of North Carolina at Chapel Hill 2 Maine Medical Center Research Institute * Address all correspondence and requests for reprints to: David R. Clemmons, M.D, CB7170, 8024 Burnett Womack, University of North Carolina, Chapel Hill, North Carolina 27599-7170, david_clemmons@med.unc.edu. Tel: (919) 966-4735, Facsimile: (919) 966-6025 6 7 2016 11 2014 21 11 2016 29 11 24272438 This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. Insulin like growth factor binding protein two (IGFBP-2) is important for acquisition of normal bone mass in mice; however, the mechanism by which IGFBP-2 functions is not defined. These studies investigated the role of IGFBP-2 in stimulating osteoblast differentiation. MC-3T3 preosteoblasts expressed IGFBP-2, and IGFBP-2 knockdown resulted in a substantial delay in osteoblast differentiation, reduced osteocalcin expression and Alizarin red staining. These findings were replicated in primary calvarial osteoblasts obtained from IGFBP-2 −/− mice and addition of IGFBP-2 rescued the differentiation program. In contrast, overexpression of IGFBP-2 accelerated the time course of differentiation as well as increasing the total number of differentiating cells. By day 6 IGFBP-2 overexpressing cells expressed twice as much osteocalcin as control cultures and this difference persisted. To determine the mechanism by which IGFBP-2 functions, the interaction between IGFBP-2 and receptor tyrosine phosphatase β (RPTPβ) was examined. Disruption of this interaction inhibited the ability of IGFBP-2 to stimulate AKT activation and osteoblast differentiation. Knockdown of RPTPβ enhanced osteoblast differentiation whereas overexpression of RPTPβ was inhibitory. Adding back IGFBP-2 to RPTPβ overexpressing cells was able to rescue cell differentiation via enhancement of AKT activation. To determine the region of IGFBP-2 that mediated this effect an IGFBP-2 mutant that contained substitutions of key amino acids in the heparin binding domain-1 (HBD-1) was prepared. This mutant had a major reduction in its ability to stimulate differentiation of calvarial osteoblasts from IGFBP-2 −/− mice. Addition of a synthetic peptide that contained the HBD-1 sequence to calvarial osteoblasts from IGFBP-2 −/− mice rescued differentiation and osteocalcin expression. In summary, the results clearly demonstrate that IGFBP-2 stimulates osteoblast differentiation and that this effect is mediated through its heparin binding domain-1 interacting with RPTPβ. The results suggest that stimulation of differentiation is an important mechanism by which IGFBP-2 regulates the acquisition of normal bone mass in mice. IGFBP-2 Osteoblast differentiation pAKT PTEN RPTPβ Introduction IGFBP-2 is a member of a family of six IGF binding proteins. Although a major function of this class of proteins is to transport the IGFs through the circulation and extracellular fluids, thereby restricting their access to receptors, each form of binding protein has been found to have distinct actions.(1) Initial studies showed that IGFBP-2 can enhance the effect of IGF-II to stimulate alkaline phosphatase in bone cell cultures.(2) When IGFBP-2 gene expression was deleted in mice, tibial bone volume was reduced and both micro CT and pQCT analysis showed diminished trabecular number and volume.(3) A subsequent study defined a 13 amino acid region of IGFBP-2 (termed HBD-1) that was required for biologic activity. Substitution of key residues within this region resulted in loss of the ability of IGFBP-2 to stimulate osteoblast proliferation in vitro.(4) Importantly when a synthetic peptide containing the HBD-1 sequence was injected into the IGFBP-2 −/− mice, micro CT analysis showed that trabecular volume and density could be rescued.(4) Furthermore this peptide was shown to stimulate osteoblast proliferation in vivo. Prior studies have suggested that IGF-I and IGFBP-2 play a role in osteoblast differentiation. Cell type specific deletion of IGF-I in osteoblasts resulted in decreased femoral BMD and decreased bone formation rate.(5) Some studies have suggested a correlation between IGFBP-2 and osteoblast differentiation. During induction of differentiation in the osteoblast sheets, analysis of gene expression profiles showed that IGFBP-2 is one of the genes that showed the greater increase.(6) PTH increases IGFBP-2 expression in differentiated osteoblasts.(7) Finally mesenchymal stromal cells can be made to further differentiate into osteoblasts with dexamethasone and this requires the interaction of the α5 integrin and IGFBP-2.(8) Although recent studies have documented the importance of the HBD-1 domain of IGFBP-2 for osteoblast growth, the relative importance of this domain for osteoblast differentiation has not been determined. A recent study demonstrated that the HBD-1 region bound directly to a cell surface receptor termed receptor tyrosine phosphatase β and that RPTP-β was expressed by MC-3T3 cells.(9) It further demonstrated that IGFBP-2 binding to this receptor induced RPTPβ dimerization which inhibited its phosphatase activity. Since the primary substrate of this phosphatase was shown to be PTEN, subsequent analysis showed that engagement of this receptor on osteoblast surfaces resulted in enhanced tyrosine phosphorylation of PTEN which inhibited its activity. This was associated with increased AKT activation. These data imply that IGFBP-2 may be functioning directly to augment constitutive AKT activation in osteoblasts. Since AKT activation has been linked to osteoblast differentiation(10), the current studies were undertaken to determine if IGFBP-2 could directly stimulate osteoblast differentiation, if it was functioning through interaction with RPTPβ and if this interaction was mediated through the HBD-1 domain. Materials and Methods Human IGF-I was a gift from Genentech (South San Francisco, CA). Immobilon-P membrane, LY294002 and PD98059 were purchased from EMDmillipore Corp. (Billerica, MA). α-MEM, streptomycin and penicillin were purchased from Life Technologies (Grand Island, NY). Anti-RPTPβ antibody was purchased from BD Bioscience (San Diego, CA). Antibodies against phospho-AKT (S473), pErk1/2, cleaved caspase-3 and PTEN were purchased from Cell Signaling Technology Inc. (Beverly, MA). Anti-phospho-tyrosine (PY99), osteocalcin, β-actin antibodies were purchased from Santa Cruz Biotechnology, Inc. (Santa Cruz, CA). PQ401 was purchased from TOCRIS bioscience (Bristol, United Kindom). IGFBP-2 antiserum was prepared as previously described.(11) The horseradish peroxidase-conjugated mouse anti-rabbit, goat anti-mouse, and mouse anti-rabbit light chain-specific antibodies were purchased from Jackson ImmunoResearch Laboratories (West Grove, PA). All other reagents were obtained from Sigma unless otherwise stated. The synthetic peptide containing the linker located heparin-binding domain of IGFBP-2 (188KHLSLEEPKKLRP200) (referred to as HBD-1 peptide) and a scrambled HBD peptide (CKPLRLSKEEHPLK) (referred to as HBD control peptide), were synthesized by the Protein Chemistry Core Facility at the University of North Carolina at Chapel Hill. Purity and the sequences were confirmed by mass spectrometry. Mice Generation of the original mixed background strain B6;129-Igfbp2<tm1Jep>, which we refer to as Igfbp2−/− mice, has been described previously.(3) The original mice were backcrossed onto C57BL/6J background for 10 generations. Igfbp2+/+ mice were C57BL/6J controls. All of the experimental studies were performed with male mice. All of the animal studies were reviewed and approved by the Institutional Animal Care and Use Committee of University of North Carolina at Chapel Hill. Cell culture MC-3T3 E1 clone 4 (CL4) cells were obtained from ATCC (Manassas, VA). Cells were cultured in α-MEM (glucose 1000mg/L) containing 10% fetal bovine serum (Thermo Fishers Scientific, Pittsburgh, PA). After confluency, culture medium was changed to differentiation medium (DM) which contained 10% fetal bovine serum plus 50 ug/ml ascorbic acid and 4 mM β-glycerol phosphate. Fresh DM was applied every 72 hr. IGFBP-2 (1 ug/ml), HBD-1 (1ug/ml or as stated), control peptide (1ug/ml) or HBD mutant IGFBP-2 (1 ug/ml) were added to the differentiation medium, and replaced every 72 hr. Neonatal calvarial osteoblasts were isolated from 3–5-day-old mice. Briefly, calvariae were digested five times with collagenase type 2 (250 unit/ml) and trypsin (0.05%) plus EDTA (0.02%) in the PBS. The cells released from digests 2–5 were collected as primary calvarial osteoblasts and maintained in DMEM (glucose 1000 mg/L) supplemented with 10% FBS and nonessential amino acids. Construction of cDNAs and establishment of MC3T3 cells expressing wild type IGFBP-2, RPTPβ and LacZ Mouse IGFBP-2 cDNA was amplified from mouse pCMV-SPORT6 (ATCC, Manassas, VA) using a 5′ primer sequence corresponding to nucleotides 89 to 110 of mouse IGFBP-2 (5′-ATGCTGCCGAGATTGGGCGGCC-3′) and a 3′ primer sequence complementary to nucleotides 981 to 1003 (5′-GGGCCCATGCCCAAAGTGTGCAG-3′). After DNA sequencing to confirm that the correct sequence had been amplified, the PCR product was subcloned into pENTR/D-TOPO vector and subsequently transferred into the pLenti6-V5 DEST expression vector using the LR Clonase reaction and following the manufacturer's instructions (Life Technologies, Grand Island, NY). Constructions of RPTPβ and LacZ have been described previously.(9) The constructs contained the correct sequences was verified by DNA sequencing. 293FT cells (Life Technologies, Grand Island, NY) were prepared for generation of virus stocks and CL4 expressing IGFBP-2, RPTPβ and LacZ were established using procedures that have been described previously.(12) Construction of cDNAs and establishment of IGFBP-2 Si, RPTPβ Si and LacZ Si cells Based on Life Technologies’ website design tools, a sequence containing 21 oligonucleotides (GGAAAGAGACCAACACTGAGC) was used to construct the shRNA template plasmid to inhibit the translation of mouse IGFBP-2 mRNA. GCCAATGCATACAGCAGTAAT was used to construct the shRNA template to knock down mouse RPTPβ. The oligonucleotides were synthesized by Nucleic Acids Core Facility at UNC, annealed and ligated into BLOCK-iT™ U6 RNAi Entry Vector (Cat# K4945-00, Life Technologies, Grand Island, NY) following manufacturer’s instructions. The complete sequence was verified by DNA sequencing. The expression vector was generated using the Gateway LR recombination reaction between the Entry Vector and BLOCK-iT™ Lentiviral RNAi Gateway® Vector (Cat# K4943-00, Life Technologies, Grand Island, NY). A sequence targeting LacZ was used as a control. After confirmation of the sequence, plasmid DNA was prepared using a Plasmid Midi Kit (Promega, Madison, WI). 293FT cells (Life Technologies, Grand Island, NY) were transfected and used to prepare for generation of virus stocks.(12) CL4 cells expressing small hairpin RNA sequence targeting IGFBP-2 (IGFBP-2 Si), RPTPβ (RPTPβ Si) and corresponding control CL4 expressing small hairpin RNA sequence targeting LacZ (LacZ Si) were established using procedures described previously.(12) Immunoprecipitation and Immunoblotting The cell monolayers were lysed in a modified radioimmunoprecipitation assay (RIPA) buffer as previously described.(12) Immunoprecipitation was performed by incubating 0.5 mg of cell lysate protein with 1 ug of each of the following antibodies: anti-IGFBP-2 and PY99 at 4°C overnight. Immunoblotting was performed as previously described(12) using a dilution 1:1000 for anti-pAKT (Ser473), PTEN and β-actin antibodies, a dilution 1:500 for anti-RPTPβ antibody, a dilution 1:200 for anti-osteocalcin antibody and a dilution 1:10000 for anti-IGFBP-2 antibody. The proteins were visualized using enhanced chemiluminescence (Thermo Fisher Scientific, Rockford, IL). Total cellular protein in the lysates was determined using BCA (Thermo Fisher Scientific, Rockford, IL). Alizarin Red staining Cells were washed with PBS twice before were fixed with 10% formalin. After 10 min fixation, 1% Alizarin Red (pH 4.2) was applied and incubated for another 10 min before it was removed. Cells were washed with ddH2O twice and drying. Images were captured using Leica M420 Microscope. RNA isolation and quantitative real-time PCR Total RNA was prepared using RNeasy plus mini kit (Qiagen, Valencia, CA, USA) for cellular extracts. cDNA was then generated from 500 ng of RNA using the High Capacity cDNA Reverse Transcription Kit (Applied Biosystems) per the manufacturer’s instructions. Quantitative real-time expression analysis was run on the CFX384 Real-time System using the iQ SYBR Green Supermix and C1000 thermal Cycler (Bio-Rad, Hercules, CA, USA). Relative expression of mRNA was determined after normalization to Hprt levels using the ΔCt method. Primers were designed, sequenced and validated to be 95% to 100% efficient by Primer Design Ltd (Southampton, UK). All primer sequences are listed in Supplementary Table 1. Cell proliferation and apoptosis assay Calvarial osteoblasts isolated from IGFBP-2 −/− mice were seeded in 6 well plate. After reaching confluency the culture medium was changed to DM or DM plus HBD-1 or DM plus IGFBP-2. Control cells and IGFBP-2 overexpressing cells were plated in 24 well plates using the same plating density. After reaching confluency the culture medium was changed to DM. Fresh DM was applied every 72 hr. After cells were exposed to DM for indicated days, the cells were released with 0.05% Trypsin-EDTA and counted. To quantify apoptosis, calvarial osteoblasts isolated from IGFBP-2 −/− mice were exposed to DM alone or DM plus the different concentrations of HBD-1 peptide for 21 days. Cell lysates were harvested as described previously and immunoblotted using an anti-cleaved caspase-3 antibody. Statistical analysis Densitometry results are expressed as the mean ± standard deviation (SD). All experiments were replicated at least three times to assure reproducibility. The results were analyzed for statistically significant differences using Student’s t-test or analysis of variance followed by Bonferroni multiple comparison post hoc test. Statistical significance was set at p<0.05. Results IGFBP-2 stimulates osteoblast differentiation Since we had shown that IGFBP-2 enhances AKT activation in osteoblasts,(9) we determined if IGFBP-2 regulates osteoblast differentiation. MC-3T3 cells have been shown to secrete IGFBP-2 and its secretion increases significantly between day 6 and 9 following the addition of differentiation medium. RNAi was used to determine the significance of these changes and if inhibiting IGFBP-2 synthesis would alter differentiation (Fig 1A). Compared to control cultures the differentiation of MC-3T3 cells in which IGFBP-2 synthesis had been inhibited was significantly attenuated. Both osteocalcin expression (Fig 1B) and the number of alizarin red positive cells were reduced (Fig 1C). To confirm the importance of IGFBP-2 for differentiation of preosteoblasts, calvarial pre-osteoblasts, isolated from IGFBP-2 −/− mice were analyzed. These cells showed impaired osteocalcin expression and differentiation compared to cells from control littermates (Fig 1D) (e.g., a 2.3 ± 0.1 fold greater level of osteocalcin in control cells on day 21, compared to IGFBP-2 −/− cells, p<0.01). The time course of differentiation was prolonged in cultures from the IGFBP-2 −/− mice and only 1.8 ± 0.2% cells had completed differentiation by day 21 (Fig 1E). The addition of IGFBP-2 to these cultures restored differentiation (Fig 1E). In contrast, overexpression of IGFBP-2 in MC-3T3 cells significantly enhanced the osteocalcin expression (Fig 1G) (e.g., a 2.5 ± 0.1 fold greater level of osteocalcin on day 6 compared to control cultures, p<0.05). In addition, in IGFBP-2 overexpressing cells osteocalcin was detected on day 3 whereas it was detected on day 6 following the addition of differentiation medium in control cells (Fig 1G). Major differences in osteocalcin expression were detected at each time point and persisted up to day 21. In addition alizarin red positive cells were detected on day 6 in IGFBP-2 overexpressing cells whereas they were not detected until day 15 in control cells (Fig 1H). To confirm these results, we analyzed the expression of several genes that are important for osteoblast differentiation. As shown in supplemental figures 1 and 2, osteocalcin, alkaline phosphatase and Wnt10b were induced significantly in the IGFBP-2 overexpressing cells compared to control cells on days 6 and 9, thereby reflecting the acceleration of differentiation. Osteopontin was significantly increased at day 9. Runx2 and osterix whose expression peaks early in differentiation declined between days 3 and 9 in the control cells and were significantly decreased in the IGFBP-2 overexpression cells whereas following IGFBP-2 knockdown, their expression was increased compared to control cultures, suggesting that differentiation is delayed (Supplemental Fig 1 and 2). Overexpression of IGFBP-2 reduced the amount of serum supplementation that was necessary to induce differentiation. For example the addition of 5% serum containing differentiation medium to IGFBP-2 transfected cells induced a similar level of cell differentiation compared to control cells exposed to 10% serum (Supplemental Fig 3A). IGF-I stimulated differentiation of control and IGFBP-2 overexpressing cells but the percentage of cells that differentiated remained significantly greater in the IGFBP-2 overexpressing cells (Supplemental Figure 3B and C). These results strongly suggest that IGFBP-2 is able to stimulate preosteoblast differentiation and that it is one of the factors that is present in 10% FBS that induces these changes. AKT and PI-3 kinase activation are required for osteoblast differentiation Several sub clones of MC-3T3 cells were originally derived from mouse calvarial osteoblasts.(13) Among them: clone 4 cells (CL4 cells) were found to differentiate in the appropriate medium. Since previous studies have shown the importance of AKT activation for osteoblast differentiation(14), we determined the IGF-I-stimulated AKT activation response during differentiation. The results showed that AKT Ser473 phosphorylation was stimulated by IGF-I during differentiation phase in MC-3T3, CL4 cells (Fig 2A). A clone of MC-3T3 cells derived from the same parental cell line (CL24) is unable to differentiate. When these cells were analyzed neither basal nor IGF-I-stimulated AKT Ser473 phosphorylation could be detected after several days in differentiation medium (Fig 2A). Importantly, overexpression of IGFBP-2 enhanced IGF-I stimulated AKT activation (Fig 2A) In order to determine the time point in the differentiation cycle wherein PI-3 kinase activation was required to induce preosteoblast differentiation, the PI-3 kinase inhibitor, LY 294002, was utilized. The results show that inhibition of PI-3 kinase completely prevented differentiation when the inhibitor was applied on day 3 following the addition of differentiation medium (Fig 2B). It also significantly suppressed differentiation when it was applied on day 6. However if it was applied after day six the inhibitory effect was minimal at day 9 and completely lost by day 12 or later (Fig 2B). When this experiment was repeated using cells overexpressing IGFBP-2, differentiation was detectible and was attenuated when the inhibitor was added on day 1 or day 3 but it was not altered if the inhibitor was added at day 6 or later (Fig 2C). Since inhibition of PI-3 kinase activation prevented differentiation, we examined the time course of AKT phosphorylation at different time points during differentiation in control and IGFBP-2 overexpressing cells. AKT activation was minimal at day 3 in control cells but it was increased significantly in the overexpressing cells (Fig. 2D). (e.g., to a level that was 7.5 fold greater at day 3, p<0.001). These results are consistent with the differences in osteocalcin expression shown in Fig 1G. When AKT activation was analyzed in primary osteoblasts that were obtained from IGFBP-2 −/− mice there was a significant reduction in constitutive pAKT expression compared to cells from control +/+ animals on days 3, 6 and 9 (Fig 2E) (e.g., to a level that was 3.1 ± 0.4 fold less than osteoblasts from +/+ mice at day 9, p<0.01). Importantly the differences in constitutive AKT activation correlated with those detected in osteocalcin expression (Fig 1D). IGFBP-2 enhances AKT activation via suppressing RPTPβ dephosphorylation of PTEN Our previous study in smooth muscle cells showed that IGFBP-2 enhances IGF-I-stimulated AKT activation via direct binding of IGFBP-2 to RPTPβ which catalyzes its polymerization and thereby inhibits its ability to dephosphorylate PTEN.(9) That study also showed that MC-3T3 cells expressed RTPTβ and that IGFBP-2 exposure increased PTEN tyrosine phosphorylation. Since tyrosine phosphorylation of PTEN attenuates its ability to inhibit AKT activation, this results in an enhancement of constitutive and IGF-I-stimulated AKT phosphorylation. RPTPβ expression increases during osteoblast differentiation(15), therefore we hypothesized that IGFBP-2 enhanced AKT activation during osteoblast differentiation through this same mechanism. To test this hypothesis we first examined whether IGFBP-2 overexpression and IGF-I addition stimulated IGFBP-2/RPTPβ association during differentiation. The results showed that the formation of the IGFBP-2/RPTPβ complex was detected on day 6 in control cultures (Fig 3A). This is consistent with the level of constitutive AKT activation (Fig 2D). Following IGF-I stimulation, complex formation increased in control cells and, in cells overexpressing IGFBP-2, there was an increase in basal and IGF-I stimulated IGFBP-2/RPTPβ association on days 3 and 6 compared to control cells (Fig 3A) (e.g., 3.6 ± 0.9 fold and 2.6 ± 0.1 fold increases in IGF-I stimulated complex formation in IGFBP-2 overexpressing cells compared to LacZ cells on days 3 and 6, p<0.05, respectively). Correspondingly PTEN tyrosine phosphorylation was increased in the IGFBP-2 overexpressing cells compared to control cells on days 3 and 6 (Fig 3B). To directly determine the role of RPTPβ on osteoblast differentiation, we manipulated the RPTPβ level in MC-3T3 cells. Knockdown of RPTPβ during the differentiation phase enhanced basal and IGF-I stimulated PTEN tyrosine phosphorylation as well as AKT activation (Fig 3C) (e.g., a 2.3 ± 0.2 fold greater level of pAKT expression in RPTPβ Si cells compared to control, p<0.05). Further analysis showed that osteocalcin expression was enhanced on days 9, 12, and 21 (Fig 3D) as well as cell differentiation on days 15, 18 and 21 compared to control cultures (Fig 3E). In contrast overexpression of RPTPβ inhibited PTEN tyrosine phosphorylation (Fig 3F) and impaired osteoblast differentiation (Fig 3G). We have shown previously that IGFBP-2 binding to RPTPβ induces polymerization which inhibits its phosphatase activity. When IGFBP-2 was added back to the RPTPβ overexpressing cells there was enhanced osteocalcin expression at day 12 and this also rescued differentiation (Fig 3H). Correspondingly the addition of IGFBP-2 enhanced basal (e.g., a 3.9 ± 0.4 fold greater compared to control, p<0.01) and IGF-I-stimulated AKT phosphorylation (e.g., a 1.7 ± 0.2 fold greater compared to no IGFBP-2 treatment, p<0.05) (Fig 3I). These results clearly show that IGFBP-2 regulation of RPTPβ activity plays an important role in preosteoblast differentiation and that RPTPβ regulates osteoblast differentiation through modulation of PTEN tyrosine phosphorylation. Disruption of IGFBP-2/RPTPβ interaction impairs IGF-I-stimulated AKT activation and osteoblast differentiation To confirm the importance of the IGFBP-2/RPTPβ interaction, MC-3T3 cells overexpressing IGFBP-2 were analyzed. Following the addition of IGF-I there was a significant increase in IGFBP-2/RPTPβ association (Fig 4A) (e.g., a 2.5 ± 0.2 fold greater level of complex formation in IGFBP-2 overexpressing cells compared to control cells p< 0.05). To inhibit this interaction we utilized an anti-RPTPβ blocking antibody and determined its effect on the IGFBP-2/RPTPβ interaction, downstream signaling and differentiation. The antibody inhibited IGF-I stimulated IGFBP-2/RPTPβ association in control and IGFBP-2 overexpressing cells (Fig 4A). Disruption of their interaction was functionally significant since it inhibited AKT activation (Fig 4B) and osteocalcin expression (Fig 4C) (e.g., 74 ± 8% reduction in osteocalcin with 500ng/ml, p<0.01). Since IGF-I stimulates IGFBP-2/RPTPβ association that is critical for AKT activation(9) and osteoblast differentiation, we determined whether the requirement for IGF-I was changed when IGFBP-2 was overexpressed. To block IGF-I signaling, PQ401, a specific inhibitor of IGF-I receptor tyrosine kinase was used. The results show that PQ401 treatment significantly impaired osteocalcin expression and cell differentiation in IGFBP-2 overexpressing cells (Fig 4D and E). HBD-1 peptide mediates the IGFBP-2 effect on osteoblast differentiation The HBD-1 domain of IGFBP-2 mediates its stimulatory effect on osteoblast proliferation.(4) To investigate the importance of the HBD-1 domain for osteoblast differentiation, we utilized an IGFBP-2 mutant in which the charged amino acids within the HBD-1 sequence were changed to alanine and an 13 amino acid synthetic peptide that contained this sequence and examined their abilities to alter the differentiation of calvarial preosteoblasts isolated from IGFBP-2 null mice. The results show that unlike wild type IGFBP-2 when the HBD-1 mutant form of IGFBP-2 was added, its ability to stimulate preosteoblast differentiation was significantly impaired (Fig 5A). To further investigate the function of HBD-1 domain, an HBD-1 peptide was added to differentiation medium. The peptide was able to rescue IGFBP-2 −/− cell differentiation (Fig 5A). When the results were quantified the differences were significant (Fig 5A). When increasing concentrations of the HBD-1 peptide were added a substantial increase in the percentage of cells that differentiated was noted at 500 ng/ml and it increased further with 1000 ng/ml (Fig 5B). When osteocalcin expression was analyzed this effect was confirmed and there was an incremental increase between 250 and 1000 ng/ml (Fig 5C). To determine whether HBD-1-enhanced cell differentiation was due to change of cell survival, we measured the cleaved caspase-3, an indicator for cell apoptosis. The results showed that the HBD-1 peptide had no effect on osteoblast apoptosis (Supplemental Figure 4A). Discussion Although IGFBP-2 functions with IGF-II to increase bone mass(16), and IGFBP-2 knockout mice have decreased cortical and trabecular bone(3–4), the specific role of IGFBP-2 in modifying osteoblast differentiation has not been reported. Prior studies showed that IGFBP-2 enhances the effect of both IGF-I and IGF-II in stimulating bone accretion in vivo.(4,16) Subsequently we showed that a peptide containing the HBD-1 sequence rescues the normal bone phenotype in IGFBP-2 −/− mice and that this peptide stimulated osteoblast proliferation.(4) These studies extend those findings to demonstrate that the HBD-1 peptide as well as intact IGFBP-2 stimulates osteoblast differentiation. The results clearly demonstrate that overexpression of IGFBP-2 results in acceleration of the differentiation program as well as increasing the total number of cells reaching the stage of mature osteoblast formation. Proteins that are markers of differentiation, such as osteocalcin, are increased in response to IGFBP-2 and they are expressed earlier in the differentiation program following IGFBP-2 stimulation. The results show that the expression of Wnt10b, alkaline phosphatase and osteopontin were increased in a similar manner. The effect of IGFBP-2 is mediated through the cell surface receptor RPTPβ since addition of an antibody which inhibited its binding to this receptor significantly attenuated its ability to stimulate signaling events that are linked to osteoblast differentiation. Moreover, knockdown of this receptor inhibited the ability of IGFBP-2 to stimulate differentiation. That the HBD-1 domain was important for signaling within the intact protein was confirmed using site directed mutagenesis. Specifically addition a mutant with an altered HBD-1 sequence resulted in attenuated differentiation. Both the time course and the absolute number of cells as well as expression of osteocalcin were deceased. Our prior studies showed that an 13 amino acid peptide containing the HBD-1 sequence stimulated trabecular bone formation in IGFBP-2 −/− mice.(4) Keipe et al(17) demonstrated that a 117 amino acid carboxy terminal fragment of IGFBP-2 that would have contained the HBD-1 sequence exerted a strong mitogenic effect on growth plate chondrocytes and the effect was equal to intact IGFBP-2. These studies extend those observations to show that a peptide encompassing the sequence of HBD-1 is sufficient to stimulate osteoblast differentiation through its interaction with RPTPβ. Our prior study showed that RPTPβ was present on the surface of MC-3T3 cells and that IGFBP-2 could interact with this protein to alter PTEN tyrosine phosphorylation.(9) IGFBP-2 stimulated RPTPβ polymerization thereby attenuating its phosphatase activity. Since PTEN is a RPTPβ substrate, this resulted in increased tyrosine phosphorylation of PTEN which attenuated PTEN enzymatic activity thereby leading to increased AKT phosphorylation. These studies extend those observations showing that enhancement of constitutive AKT phosphorylation occurs concomitantly with earlier differentiation in cells that overexpress IGFBP-2 and that these responses are attenuated when IGFBP-2 expression is diminished. That these changes are mediated through RPTPβ was proven by demonstrating that inhibition of IGFBP-2 binding to RPTPβ could block enhanced AKT activation and differentiation, and that knocking down of RPTPβ resulted in escape from its ability to inhibit AKT activation as well as a reduction in cell responsiveness to intact IGFBP-2. The studies also demonstrated that constituently synthesized IGFBP-2 is important for osteoblast differentiation. Knockdown of constituently synthesized IGFBP-2 resulted in attenuation of differentiation and expression of osteocalcin as well as constitutive AKT phosphorylation. Addition of an antibody that inhibits the binding of IGFBP-2 to RPTPβ could attenuate these responses in non-transfected MC-3T3 cells. Therefore, these results further support the conclusion that IGFBP-2 functions by attenuating RPTPβ mediating PTEN dephosphorylation and stimulating AKT activation, leading to enhanced osteoblast differentiation. The importance of AKT activation for differentiation was also shown by inhibiting PI-3 kinase, which is upstream of AKT. The addition of a PI-3 kinase inhibitor, after 3 day exposure to differentiation medium, completely prevented osteoblast differentiation. However, to obtain similar level of inhibition in IGFBP-2 overexpressing cells the inhibitor needed to be added at an earlier time point. Since previous studies have also shown that suppression of MAP kinase activation stimulated osteoblast differentiation,(14,18–19) we also analyzed MAP kinase activation using a similar experimental paradigm. Consistent with prior reports, our results showed that inhibition of MAP kinase activation significantly stimulated osteoblast differentiation, however, this stimulation was only detected when inhibitor was added at the early stage of cell differentiation, such as on day 3 and day 6 (Supplemental Fig 4B). Importantly, over-expression of IGFBP-2 did not significantly alter MAP kinase activation, compared to control cells (Supplemental Fig 4C), indicating that MAP kinase pathway did not play an important role in mediating the stimulatory effect of IGFBP-2 on osteoblast differentiation. Consistently, exogenous addition of a peptide containing HBD-1 sequence or IGFBP-2 or overexpression of IGFBP-2 had no significant effect on cell proliferation in the differentiation medium (Supplemental Fig 4D and E). Other studies have suggested that expression of IGFBP-2 correlates with changes in osteoblast differentiation although they have not shown the direct causal links reported herein. Specifically Kawase et al induced chondrocytes sheets to differentiate into osteoblasts and showed increased secretion of both IGF-I and IGFBP-2 that occurred during deposition of osteoid and mineralized tissue.(6) Similarly, Hamidouche et al. demonstrated that induction of osteoblast differentiation from mesenchymal stromal cells was accompanied by an increase in the synthesis of IGF-II, IGFBP-2 and the α5 integrin subunit.(8) Both IGF-II and IGFBP-2 were shown to increase the expression of phenotypic markers as well as the in vitro osteogenic capacity of the cells. They also demonstrated that downregulation of the α5 subunit decreased IGF-II and IGFBP-2 expression and that their expression was dependent on constituitive integrin α5 activation suggesting a link between increased IGFBP-2 synthesis and differentiation. Lee et al showed that treatment of mesenchymal stem cells during osteoblast induction with parathyroid hormone resulted in increased expression of IGF-I, IGF-II and IGFBP-2 whereas PTH treatment of cord blood derived the stem cells that did not differentiate into osteoblasts did not show these changes.(7) These findings have been extended to human osteoblasts wherein it was demonstrated that IGFBP-2 and IGF-I or II expression are upregulated during in vitro induction of differentiation and that this correlated negatively with proliferation.(20) Palermo et al showed that IGF-II stimulated IGFBP-2 synthesis in tibial osteoblast cultures during differentiation and that IGFBP-2 was the most abundant form of IGFBP that was induced.(2) Thraikill et al reported that MC-3T3 cells increased IGFBP-2 expression between days 10 and 14 of differentiation: concomitant with the onset of osteocalcin expression.(21) Several factors that have been shown to stimulate IGFBP-2 expression by MC-3T3 cells specifically phorbol esters(22) and FGF(23). A more recent study by Yerges et al demonstrated that IGFBP-2 SNPs were associated with lumbar volumetric bone mineral density in humans and that only 7 genes were found to be this tightly associated.(24) Other cell types have also been analyzed to determine the role of IGFBP-2 in differentiation. In hematopoetic stem cells IGFBP-2 supports stem cell expansion but no specific mechanism by which it stimulates differentiation in this cell type has been defined.(25–26) Knockdown of IGFBP-2 in zebrafish embryos resulted in disruption of cardiac development and impaired differentiation of cardiomyocytes.(27) Additionally there were vessel sprouting defects which suggested a role in angiogenesis and endothelial cell differentiation. Our studies have demonstrated that IGFBP-2 expression is required for osteoclast differentiation.(28) Cells derived from IGFBP-2 −/− mice showed minimal osteoclast differentiation which could be rescued with exogenous addition of IGFBP-2. The defect appeared to be an inability to form mature osteoclasts that retain full bone resorbing activity. The role of IGFBP-2 in differentiation has been intensively studied in skeletal myoblasts wherein it has been demonstrated that the addition of differentiation medium to myoblasts in culture results in a major increase in expression of IGFBP-2 and inhibition of IGFBP-2 using neutralizing antibodies inhibits myoblast differentiation.(29) Therefore it appears that IGFBP-2 coordinately regulates the ability of IGF-I and IGF-II stimulate differentiation in several cell types. Numerous studies have shown a positive effect of IGF-I on bone formation in vivo and on osteoblast differentiation in vitro. Addition of IGF-I to culture medium with BMP-2 enhanced osteoblast differentiation and this effect was believed to be mediated through AKT.(30) Yeh et al. demonstrated that BMP-2 and IGF-I induced a synergistic increase in osteoblast differentiation and that this response could be inhibited by a protein kinase D inhibitor.(31) IGF-I also mediates chondrocyte differentiation and mature chondrocytes can differentiate into osteoblasts therefore this indirectly alters osteoblast differentiation.(32) Similarly IGF-II has been shown to enhance osteogenic differentiation and it directly potentiates the effects of BMP 9 on alkaline phosphatase activity.(33) These effects are inhibited by PI-3 kinase inhibitors suggesting the AKT pathway that is the primary mediator. Matrix IGF-I has been shown to maintain bone mass by enhancing osteoblast differentiation. This effect required concomitant injection of IGFBP-3 which improved bone matrix localization.(10) Our current study also showed that blockage of IGF-I signaling significantly impaired osteoblast differentiation even though IGFBP-2 was overexpressed. We conclude that IGF-I and IGFBP-2 function coordinately to stimulate differentiation and both peptides are required for an optimal stimulation. Transgenic mice that overexpress IGF-I in osteoblasts have increased trabecular bone and increased bone formation.(34) Conditional IGF-I receptor null mice showed decreased osteoblast number and reduced trabecular volume and impaired differentiation and calcification(35) and locally produced skeletal IGF-I plays an important role in trabecular bone integrity.(36) Since IGFBP-2 stimulates trabecular bone formation and osteoblast differentiation, our results suggest that the two proteins are functioning coordinately. This conclusion is supported by the observation that PTH is a potent stimulant of not only IGF-I synthesis in bone but it also induces IGFBP-2. In conclusion, the results of our studies suggest that IGFBP-2 functions to enhance the ability of IGF-I to stimulate osteoblast differentiation and that this effect is specific for IGFBP-2. Since IGF-I can stimulate both osteoblast proliferation and differentiation, our findings suggests that IGFBP-2 may function directly to coordinate these responses and independently of its transport capacity for the IGFs. Supplementary Material Supp Info The authors wish to thank Ms. Laura Lindsey, University of North Carolina at Chapel Hill, for her help in preparing the manuscript. This work was supported by a grant (AR-06114) from the National Institute of Health. Figure 1 IGFBP-2 stimulates osteoblast differentiation (A) Equal amounts of cell lysate from MC-3T3 cells expressing a shRNA sequence targeting LacZ (Ctrl Si) or IGFBP-2 (IGFBP-2 Si) were immunoblotted with indicated antibody. β-actin was immunoblotted as a loading control. (B) Cell lysate from Ctrl Si or IGFBP-2 Si cells on the indicated day after differentiation medium (DM) exposure were immunoblotted with the indicated antibody. (C) Ctrl Si or IGFBP-2 Si expressing cells were stained by Alizarin Red following the procedure described in “Materials and Methods” on indicated day after DM exposure. (D) Cell lysates from IGFBP-2−/− or IGFBP-2 +/+ derived calvarial osteoblasts prepared on indicated day after DM exposure were immunoblotted with indicated antibody. The bar graph shows the ratio of scanning densitometry units of osteocalcin/β-actin obtained from three individual experiments. (E) Calvarial osteoblasts isolated from IGFBP-2 +/+ or IGFBP-2 −/− mice were exposed to DM alone or DM plus IGFBP-2 (1 ug/ml) and stained with Alizarin Red on day 21. (F) Lysates from cells expressing LacZ or IGFBP-2 were immunoblotted with indicated antibody. (G) Lysates from cells expressing LacZ or IGFBP-2 on indicated day after DM exposure were immunoblotted with indicated antibody. β-actin was immunoblotted as a loading control. The bar graphs show the ratio of scanning densitometry units of osteocalcin/β-actin obtained from three individual experiments. (H) Cells expressing LacZ or IGFBP-2 were stained with Alizarin Red on indicated day after DM exposure. Figure 2 AKT activation is required for osteoblast differentiation (A) Lysates obtained from MC-3T3 cells, clone 24 (CL24) or clone 4 (CL4) on day 6 after DM exposure were immunoblotted with indicated antibody. Lysates from quiescent cells expressing LacZ or IGFBP-2 on day 6 after DM exposure were immunoblotted with the indicated antibody. Wild type MC-3T3 cells (B) or IGFBP-2 overexpressing cells (C) were stained by Alizarin Red on day 21 after differentiation medium (DM) alone or DM plus LY294002 which was added on the indicated day. The medium was changed every 72hr. (D) Lysates obtained from cells overexpressing IGFBP-2 or LacZ after indicated day of DM exposure were immunblotted with indicated antibody. The bar graph shows the ratio of scanning densitometry units of pAKT/β-actin obtained from three individual experiments. (E) Lysates from IGFBP-2−/− or IGFBP-2 +/+ derived calvarial osteoblasts obtained on indicated day after DM exposure were immunoblotted with indicated antibody. The bar graph shows the ratio of scanning densitometry units of pAKT/β-actin obtained from three individual experiments. Figure 3 IGFBP-2 enhances AKT activation via suppressing RPTPβ dephosphorylation of PTEN (A) Cell lysates from quiescent LacZ or IGFBP-2 overexpressing cells were immunoprecipitated with an anti-IGFBP-2 antibody and immunoblotted with an anti-RPTPβ antibody. β-actin was immunoblotted as a loading control. (B) Lysates from LacZ or IGFBP-2 overexpressing cells on indicated day after differentiation medium (DM) exposure were immunoprecipated with an anti-PY99 antibody and immunoblotted with an anti-PTEN antibody. PTEN was immunoblotted as an input control. (C, D) Lysates from MT-3C3 cells expressing shRNA sequence targeting LacZ (Ctrl Si) or RPTPβ (RPTPβ Si) were immunoblotted with the indicated antibodies. (E) Cells expressing Ctrl Si or RPTPβ Si were stained by Alizarin Red on indicated day after DM exposure. (F) Lysates from LacZ or RPTPβ overexpressing cells were immunoblotted with anti-HA and β-actin antibodies. The same cell lysates were immunoprecipitated with an anti-PY99 antibody and immuoblotted with an anti-PTEN antibody. PTEN was immunoblotted as an input control. (G) Cells expressing LacZ or RPTPβ were stained by Alizarin Red on indicated day after DM exposure. (H) Cells expressing RPTPβ were stained by Alizarin Red on day 21 after DM alone or DM plus IGFBP-2 exposure. Lysates from the same RPTPβ overexpressing cultures were immunoblotted with anti-osteocalcin and β-actin antibodies. (I) Lysates from quiescent RPTPβ overexpressing cells obtained on day 6 after IGF-I alone or IGFBP-2 alone (1ug/ml) or IGF-I plus IGFBP-2 (1 ug/ml) were immunoblotted with anti-pAKT and β-actin antibodies. Figure 4 Disruption of IGFBP-2/RPTPβ interaction impairs IGF-I-stimulated AKT activation and osteoblast differentiation (A) Lysates from quiescent LacZ or IGFBP-2 overexpressing cells obtained on day 6 after differentiation medium (DM) exposure treated with or without IGF-I alone (10 min) or IGF-I following a 4 hr exposure to anti-fibronectin domain (FN3) antibody were immunoprecipitated using an anti-IGFBP-2 antibody and immunoblotted with an anti-RPTPβ antibody (B) Lysates from quiescent IGFBP-2 overexpressing cells that received the same treatments as in panel A were obtained on Day 6 after DM exposure and were immunoblotted with indicated antibody. (C) Lysates from LacZ overexpressing cells obtained on day 21 after DM exposure following incubation with the indicated concentration of anti-fibronectin antibody (FN3) were immunoblotted with anti-osteocalcin and anti-β-actin antibodies. (D) Lysates from IGFBP-2 overexpressing cells obtained on day 9 and 12 after DM exposure following incubation with PQ401 (10 uM) were immunoblotted with anti-osteocalcin and anti-β-actin antibodies. (E) Cells expressing IGFBP-2 that had been incubated with or without PQ401 were stained with Alizarin Red on day 18 after DM exposure. Figure 5 The heparin binding domain-1 (HBD-1) mediates the IGFBP-2 effect on osteoblast differentiation (A) Calvarial osteoblasts isolated from IGFBP-2 +/+ or IGFBP-2 −/− mice were exposed to differentiation medium (DM) alone, DM plus IGFBP-2 (1 ug/ml), DM plus control peptide (Ctrl Pep, 1 ug/ml), DM plus HBD-1 (1 ug/ml) or DM plus the HBD-1 IGFBP-2 mutant protein (IGFBP-2 MP, 1 ug/ml) then stained with Alizarin Red on day 21. The bar graph shows the percentage of stained area that was quantified using NIH Image J (1.47n). (B, C) Calvarial osteoblasts isolated from IGFBP-2 −/− mice were exposed to DM alone (Ctrl) or DM plus the indicated concentration of HBD-1 peptide for 21 days and stained with Alizarin Red (B). Cell lysates were immunoblotted with anti-osteocalcin and β-actin antibodies (C). Disclosures The authors state that they have no conflicts of interest. Author’s roles: Study design: GX, CR and DC; Data collection: GX, CW and VD; Data analysis and interpretation: GX, CR and DC. Drafting and reviewing manuscript: GX, CR and DC. References 1 Firth SM Baxter RC Cellular actions of the insulin-like growth factor binding proteins Endocr Rev 2002 23 6 824 854 12466191 2 Palermo C Manduca P Gazzerro E Foppiani L Segat D Barreca A Potentiating role of IGFBP-2 on IGF-II-stimulated alkaline phosphatase activity in differentiating osteoblasts Am J Physiol Endocrinol Metab 2004 286 4 E648 E657 14665441 3 DeMambro VE Clemmons DR Horton LG Bouxsein ML Wood TL Beamer WG Canalis E Rosen CJ Gender-specific changes in bone turnover and skeletal architecture in igfbp-2-null mice Endocrinology 2008 149 5 2051 2061 18276763 4 Kawai M Breggia AC DeMambro VE Shen X Canalis E Bouxsein ML Beamer WG Clemmons DR Rosen CJ The heparin-binding domain of IGFBP-2 has insulin-like growth factor binding-independent biologic activity in the growing skeleton J Biol Chem 2011 286 16 14670 14680 21372140 5 Govoni KE Lee SK Chung YS Behringer RR Wergedal JE Baylink DJ Mohan S Disruption of insulin-like growth factor-I expression in type IIalphaI collagen-expressing cells reduces bone length and width in mice Physiol Genomics 2007 30 3 354 362 17519362 6 Kawase T Okuda K Kogami H Nakayama H Nagata M Nakata K Yoshie H Characterization of human cultured periosteal sheets expressing bone-forming potential: in vitro and in vivo animal studies J Tissue Eng Regen Med 2009 3 3 218 229 19266490 7 Lee JH Hwang KJ Kim MY Lim YJ Seol IJ Jin HJ Jang YK Choi SJ Oh W Cho YH Lee YH Human parathyroid hormone increases the mRNA expression of the IGF system and hematopoietic growth factors in osteoblasts, but does not influence expression in mesenchymal stem cells J Pediatr Hematol Oncol 2012 34 7 491 496 23007338 8 Hamidouche Z Fromigue O Ringe J Haupl T Marie PJ Crosstalks between integrin alpha 5 and IGF2/IGFBP2 signalling trigger human bone marrow-derived mesenchymal stromal osteogenic differentiation BMC Cell Biol 2010 11 44 20573191 9 Shen X Xi G Maile LA Wai C Rosen CJ Clemmons DR Insulin-like growth factor (IGF) binding protein 2 functions coordinately with receptor protein tyrosine phosphatase beta and the IGF-I receptor to regulate IGF-I-stimulated signaling Mol Cell Biol 2012 32 20 4116 4130 22869525 10 Xian L Wu X Pang L Lou M Rosen CJ Qiu T Crane J Frassica F Zhang L Rodriguez JP Xiaofeng J Shoshana Y Shouhong X Argiris E Mei W Xu C Matrix IGF-1 maintains bone mass by activation of mTOR in mesenchymal stem cells Nat Med 2012 18 7 1095 1101 22729283 11 Cohick WS Clemmons DR Regulation of insulin-like growth factor binding protein synthesis and secretion in a bovine epithelial cell line Endocrinology 1991 129 3 1347 1354 1714831 12 Xi G Shen X Clemmons DR p66shc negatively regulates insulin-like growth factor I signal transduction via inhibition of p52shc binding to Src homology 2 domain-containing protein tyrosine phosphatase substrate-1 leading to impaired growth factor receptor-bound protein-2 membrane recruitment Mol Endocrinol 2008 22 9 2162 2175 18606861 13 Wang D Christensen K Chawla K Xiao G Krebsbach PH Franceschi RT Isolation and characterization of MC3T3-E1 preosteoblast subclones with distinct in vitro and in vivo differentiation/mineralization potential J Bone Miner Res 1999 14 6 893 903 10352097 14 Raucci A Bellosta P Grassi R Basilico C Mansukhani A Osteoblast proliferation or differentiation is regulated by relative strengths of opposing signaling pathways J Cell Physiol 2008 215 2 442 451 17960591 15 Schinke T Gebauer M Schilling AF Lamprianou S Priemel M Mueldner C Neunaber C Streichert T Ignatius A Harroch S Amling M The protein tyrosine phosphatase Rptpzeta is expressed in differentiated osteoblasts and affects bone formation in mice Bone 2008 42 3 524 534 18178537 16 Conover CA Johnstone EW Turner RT Evans GL John Ballard FJ Doran PM Khosla S Subcutaneous administration of insulin-like growth factor (IGF)-II/IGF binding protein-2 complex stimulates bone formation and prevents loss of bone mineral density in a rat model of disuse osteoporosis Growth Horm IGF Res 2002 12 3 178 183 12162999 17 Kiepe D Van Der Pas A Ciarmatori S Standker L Schutt B Hoeflich A Hugel U Oh J Tonshoff B Defined carboxy-terminal fragments of insulin-like growth factor (IGF) binding protein-2 exert similar mitogenic activity on cultured rat growth plate chondrocytes as IGF-I Endocrinology 2008 149 10 4901 4911 18556354 18 Higuchi C Myoui A Hashimoto N Kuriyama K Yoshioka K Yoshikawa H Itoh K Continuous inhibition of MAPK signaling promotes the early osteoblastic differentiation and mineralization of the extracellular matrix J Bone Miner Res 2002 17 10 1785 1794 12369782 19 Nakayama K Tamura Y Suzawa M Harada S Fukumoto S Kato M Miyazono K Rodan GA Takeuchi Y Fujita T Receptor tyrosine kinases inhibit bone morphogenetic protein-Smad responsive promoter activity and differentiation of murine MC3T3-E1 osteoblast-like cells J Bone Miner Res 2003 18 5 827 835 12733721 20 Viereck V Siggelkow H Pannem R Braulke T Scharf JG Kubler B Alteration of the insulin-like growth factor axis during in vitro differentiation of the human osteosarcoma cell line HOS 58 J Cell Biochem 2007 102 1 28 40 17372931 21 Thrailkill KM Siddhanti SR Fowlkes JL Quarles LD Differentiation of MC3T3-E1 osteoblasts is associated with temporal changes in the expression of IGF-I and IGFBPs Bone 1995 17 3 307 313 8541146 22 Hakeda Y Yoshizawa K Hurley M Kawaguchi H Tezuka K Tanaka K Satoh T Kumegawa M Stimulatory effect of a phorbol ester on expression of insulin-like growth factor (IGF) binding protein-2 and level of IGF-I receptors in mouse osteoblastic MC3T3-E1 cells J Cell Physiol 1994 158 3 444 450 7510294 23 Hurley MM Abreu C Hakeda Y Basic fibroblast growth factor regulates IGF-I binding proteins in the clonal osteoblastic cell line MC3T3-E1 J Bone Miner Res 1995 10 2 222 230 7538725 24 Yerges LM Klei L Cauley JA Roeder K Kammerer CM Ensrud KE Nestlerode CS Lewis C Lang TF Barrett-Connor E Moffett SP Hoffman AR Ferrell RE Orwoll ES Zmuda JM Candidate gene analysis of femoral neck trabecular and cortical volumetric bone mineral density in older men J Bone Miner Res 2010 25 2 330 338 19619005 25 Huynh H Zheng J Umikawa M Zhang C Silvany R Iizuka S Holzenberger M Zhang W Zhang CC IGF binding protein 2 supports the survival and cycling of hematopoietic stem cells Blood 2011 118 12 3236 3243 21821709 26 Celebi B Mantovani D Pineault N Insulin-like growth factor binding protein-2 and neurotrophin 3 synergize together to promote the expansion of hematopoietic cells ex vivo Cytokine 2012 58 3 327 331 22459634 27 Wood AW Schlueter PJ Duan C Targeted knockdown of insulin-like growth factor binding protein-2 disrupts cardiovascular development in zebrafish embryos Mol Endocrinol 2005 19 4 1024 1034 15618288 28 DeMambro VE Maile L Wai C Kawai M Cascella T Rosen CJ Clemmons D Insulin-like growth factor-binding protein-2 is required for osteoclast differentiation J Bone Miner Res 2012 27 2 390 400 22006816 29 Sharples AP Al-Shanti N Hughes DC Lewis MP Stewart CE The role of insulin-like-growth factor binding protein 2 (IGFBP2) and phosphatase and tensin homologue (PTEN) in the regulation of myoblast differentiation and hypertrophy Growth Horm IGF Res 2013 23 3 53 61 23583027 30 Mukherjee A Rotwein P Akt promotes BMP2-mediated osteoblast differentiation and bone development J Cell Sci 2009 122 Pt 5 716 726 19208758 31 Yeh LC Ma X Matheny RW Adamo ML Lee JC Protein kinase D mediates the synergistic effects of BMP-7 and IGF-I on osteoblastic cell differentiation Growth Factors 2010 28 5 318 328 20380591 32 Longobardi L Granero-Molto F O'Rear L Myers TJ Li T Kregor PJ Spagnoli A Subcellular localization of IRS-1 in IGF-I-mediated chondrogenic proliferation, differentiation and hypertrophy of bone marrow mesenchymal stem cells Growth Factors 2009 27 5 309 320 19639489 33 Chen L Jiang W Huang J He BC Zuo GW Zhang W Luo Q Shi Q Zhang BQ Wagner ER Luo J Tang M Wietholt C Luo X Bi Y Su Y Liu B Kim SH He CJ Hu Y Shen J Rastegar F Huang E Gao Y Gao JL Zhou JZ Reid RR Luu HH Haydon RC He TC Deng ZL Insulin-like growth factor 2 (IGF-2) potentiates BMP-9-induced osteogenic differentiation and bone formation J Bone Miner Res 2010 25 11 2447 2459 20499340 34 Zhao G Monier-Faugere MC Langub MC Geng Z Nakayama T Pike JW Chernausek SD Rosen CJ Donahue LR Malluche HH Fagin JA Clemens TL Targeted overexpression of insulin-like growth factor I to osteoblasts of transgenic mice: increased trabecular bone volume without increased osteoblast proliferation Endocrinology 2000 141 7 2674 2682 10875273 35 Zhang M Xuan S Bouxsein ML von Stechow D Akeno N Faugere MC Malluche H Zhao G Rosen CJ Efstratiadis A Clemens TL Osteoblast-specific knockout of the insulin-like growth factor (IGF) receptor gene reveals an essential role of IGF signaling in bone matrix mineralization J Biol Chem 2002 277 46 44005 44012 12215457 36 Kesavan C Wergedal JE Lau KH Mohan S Conditional disruption of IGF-I gene in type 1alpha collagen-expressing cells shows an essential role of IGF-I in skeletal anabolic response to loading Am J Physiol Endocrinol Metab 2011 301 6 E1191 E1197 21878662
PMC005xxxxxx/PMC5117427.txt
LICENSE: This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. 9421564 8584 Shock Shock Shock (Augusta, Ga.) 1073-2322 1540-0514 27755473 5117427 10.1097/SHK.0000000000000735 NIHMS810373 Article WHAT’S NEW IN SHOCK, NOVEMBER 2016? Efron Philip A. MD Departments of Surgery, Anesthesiology, Aging and Geriatric Research, and Molecular Genetics and Microbiology 18 8 2016 11 2016 01 11 2017 46 5 465467 This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. The journal Shock is unique in that it reports on all aspects of inflammation, injury and sepsis – in a sense, “Shock is where the action is!” This month’s journal only serves to emphasize how Shock remains at the forefront of international clinical and scientific research. Be it a review article or basic science manuscript, the November 2016 issue of Shock is a must read for all individuals interested in the field. This month’s journal begins with a very thorough and complete review of plasma transfusion from our colleagues on the west coast of the United States (1). Understanding the benefits versus the detriments of transfusion has become a key aspect of daily bedside medicine. In fact, transfusion is now tracked as a ‘best practice measure’ by many national organizations. Watson, et al’s essential review of the medical use of plasma, from its origins to its ongoing research (1) is both opportune and beneficial. In addition to summarizing all of the key literature and studies regarding the use of plasma for shock, it discusses the various formulations of plasma that are currently being used or in development (1). Certainly this article will be in the library of every critical care resident for the next decade. As Shock is the official journal of a consortium of international societies, it is of no surprise that the next article illustrates some exceptional work from South America. Dr. Filho, et al have produced some very timely work regarding blood lactate levels and sepsis (2). The Third International Consensus Definitions for Sepsis and Septic Shock (Sepsis-3) has defined septic shock as the requirement for a vasopressor (in the absence of hypovolemia) to maintain a minimum mean arterial pressure of 65mmHg and a serum lactate level greater than 2mmol/L (>18mg/dL) (3). With this in mind, abnormal lactate levels above a level of 2mmol/L are now more relevant than ever, as presented by Filho and colleagues, who were able to use an Emergency Room admission lactate cutoff of 2.5mmol/L to predict 28 day mortality, and this had a receiver operator curve of 0.70 (2). Although Filho et al.’s work is a retrospective analysis, this real world study presents a simple, clinically relevant test that can be utilized for predicting mortality in septic patients with organ dysfunction or pressor requirements (2). Not unexpectedly, Dr. Herndon’s group continues to lead the way in demonstrating the effectiveness of interventional therapies that are United States Food and Drug Administration approved as well as inexpensive. It goes against the better judgement of any clinician to give a medication that potentially lowers blood pressure in the patient in the acute phase of an inflammatory response. However, Dr. Wurzer, et al have demonstrated that giving propanolol in burned children is not only safe but potentially helpful (4). The medication reduced cardiogenic stress without adversely affecting other multiple important parameters (4). This includes, but is not limited to: peripheral oxygen delivery, events of lactic acidosis, wound healing, and mortality (4). Clearly, Dr. Wurzer and colleagues are part of a select few investigators with the remarkable ability to see beyond many clinicians’ trepidation to utilize agents such as propanolol in the initial phase of inflammation and shock to help improve outcomes (5, 6). Keeping with the theme of top notch work accomplished in both the burn population as well as around the world, Dr. Lopez-Rodriguez, et al have continued their analysis of their single-center, prospective, randomized, double-blind clinical trial on the effect of selective decontamination of the digestive tract (SDD) in severe burn patients (7). ‘No organ is an island,’ and this is certainly true of the intestines in the acute and sub-acute phases of shock, trauma and burn. After previously demonstrating that SDD can improve mortality after burns, the authors have illustrated that this simple intervention was independently associated with a reduction in organ dysfunction in severely burned patients, which also suggests a modulatory role of SDD on the inflammatory response (7). And what was able to induce this huge impact? The answer is the early and temporary use of non-proprietary antibiotics, such as polymyxin, amphotericin B and cefotaxime (7). Again, an inexpensive and safe intervention is demonstrated to have an impact, this time influencing the host as well as the microbiome of these very sick patients (8). Not to be superseded, French investigators have also analyzed an inexpensive drug that has been debated for decades in sepsis. I am, of course, referring to steroids! Dr. Herve, et al conducted a multicenter, prospective, randomized, double-blind, pilot study comparing two low dose regimens of hydrocortisone: 200mg versus 300mg (9). Their results have illustrated, like many of the recent sepsis prospective trials in sepsis, that it’s not so much the specifics of the intervention, such as the total dose, but the early recognition of the need for a therapy along with its timely institution that is most important to the patient’s outcome (9). Thus, the authors found no difference in 28 day mortality between the groups – however, the analysis may lead to important further weight based steroid experimentation, as well reviews of sepsis persistence and etomidate use in these patients (9). Leelahavanichkul, et al have made further progress in the field of practical predictive medicine (10). This work from Thailand looked at serum (1→3)-b-D-glucan (BG) in not just septic mice, but septic humans (10). BG is a key structural polysaccharide of the cell wall of most fungi and the authors have revealed that it can be used as a marker of gastrointestinal leakage and sepsis, even during/after bacterial infections (10). As clinicians are moving towards precision medicine (11), this type of biomarker will prove vital as scientists tailor therapy only to those individuals that require intervention. It’s impossible to investigate inflammation without considering toll-like receptors (TLR), and when you combine Dr. Billiar’s laboratory and the journal Shock, outstanding work is always revealed. That tradition continues this month as Korff, Scott, Billiar, et al use clever investigative basic science, including knock out and chimera mice and a clinically relevant model of hemorrhagic shock (12), to further our understanding of the role of TLR in inflammation. Their work illustrated that TLR2 regulates both bone marrow and non-bone marrow derived cells’ ability to affect inflammation, and more importantly, organ failure (12). Interestingly, the mechanism of this was in conjunction with TLR4 (12). It is only through clinically relevant work like this that progress will be made to enable future physicians to immunomodulate the human patient after trauma and hemorrhagic shock. As a global journal, revealing and analyzing cutting edge technology has always been a vital component of the journal Shock. Thus, in this November’s issue the editors are very proud to publish the work of Dr. Lane Smith and the collaborative team at Wake Forrest. Photoacoustic (PA) imaging, is a technology that evaluates both tissue structure and function through ultrasound and laser energy (13). The investigators have been able to illustrate that PA is able to measure, in real-time, oxygen saturation in the macro and microcirculation during acute hypoxia (13). Anyone involved in research regarding shock will need to be familiar with this technology, as its future use, in combination with other agents, will likely become common place in the critically ill (13). Clinical relevance does not mean abandoning basic science at its most fundamental level. Kidney injury is a key driver of poor patient outcomes - much more than previously realized. Dr. Wang and colleagues from China have performed some very elegant basic research regarding myofibrillogenesis regulator 1 (MR-1) in a clinically relevant murine model of renal ischemia/reperfusion injury (I/R) (14). MR-1 is a mitochondrial-targeted protein, and the researchers demonstrated that through the recruitment of phosphatidylinositol 3 kinase-dependent phosporylated-Akt to the mitochondria, MR-1 was able to protect the kidney from I/R injury by inhibiting mitochondrial permeability transition pore opening and maintaining mitochondrial integrity (14). The various methodologies conducted by the investigators in this study are impressive, and this work has the capacity to introduce new therapeutics to the realm of shock research (14). Returning to the investigation of burn injury, Dr. Caldwell’s laboratory has revealed another important aspect to the treatment of depression (15). Although depression is not considered normally in the area of shock research, depression and medication for its treatment are fairly prevalent in the United States. Dr. Johnson, et al were able to determine that amitriptyline, a tricyclic antidepressant that inhibits acid sphingomyelinase, had significant effects on the immunity of host after burn injury (15). This included a reduction in lymphocyte precursors, lymphocyte numbers and neutrophil recruitment (15). Clearly, their work suggests that future precision medicine for inflammation, injury and infection will require consideration of the patient’s ‘medication profile.’ Which leads to the concept that precision medicine will also need to take into consideration a patient’s diet with the treatment of, let’s say, of cardiovascular disease. Although debated to some extent, patients whose lifestyles incorporate certain seeds or fish are much less likely to succumb to certain pathology, such as acute myocardial infarctions. However, the medical practitioner is not able to pre-emptively create such environment when their patient arrives at the emergency room. Interestingly, Burban et al have determined that one single intravenous omega-3 bolus before reperfusion in a clinically relevant rat model of I/R-induced shock was able to improve multiple parameters (16). This included an increased mean arterial pressure and carotid blood flow as well as decreased cardiac troponin levels (16). This improvement in blood pressure and vasoreactivity could have significant repercussions regarding the treatment of acute coronary syndromes, and again the work in this issue reveals possible therapies that are both inexpressive and safe (16)! The need to improve cardiac function and outcomes is not limited to myocardial infractions, though. Dr. Li, et al have investigated the well-known cardio-dysfunction induced by severe sepsis and septic shock. Translating work done in cardiac I/R, the authors were able to conduct research on intermedin, a calcitonin related peptide, using the cecal ligation and puncture murine sepsis model (17). Early and late administration of the compound, specifically intermedin 1–53, to septic mice improved heart function, tissue oxygenation/perfusion and survival (17). This was in part through the Rho kinase phosphorylation pathway and by increasing intracellular calcium (17). As a journal of world-wide importance, it is of no surprise that notable work is being published in this issue Shock regarding melioidosis. This is an infection with Burkholderia pseudomallei that is relatively common in Southeast Asia and Northern Australia with significant morbidity and mortality. Dr. Weehuiz has produced some impressive data with a collaborative international laboratory group regarding the use of a monoclonal anti-IL-1b antibody in this condition (18). Although treatment with such compounds in the past failed to improved outcomes, application of anti-IL1b antibodies could be effective in more select patient population, such as those suffering from melioidosis (18). This research was able to demonstrate that their intervention were able to affect the inflammasome and improve the host’s response to the bacterium B. pseudomallei(18). Taiwanese investigators have made some ‘in-roads’ regarding our understanding of the acute respiratory distress syndrome, as displayed by the work of Day, et al. Using a rat model of the Acute Respiratory Distress Syndrome (ARDS) combined with intraperitoneal lipopolysaccharide injection, the authors were able test the hypothesis that preactivated and disaggregated shape-changed platelets could attenuate lung injury (19). Their intervention was able to improve the outcomes of the host on multiple levels, including, but not limited to, histological, cellular and molecular results (19). This work has improved not only our understanding of the relationship of pathology of ARDS, but the anti-inflammatory and anti-oxidative properties of preactivated and disaggregated shape-changed platelets, which may be considered as a future therapeutic in a disease process that has few current interventions besides supportive care (19). Finally, in an article that combines some of the themes investigated by other scientists in this issue (sepsis, ARDS and a single injection of nutritional compound), Dr. Yeh and colleagues have eloquently demonstrated that glutamine can modify progenitor cell and lung injury in mice exposed to severe infection (20). Their basic science work revealed that an intravenous injection of glutamine after cecal ligation and puncture could promote the mobilization of endothelial progenitor cells, in part due to the release of C-X-C motif chemokine 1, vascular endothelial growth factor and nitric oxide (20). These effects are associated with improved vascular function, ameliorated inflammation and reduced damage of lung tissues (20). Although the use of glutamine in the critically ill is currently debated, the Shock journal has never shied away from contentious issues that require further investigation in order to elucidate appropriate answers for the scientific and medical community! Based on this issue and the ten issues before it in 2016, there can be no doubt that the journal Shock has led the way this year in reporting the best research, both laboratory and clinical, regarding inflammation, injury and sepsis. For several decades now, this journal has truly served its readers around the world. 1 Watson JJJ Pati S Schreiber MA Plasma transfusion: History, current realities, and novel improvements Shock 46 ____-____ 2016 2 Filho RR Rocha LL Corrêa TD Pessoa CMS Colombo G Assuncão MSC Blood lactate levels cutoff and mortality prediction in sepsis-time for a reappraisal? A retrospective cohort study Shock 46 ____-____ 2016 3 Singer M Deutschman CS Seymour CW Shankar-Hari M Annane D Bauer M Bellomo R Bernard GR Chiche JD Coopersmith CM Hotchkiss RS Levy MM Marshall JC Martin GS Opal SM Rubenfeld GD van der Poll T Vincent JL Angus DC The Third International Consensus Definitions for Sepsis and Septic Shock (Sepsis-3) JAMA 315 80 10 2016 4 Wurzer P Branski LK Clayton RP Hundeshagen G Forbes AA Voigt CD Andersen CR Kamolz L-P Woodson LC Suman OE Finnerty CC Herndon DN Propranolol reduces cardiac index but does not adversely affect peripheral perfusion in severely burned children Shock 46 ____-____ 2016 5 Morelli A Ertmer C Westphal M Rehberg S Kampmeier T Ligges S Orecchioni A D’Egidio A D’Ippoliti F Raffone C Venditti M Guarracino F Girardis M Tritapepe L Pietropaoli P Mebazaa A Singer M Effect of heart rate control with esmolol on hemodynamic and clinical outcomes in patients with septic shock: a randomized clinical trial JAMA 310 1683 91 2013 24108526 6 Novotny NM1 Lahm T Markel TA Crisostomo PR Wang M Wang Y Ray R Tan J Al-Azzawi D Meldrum DR beta-Blockers in sepsis: reexamining the evidence Shock 31 113 9 2009 18636043 7 López-Rodríguez L de la Cal MA García-Hierro P Herrero R Martins J van Saene HKF Lorente JA Selective digestive decontamination attenuates organ dysfunction in critically ill burn patients Shock 46 ____-____ 2016 8 Krezalek MA1 DeFazio J Zaborina O Zaborin A Alverdy JC The Shift of an Intestinal “Microbiome” to a “Pathobiome” Governs the Course and Outcome of Sepsis Following Surgical Injury Shock 45 475 82 2016 26863118 9 Hervé H Rémy B Gentilhomme A Francois C-GJ Freche A Kaidomar M Bernard G Pradier C Dellamonica J Bernardin G Effects of increasing hydrocortisone to 300 mg per day in the treatment of septic shock: A pilot study Shock 46 ____-____ 2016 10 Leelahavanichkul A Worasilchai N Wannalerdsakun S Jutivorakool K Somparn P Issara-Amphorn J Tachaboon S Srisawat N Finkelman M Chindamporn A Gastrointestinal leakage detected by serum (1→3)-β-D-glucan in mouse models and a pilot study in patients with sepsis Shock 46 ____-____ 2016 11 Mathias B Lipori G Moldawer LL Efron PA Integrating “big data” into surgical practice Surgery 159 371 4 2016 26603852 12 Korff S Loughran P Cai C Fan J Elson G Shang L Pires SS Lee YS Guardado J Scott M Billiar TR TLR2 on bone marrow and non-bone marrow derived cells regulates inflammation and organ injury in cooperation with TLR4 during resuscitated hemorrhagic shock Shock 46 ____-____ 2016 13 Smitih L Varagic J Yamaleyeva L Photoacoustic imaging for the detection of hypoxia in the rat femoral artery and skeletal muscle microcirculation Shock 46 ____-____ 2016 14 Wang X-R Ding R Tao T-Q Mao H-M Liu M Xie Y-S Liu X-H Myofibrillogenesis regulator 1 rescues renal ischemia/reperfusion injury by recruitment of P13K –dependent P-AKT to mitochondria Shock 46 ____-____ 2016 15 Johnson BL III Rice TC Xia BT Boone KI Green EA Gulbins E Caldwell CC Amitriptyline usage exacerbates the immune suppression following burn injury Shock 46 ____-____ 2016 16 Burban M Meyer G Olland A Séverac F Yver B Toti F Schini-Kerth V Meziani F Boisramé-Helms J An intravenous bolus of EPA:DHA 6:1 protects against myocardial ischemia-reperfusion-induced shock Shock 46 ____-____ 2016 17 Li T Yu Z Wu H Wu Y Zhang J Peng X Zang J Xiang X Liu L Beneficial effect of intermedin 1–53 in septic shock rats: Contributions of Rho kinase and BKCA pathway-mediated improvement in cardiac function Shock 46 ____-____ 2016 18 Weehuizen TAF Lankelma JM De Jong HK De Boer OJ Roelofs JJTH Day NPJ Gram H De Vos AF Wiersinga WJ Therapeutic administration of a monoclonal anti-IL-1β antibody protects against experimental melioidosis Shock 46 ____-____ 2016 19 Day Y-K Chen K-H Chen Y-L Huang T-H Sung P-H Lee F-Y Chen C-H Chai H-T Yin T-C Chiang H-J Chung S-Y Chang H-W Yip H-K Preactivated and disaggregated shape-changed platelets protected against acute respiratory distress syndrome complicated by sepsis through inflammation suppression Shock 46 ____-____ 2016 20 Pai M-H Shih Y-M Shih J-M Yeh C-L Glutamine administration modulates endothelial progenitor cell and lung injury in septic mice Shock 46 ____-____ 2016
PMC005xxxxxx/PMC5117435.txt
LICENSE: This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. 9214969 2488 Methods Mol Biol Methods Mol. Biol. Methods in molecular biology (Clifton, N.J.) 1064-3745 1940-6029 27714613 5117435 10.1007/978-1-4939-6451-2_8 NIHMS810158 Article Protein chemical modification inside living cells using split inteins Borra Radhika 1 Camarero Julio A. 12* 1 Department of Pharmacology and Pharmaceutical Sciences, University of Southern California, Los Angeles, CA 90089-9121, USA 2 Department of Chemistry, University of Southern California, Los Angeles, CA 90089-9121, USA Phone: 323-442-1417, Fax: 323-224-7473, jcamarer@usc.edu 13 8 2016 2017 01 1 2018 1495 111130 This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. Summary Methods to visualize, track, measure, and perturb or activate proteins in living cells are central to biomedical efforts to characterize and understand the spatial and temporal underpinnings of life inside cells. Although fluorescent proteins have proven to be extremely useful for in vivo studies of protein function, their utility is inherently limited because their spectral and structural characteristics are interdependent. These limitations have spurred the creation of alternative approaches for the chemical labeling of proteins. We describe in this protocol the use of fluorescence resonance emission transfer (FRET)-quenched DnaE split-inteins for the site-specific labeling and concomitant fluorescence activation of proteins in living cells. We have successfully employed this approach for the site-specific in-cell labeling of the DNA binding domain (DBD) of the transcription factor YY1 using several human cell lines. Moreover, we have shown that this approach can be also used for modifying proteins in order to control their cellular localization and potentially alter their biological activity. split-intein protein trans-splicing Npu intein protein labeling fluroescence 1. Introduction Understanding the roles of specific proteins in cellular processes is a fundamental goal of molecular biology [1–3]. Methods to label and visualize proteins inside living cells are extremely useful in the study of localization, movement, interactions, and microenvironments of proteins in living cells. Although fluorescent proteins have revolutionized such studies, they have numerous shortcomings, which have spurred the creation of alternative approaches to chemically label proteins in living cells. These next generation approaches combine the genetic targeting capabilities of fluorescent proteins with the diversity and environmental sensitivity of fluorescent small molecules and/or other biophysical probes. Most of the available techniques, however, provide only limited temporal resolution for labeling of biomolecules in living cells. Ideally these approaches should be modular, thus making possible the introduction of a wide variety of fluorophores or other type of biophysical probes. The kinetics of the labeling reaction should be fast enough to provide temporal resolution to satisfy the most time-sensitive biological assays. It should also allow spatial control during the in-cell labeling process. The labeling reaction should introduce minimal modifications on the target protein in order to preserve its original structure and biological function. Finally, it should make possible the simultaneous introduction of different probes onto multiple target proteins for simultaneous tracking purposes. One of the most promising approaches for in-cell protein labeling involves the use of intein-mediated protein trans-splicing (Fig. 1) [4]. Protein trans-splicing is a naturally occurring post-translational modification similar to protein splicing with the difference being that the intein self-processing domain is split in two fragments, called N-intein (IN) and C-intein (IC), respectively [5, 6]. These two intein fragments are inactive individually, however, they can bind each other with high specificity under appropriate conditions to form a functional protein-splicing domain. Split mini-inteins have been widely used by our group and others for the site-specific modification of proteins in vitro [7–10] and in living cells [11–13]. In-cell labeling of proteins can be easily accomplished by expressing the protein of interest fused to the IN fragment. The second half of the split intein can be chemically synthesized to contain any chemical probe at the C-extein moiety, and then introduced into the cells by using peptide transducing domains (PTD) [11, 13]. Intein-mediated labeling of proteins is highly modular allowing the covalent site-specific incorporation of a myriad of biophysical probes into proteins [8–10]. The kinetics of protein splicing is also relatively fast, with a number of split-inteins having reaction times in the order of several minutes [9, 14, 15]. Moreover, the recent development of conditional protein splicing, both through chemical and photochemical means, makes possible the chemical modification of proteins in living cells with temporal and spatial control [16–19]. One of the best-characterized naturally occurring split-inteins are α-subunit DNA polymerase III (DnaE) intein [20], with many known orthologs with high sequence homology in many cyanobacteria species (Fig. 2A) [14, 21]. The DnaE split-inteins are characterized for having IN and IC fragments with ≈120 and ≈30 residues, respectively. The relatively small size of the IC fragment facilitates its chemical synthesis thus allowing the use of synthetic IC fragments bearing different biophysical probes in the C-extein segment to be used for the chemical modification of proteins through protein trans-splicing [9, 13, 17, 18]. We will use in this protocol the Nostoc puntiforme PCC73102 (Npu) DnaE split-intein. This particular DnaE split-intein has one of the highest rate reported for protein trans-splicing (τ1/2 ≈ 60 s) [15] and a high splicing yield [15, 22]; and therefore is ideal for in-cell protein labeling purposes. The use of protein trans-splicing for the site-specific labeling of proteins with fluorogenic dyes for in-cell tracking purposes requires that the labeling process must be linked to the simultaneous activation of fluorescence (Fig. 1). This can be accomplished by making use of fluorescence resonance emission transfer (FRET)-quenched DnaE split-inteins for the site-specific labeling and concomitant fluorescence activation of proteins in living cells. In this protocol we use fluorescein and dabcyl as fluorescence donor and FRET-quencher, respectively (Fig. 2), but any other combination of donor and quencher could be also used. The fluorescein group is introduced at the C-terminus of the first four residues (Cys-Phe-Asn-Lys) of the C-extein, which are required for efficient trans-splicing (Fig. 2) [13] The dabcyl group (QM, Fig. 2) is introduced on residue 22 of the Npu DnaE IC polypeptide (peptide IC, Table 1). This position is in close proximity to the C-extein (≈17 Å, Fig. 2B) and provides an excellent FRET-quenching (>99% FRET-quenching) [13]. In this chapter we describe the protocol for in-cell C-terminal labeling of the DNA binding domain (DBD) of the transcription factor Yin Yang 1 (YY1) in live U2OS and HeLa cells. YY1 is a ubiquitously distributed multifunctional transcription factor belonging to the GLI-Kruppel class of zinc finger proteins [23]. The protein is involved in repressing and activating a diverse number of promoters including negative regulation of p53, thus making it of particular interest [24, 25]. In the example described in this chapter the DBD of YY1 was labeled at its C-terminal with a fluorophore (fluorescein) and a nuclear localization (NLS) signal peptide to demonstrate the potential of this technique to control the localization of and biological function of a protein/protein domain. The protocol described uses humans U2OS cells but it could be easily adapted to any other mammalian cell line. It is important to note that this approach is highly modular and can be used for in-cell labeling of proteins with other biophysical probes or peptide sequences required for activity. In addition, the use of different orthogonal split inteins should also make possible the simultaneous labeling of multiple proteins with different probes. Before performing the labeling experiment in-cell, it is advisable to test the labeling reaction in vitro first. This protocol also provides instructions on how to evaluate labeling by protein trans-splicing in vitro. 2. Materials All solutions were prepared using ultrapure water with a resistivity of 18 MΩ × cm at 25° C and analytical grade reagents. All reagents and solutions were stored at room temperature unless indicated otherwise. 2.1 Instruments Water bath able to operate at 42° C and 94°C. Table-top micro centrifuge capable of operating at 14,000 rpm. Microbiology incubator set at 37°C. Temperature controlled incubator Shaker. Orbital shaker. Polymerase chain reaction thermocycler. Agarose gel electrophoresis unit. Electrophoresis power pack able to operate up to 250 V. UV-visible spectrophotometer. Sonicator to lyse E. coli cells. High speed centrifuge (e.g. Sorvall RC 5C Plus, Thermo Fisher scientific). SDS-PAGE electrophoresis apparatus. Centrifuge tubes of 0.5 mL, 1.5 mL, 15 mL and 30 mL of capacity. 5 ml Polypropylene Columns. Class II, type A2 biosafety cabinets. Gel and Blot Imaging System. Fluorescence microscope. CO2 incubator. 2.2 Cloning of YY1-IN construct Synthetic DNA primers used to amplify genes encoding Npu DnaE IN and DBD-YY1 (20 nmol scale, HPLC purified) (Table 2). Genomic DNA from Nostoc punctiforme strain ATCC 29133/PCC 73102 (obtained from ATCC). DNA encoding human YY1 proteins (cDNA clone IMAGE: 5261384) (can be obtained from many sources, eg. Genscript, USA). TE buffer: 10 mM Tris-HCl, 1 mM EDTA, pH 8.0. Vent DNA polymerase, TaqDNA polymerase, dNTPs solution, 10X thermopol PCR buffer, 10X Taq DNA polymerase buffer. Restriction enzymes Not I, Nde I, BamH I, Kpn I and Sal I. PCR Purification Kit (e.g. QIAquick from QIAGEN). Miniprep Kit (e.g. QIAprep from QIAGEN). Gel Extraction Kit (e.g. QIAquick from QIAGEN). Chemical competent DH5α cells. Expression plasmid pET28a (Novagen-EMD Millipore). Mammalian Expression vector pcDNA4/TO/myc-His (Invitrogen). T4 DNA ligase and T4 DNA ligase buffer. Ampicillin stock solution: 100 mg ampicillin/mL in pure H2O, sterilized by filtration. Store in 1 mL aliquots at −20° C. Kanamycin stock solution: 25 mg kanamycin/mL in pure H2O, sterilized by filtration. Store in 1 mL aliquots at −20° C. Chloramphenicol stock solution: 34 mg chloramphenicol/mL in EtOH. Store in 1 mL aliquots at −20° C. LB medium: 25 g of LB broth was dissolved in 1 L of pure H2O and sterilized by autoclaving at 120° C for 30 min. LB medium-agar: 3.3 g of LB agar was suspended in 100 mL of pure H2O and sterilized by autoclaving at 120° C for 30 min. To prepare plates, allow LB medium-agar to cool to ≈50° C, then add 0.1 mL of antibiotic stock solution. SOC Medium: 20 g of tryptone, 5 g yeast extract, 0.5 g NaCl and 0.186 g KCl were suspended into 980 ml of pure water and sterilized by autoclaving at 120° C for 30 min. Dissolve 4.8 g MgSO4, 3.603 g dextrose in 20 mL of pure H2O and filter sterilize over a 45 μm filter and add to the autoclaved medium. 2.3 Bacterial expression YY1-IN construct Chemical competent BL21 (DE3) and Origami2 (DE3) cells (EMD Millipore). Isopropyl-thio-β-D-galactopyranoside (IPTG): Prepare a stock solution of 1 M analytical grade IPTG in H2O and sterilize by filtration over 45 μm filter. Store at −20° C. Lysis buffer: 0.1 mM EDTA, 25 mM sodium phosphate, 150 mM NaCl, 10% (v/v) glycerol, pH 7.4. Phosphate buffer saline (PBS): 25 mM sodium phosphate, 150 mM NaCl, pH 7.4 100 mM phenylmethylsulphonyl fluoride (PMSF) in EtOH (better to prepare fresh before use). 4X SDS-PAGE sample buffer: 1.5 mL of 1 M Tris-HCl buffer at pH 6.8, 3 mL of 1 M DTT (dithiothreitol) in pure H2O, 0.6 g of sodium dodecyl sulfate (SDS), 30 mg of bromophenol blue, 2.4 mL of glycerol, bring final volume to 7.5 mL. SDS-PAGE sample buffer: dilute 4 times 4×SDS-PAGE sample buffer in pure H2O and add 20% (v/v) 2-mercaptoethanol. Prepare fresh. SDS-4–20% PAGE gels, 1X SDS running buffer. Gel stain: Coomassie brilliant blue or Gelcode® Blue (Thermo scientific, USA) or silver stain kit. 2.4 In-vitro trans-splicing Pure labeled DnaE IC polypeptide shown in Table 1. The synthetic peptides used in this study were generated in-house but they could be ordered from any chemical supplier specialized in providing synthetic peptides. Trans-splicing buffer: 0.5 mM EDTA, 1 mM tris-(2-carboxyethyl)phosphine (TCEP), 50 mM NaH2PO4, 250 mM NaCl, pH 7.0 (Note 1). 2.5 In-cell trans-splicing reaction U2OS cells, available from ATCC (ATCC® HTB-96™). HeLa cells, available from ATCC (ATCC® CCL-2™). Dulbecco’s modified eagle medium (DMEM) containing 10% heat inactivated FBS (Fetal Bovine Serum), 1% L-glutamine and 1% penicillin-streptomycin solution. RIPA BUFFER: 50 mM Tris-HCl, 150 mM NaCl buffer, pH 8.0, 1% NP-40, 0.5% sodium deoxycholate, 1% Triton X-100. TBST buffer: 50 mM Tris-HCl, 150 mM NaCl, pH 7.6. Nonpyrogenic sterile 100 × 20 mm polystrene plates. Nonpyrogenic sterile 35 mm glass bottom plates (e.g. MatTek). Transfection reagent for mammalian cells (e.g. Fugene-6 from Promega or equivalent). Complete protease cocktail (e.g. Thermo Scientific). PVDF membrane for western blotting. 5% skim milk in TBST buffer. Anti-His Antibody (e.g. murine IgG). Store at −20° C. Secondary antibody (e.g. horseradish peroxidase-conjugated anti-murine IgG, Vector Lab). ECL kit (e.g. Life Technologies). Chariot protein delivery reagent (Active Motif). 3. Methods 3.1 Cloning of DNA encoding Npu DnaE IN into expression vector pET28a(+) Amplify by PCR the gene containing the Npu DnaE IN (residues 770–876, UniProtKB: B2J066) using a plasmid containing the DnaE gene from Nostoc punctiforme (Strain ATCC 2913/PCC 73102) as template using primers p5-IN and p3-IN (Table 2). The 5′-primer encodes a Sal I restriction site. The 3′-primer introduces a Not I restriction site and stop codon. Carry out the PCR reaction as follows: 40 μL sterile pure H2O, 1 μL of DNA template (≈10 ng/μL), 5 μL of 10× thermopol reaction buffer, 1.0 μL of dNTP solution (10 mM each), 1 μL of p5-IN primer solution (0.2 μM), 1 μL of p3-IN r primer solution (0.2 μM), and 1 μL Vent DNA polymerase (2 units). PCR cycle conditions used: initial denaturation at 94° C for 5 min followed by 30 cycles (94° C denaturation for 30 s, annealing at 52° C for 45 s, and extension at 72° C for 60 s) and final extension at 72° C for 10 min. Purify the PCR amplified fragment encoding Npu Dna IN using a PCR purification kit following the manufacturer instructions and quantify it by UV absorption (for a 1-cm pathlength, an optical density at 260 nm (OD260) of 1.0 equals to a concentration of 50 μg/mL solution of dsDNA). Digest plasmid pET28a(+) (Novagen-EMD Millipore) and PCR-amplified gene encoding the DnaE IN polypeptide with restriction enzymes Sal I and Not I. Use a 0.5 mL centrifuge tube and add 5 μL of 10× restriction buffer (e.g. NEB buffer 2.1 from New England Biolabs), add enough pure sterile water to have a final volume reaction of 50 μL, add ≈10 μg of the corresponding dsDNA to be digested and finally add 1 μL (20 units) of restriction enzyme Not I. Incubate at 37° C for 3 h. Then, add 1 μL (20 units) of restriction enzyme Sal I to the same tube and incubate at 37° C for 1 h. Purify the double digested PCR-product and pET28a plasmid by agarose (0.8% and 2% agarose gels for pET28a(+) and PCR product should be used, respectively) gel electrophoresis. Cut out the bands corresponding to the double digested DNA and purify the DNA using a gel extraction kit. Elute DNA from spin columns with TE buffer and quantify using UV. Ligate double digested pET28a(+) and PCR-product encoding DnaE IN. Use a 0.5 mL centrifuge tube, add ≈ 100 ng of Sal I, Not I-digested pET28a, ≈ 50 ng of Sal I, Not I-digested PCR-amplified DNA encoding DnaE IN, enough pure sterile H2O to make a final reaction volume of 20 μL, 2 μL of 10X T4 DNA ligase buffer, 1 μL of 10 mM ATP and 1 μL (400 units) T4 DNA ligase. Incubate at 16° C overnight. Transform the ligation mixture into DH5α competent cells. ≈100 μL of chemical competent cells are thawed on ice and mixed with the ligation mixture (20 μL) for 30 min. Heat-shock the cells are heat-shocked at 42° C for 45 s and then keep on ice for an extra 10 min. Add 900 μL of SOC medium and incubate at 37° C for 1 h in an orbital shaker. Plate 100 μL on LB agar plate containing kanamycin (25 μg/mL) and incubate the plate at 37° C overnight. Pick up several colonies (most of the times 5 colonies should be enough) and inoculate into 5 ml of LB medium containing kanamycin (25 μg/mL). Incubate tubes at 37° C overnight in an orbital shaker. Pellet down cells and extract DNA using a miniprep kit following the manufacturer protocol and quantify plasmid using UV spectroscopy. Verify the presence of DNA encoding DnaE IN in each colony using PCR and the same conditions described in step 1 of this section. Screen colonies containing DNA encoding DnaE IN for protein expression (Steps 11 through 17). Transform chemical competent BL21 (DE3) cells with plasmids containing the DNA encoding DnaE IN (Note 2). Transformed cells are plated on LB plate containing kanamycin (25 μg/mL) and incubated at 37° C overnight. Resuspend the colonies from 1 plate in 1 mL of LB and inoculate 100 mL of LB containing kanamycin (25 μg/mL) in a 250 mL flask. Grow cells in an orbital shaker incubator at 37° C for 2–3 h to reach mid-log phase (OD at 600 ≈ nm 0.5). Add IPTG to reach a final concentration of 1 mM and incubate cells for 3 h at 37° C. Pellet 1 mL of cells by centrifugation at 6,000 × g for 15 min at 4° C. Discard the supernatant and resuspend pellets in fresh SDS-PAGE sample buffer. Heat samples at 94 °C for 5 min and separate the soluble cell lysate fraction by centrifugation at 15,000 × g for 20 min at 4° C Analyze the soluble fraction by SDS-PAGE analysis to estimate the protein expression of the DnaE IN intein in each clone analyzed. The DnaE IN polypeptide should give a band around 15 kDa. 3.2 Cloning of DNA encoding YY1-IN construct into expression vector pET28a Amplify the gene containing the DNA binding domain of YY1 by PCR using the cDNA for human YY1 (cDNA clone IMAGE: 5261384) as template using primers p5-YY1 and p3-YY1 (Table 2). The 5′-primer and 3′-primer introduce Nde I and BamH I restriction sites, respectively. Carry out the PCR reaction as follows: 40 μL sterile pure H2O, 1 μL of DNA template (≈10 ng/μL), 5 μL of 10× thermopol reaction buffer, 1.0 μL of dNTP solution (10 mM each), 1 μL of p5-YY1 primer solution (0.2 μM), 1 μL of p3-YY1 primer solution (0.2 μM), and 1 μL Vent DNA polymerase (2 units). Use the following PCR cycle conditions: initial denaturation at 94° C for 5 min followed by 30 cycles (94° C denaturation for 30 s, annealing at 52° C for 45 s, and extension at 72° C for 60 s) and final extension at 72° C for 10 min. Purify the PCR amplified fragment encoding YY1 using a PCR purification kit following the manufacturer instructions and quantify by UV spectroscopy. Digest plasmid pET28a encoding DnaE IN (pET-IN) (obtained in section 3.1) and PCR-amplified gene encoding YY1 construct with restriction enzymes Nde I and BamH I. Use a 0.5 mL centrifuge tube and add 5 μL of 10× restriction buffer (e.g. NEB buffer 3.1 from New England Biolabs), add enough pure sterile water to have a final volume reaction of 50 μL, add ≈10 μg of the corresponding dsDNA to be digested and finally add 1 μL (20 units) of restriction enzyme Nde I. Incubate at 37° C for 3 h. Then, add 1 μL (20 units) of restriction enzyme BamH I to the same tube and incubate at 37° C for 1 h. Purify the double digested PCR-product and pET-IN plasmid by agarose (0.8% and 2% agarose gels for pET-IN and PCR product should be used, respectively) gel electrophoresis. Cut out the bands corresponding to the double digested DNA and purify them using a gel extraction kit. Elute DNA from the spin columns with TE buffer and quantify using UV spectroscopy. Ligate double digested pET-IN and PCR-product encoding the DBD of YY1. Use a 0.5 mL centrifuge tube, add ≈100 ng of Nde I, BamH I-digested pET-IN, ≈50 ng of Nde I, BamH I-digested PCR-amplified DNA encoding the DBD of YY1, enough pure sterile H2O to make a final reaction volume of 20 μL, 2 μL of 10X T4 DNA ligase buffer, 1 μL of 10 mM ATP and 1 μL (400 units) T4 DNA ligase. Incubate at 16° C overnight. Transform the ligation mixture into DH5α competent cells, plate them on a LB agar plate containing kanamycin (25 μg/mL), and incubate the plate at 37° C overnight as described previously (Section 3.1, steps 5 and 6). Pick up several colonies (most of the times 5 colonies should be enough) and screen for the presence of DNA inserts encoding the DBD of YY1 by PCR as described previously (Section 3.1, steps 7 through 9). Screen colonies containing DNA encoding the YY1-IN construct for protein expression (Steps 9 through 12). Transform chemical competent Rosetta (DE3) cells with plasmids containing the DNA encoding YY1-IN (Note 3). Transformed cells are plated on LB plate containing kanamycin (25 μg/mL) and and chloramphenicol (34 μg/mL) incubated at 37° C. Resuspend the colonies from 1 plate in 1 mL of LB and inoculate 100 mL of LB containing kanamycin (25 μg/mL) and chloramphenicol (34 μg/mL) in a 250 mL flask. Grow cells in an orbital shaker incubator at 37° C for 2–3 h to reach mid-log phase (OD at 600 nm ≈ 0.5). Add IPTG to reach a final concentration of 1 mM and incubate cells for 3 h at 37° C. Pellet, lyse cells and analyze protein expression level of YY1-IN construct by SDS-PAGE as described in sections 3.1.14 through 3.1.17. The YY1-IN construct should give a band around 30 kDa. 3.3 Bacterial expression of the YY1-IN construct Transform chemical competent Rosetta (DE3) cells with plasmid containing the DNA encoding YY1-IN (plasmid pET-YY1-IN). Transformed cells are plated on LB plate containing kanamycin (25 μg/mL) and chloramphenicol (34 μg/mL) and incubated at 37° C overnight (Note 4). Resuspend the colonies from 2 plates in 2 mL of LB and inoculate 1 L of LB containing kanamycin (25 μg/mL) and chloramphenicol (34 μg/mL) in a 2.5 L flask. Grow cells in an orbital shaker incubator at 37° C for 2–3 h to reach mid-log phase (OD at 600 nm ≈ 0.5). Add IPTG to reach a final concentration of 1 mM and incubate cells for 3 h at 37° C. Pellet cells by centrifugation at 6,000 × g for 15 min at 4° C. Discard the supernatant and process the pellet immediately (Note 5). 3.4 Purification of YY1-IN Protein YY1-IN was purified from inclusion bodies. Resuspend cell pellet with 30 mL of lysis buffer containing 1 mM PMSF. Lyse cells by sonication on ice using 25 s bursts spaced 30 s each (Note 6). Repeat the cycle six times (Note 7). Separate the soluble cell lysate fraction by centrifugation at 15,000 × g for 20 min at 4° C. Store the pellets at −80° C in case they need to be re-processed. Resuspend the insoluble fraction with lysis buffer (30 mL) containing detergent (0.1% Triton X-100). Separate soluble fraction by centrifugation at 15,000 × g for 20 min at 4° C. Repeat this process 2 more times. Wash the insoluble fraction with lysis buffer without detergent as described in step 3. Extract YY1-IN with 10 mL of PBS containing 4 M urea (Note 8). Characterize protein purity by SDS-PAGE analysis and determine concentration by UV spectroscopy (ε280 = 17,180 M−1 cm−1). Use immediately for in vitro trans-splicing experiments. 3.5 In vitro labeling of YY1 using protein trans-splicing Pure polypeptide IC (Table 1) and YY1-IN fusion protein are combined in freshly prepared and degassed trans-splicing buffer to a concentration of ≈ 1 μM and 0.1 μM, respectively. Dissolve IC peptide in pure 30% acetonitrile in pure H2O containing 0.1% trifluoroacetic acid (TFA) to obtain a stock solution of ≈ 1 mg/mL (≈160 μM). Add 3.1 μL of IC stock solution and the appropriate amount of YY1-IN dissolved in lysis buffer containing 4 M urea (Section 3.4, step 6) to 500 μL of fresh trans-splicing buffer. Keep the reaction at room temperature with occasional gently shaking. Take aliquots (50 μL) at different times (1, 3, 7, 10, 15, 30, and 45 min) and rapidly quench them by adding 15 μL of 4X SDS-PAGE sample buffer and heating them at 94° C for 2 min. Monitor the progression of the trans-splicing reaction by using SDS-PAGE (Fig. 3). Load 25 μL of each time point onto an SDS-4–20% PAGE gel. Run the samples at 125 V for about 1 h and 30 min in 1X SDS running buffer. Remove SDS with pure water. Visualize trans-splice reaction by epifluorescence (e.g. Storm 860 Molecular Imager), and silver stain kit (e.g. Thermo scientific, USA) following manufacturer protocol (Fig. 3) (Note 9). 3.6 Cloning of DNA encoding YY1-IN construct into mammalian expression vector pcDNA4/TO/myc-His 1 Amplify the DNA encoding the DBD of YY1 fused to the N-terminus of the DnaE IN (YY1-IN) by PCR using plasmid pET-YY1-IN (Section 3.2) as template using primers p5-YY1-IN and p3-YY1-IN (Table 2). The 5′-primer and 3′-primer introduce Kpn I and Not I restriction sites, respectively. Carry out the PCR reaction as follows: 40 μL sterile pure H2O, 1 μL of DNA template (≈10 ng/μL), 5 μL of 10X thermopol reaction buffer, 1.0 μL of dNTP solution (10 mM each), 1 μL of p5-YY1-IN primer solution (0.2 μM), 1 μL of p3-YY1-IN primer solution (0.2 μM), and 1 μL Vent DNA polymerase (2 units). Use the following PCR cycle conditions: initial denaturation at 94° C for 5 min followed by 30 cycles (94° C denaturation for 30 s, annealing at 52° C for 45 s, and extension at 72° C for 60 s) and final extension at 72° C for 10 min. 2 Purify the PCR amplified fragment encoding the YY1-IN fusion protein using the a PCR purification kit following the manufacturer instructions and quantify it by UV-visible spectroscopy. 3 Digest plasmid pcDNA4/TO/myc-His (Invitrogen) and PCR-amplified gene encoding YY1-IN with restriction enzymes Not I and Kpn I. Use a 0.5 mL centrifuge tube and add 5 μL of 10× restriction buffer (e.g. NEB buffer 2.1 from New England Biolabs), add enough pure sterile water to have a final volume reaction of 50 μL, add ≈10 μg of the corresponding dsDNA to be digested, add 1 μL (20 units) of restriction enzyme Not I and 1 μL (20 units) of restriction enzyme Kpn I. Incubate at 37° C for 16 h. 4 Purify the double digested PCR-product and pcDNA4 plasmid by agarose (0.8% and 2% agarose gels for pCDNA4 and PCR product should be used, respectively) gel electrophoresis. Cut out the bands corresponding to the double digested DNA and purify using a gel extraction kit. Elute DNA from the spin columns with TE buffer and quantify using UV-visible spectroscopy. 5 Ligate double digested pcDNA4 and PCR-product encoding YY1-IN. Use a 0.5 mL centrifuge tube, add ≈ 100 ng of Kpn I, Not I-digested pcDNA4, ≈ 50 ng of Kpn I, Not I-digested PCR-amplified DNA encoding YY1-IN, enough pure sterile H2O to make a final reaction volume of 20 μL, 2 μL of 10X T4 DNA ligase buffer, 1 μL of 10 mM ATP and 1 μL (400 units) T4 DNA ligase. Incubate at 16° C overnight. 6 Transform the ligation mixture into DH5α competent cells. Thaw ≈ 100 μL of chemical competent cells on ice and mix with the ligation mixture (20 μL) for 30 min. Heat-shock the cells at 42° C for 45 s and then keep on ice for an extra 10 min. Add 900 μL of SOC medium and incubate at 37° C for 1 h in an orbital shaker. Plate 100 μL on LB agar plate containing ampicillin (100 μg/mL) and incubate the plate at 37° C overnight. 7 Pick up several colonies (most of the times 5 colonies should be enough) and inoculate into 5 mL of LB medium containing ampicillin (100 μg/mL). Incubate tubes at 37° C overnight in an orbital shaker. 6 Pellet down cells and extract DNA using a miniprep kit following the manufacturer protocol and quantify plasmid using UV-visible spectroscopy. 7 Verify the presence of DNA encoding YY1-IN construct in each colony using PCR. Carry out the PCR reaction out as follows: 40 μL sterile pure H2O, 1 μL of plasmid DNA (≈50 ng/μL), 5 μL of 10× TaqDNA polymerase buffer, 1.0 μL of dNTP solution (10 mM each), 1 μL primer p5-YY1-IN solution (0.2 μM), 1 μL of primer p3-YY1-IN (0.2 μM), and 1 μL Taq DNA polymerase (5 units). 8 Use the following PCR cycle conditions: initial denaturation at 94° C for 5 min followed by 30 cycles (94° C denaturation for 30 s, annealing at 56° C for 45 s, and extension at 72° C for 60 s) and final extension at 72° C for 10 min. 3.7 Expression of YY1-IN fusion protein in U2OS and HeLa cells Grow U2OS and HeLa cells in DMEM containing 10% heat inactivated FBS, 1% L-glutamine and 1% penicillin-Streptomycin solution in a humidified incubator under 5% CO2 atmosphere at 37 °C. The transfection conditions and expression conditions should be optimized for each protein and cell line. Grow U2OS and HeLa cells in 100 mm nonpyrogenic sterile polystrene plates to ≈60% confluency. Transiently transfect the cells with plasmid pcDNA4-YY1-IN (1 μg DNA) using transfection reagent (e.g. Fugene-6) following the manual instructions. The transfected cells are then incubated for 24 h at 37° C. Expression of YY1-IN protein is estimated by western-blot analysis (steps 5–14). Wash cells twice with PBS. Discard PBS wash. Resuspend cells in 0.2 mL RIPA buffer in the presence of 0.1% SDS, 1 mM PMSF and complete protease cocktail. Use a cell scrapper to dislodge cells. Transfer the cell suspension to 1.5 mL centrifuge tubes and incubate on ice for 10 min. Separate the insoluble and soluble fractions by centrifugation at 14,000 rpm in a microcentrifuge at 4° C for 30 min. Incubate 100 μL of cell lysate with 20 μL of 4X SDS-PAGE sample buffer containing 20% mercaptoethanol. Heat the sample at 94°C for 2 min. Analyze the cell lysate samples using SDS-PAGE. Load samples (25 μL) onto an SDS-4–20% PAGE gel. Run the samples at 125 V for about 1 h and 30 min in 1X SDS running buffer. Transfer proteins from PAGE gel to a PVDF membrane using standard protocol. Block membrane with 5% skim milk in TBST buffer for 1 h at room temperature. Add primary anti-His antibody (e.g. murine anti-His IgG, Invitrogen) (Note 10) in TBST buffer containing 5% skim milk and incubate overnight at 4°C on an orbital shaker. Wash the membrane 3 times with TBST buffer for 5 min. Add secondary antibody (e.g. horseradish peroxidase-cojugated anti-murine IgG, Vector Lab) in TBST buffer containing 5% skim, and incubate at room temperature for 1 h. Wash membrane 3 times with TBST buffer for 5 min. Develop membrane with ECL mix (Life Technologies) following manufacturer instructions. Visualize bands using a molecular imager system (e.g. Storm 860, Amersham Biosciences) or using an X-ray film (Fig. 4) 3.8 In-cell labeling using protein trans-splicing 1 Grow U2OS and HeLa cells in either 35 mm glass bottom plates (when fluorescence microscopy is required) or 100 mm nonpyrogenic sterile polystrene plates to 40–50% confluency (see 3.7.1–3.7.3) and then transiently transfected with plasmid pcDNA4-YY1-IN (1 μg DNA) using a transfection reagent (e.g. Fugene-6) following the manual instructions. Incubate transfected cells for 24 h at 37° C. 2 Wash cells with PBS. Transfect peptide IC (50 nM) using the Chariot protein delivery reagent (Active Motif) for 1 h as described in the manufacturer manual (Note 11). 3 Wash transfected cells with full media 2 times and incubate for 1 h at 37° C. 4 Wash cells three times with serum free media and observe fluorescence-labeled proteins in live cells using a fluorescence microscope (Fig. 5A and 5B) (Note 12). 4 Lyse cells using RIPA buffer and analyze soluble cell lysate by SDS-PAGE as described previously (Section 3.7, Steps 5 through 9). 5 Visualize fluoresceine-labeled protein on PAGE-gel using a molecular imaging system (Fig. 5C). 5 Use the same PAGE-gel to analyze the efficiency of the labeling reaction by Western blotting as described previously (Section 3.7, steps 10 through 14) (Fig. 5C). Figure 1 A. Site-specific labeling and fluorescence activation of a protein of interest (POI) by FRET-quenched protein trans-splicing. Key to this approach is the introduction of fluorescence quencher (Q) into the IC polypeptide, which blocks the fluorescence signal of the fluorophore (F) located at the C-terminus of the IC polypeptide before protein trans-splicing happens. When protein trans-splicing occurs the fluorophore is covalently attached to the C-terminus of the POI triggering its fluorescence. The use of this approach for in-cell modification and fluorescence tagging of proteins minimizes the fluorescence background from the unreacted IC polypeptide thus facilitating the optical tracking of the labeled protein inside the cell. B. Scheme showing the approach used for in-cell labeling of a POI with a fluorophore inside a live cell using protein trans-splicing (figure modified from [13]). Figure 2 Design of FRET-quenched DnaE split inteins. A. Multiple sequence alignment of the DnaE IC for different species indicating the positions used for the introduction of the quencher group in the IC polypeptide. Multiple sequence alignment was performed using T-Coffee and visualized using Jalview [26]. Molecular representations of the DnaE inteins were generated using the PyMol software package. B. Crystal structure of the Npu DnaE intein in the pre-spliced state (PDB code: 2KEQ) [27]. DnaE IC and IN are shown in red and blue respectively. The structural secondary elements are also shown. The position used to place the quencher and fluorophore groups at the IC and C-extein, as well as the distances are indicated (figure modified from [13]). Figure 3 SDS-PAGE analysis of the in vitro protein trans-splicing/labeling reaction between FRET-quenched DnaE IC (Table 1) and YY1-IN. Protein detection was performed by silver staining (top) and epifluorescence (bottom). TS = trans-splicing. Figure 4 Expression of protein YY1-IN in U2OS (and HeLa) cells. Cells were collected after 24 h post-transfection, lysed and the soluble fraction analyzed and quantified by western blot using an anti-His antibody. Figure 5 In-cell site-specific labeling of YY1 DBD with a nuclear localization signal and concomitant fluorescence activation using protein trans-splicing. A. U2OS (and HeLa) cells were first transiently transfected with a plasmid encoding YY1-IN and with DnaE IC polypeptides as described. Cells were then extensively washed and examined by fluorescence microscopy. B. Magnification of cells after 18 h of incubation showing the migration of the labeled-YY1 to the nuclear compartment. C. Quantification of labeling yield for in-cell trans-splicing reaction. Identification of labeled YY1 DBD protein and quantification of in-cell trans-splicing yield was performed by western blot (right panel) and epifluorescence (left panel), respectively. Bar represents 25 μm in panels A and B. TS = trans-splicing. Table 1 Sequence of the DnaE C-intein (IC) polypeptide used in this protocol. Standard single code letters are used for the peptides sequences. Single letter codes B and X stand for norleucine and 6-amino hexanoic acid, respectively. 5-(Iodoacetamide)-fluoresceine (IAF) is used to introduce fluorescein into specific Lys or Cys residues, respectively. Dabcyl, Cam, Cam-Fl stand for 4-dimethylaminoazobenzene-4’-carboxyl, carboxamidomethyl, and fluorescein-carboxamidomethyl, respectively. Residues in blue, magenta and yellow represent the Npu DnaE IC intein, Npu DnaE C-extein and NLS peptide, respectively. The quencher and fluorophore groups are in red and green respectively. Peptide Name Compound Sequence Molecular Weight Found (Expecteda)/Da Npu QM-IC-NLS-Fl IC 6449.0±0.1 (6447.6) a Average molecular weight Table 2 DNA oligonucleotides used to generate the dsDNA encoding the YY1-IN and DnaE IN. Primer Name Nucleotide Sequence p5-YY1 5′-AAA GAA GAT CAT ATG CCA AGA ACA ATA GCT TGC CCT C-3′ p3-YY1 5′-C TTC GGA TCC CTG GTT GTT TTT GGC CTTA GC-3′ p5-IN 5′-CTA GTC GAC AAG CTT TTA AGT TTG CGG AAT ATT GTT TAA G CTA TG -3′ p3-IC 5′-TTT GCG GCC GCT TAA TTC GGC AAA TTA TCA ACC CGC AT -3′ p5-YY1-IN 5′-AGG GGT ACC ACC ATG GGC AGC AGC -3′ p3-YY1-IN 5′-GT GGT GCT CGA GTG CGG CCG CA -3′ 1 The buffer should be degassed before adding the TCEP. The buffer should be prepared fresh every time and not stored as TCEP has a limited stability at pH 7.0 in the presence of air. 2 We recommend to screen at least 3–4 different colonies for protein expression in BL21(DE3) cells to make sure that the polypeptide encoding DnaE IN is expressed efficiently. 3 We recommend to screen at least 3–4 different colonies for protein expression in Rosetta(DE3) cells to make sure that the clone with highest expression yield is selected. Expression in Rosetta cells is recommended when the protein of interest (POI) contains rare codons in E. coli. Select the clone with the highest expression yield and proceed to the next section. 4 When plating the transformed cells with pET-YY1-IN, it is better to aim for plates containing 200–300 colonies. 5 Cell pellets can be stored at −80° C for no more than 2–3 weeks before being processed. 6 During sonication, be sure the temperature of the sample does not overheat. 7 A french press can be also used to lyse cells, depending on the availability. 8 Use the highest quality urea available. PBS containing urea should be prepared fresh and not stored for more than 1 day, as urea is not stable in buffers at pH above 7. 9 It is extremely import to check that the labeling/trans-splicing reaction works efficiently in vitro before trying it in live cells. 10 In this particular work the N-terminal of the DBD of YY1 contained a His-tag and therefore an anti-His IgG was used to detect the protein by Western blotting. 11 Peptide transfection should be optimized for any particular case. In our hands, the best peptide transfection efficiency was obtained for 50 nM IC using a molecular ratio IC: Pep-1 of 1:20. Pep-1 is the name of the peptide used in the Chariot transfection system and its sequence is Ac-KETWWETWWTEWSQPKKKRKV-cysteamine. This peptide can be also obtained from different commercial sources (e.g. Anaspec). 12 The use of a FRET-quenched IC polypeptide allows concomitant labeling of the protein with the corresponding fluorophore and activation of its fluorescence. 1 Xie XS Yu J Yang WY 2006 Living cells as test tubes Science 312 228 230 16614211 2 Chen I Ting AY 2005 Site-specific labeling of proteins with small molecules in live cells Curr Opin Biotechnol 16 35 40 15722013 3 Miller LW Cornish VW 2005 Selective chemical labeling of proteins in living cells Curr Opin Chem Biol 9 56 61 15701454 4 Perler FB 2005 Protein splicing mechanisms and applications IUBMB Life 57 469 476 16081367 5 Saleh L Perler FB 2006 Protein splicing in cis and in trans Chem Rec 6 183 193 16900466 6 Xu MQ Evans TC Jr 2005 Recent advances in protein splicing: manipulating proteins in vitro and in vivo Curr Opin Biotechnol 16 440 446 16026977 7 Muir TW 2003 Semisynthesis of proteins by expressed protein ligation Annu Rev Biochem 72 249 289 12626339 8 Shi J Muir TW 2005 Development of a tandem protein trans-splicing system based on native and engineered split inteins J Am Chem Soc 127 6198 6206 15853324 9 Kwon Y Coleman MA Camarero JA 2006 Selective Immobilization of Proteins onto Solid Supports through Split-Intein-Mediated Protein Trans-Splicing Angew Chem Int Ed 45 1726 1729 10 Kurpiers T Mootz HD 2008 Site-specific chemical modification of proteins with a prelabelled cysteine tag using the artificially split Mxe GyrA intein Chembiochem 9 2317 2325 18756552 11 Giriat I Muir TW 2003 Protein semi-synthesis in living cells J Am Chem Soc 125 7180 7181 12797783 12 Woo YH Stubbs L Camarero JA 2008 In vivo protein labeling via protein trans-splicing The 21st Annual Symposium of the Protein Society 32 San Diego 13 Borra R Dong D Elnagar AY Woldemariam GA Camarero JA 2012 In-cell fluorescence activation and labeling of proteins mediated by FRET-quenched split inteins J Am Chem Soc 134 6344 6353 22404648 14 Dassa B Amitai G Caspi J Schueler-Furman O Pietrokovski S 2007 Trans protein splicing of cyanobacterial split inteins in endogenous and exogenous combinations Biochemistry 46 322 330 17198403 15 Zettler J Schutz V Mootz HD 2009 The naturally split Npu DnaE intein exhibits an extraordinarily high rate in the protein trans-splicing reaction FEBS Lett 583 909 914 19302791 16 Mootz HD Blum ES Tyszkiewicz AB Muir TW 2003 Conditional protein splicing: a new tool to control protein structure and function in vitro and in vivo J Am Chem Soc 125 10561 10569 12940738 17 Vila-Perello M Hori Y Ribo M Muir TW 2008 Activation of protein splicing by protease- or light-triggered O to N acyl migration Angew Chem Int Ed 47 7764 7767 18 Berrade L Kwon Y Camarero JA 2010 Photomodulation of protein trans-splicing through backbone photocaging of the DnaE split intein Chembiochem 11 1368 1372 20512791 19 Binschik J Zettler J Mootz HD 2011 Photocontrol of protein activity mediated by the cleavage reaction of a split intein Angew Chem Int Ed Engl 50 3249 3252 21384476 20 Wu H Hu Z Liu XQ 1998 Protein trans-splicing by a split intein encoded in a split DnaE gene of Synechocystis sp. PCC6803 Proc Natl Acad Sci USA 95 9226 9231 9689062 21 Wei XY Sakr S Li JH Wang L Chen WL Zhang CC 2006 Expression of split dnaE genes and trans-splicing of DnaE intein in the developmental cyanobacterium Anabaena sp. PCC 7120 Res Microbiol 157 227 234 16256311 22 Iwai H Zuger S Jin J Tam PH 2006 Highly efficient protein trans-splicing by a naturally split DnaE intein from Nostoc punctiforme FEBS Lett 580 1853 1858 16516207 23 Wang CC Chen JJ Yang PC 2006 Multifunctional transcription factor YY1: a therapeutic target in human cancer? Expert Opin Ther Targets 10 253 266 16548774 24 Gronroos E Terentiev AA Punga T Ericsson J 2004 YY1 inhibits the activation of the p53 tumor suppressor in response to genotoxic stress Proc Natl Acad Sci U S A 101 12165 12170 15295102 25 Sui G Affar el B Shi Y Brignone C Wall NR Yin P Donohoe M Luke MP Calvo D Grossman SR 2004 Yin Yang 1 is a negative regulator of p53 Cell 117 859 872 15210108 26 Taki M Sisido M 2007 Leucyl/phenylalanyl(L/F)-tRNA-protein transferase-mediated aminoacyl transfer of a nonnatural amino acid to the N-terminus of peptides and proteins and subsequent functionalization by bioorthogonal reactions Biopolymers 88 263 271 17216634 27 Oeemig JS Aranko AS Djupsjobacka J Heinamaki K Iwai H 2009 Solution structure of DnaE intein from Nostoc punctiforme: structural basis for the design of a new split intein suitable for site-specific chemical modification FEBS Lett 583 1451 1456 19344715
PMC005xxxxxx/PMC5117463.txt
LICENSE: This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. 0370522 482 Am Surg Am Surg The American surgeon 0003-1348 1555-9823 27657564 5117463 NIHMS813549 Article Overwhelming Recurrent Clostridium difficile Infection after Reversal of Diverting Loop Ileostomy Created for Prior Fulminant C. difficile Colitis Fashandi Anna Z. M.D. Ellis Scott R. Smith Philip W. M.D. Hallowell Peter T. M.D. Department of Surgery, University of Virginia School of Medicine, Charlottesville, Virginia, USA Address correspondence to: Peter T. Hallowell, University of Virginia, Department of Surgery, PO Box 800679, Charlottesville, Virginia 22908-1394, USA, Phone: (434) 243-4811, Fax: (434) 243-7272, PTH2F@hscmail.mcc.virginia.edu 31 8 2016 8 2016 01 8 2017 82 8 194195 This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. Clostridium difficile infection (CDI) is the leading cause of infectious diarrhea in the developed world and the incidence and severity of CDI began increasing at the turn of the 21st century. “Fulminant” CDI refers to illness that is life-threatening and, importantly, 36–75% of those who develop fulminant CDI have had recent surgery.1,2 Initial treatment of CDI depends on severity of infection and involves oral metronidazole, vancomycin or fidaxomicin. For CDI which is not responding to medical management, early surgical consultation is recommended with the gold standard surgical intervention being total abdominal colectomy and end ileostomy.1 In 2011, however, Neal and colleagues published the novel technique of performing diverting loop ileostomy with colonic lavage and postoperative antegrade vancomycin enemas in patients with severe CDI. They reported preservation of the colon in 93% of patients in addition to reduced mortality (19% vs 50%, odds ratio 0.24) when compared to matched historical patients treated with total abdominal colectomy.3 Although their outcomes interested many in the surgical community, critics have cited concerns over study design, small sample size, and results that have not been reliably replicated.1 We present the case of a 77 year old male who developed severe CDI after taking ciprofloxacin for prostatitis. He underwent emergent diverting loop ileostomy with colonic lavage and antegrade vancomycin enemas resulting in control of his severe colitis. Colonoscopy five months later showed nonspecific colitis and inflammation. He was referred to our facility three months later regarding ileostomy reversal, after his health had returned to baseline. One year after his index operation, he underwent technically uneventful ileostomy reversal. He had early return of bowel function on postoperative day one with loose bowel movements and, by postoperative day two, he felt well and was tolerating a full liquid diet. On the morning of postoperative day three, he was febrile, tachycardic and began having watery diarrhea. Several hours later, he was hypotensive with altered mental status, a markedly distended abdomen, a white blood cell count of 4.5 k/μl, a lactic acid of 5.5 mmol/L and rising serum creatinine. Abdominal plain film showed colonic distension and no pneumoperitoneum. He then required vasopressors for persistent hypotension and broad-spectrum antibiotics were initiated for concern for anastomotic leak. He developed respiratory distress requiring emergent intubation along with central and arterial line placement. His C. difficile test came back positive and a CT scan was consistent with recurrent C. difficile colitis (Fig. 1A & B). That evening, he was taken emergently for exploratory laparotomy and total abdominal colectomy. A short segment enterectomy also was performed due to a single enterotomy. His bowels were left in discontinuity and an Abthera was placed with plans for re-exploration. The following day, he remained acidotic on a bicarbonate drip with increasing pressor requirements and multisystem organ failure requiring high flow oscillating ventilator use as well as continuous dialysis. Based on the severity of his illness, his family elected to withdraw vasopressor and ventilator support. He was extubated and expired shortly thereafter, five days after his ileostomy reversal. Final pathology showed pseudomembranous enteritis and pseudomembranous colitis. This case highlights several questions including appropriate timing of ileostomy reversal and testing for persistent C. difficile. Neal and colleagues did not discuss their criteria for determining when and on whom to perform ileostomy reversal in their series. At the time of initial publication, fifteen of their nineteen surviving patients (79%) had undergone ileostomy reversal. Because diverting loop ileostomy and colonic lavage is a new approach to managing fulminant CDI, there is not yet any long-term follow up data regarding recurrence of CDI after ileostomy reversal. Neal and colleagues did not report subsequent testing for C. difficile prior to ileostomy reversal, nor did they document any immediate recurrences after reversal. Abe and colleagues, however, published a case report in Japan, in which a 69 year old man developed fulminant and fatal CDI several days after ileostomy closure in an ileostomy formed for reasons unrelated to CDI.2 There have been other reports of CDI after ileostomy closure and one series found a statistically significant association of postoperative CDI with delayed ileostomy closure (>6 months from index procedure, p=0.003).4 After this alarming case of fatal recurrence of CDI, we recommend counseling patients about the risk of C. difficile recurrence prior to offering ileostomy closure to those who had their stomas initially created for treatment of CDI. A high index of suspicion as well as a multidisciplinary approach including surgeons and gastroenterologists is necessary for swift diagnosis and treatment of this postoperative complication. Additionally, we are looking into the possibility of perioperative fecal transplantation to both prevent and treat recurrent CDI after ileostomy reversal. Fig. 1 Abdominal computed tomography scan of patient. Representative (A) axial and (B) coronal images showing inflammation and fat stranding around the cecum and ascending colon, consistent with recurrent C. difficile colitis. 1 Steele SR McCormick J Melton GB Practice parameters for the management of clostridium difficile infection Dis Colon Rectum 2015 58 1 10 24 25489690 2 Abe I Kawamura YJ Sasaki J Konishi F Acute fulminant pseudomembranous colitis which developed after ileostomy closure and required emergent total colectomy: A case report J Med Case Rep 2012 6 130-1947-6-130 3 Neal MD Alverdy JC Hall DE Diverting loop ileostomy and colonic lavage: An alternative to total abdominal colectomy for the treatment of severe, complicated clostridium difficile associated disease Ann Surg 2011 254 3 423 7 discussion 427–9 21865943 4 Rubio-Perez I Leon M Pastor D Increased postoperative complications after protective ileostomy closure delay: An institutional study World J Gastrointest Surg 2014 6 9 169 174 25276286
PMC005xxxxxx/PMC5117630.txt
LICENSE: This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. 8500909 5316 J Subst Abuse Treat J Subst Abuse Treat Journal of substance abuse treatment 0740-5472 1873-6483 27776677 5117630 10.1016/j.jsat.2016.08.015 NIHMS812095 Article From long-term injecting to long-term non-injecting heroin and cocaine use: the persistence of changed drug habits Des Jarlais Don C. 1 Arasteh Kamyar 1 Feelemyer Jonathan 1 McKnight Courtney 1 Barnes David M. 1 Tross Susan 2 Perlman David C. 1 Campbell Aimee N. C. 2 Cooper Hannah LF 3 Hagan Holly 4 1 Icahn School of Medicine at Mount Sinai, New York, NY 2 New York State Psychiatric Institute, Department of Psychiatry, Columbia University Medical Center, New York, NY 3 Department of Behavioral Sciences and Health Education, Rollins School of Public Health, Emory University, Atlanta Georgia 4 College of Nursing, New York University, New York NY Contact Author Information: Don C. Des Jarlais, PhD, Professor of Psychiatry, The Baron Edmond de Rothschild Chemical Dependency Institute, Icahn School of Medicine at Mount Sinai, 39 Broadway 5th Floor Suite 530, New York, NY 10006, 212.256.2548, ddesjarlais@chpnet.org 24 8 2016 21 8 2016 12 2016 01 12 2017 71 4853 This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. Objectives Transitioning from injecting to non-injecting routes of drug administration can provide important individual and community health benefits. We assessed characteristics of persons who had ceased injecting while continuing to use heroin and/or cocaine in New York City. Methods We recruited subjects entering Mount Sinai Beth Israel detoxification and methadone maintenance programs between 2011 and 2015. Demographic information, drug use histories, sexual behaviors, and “reverse transitions” from injecting to non-injecting drug use were assessed in structured face-to-face interviews. There were 303 “former injectors,” operationally defined as persons who had injected at some time in their lives, but had not injected in at least the previous 6 months. Serum samples were collected for HIV and HCV testing. Results Former injectors were 81% male, 19% female, 17% White, 43% African-American, 38% Latino/a, with a mean age of 50 (SD=9.2), and were currently using heroin and/or cocaine. They had injected drugs for a mean of 14 (SD=12.2) years before ceasing injection, and a mean of 13 (SD=12) years had elapsed since their last injection. HIV prevalence among the sample was 13% and HCV prevalence was 66%. The former injectors reported a wide variety of reasons for ceasing injecting. Half of the group appeared to have reached a point where relapse back to injecting was no longer problematic: they had not injected for three or more years, were not deliberately using specific techniques to avoid relapse to injecting, and were not worried about relapsing to injecting. Conclusions Former injectors report very-long term behavior change towards reduced individual and societal harm while continuing to use heroin and cocaine. The behavior change appears to be self-sustaining, with full replacement of an injecting route of drug administration by a non-injecting route of administration. Additional research on the process of long-term cessation of injecting should be conducted within a “combined prevention and care” approach to HIV and HCV infection among persons who use drugs. Former-injectors Relapse Non-injection drugs use HIV Hepatitis C 1. Introduction The transition from using illicit drugs through non-injecting routes of administration to injecting greatly increases the risk of harmful consequences (Fuller et al., 2002). Injecting greatly increases the likelihood of infection with blood-borne viruses such as HIV and hepatitis C (HCV), the likelihood of other infections such as skin abscesses and endocarditis, the likelihood of developing a substance use disorder, and the likelihood of an overdose (Degenhardt & Hall, 2012; Garfein, Vlahov, Galai, Doherty, & Nelson, 1996; Kerr et al., 2007; Spijkerman, van Ameijden, Mientjes, Coutinho, & van den Hoek, 1996). As injecting drug use is heavily stigmatized, injecting also increases the likelihood that the user will experience severe social discrimination (Ahern, Stuber, & Galea, 2007). Compared to intranasal administration, injecting typically produces more intense drug effects and is a relatively cost-efficient method of drug administration. The transition from non-injecting to injecting drug use is often considered a permanent change in the preferred route of drug administration. While the person who injects may also use non-injectable drugs (nicotine, alcohol, marijuana), continued use of injectable drugs is likely to be primarily through injecting. “Reverse transitions” from injecting to non-injecting drug use have been observed in a variety of locations, including New York City (Des Jarlais et al., 2007), New Haven (Schottenfeld, O'Malley, Abdul-Salaam, & O'Connor, 1993), Baltimore (Genberg et al., 2011), Amsterdam (Buster et al., 2009), Brazil (Inciardi et al., 2006), China (Li et al., 2011) and Malaysia (Tejani, Chawarski, Mazlan, & Schottenfeld, 2011). These “former injectors” can maintain heroin/cocaine use for long periods of time—often decades—without relapsing back to injecting (Des Jarlais et al., 2007). They do as well in methadone treatment as persons who inject (Schwartz et al., 2015) and they are less likely to acquire HCV than persons who continue to inject (Des Jarlais et al., 2013). There is still much that is not known about reverse transitions from injecting to non-injecting drug use, in particular, how some former injectors avoid relapse to injecting over long periods of time. Relapse is considered one of the defining characteristics of substance use disorders. One would expect that persons who have reverse transitioned from injecting to non-injecting drugs would have great difficulties in avoiding relapse back to a route of administration that produces an intense drug effect at a relatively low monetary cost. For example, in a Baltimore study of 936 persons who ceased injecting, three-quarters of them relapsed back to injecting, the median time before relapse was only 1 year, and both non-injecting use of heroin and of cocaine after ceasing injecting were significantly associated with shorter time to relapse (Shah, Galai, Celentano, Vlahov, & Strathdee, 2006). In this report we examine various characteristics of a group of 303 former injectors, most of whom have maintained their non-injecting drug use over long periods of time. We specifically examine their reasons for stopping injecting, the length of time since their last injection, whether they are worried about relapsing to injecting, their use of specific mechanisms for avoiding relapse, and their attitudes towards the different highs produced by injecting versus non-injecting drug use. Finally, we consider implications of the findings for reducing drug injecting and for changing drug use behavior in general. 2. Materials and Methods The findings reported here are derived from data collected from patients/subjects entering the Mount Sinai Beth Israel drug detoxification and methadone maintenance programs in New York City. The methods for this “Risk Factors” study have been previously described in detail (Des Jarlais et al., 1989; Des Jarlais et al., 2009) so only a summary will be presented here. The Mount Sinai Beth Israel detoxification program serves New York City as a whole, with approximately half of the patients residing in Manhattan, one quarter in Brooklyn, one-fifth in the Bronx, and the remainder (about 5%) in other areas. Patients enter the program voluntarily. Research staff visited the general admission wards of the program in a preset order and examined all intake records of a specific ward to construct lists of all patients admitted within the prior 3 days. All of the patients on the list for the specific ward were then asked to participate in the study. Among patients approached by our interviewers, willingness to participate was more than 95%. After all of the patients admitted to a specific ward in the 3-day period had been asked to participate and interviews had been conducted among those who agreed to participate, the interviewer moved to the next ward. As there was no relationship between assigning patients to wards and the order that the staff rotated through the wards, these procedures would yield an unbiased sample of persons entering the detoxification program. A structured questionnaire covering demographic characteristics, HIV risk behavior, and drug use history was administered by a trained interviewer to each patient. Most drug use and HIV risk behavior questions referred to the 6 month period prior to the interview. Subjects were asked if they had ever injected illicit drugs, and if yes, their age at first injection and how long it had been since their last injection. “Former injectors” were operationally defined as subjects who 1) reported that they had injected drugs at some point in their lives, 2) reported that they had not injected within the last 6 months, and 3) that they had continued to use injectable drugs (heroin, cocaine or amphetamines) through non-injecting routes of administration (intranasal use and/or smoking and/or oral use). Former injectors were also asked about reasons for stopping injecting, whether they were using specific strategies to avoid relapse, and if yes, to describe those strategies. Multiple responses were permitted for both reasons for ceasing injecting and strategies. Subjects were also asked to compare the “highs” of cocaine and heroin when used through different routes of administration. They were asked “How do you compare the high of injecting heroin (and/or cocaine) to the high of snorting heroin (and/or cocaine)?” After completing the interview, each participant was seen by an HIV counselor for pretest counseling for HIV and HCV, along with specimen collection. (It was not possible to collect serum samples from all participants due to problems with collapsed veins.) HIV testing was conducted at the New York City Department of Health laboratory by using a commercial, enzyme-linked, immunosorbent assays (EIA) test with Western blot confirmation (BioRad Genetic Systems HIV-1-2+0 EIA and HIV-1 Western Blot, BioRad Laboratories, Hercules, CA). Samples were tested for HCV antibody with the Ortho HCV enzyme immunoassay (EIA) 3.0 (Ortho-Clinical Diagnostics, Inc., Raritan, NJ). Samples with optical density values of > 8.0 were considered positive, samples with values of 1.0 to 8.0 were confirmed positive with radio-immune blotting assay (RIBA) (Chiron RIBA HCV 3.0 Strip Immunoblot Assay, Novartis Vaccines & Diagnostics, Inc. Emeryville, CA) and samples with values < 1.0 were considered negative. Serial cross-sectional data have been collected for the project since 1990. We did permit individuals to participate in the study in different years. For the analyses reported here we used only the last interview from the 9 former injectors who participated more than once. STATA 13 (StataCorp, College Station, TX), was used for analyses and for generating graphs. We utilized the Epanechnikov kernel density estimates for smoothing curves in the graphs. The study was approved by the Mount Sinai Beth Israel Institutional Review Board. 3. Results A total of 303 participants were included in the analysis; 63% from the detoxification program and 37% from the methadone maintenance program. Below we describe the participant sample along with the results of the qualitative analysis of injecting patterns, strategies to avoid relapse back to injecting, and how different routes of administration produce different highs. 3.1 Demographics and Drug Use Behavior Table 1 presents demographic characteristics, current drug use behaviors, HIV and hepatitis C (HCV) serostatus. The subjects were predominantly male and predominantly African-American and Latino/a. They had a mean age of 50 (SD 9.2), and had injected drugs for considerable amounts of time, with a mean of 14 and median of 12 years of injecting. Intranasal heroin was used by a substantial majority (71%) of subjects in the 6 months prior to the interview, though a majority (53%) also reported smoking crack cocaine and a substantial minority (34%) reported using intranasal cocaine. All subjects reported previous episodes of substance use treatment, with 98% having previously received methadone and/or detoxification programs, and 61% having previously received both detoxification and methadone maintenance. Figure 1 shows the distribution of times since last injection. We represented the distribution of time since last injection in a histogram. The height of each column in the histogram depicts the number of participants corresponding to the years-since-last-injection at the base of that column. In order to also present a continuous depiction of this distribution, we used the Epanechnikov kernel density estimate to connect the column data points. In this techniques the data point being evaluated is placed at the center of the kernel and other data points are weighted according to their distance from the point being evaluated, thereby giving greater influence to the data points closer to the center of the kernel. While the modal time since last injection was within the previous year (15%), substantial proportions reported very long time periods since their last injection: 56% of these former injectors reported a decade or longer since their last injection, 35% reported 20 years or longer since their last injection, and 15% reported 30 years or longer since their last injection. With allowances for recall rounding to the nearest decade by some subjects in their reported time since last injection, the curve is similar to an exponential decay curve. Table 2 shows a cross-tabulation of last drug injected (only a single drug could be named in response to this question) and the non-injecting drug use reported for the last 6 months by the former injectors (multiple drugs could be mentioned). There is considerable continuity in the use of heroin and cocaine. Of the 227 persons who reported heroin as their last drug injected, 75% of them reported intranasal use of heroin in the 6 months prior to the interview, and of the 26 who reported cocaine as their last drug injected 85% of them reported smoking crack cocaine in the 6 months prior to the interview. Thus, even within a context of poly-drug use, these subjects maintained considerable continuity in the drugs they were using while having made a major change in their route of drug administration. 3.2 Reasons for ceasing injection Table 3 presents the reasons cited by former injectors for why they stopping injecting. Subjects were permitted to endorse multiple reasons (the percentages thus add to greater than 100%). A considerable variety of reasons were endorsed, and no single reason was endorsed by as many as 20% of the former injectors. Protecting health (avoiding HIV/AIDS endorsed by 12%, afraid of overdose by 15%, other health concerns by 17%) and problems with injecting as a route of administration (don't like needles by 16%, got tired of injecting by 14%, loss of veins by 9%, prefer mellow high of snorting by 5%, difficulties in obtaining injection equipment by 4%) were the two most frequently endorsed major categories of reasons for ceasing to inject. A substantial percentage also cited social and self-image concerns (avoiding stigmatization by 12%, avoiding track marks by 12%, maintaining self-image as a non-injector by 4%) as reasons for ceasing to inject. 3.3 Worry about relapse Many former drug users report avoiding relapse back to injecting drug use as being a “one day at a time” continuous struggle, and with great concern that they will relapse (Binswanger et al., 2012; Evans, Hahn, Lum, Stein, & Page, 2009; McKay, 1999). We asked these former injectors whether they were “worried that they would relapse back to injecting?” A very large majority (86%) reported that they were not worried about relapsing back to injecting. Length of time since last injection was negatively associated with being worried about relapsing to injecting in univariate logistic regression (see Table 4a). Among the 85 former injectors whose last injection was ≤ 36 months prior to the interview, 21 (25%) reported being worried about relapsing, while among the 218 former injectors whose last injection was > 36 months prior to the interview, only 20 (9%) were worried about relapsing back to injecting (chi squared = 12.57, df=1, p < 0.001; OR=0.31, 95% CI= 0.15 – 0.61). Worrying about relapse was not significantly associated with any other demographic and drug use variables in Table 1. 3.4 Strategies to avoid relapse Relapse prevention programs typically teach former drug users a variety of techniques to prevent relapse, including avoiding situations that would cue drug craving, seeking social support, and realizing that a single “lapse” does not have to mean a full relapse back to continued drug use (Dejong, 1994; Marlatt & Donovan, 2005; Witkiewitz & Marlatt, 2004). We asked the former injectors if they were using any specific strategy to avoid relapse, and, if they were, to briefly describe the strategy. A large majority (235/303, 78%) reported that they were not consciously using any specific strategy. Among the 67 former injectors who reported that they were using a specific strategy, 43% reported using self-talk/thinking negative thoughts about injecting, 18% reported avoiding places and people that might lead them back to injecting, 13% reported that they attended meetings, 9% reported that they were using alternative methods of drug administration, and 8% reported aversion to needles. There was a positive relationship between worrying about relapse and using specific strategies to avoid relapse—former injectors who reported worrying about relapse were more likely to report that they were using specific strategies than former injectors who were not worried about relapse (see Table 4b). Having a specific strategy was not significantly related to any of the demographic or current drug use variables in Table 1 (full data available from the first author). 3.5 Comparisons of “highs” between injecting and intranasal drug use As noted above, it is generally accepted that injecting a psychoactive drug produces a more intense drug effect than intranasal administration, though there may be considerable individual variation in the differences. We asked these former injectors if injecting heroin gave them a more intense high compared to intranasal use and if injecting cocaine gave them a more intense high compared to intranasal use. (These questions were asked only of the persons who were currently using heroin or cocaine intranasally and had injected that drug in the past.) Modest majorities of the current heroin and cocaine users reported that injecting gave them a more intense high—63% endorsing that injecting heroin gave a more intense high and 52% endorsing that injecting cocaine gave a more intense high. We assessed whether endorsing the greater intensity statements was associated with being worried about relapse (results presented in Tables 5a and 5b). The association between endorsing greater intensity of injecting and being worried about relapse approached statistical significance for heroin (p =0.066) and was significant for cocaine (p = 0.03). 4. Discussion Addiction is often defined as a chronic, relapsing condition in which it is very difficult—though not impossible—for individuals to make long-lasting changes in their patterns of drug use. The common image of a former drug user is a person who is attempting to avoid relapse, a person who must be vigilant to avoid people, places, and things that can trigger craving, and is deliberately using multiple evidence-based techniques to avoid relapse. As shown in Table 3, the former injectors interviewed in this study reported a great number of reasons for ceasing to inject drugs. Ceasing to inject usually was not a goal in itself, but rather was a means to achieve a wide variety of individual goals. From the content of the reasons in Table 3, it would appear that ceasing to inject would probably have been very effective in achieving these goals. For example, a third of the former injectors ceased injecting over 20 years ago, before large-scale syringe exchange programs were implemented in New York City. It is likely that ceasing to inject at that time provided considerable protection against HIV and HCV infection, as well as protection from transmitting to others if they were seropositive. And, as the stigmatization of injecting drug use has clearly continued in New York City, it is likely that ceasing to inject also reduced stigmatization. A recent study from Finland would also suggest that transitioning to non-injecting drug use would reduce the risk of fatal drug overdose. In that study, fatal overdoses among people who injected drugs were three times more likely than among people using the same drugs though other routes of administration (Onyeka et al., 2016). As a group, the former injectors in this study reported relatively long periods of injecting drug use—a mean of 12 years—followed by long periods since their last injection, with over half reporting 10 years or more since their last injection and over a third reporting 20 years or more since their last injection. There was, however, considerable variation among the former injectors. A subgroup of former injectors appear to be still “in the process” of actively avoiding relapse to injection drug use. They were worried about relapsing, had shorter times since last injection, deliberately used specific strategies to avoid relapse and were likely to recall injecting as providing a more intense high than intranasal drug use. However, this description fits only a modest percentage of these former injectors—only 6/303 (2%) had all four of these characteristics, and 39 (13%) had three of these characteristics. A second, much larger proportion of these former injectors appear to have reached stability where avoiding relapse to injecting was no longer problematic for them. It had been a long time since their last injection (at least 3 years and with a mean of 19 years), they were not worried about relapsing, they were not consciously using specific strategies to avoid relapse, and only about half of them recalled injecting as providing a more intense high than intranasal use. This description fits 145/303 (48%) of the former injectors in our sample. It would seem that they had fully replaced the habit of injecting drug use with a habit of non-injecting drug use. Changing drug use behavior in a direction of reduced individual and societal harm and in a way that becomes self-sustaining is a major goal of harm reduction and substance use treatment programs. It is worth considering several aspects of the sustained behavior change exhibited by these former injectors. In addition to individual goals, former injectors also ceased injecting and avoided relapse in an environment that provided facilitators for doing so. The quality of street heroin and cocaine in New York City has been relatively high for a long time, so that it is economically feasible to maintain a drug habit without having to inject. There are also low threshold, harm reduction-oriented substance use treatment programs in New York City, so that it is possible to receive treatment that provides a respite from the difficulties of street drug use, reduce one's level of drug tolerance, and reduce (or cease) drug use. 98% of the former injectors in this study reported that they had previously received either detoxification or methadone maintenance treatment and 61% reported that they had previously received both detoxification and methadone maintenance treatment. This episodic treatment for substance use problems clearly did not lead to permanent abstinence, but it is likely to have reduced the chances of relapsing to injecting. These former injectors did not, however, receive any formal treatment services for avoiding relapse to injecting while continuing non-injecting use of heroin and cocaine. Currently, neither drug treatment programs nor syringe exchange programs in New York City support ceasing to inject while continuing to use heroin or cocaine through non-injecting routes of administration as a formal “treatment goal.” About a sixth of the former injectors gave their reason for injecting as “They don't like needles.” Fear of/dislike for needles persisted during their injecting careers. Further research into fear of/dislike for needles may provide valuable insights for the treatment of persons with substance use disorders who are currently injecting and for programs to prevent initiation into injecting drug use. 4.1 Memories of injecting Almost half of these former injectors did not recall injecting as producing a “more intense” high than intranasal heroin or cocaine use is a particularly interesting finding deserving of additional research. It may be that experiencing injecting as not producing a more intense high has a strong biological component and is a selective factor for ceasing to inject and for avoiding relapse to injecting. It is also possible that their memories of injecting were evoked during the long time periods since last injection, and that interference in reconsolidation of these memories led to qualitative changes in the memories towards injecting being a less intense experience. Understanding how memories of injecting might change after ceasing to inject—or ceasing to use specific drugs—could provide important insights into avoiding relapse. 4.2 Limitations The major limitation is that the data come from cross-sectional surveys rather than a longitudinal study. Thus, we do not know how many former injectors relapsed back to injecting, or the factors that led them to relapse. We also do not know how many ceased injecting and then later ceased using heroin and cocaine. We also do not know when changes from “being in the process” of avoiding relapse changed to reaching a point where “relapse is no longer problematic.” In the associations between the reasons for ceasing to inject and current (past 6 month) non-injecting drug use, the reason for ceasing to inject would necessarily have preceded current drug use, but considerable caution is needed with respect to drawing causal inferences because of the many other factors that might have operated over the very long time periods involved. This study also does not permit estimating the number of former injectors in New York City. In a respondent driven sampling (RDS) study conducted in 2004 (Abdul-Quader et al., 2006), current injectors were permitted to recruit current non-injecting heroin and cocaine users and current non-injecting users were permitted to recruit current injectors. The two groups (current injectors and current non-injecting users) were equally likely to recruit members of the other group as they were to recruit members of their own group (RDS homophilies near 1.0). Half of the subjects recruited in that study were non-injecting drug users and half of the non-injecting users reported that they had previously injected heroin and/or cocaine. Thus, it would appear that about a quarter of street heroin and cocaine users in the city are former injectors, though this may be changing due to the new increases in prescription opioid users beginning to inject heroin. We did ask the former injectors why they had ceased injecting. From the content of the reasons for ceasing to inject (see Table 3), we would expect that the persons who had ceased injecting and had avoided relapse to injecting are likely to have accomplished these goals. We did not, however specifically determine if they had accomplished these goals. These limitations would need to be addressed in a cohort study, but note that this may require a very long-term study to capture the full experience of avoiding relapse to injecting over decades during which these former injectors avoided relapse back to injecting. 4.3 Implications for promoting long-term reductions in very harmful drug use behaviors These former injectors did not cease using heroin and cocaine but they did make a long-term change in their drug use behavior that almost certainly reduced important harmful effects of drug use for both themselves and for the community. This sustained change process appears to involve at least three factors: The majority set individual, achievable behavior change goals, with ceasing injection a means to these goals. Ceasing injection was not an externally imposed goal. Abstinence from heroin and cocaine use was not required, though it was not precluded as part of the long-term drug behavior change process. That important behavior change occurred while the former injectors continued to use psychoactive drugs supports the logic of using agonist drug therapies and not requiring abstinence as a precondition for other important behavior changes. They had a safety net of substance use treatment programs that could be utilized when they could no longer manage their non-injecting drug use. Note that all of these former injectors were interviewed on entry into substance use treatment programs, and all reported episodes of previous drug treatment. 4.4 Combined prevention and care for HIV, HCV, and overdose among PWID Implementing programs that support “reverse transitions” from injecting to non-injecting drug use might be an important part of combined prevention and care for HCV. HCV is much more efficiently transmitted than HIV through sharing of injection equipment and high rates of HCV infection have persisted among injection drug users in many places where HIV has been brought under control. PWID who reverse transition to non-injecting drug use should greatly reduce their chances of acquiring HIV and/or HCV. PWID who reverse transition after being infected with HIV or HCV should greatly reduce their chances of transmitting HIV or HCV to others. Additionally, HCV infected PWID who reverse transitioned and were successfully treated for HCV would greatly reduce their chances of re-infection with HCV. Programs to support “reverse transitions” back to non-injecting drug use might be particularly helpful in areas experiencing transitions from non-medical use of opioid analgesics to heroin injecting. 5. Conclusions The former injectors in this study have made an important change in their drug use behavior that would reduce adverse consequences at both the individual and societal level. For the majority, this change appears to have reached a point where relapsing back to injecting is no longer problematic for them. Understanding how long-term, self-sustaining changes occur in drug use behaviors is a fundamental question in research on problematic drug use. Additional research on former injectors may provide valuable insights into such change processes. We would suggest that research on cessation of injection among persons not ready or able to completely cease drug use be conducted with a framework of combined prevention and care for HIV/HCV among persons who use drugs. Acknowledgments We would like to thank the staff at Mount Sinai Beth Israel who collected the data and performed serologic testing for the participants included in the analysis. We would also like to thank all co-authors for their careful revisions and recommendations of the manuscript. Role of Funding Source This work was supported through grants R01DA003574, R01DA035707, and P30DA011041 from the US National Institute on Drug Abuse The funding agency had no role in the design, conduct, data analysis or report preparation for the study. Figure 1 Distribution of time since last injection (with Epanechnikov kernel density smoothing) Table 1 Demographics, current drug use characteristics, and HIV and HCV seroprevalence Mean SD Age 50 9.2 Years injected 12 12.2 N % Total 303 100 Gender     Female 56 18     Male 246 81 Race/ethnicity     White 51 17     African American 131 43     Latino/a 115 38 Current (past 6 month) drug use     Speedball (nasal) 34 11     Heroin (nasal) 214 71     Cocaine (nasal) 103 34     Crack cocaine 162 53 Previous drug treatment experience 303 100 Total with valid test results 258     HIV+ 34 13     HCV+ 170 66 Table 2 Current drug use by last drug injected among former injectors Last drug injected Current drug use Speedball (nasal) N (%) Heroin (nasal) N (%) Heroin (smoked) N (%) Cocaine N (%) Crack cocaine N (%) Speedball (N=47) 9 (19) 33 (70) 1 (2) 20 (43) 23 (49) Heroin (N=227) 20 (9) 170 (75) 13 (6) 68 (30) 114 (50) Cocaine (N=26) 4 (15) 10 (38) 2 (8) 13 (50) 22 (85) Table 3 Reasons reported for stopping injecting among former injectors Reason reported N (%) Total 303 (100) Health concerns (avoid AIDS, avoid overdose, other health concerns) 131 (44) Problems with injecting (don't like needles, tired of injecting, loss of veins, problems obtaining injecting equipment) 134 (45) Social reactions/self-image (stigmatization by others, wanting to preserve self-image as non-injector) 85 (28) Other reasons 66 (22) Table 4a Being “worried about relapsing to injecting” among former injectors Worried Yes N (%) No N (%) OR 95% CI Time since last injection ≤ 36 months 21 (25) 64 (75) 1.00 > 36 months 20 (9) 198 (91) 0.31 0.15 - 0.61 Table 4b Being “worried about relapsing to injecting” among former injectors Worried Yes N (%) No N (%) OR 95% CI Specific strategy to avoid relapse Yes 15 (37) 52 (20) 1.00 No 26 (63) 209 (80) 0.43 0.21 - 0.88 Table 5a Intensity of the high from heroin injection and “worried about relapsing to injecting” among former injectors Worried Yes N (%) No N (%) OR 95% CI More intense high from injection No 22 (16) 112 (84) 1.00 Yes 6 (8) 73 (92) 2.39 0.93 – 6.18 Table 5b Intensity of the high from cocaine injection and “worried about relapsing to injecting” among former injectors Worried Yes N (%) No N (%) OR 95% CI More intense high from injection No 4 (8) 45 (92) 1.00 Yes 13 (24) 41 (76) 3.57 1.08 – 11.82 Highlights Former PWID reported long term behavior changes, reducing individual and societal harms Many former PWID permanently transitioned back to non-injection drug use Over 50% of the sample was not worried about relapsing back to injecting drugs Multiple reasons for ceasing injection drug use were cited by former PWID Ceasing to inject provides considerable protection against HIV and HCV infection This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final citable form. Please note that during the production process errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain. References Abdul-Quader AS Heckathorn DD McKnight C Bramson H Nemeth C Sabin K Des Jarlais DC Effectiveness of respondent-driven sampling for recruiting drug users in New York City: findings from a pilot study. Journal of Urban Health 2006 83 3 459 476 16739048 Ahern J Stuber J Galea S Stigma, discrimination and the health of illicit drug users. Drug and Alcohol Dependence 2007 88 2 188 196 17118578 Binswanger IA Nowels C Corsi KF Glanz J Long J Booth RE Steiner JF Return to drug use and overdose after release from prison: a qualitative study of risk and protective factors. 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PMC005xxxxxx/PMC5117632.txt
LICENSE: This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. 101231976 32624 Nat Chem Biol Nat. Chem. Biol. Nature chemical biology 1552-4450 1552-4469 27748750 5117632 10.1038/nchembio.2207 NIHMS810261 Article Discovery of MRSA active antibiotics using primary sequence from the human microbiome Chu John 1‡ Vila-Farres Xavier 1‡ Inoyama Daigo 3 Ternei Melinda 1 Cohen Louis J. 1 Gordon Emma A. 1 Reddy Boojala Vijay B. 1 Charlop-Powers Zachary 1 Zebroski Henry A. 2 Gallardo-Macias Ricardo 3 Jaskowski Mark 3 Satish Shruthi 3 Park Steven 4 Perlin David S. 4 Freundlich Joel S. 3 Brady Sean F. 1* 1 Laboratory of Genetically Encoded Small Molecules, The Rockefeller University, New York, New York, USA 2 Proteomics Resource Center, The Rockefeller University, New York, New York, USA 3 Department of Pharmacology, Physiology, and Neuroscience, Rutgers University – New Jersey Medical School, Newark, New Jersey, USA 4 Public Health Research Institute, Rutgers University – New Jersey Medical School, Newark, New Jersey, USA * Corresponding author: sbrady@rockefeller.edu ‡ These authors contributed equally to this work. 23 8 2016 17 10 2016 12 2016 17 4 2017 12 12 10041006 This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. Here, we present a natural product discovery approach whereby structures are bioinformatically predicted from primary sequence and produced by chemical synthesis (synthetic-bioinformatic natural products, syn-BNPs), circumventing the need for bacterial culture and gene expression. When applied to nonribosomal peptide synthetase gene clusters from human-associated bacteria we identified the humimycins. These antibiotics inhibit lipid II flippase and potentiate β-lactam activity against methicillin-resistant Staphylococcus aureus in mice, potentially providing a new treatment regimen. The characterization of small molecules produced by bacteria in laboratory culture has been a key step to understanding bacterial physiology and developing small molecule therapeutics.1 As successful as this approach has been for identifying novel bioactive small molecules, extensive sequencing of bacterial genomes and metagenomes has revealed that the bacterial biosynthetic diversity traditionally accessed in the laboratory represents only a small fraction of what is predicted to exist in nature.2,3 This shortcoming arises from our inability to culture most bacteria in the laboratory and from the fact that most biosynthetic gene clusters remain silent under laboratory fermentation conditions.4 Here, we present a bioactive small molecule discovery pipeline that circumvents the requirement for either bacterial culture or gene cluster expression. In our approach, natural product structures are bioinformatically predicted from primary sequence data and produced by chemical synthesis. Since natural products often appear in nature as families of related structures with the same biological activity, we reasoned that even if our structural predictions were not perfect, many syn-BNPs would be sufficiently accurate representations of nature to elicit the intended bioactivities. We have called these bioinformatically inspired compounds syn-BNPs for Synthetic Bioinformatic Natural Products (Fig. 1a). The human microbiome is an exemplary test case for a syn-BNP discovery approach. Tremendous resources have been allocated to the sequencing and bioinformatic analysis of the human microbiome.5,6 Nevertheless, the functional characterization of this data, including commensal bacteria-encoded natural product biosynthetic gene clusters, remains rare. Our interest in exploring syn-BNPs encoded by the human microbiota stems from the potential use of these metabolites as therapeutics and as tools for improving our understanding of human microbiome functions. Because antibiotics can serve as medicines and as modulators of the composition of the human microbiome, we chose to screen syn-BNPs predicted from the human microbiome for antibacterial activity against human associated commensal and pathogenic bacteria. Systematic bioinformatic analysis of sequenced bacterial genomes indicate that nonribosomal peptides (NRPs) are one of the most common and diverse families of complex secondary metabolites produced by bacteria.7,8 Over the past two decades, a number of models have been developed for predicting the identity, order, and modification of the amino acids comprising an NRP, based solely on the primary sequence of NRP megasynthetases.9–12 Concurrently, solid phase peptide synthesis (SPPS) of structurally diverse peptides has become rapid and economical, making NRP gene clusters an ideal test case for a syn-BNP approach (Fig. 1b). Genomic sequence data from human (commensal and pathogenic) associated bacteria were bioinformatically queried for gene clusters predicted to encode large NRPs (≥5 residues), as short NRPs are often highly modified and are therefore not easily accessible using SPPS alone. This analysis led to the identification of 57 unique nonribosomal peptide synthetase (NRPS) gene clusters, from which we removed those that appeared to be incomplete in the existing sequence data and those containing more than one PKS module, a thioreductase domain, or any heterocyclization domains. The chemical outputs of the remaining 25 gene clusters, which we believed to be amenable to SPPS, were predicted using three published NRPS prediction algorithms (Stachelhaus, Minowa, and NRPSPredictor2) to produce syn-BNP targets.9–12 In instances where bioinformatic predictions for human microbiome associated gene clusters diverged strongly between algorithms (e.g., side-chains were predicted to carry opposite charges), multiple syn-BNP peptides were designed and synthesized. In all cases where NRPS gene clusters were bioinformatically predicted to encode an N-terminally acylated peptide, we elected to design the syn-BNP to be N-acylated with β-hydroxymyristic acid (HMA), a fatty acid commonly observed in NRPs.13 In total, 30 syn-BNPs targets were designed based on the gene clusters found in human commensal bacterial sequence data. After two rounds of SPPS using standard Fmoc chemistry, we obtained pure samples for 25 of the 30 targeted syn-BNPs (Supplementary Results, Supplementary Table 1). To identify novel antibiotic scaffolds with potential in vivo roles in shaping the ecology of the human microbiome, we assayed this collection of syn-BNPs for antibacterial activity against a panel of common human commensal and pathogenic bacteria. This led to the identification of two antibiotics we have trivially named humimycin A (1) and B (2) (human microbiome mycin, Fig. 2a). The humimycins were predicted from closely related NRPS gene clusters found in the genomes of Rhodococcus equi and Rhodococcus erythropolis, respectively. Bioinformatic analyses of these two NRPS gene clusters indicated that they encoded hepta-peptides that differed at only the fourth and sixth residues (F/Y and V/I, respectively, Fig. 2b). Both syn-BNPs were synthesized with N-terminal HMA modifications, due to the presence of starter condensation domains (Cs) in the gene clusters, which are associated with acylation of the first amino acid of an NRP.13 Rhodococcus species have been extensively studied for natural product production using traditional fermentation-based discovery methods. None of these studies report the identification of a metabolite resembling the humimycins.14 Likewise, our extensive analysis of Rhodococcus species culture broth extracts by both LCUV and LCMS analysis did not reveal any metabolites related to the humimycins, suggesting that the humimycin gene cluster is silent under laboratory fermentation conditions. The humimycins were found to be broadly active against Firmicutes and to show some activity against Actinobacteria, when screened for antibiosis against commensal and pathogenic bacteria (Fig. 2c). The humimycins are particularly active against Staphylococcus and Streptococcus species, including common members of the normal human flora such as S. aureus (minimum inhibitory concentration (MIC) 8 μg/mL) and S. pneumoniae (MIC 4 μg/mL). This spectrum of activity is interesting in light of the fact that Firmicutes and Actinobacteria dominate the human microbiota of the gut (Fig. 2d).15 In a structure-activity relationship study, we found that no residue in 1 could be replaced with alanine without dramatically impacting the potency of the antibiotic (Supplementary Table 3). Humimycin A exhibits MICs ranging from 8–128 μg/mL against methicillin-resistant S. aureus (MRSA) clinical isolates (Supplementary Table 4). To study the antibacterial mode of action of the humimycins, we selected S. aureus USA300 mutants that could survive on 2.5 times the MIC (20 μg/mL) and sequenced the genomes of 23 resistant mutants. Upon comparison to the parent strain, we found that all 23 mutants contained one non-synonymous mutation in SAV1754, an essential gene in S. aureus (Supplementary Figure 3 and Table 5). Fifteen of these strains contained no other detectable mutations. Overexpression of SAV1754 in S. aureus confers resistance to humimycin A (MIC >128 μg/mL), further supporting inhibition of SAV1754 as a likely mode of action of the humimycins (Supplementary Table 6). The gene product of SAV1754 is believed to be a homolog of MurJ, a flippase responsible for the translocation of peptidoglycan precursors from the inside to the outside of the cell.16 While MurJ is essential in many bacteria, including many important pathogens, it remains an underexplored antibacterial target.17 The ability of SAV1754 inhibitors to potentiate β-lactam antibiosis is thought to arise from the fact that both antibiotics target the same essential pathway, peptidoglycan biosynthesis (Fig. 3a). In a high throughput screen for molecules that could potentiate β-lactam antibiosis against otherwise resistant strains Merck & Co. identified synthetic small molecule inhibitors of SAV1754.18,19 Humimycin A exhibits a similar ability to restore β-lactam sensitivity to β-lactam resistant bacteria. For example, the MIC of carbenicillin (carboxypenicillin) was reduced from 32 to 1 μg/mL in the presence of 2 μg/mL humimycin A (0.25× MIC) against MRSA USA300 (Fig. 3b), one of the most predominant community-associated MRSA strains in the U.S. Humimycin A’s ability to potentiate β-lactam activity is also seen with strains where it alone shows no detectable antibacterial activity. For example, the MRSA COL strain, while not susceptible to humimycin A (MIC >512 μg/ml) and exhibiting a very high MIC for the β-lactam dicloxacillin (MIC 256 μg/mL), is sensitive to dicloxacillin at 8 μg/mL in the presence of as little as 4 μg/mL of humimycin A (Fig. 3c). The ability of humimycin A to potentiate β-lactam activity in vitro led us to explore the possibility that it might do the same in vivo. In murine tolerability studies humimycin A is tolerated at concentrations (>50 mg/kg), far exceeding those expected to be necessary for β-lactam potentiation. In a murine peritonitis-sepsis model treatment of a MRSA COL infection with dicloxacillin and humimycin together dramatically increases survival compared to treatment with either humimycin or dicloxacillin alone (Fig. 3d), potentially providing a novel MRSA treatment regimen. While R. equi has historically been regarded as an opportunistic pathogen seen in animals and immune-compromised patients,20 R. erythropolis is found as a part of the normal human nasal, mouth and eye microbiota.21,22 Interestingly, the occurrence of Rhodococcus species in the gut increases dramatically to a median of 30% in some patients diagnosed with ulcerative colitis (UC).23 The production of an antibiotic with activity against Firmicutes and Actinobacteria could play a role in establishing the overpopulation of R. erythropolis in the UC gut as Firmicutes and Actinobacteria normally represent nearly half of the gut microbiota.15 In addition to the potential to provide new small molecule therapeutics, characterization of molecules inspired by commensal bacteria biosynthetic gene clusters can provide a means for developing hypotheses about how commensal bacteria affect human physiology. For example, the discovery of the humimycins provides a testable mechanistic hypothesis for how dysbiosis of gut microbiota might evolve in UC.24 Our identification of the humimycins using a syn-BNP approach validates this as a strategy for identifying bioactive metabolites and highlights the unique state of the field of natural product chemistry today. Extensive biosynthetic studies have culminated in our emerging ability to predict the structures of many natural products from primary sequence alone. While in this study we focused on the synthesis of linear peptides because of the ease with which they can be generated by SPPS, there are many ways to expand this approach to more topologically and functional complex NRPs. For example, the construction of cyclic peptides using purified thioesterase domains is compatible with SPPS.25 Based on our analysis of high-quality sequenced bacterial genomes in GenBank not associated with the human microbiome, there are currently more than 1,500 unique large NRPS gene clusters (encoding ≥5 amino acids) amenable to a SPPS-based syn-BNP approach. As the sequencing of microbial genomes is still in an early exponential growth phase, this number should only continue to grow for the foreseeable future (Supplementary Figure 2). With the development of improved bioinformatic prediction algorithms for biosynthetic gene cluster families beyond NRPSs and the incorporation of more sophisticated chemical and chemo-enzymatic synthesis steps into the production of syn-BNPs, we believe this approach will enable broad and rapid access to diverse bioactive compounds that are inspired by gene clusters found within the ever-growing assemblage of microbial sequence data. Online Methods Bioinformatic prediction of NRPs Genome sequences of the human microbiota were downloaded from the NIH Human Microbiome Project (HMP, (ftp://ftp.ncbi.nlm.nih.gov/genomes/HUMAN_MICROBIOM/Bacteria)26 and the Human Oral Microbiome Database (HOMD, (ftp://ftp.homd.org/HOMD_annotated_genomes).27 The software package Antibiotics and Secondary Metabolite Analysis Shell (antiSMASH) v2.0 was used for the identification and prediction of NRP biosynthetic gene clusters encoded by these genomes.28 Syn-NRPs originating from the HMP and HOMD databases were named serially as [Human.N] and [Oral.N]. All syn-NRPs discussed in this manuscript are listed in Supplementary Table 1. AntiSMASH consults three prediction algorithms to call the amino acid substrate specificity of an adenylation domain (NRPSPredictor2, Stachelhaus code, and Minowa). A consensus prediction refers to the situation wherein two (or all three) algorithms make consistent substrate predictions for a given adenylation domain. In this case the predicted amino acid was used in the synthesis of the syn-BNP. In case of a minor conflict between prediction algorithms we opted for the amino acid with the smaller side-chain, e.g., Val/Leu/Ile and Ser/Thr. In case of major conflicts (e.g., where side-chains were predicted to carry opposite charges), both peptides were synthesized. Tyrosine and phenylalanine prediction made by NRPSPredictor2 or Stachelhaus code were chosen over tryptophan (Trp) predictions made Minowa, as we noticed that Trp is overrepresented in Minowa predictions. Lastly, tyrosine (Tyr) was used at the first residue in place of p-hydroxyphenylglycine (Hpg) in Human.8v1 and v2. To check the robustness of these NRPS prediction algorithms we carried out a similar analysis of NRPS gene clusters deposited in the MiBIG database and found that the core peptide encoded by the vast majority NRPS gene clusters was predicted correctly (Supplementary Figure 2). Peptide synthesis Resins for peptide synthesis were purchased from AnaSpec. Coupling reagents (PyBOP) and Nα-Fmoc/side-chain protected amino acids were purchased from P3BioSystems. 3-Hydroxymyristic acids were purchased from TCI America (racemic mixture) and Santa Cruz Biotechnology (pure enantiomers). All other chemical reagents and solvents were purchased from Sigma Aldrich. Reaction vessels were custom made by the Scientific Glassblowing Laboratory at the Department of Chemistry of Yale University. Pure samples were obtained for 25 of the 30 syn-BNP peptides targeted for chemical synthesis (Supplementary Table 1). 20 of these peptides were purchased through the custom peptide synthesis service of GenScript Biotech Corporation and five were synthesized in-house. Peptides from GenScript were delivered as lyophilized materials that had been HPLC-purified and MS-verified (MALDI). All pure peptides were dissolved in DMSO at 12.8 mg/mL as stock solutions and stored at −20 °C. In-house peptide syntheses, including humimycin A and B, were built on Wang resin29 following standard Fmoc/tBu SPPS methods. The first amino acid (6 equiv.) was activated using DIC (3 equiv.) in 10% DMF/DCM (0°C), added to the resins in the presence of DMAP as a catalyst (0.1 equiv.) and shaken under nitrogen (4 h at 0°C). Unreacted resins were capped using acetic anhydride in pyridine (1 h). Fmoc removal was accomplished using three rounds of treatment with 20% piperidine in DMF (15, 10, and 5 min. each). All ensuing amino acids were coupled twice. In each coupling an Nα-Fmoc and side-chain protected amino acid was activated using a mixture of PyBOP (4 equiv.) and DIEA (8 equiv.), followed by reaction with the peptide on-resin (1 h). Peptides were cleaved by 95% TFA supplemented with TIS and H2O (2.5% of each, v/v) for 2 h, concentrated to approximately 10% of the original volume, diluted with aqueous MeCN (75%, v/v), passed through a 0.45 μm filter and HPLC-purified. All purified peptides were examined by LC/MS (ESI). Characterization of the humimycins A racemic mixture of 3-hydroxymyristic acid was used for N-terminal modification in our initial syntheses of all syn-BNPs. Humimycin A diastereomers showed different MIC values when tested against MRSA USA300 (Supplementary Table 3). The absolute stereochemistry of the most active diastereomer was determined by comparing HPLC-purified peptides from the bulk synthesis to independent batches of small-scale syntheses using enantiopure (R) and (S)-3-hydroxymyristic acid (Supplementary Figure 1). The more potent (S)-isomer is referred to as humimycin A (1). In the case of humimycin B the analogous (S)-isomer was purified and is referred to as compound 2. Humimycin A (1) HRMS: m/z calculated for [M − H]− (C58H84N7O14): 1102.6076, found: 1102.6075. Humimycin B (2) HRMS: m/z calculated for [M − H]− (C59H86N7O15): 1132.6182, found: 1132.6194. Syn-BNP screening Syn-BNPs were screened against a panel of commensal and pathogenic bacteria covering the four major phyla associated with the human microbiome. This included five Actinobacteria, four Bacteroidetes, six Firmicutes and three Proteobacteria species. All peptides were tested in duplicate for antibiosis activity. Assays were performed in microtiter plates, wherein each well contained growth media (see Supplementary Table 2 for a list of growth media) (100 μL), syn-BNP (32 μg/mL) and bacteria diluted 1,000-fold from a stationary phase culture. Binary antibiosis results for most bacteria were determined by visual inspection after static incubation at 37 °C for 18 h. P. melaninogenica and Eubacterium sp. 3_1_31 were grown for 36 h, and C. amycolactum was grown for 60 h. Specific MICs were determined for syn-BNPs that inhibited bacterial growth in this initial screen (see Susceptibility assays, part a). Bacteria species associated with the human flora were obtained from BEI Resources. Susceptibility assays a) Standard assays MIC assays were performed in duplicate in 96-well microtiter plates based on the protocol recommended by Clinical and Laboratory Standards Institute.30 DMSO stock solutions of syn-BNPs (12.8 mg/mL) were added to the first well in a row and serially diluted (2 fold per transfer) across the microtiter plate. The last well was reserved for a peptide-free control. Overnight cultures of bacteria were diluted 5,000-fold and 50 μL was used as an inoculum in each well. MIC values were determined by visual inspection after 18 h incubation (37 °C, static growth). b) Synergy assays Synergistic β-lactam-humimycin activities were assessed through a two-dimensional (2D) susceptibility assay. Two fold serial dilutions were carried out as described above. Carbenicillin (a β-lactam antibiotic) was diluted serially from left to right, and humimycin was diluted serially from top to bottom. The highest concentration tested for both antibiotics was 32 μg/mL. Fractional inhibitory concentration (FIC) is defined as the ratio of the apparent synergistic MIC divided by the MIC of the antibiotic measured alone.29 Selection of humimycin A resistant mutants A single S. aureus USA300 colony (the parent) from a freshly struck plate was inoculated into LB medium and grown overnight at 37 °C. Part of the overnight culture (4 mL) was spun down and kept frozen at −20 °C. The rest of the overnight culture was diluted 100-fold, supplemented with humimycin A at 20 μg/mL (2.5X MIC) and 100 μL aliquots was distributed into 200 unique microtiter plate wells. Growth was observed in 50 wells after overnight incubation, indicating the presence of bacteria with mutation(s) conferring humimycin A resistance. Approximately 2 μL of culture from each of these wells was used to inoculate freshly prepared 100 μL aliquots of LB media supplemented with humimycin A (20 μg/mL). The resulting cultures after overnight incubation were struck out for single colonies on LB/agar plates supplemented with humimycin A (20 μg/mL) for single colonies. Genome sequencing Single colonies of 23 humimycin A resistant mutants as well as the USA300 parent were individually inoculated into 4 mL of LB media free of any antibiotics. After overnight incubation cells were collected by centrifugation. DNA extractions were performed using a MasterPure Purification Kit (EpiCentre Biotechnologies). Multiplex sequencing libraries were prepared from the resulting genomic DNA using a Nextera XT DNA Sample Preparation Kit (FC-131-1024) with Nextera XT Index kit (FC-131-1001) based on protocols provided by the manufacturer (Illumina). Briefly, the genomic DNA was treated with RNase and quantified using the Qubit dsDNA HS Assay System (Q32854, ThermoFisher Scientific). Tagmentation and PCR amplification proceeded according to the manufacturer’s protocol, after which the quality and size of the libraries were verified using HS D1000 ScreenTape (TapeStation 2200, Agilent Technologies). Libraries were pooled at equimolar concentrations and column purified by NucleoSpin Gel and PCR Cleanup (MN-750609-250, Macherey-Nagel). The resulting tagged DNA library was size-selected by E-Gel (Life Technologies) and the 450 bp band was excised. The final library pool was checked for molarity on TapeStation and sequenced using MiSeq Reagent Kit v3 (MS-102-3003, Illumina). Mutation (SNP) identification De-barcoded MiSeq reads were assessed for mutations by comparing each read against the reference genome of Staphylococcus aureus USA300_FPR3757 (RefSeq assembly accession: GCF_000013465.1). All reads were mapped to the reference genome using SNIPPY (https://github.com/tseemann/snippy) for the identification of variants. SNIPPY is a wrapper of several programs including freebayes (https://github.com/ekg/freebayes).32 Single-nucleotide polymorphisms (SNP) observed in the parent strain were then subtracted from those observed in the humimycin A resistant strains, resulting in a final list of SNPs (Supplementary Table 5). Cloning and overexpression of SAV1754 The SAV1754 gene was PCR amplified from wild type S. aureus USA300 and a mutant resistant to humimycin A (mutant no. 8, Supplementary Table 5). PCR products and the pRMC233 vector were digested (SacI/KpnI) and ligated, followed by transformation into S. aureus RN4220 and selection on BHI agar plates containing chloramphenicol (10 μg/mL). The recombinant plasmids were verified by DNA sequencing. Overnight cultures of the resulting S. aureus strains were used to inoculate LB containing chloramphenicol (10 μg/mL). Late log-phase cultures (OD600 ~0.8) were induced by anhydrotetracycline (50 ng/mL) for 5 h and then tested in the presence of anhydrotetracycline (5 ng/mL) for susceptibilities against humimycin A. Primer sequences, PCR conditions, and susceptibility data are listed in Supplementary Table 6. Murine peritonitis-sepsis model Female outbred Swiss Webster mice were used for this study. MRSA COL was grown in Mueller-Hinton broth at 37°C overnight and diluted with 5% hog mucin and 0.9% NaCl to provide challenge inoculum of approximately 5 × 108 CFU per mouse in a volume of 0.5 mL via intraperitoneal injection. Forty mice were randomly grouped into 10 per cohort, and each group was given single doses of vehicle (20% DMA, 40% PEG, 40% D5W), humimycin (HM) at 50 mg/kg, dicloxacillin (DCX) at 125 mg/kg, and HM:DCX combination at 12.5 mg/kg HM:125 mg/kg DCX 1 h post-infection via IV injection. Mice were maintained in accordance with American Association for Accreditation of Laboratory Care criteria. The Rutgers University Institutional Animal Care and Use Committee approved all animal procedures. Supplementary Material 1 We thank the Fischetti (MRSA), Tomasz (MRSA) and Marraffini (S. aureus, S. delphini, S. intermedius, and S. pseudo-intermedius) laboratories at the Rockefeller University for providing strains. This work was support by the Rainin Foundation, NIH grants U19AI109713 (D.S.P) and F32 29 AI110029 (Z.C.P.). Figure 1 Overview of the Syn-BNP approach a) Advances in our understanding of natural product biosynthesis have enabled the prediction of natural product structures from primary sequence data alone. In a syn-BNP approach these structures are accessed through chemical synthesis instead of biosynthesis. b) Here we apply a syn-BNP approach to NRPs predicted from human microbiome sequence data and assay these new molecules for antibiosis activities. Figure 2 Discovery and screening of the humimycins a) The humimycins were predicted from closely related gene clusters found in two Rhodococcus spp. cultured from human subjects. b) Chemical structures of humimycin A (1) and B (2). The two antibiotics differ only at the fourth (F/Y) and sixth (V/I) residues. c) MIC values for the humimycins against a panel of human commensal and pathogenic bacteria were determined (n = 2). The right panel shows that the humimycins are particularly active against bacteria in the Staphylococcus and Streptococcus genus (n = 3). Figure 3 Humimycin A and β-lactam act in synergy a) SAV1754 is the S. aureus homolog of MurJ, which is a flippase responsible for the transportation of peptidoglycan precursors across the cytoplasmic membrane. b) Carbenicillin (C) and humimycin A (HM) act synergistically to inhibit the growth of MRSA USA300 (n = 2). Fraction inhibitory concentration (FIC) values ≤0.5 defines synergy between two agents (shaded in light gray); [C:HM] denotes the respective inhibitory concentrations at each data point (μg/mL). c) The minimum inhibitory concentration (MIC) of humimycin A with dicloxacillin (DCX) alone and at various humimycin A concentrations against MRSA COL (n = 2) are shown in red and purple, respectively. Humimycin A alone does not inhibit MRSA COL growth (MIC >512 μg/mL, blue). d) Survival data for mice treated with humimycin A or dicloxacillin either alone or together using a MRSA COL peritonitis model (n = 10 mice per cohort) are shown. In this model humimycin potentiates β-lactam activity in vivo. Author Contributions SFB conceived of the project. JC and XVF carried out antibiosis assays, spectrum of activity screening, and resistant mutant selection. DI, HAZ, RGM, MJ, SS, and JSF carried out peptide synthesis on large scale. MAT carried out genome sequencing. LJC and EAG screened anaerobic bacteria. BVBR and ZCP carried out bioinformatic analysis. SP and DSP carried out mice studies. Financial Interest Statement The authors declare no competing financial interests. 1 Newman DJ Cragg GM J Nat Prod 79 629 661 2016 26852623 2 Charlop-Powers Z Milshteyn A Brady SF Curr Opin Microbiol 19 70 75 2014 25000402 3 Piel J Annu Rev Microbiol 65 431 453 2011 21682647 4 Rutledge PJ Challis GL Nat Rev Microbiol 13 509 523 2015 26119570 5 Qin J Nature 464 59 65 2010 20203603 6 Turnbaugh PJ Nature 457 480 484 2009 19043404 7 Charlop-Powers Z eLife 4 2015 8 Doroghazi JR Nat Chem Biol 10 963 968 2014 25262415 9 Stachelhaus T Mootz HD Marahiel MA Chem Biol 6 493 505 1999 10421756 10 Minowa Y Araki M Kanehisa M J Mol Biol 368 1500 1517 2007 17400247 11 Rottig M Nucleic Acids Res 39 W362 367 2011 21558170 12 Weber T Nucleic Acids Res 43 W237 243 2015 25948579 13 Rausch C Hoof I Weber T Wohlleben W Huson DH BMC Evol Biol 7 78 2007 17506888 14 Kitagawa W Tamura T Microbes Environ 23 167 171 2008 21558704 15 D’Argenio V Salvatore F Clin Chim Acta 451 97 102 2015 25584460 16 Sham LT Science 345 220 222 2014 25013077 17 Sewell EW Brown ED J Antibiot 67 43 51 2014 24169797 18 Lee SH Sci Transl Med 8 329ra332 2016 19 Huber J Chem Biol 16 837 848 2009 19716474 20 Kraal L Abubucker S Kota K Fischbach MA Mitreva M PLoS One 9 e97279 2014 24827833 21 Rasmussen TT Kirkeby LP Poulsen K Reinholdt J Kilian M APMIS 108 663 675 2000 11200821 22 Graham JE Invest Ophthalmol Vis Sci 48 5616 5623 2007 18055811 23 Lepage P Gastroenterology 141 227 236 2011 21621540 24 Jostins L Nature 491 119 124 2012 23128233 25 Kohli RM Walsh CT Burkart MD Nature 418 658 661 2002 12167866 26 Human Microbiome Project Consortium Nature 2012 486 215 22699610 27 Chen T Database (Oxford) 2010 baq013 20624719 28 Blin K Nucleic Acids Res 2013 41 W204 23737449 29 Wang SS J Am Chem Soc 1973 95 1328 4687686 30 Methods for Dilution Antimicrobial Susceptibility Tests for Bacteria That Grow Aerobically; Approved Standard 9 Clinical and Laboratory Standards Institute Wayne, PA 2012 31 Hall MJ Middleton RF Westmacott D J Antimicrob Chemother 1983 11 427 6874629 32 Garrison E Marth G arXiv 2012 33 Corrigan RM Foster TJ Plasmid 2009 61 126 18996145
PMC005xxxxxx/PMC5117677.txt
LICENSE: This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. 1300217 533 Anesthesiology Anesthesiology Anesthesiology 0003-3022 1528-1175 27753644 5117677 10.1097/ALN.0000000000001390 NIHMS817098 Article Tryptophan and Cysteine Mutations in M1 Helices of α1β3γ2L γ-Aminobutyric Acid Type A Receptors Indicate Distinct Inter-subunit Sites for Four Intravenous Anesthetics and One Orphan Site Nourmahnad Anahita B.S. 1* Stern Alex T B.S. 1*a Hotta Mayo B.S. 1a Stewart Deirdre S. Ph.D. 1 Ziemba Alexis M. B.A. 1b Szabo Andrea B.S. 1 Forman Stuart A. M.D., Ph.D. 1 1 Dept. of Anesthesia Critical Care & Pain Medicine, Massachusetts General Hospital, Boston, MA, USA. Corresponding author: Stuart A. Forman, MD-PhD, Dept. of Anesthesia Critical Care & Pain Medicine, Jackson 444, Massachusetts General Hospital, 55 Fruit Street, Boston, MA, USA. saforman@partners.org; Phone: 617-724-5156; Fax: 617-724-8644 * These authors contributed equally to this research. a Current affiliation: University of Southern California, Keck School of Medicine, Los Angeles, CA, USA. b Current affiliation: Dept. of Biomedical Engineering, Rensselaer Polytechnic Institute, Troy, NY, USA. 17 9 2016 12 2016 01 12 2017 125 6 11441158 This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. Background GABAA receptors mediate important effects of intravenous general anesthetics. Photolabel derivatives of etomidate, propofol, barbiturates, and a neurosteroid incorporate in GABAA receptor transmembrane helices M1 and M3 adjacent to inter-subunit pockets. However, photolabels have not been consistently targeted at heteromeric αβγ receptors and don’t form adducts with all contact residues. Complementary approaches may further define anesthetic sites in typical GABAA receptors. Methods Two mutation-based strategies, substituted tryptophan sensitivity and substituted cysteine modification-protection, combined with voltage-clamp electrophysiology in Xenopus oocytes, were used to evaluate interactions between four intravenous anesthetics and six amino acids in M1 helices of α1, β3, and γ2L GABAA receptor subunits: two photolabeled residues, α1M236 and β3M227, and their homologs. Results Tryptophan substitutions at α1M236 and positional homologs β3L231 and γ2L246 all caused spontaneous channel gating and reduced GABA EC50. Substituted cysteine modification experiments indicated etomidate protection at α1L232C and α1M236C, mTFD-MPAB protection at β3M227C and β3L231C, and propofol protection at α1M236C and β3M227C. No alphaxalone protection was evident at the residues we explored and none of the tested anesthetics protected γ2I242C or γ2L246C. Conclusions All five inter-subunit transmembrane pockets of GABAA receptors display similar allosteric linkage to ion channel gating. Substituted cysteine modification and protection results were fully concordant with anesthetic photolabeling at α1M236 and β3M227, and reveal overlapping non-congruent sites for etomidate and propofol in β+ – α− interfaces and mTFD-MPAB and propofol in α+ – β− and γ+ – β− interfaces. Our results identify the α+ – γ− transmembrane interface as a potentially unique “orphan” modulator site. Ligand-gated ion channel glycine receptor GluCl alcohol general anesthetic cysteine modification photolabel electrophysiology allosteric modulator allosteric agonist Introduction Etomidate, propofol, alphaxalone, and barbiturates are intravenous general anesthetics that enhance the activity of γ-aminobutyric acid type A (GABAA) receptors, the dominant inhibitory neurotransmitter receptors in mammalian brain and members of the pentameric ligand-gated ion channel (pLGIC) superfamily 1–4. GABAA receptor subunits contain structural elements common to all pLGICs, including an N-terminal extracellular domain and a transmembrane domain with four alpha helices (M1 to M4). Most GABAA receptors consist of two a, two b, and one g subunit arranged βαβαγ counterclockwise 5, creating four distinct types of subunit interfaces: α+ – β−, α+ – γ−, β+ – γ−, and two β+ – α− (Fig 1). Anesthetic photolabels form adducts with GABAA receptor residues that are homologs of ivermectin contacts in transmembrane inter-subunit pockets of GluCl pLGICs, imaged with x-ray crystallography 6. Azi-etomidate labeled αM236 in α-M1 and βM286 in β-M3 in GABAA receptors from bovine brain or cells expressing α1β3γ2L 7,8. The barbiturate R-5-allyl-1-methyl-5-(m-trifluoromethyl-diazirinylphenyl) barbituric acid (mTFD-MPAB), photolabeled residues in b3-M1 (β3M227), α1-M3, and γ2-M3 8. m-Azi-propofol (azi-Pm) photolabeled both α1M236 and β3M227 in α1β3 receptors 9. 6-Azi-pregnanalone (6-aziP), a neurosteroid derivative, photolabeled b3F301 in β3 homomeric receptors 10. Propofol, but not alphaxalone, displaced both azi-etomidate and mTFD-MPAB labeling in α1β3γ2L receptors 8,11,12. These results suggest that α1β3γ2L receptors form overlapping etomidate and propofol sites in β3+ – α1− interfaces adjacent to α1-M1s, and overlapping mTFD-MPAB and propofol sites in homologous α1+ – β3− and γ2+ – β3− pockets abutting β3-M1s (Fig 1). However, we don’t know how propofol sites overlap with vs. differ from etomidate and mTFD-MPAB sites, because photolabels don’t adduct all residues that contact parent drugs 13,14. Additionally, no anesthetics have photolabeled γ2-M1, and because receptors photolabeled by aziPm and 6-aziP lacked γ2 subunits, propofol or neurosteroid interactions with γ2 remain untested. To both complement and supplement photolabeling data, two approaches based on voltage-clamp electrophysiological studies of GABAA receptors with mutations at putative anesthetic contact residues have been widely applied. Tryptophan substitutions in putative anesthetic sites have been reported to both mimic the channel-gating effects of anesthetic binding and impair anesthetic modulation 15–19. Cysteines substituted at putative contact residues have been covalently modified by probes such as p-chloromercuricbenzenesulfonate (pCMBS) and protected from modification by anesthetics 14,20–24. However, neither of these approaches has been rigorously compared to photolabeling. In the current study, we created tryptophan and cysteine mutations at two photolabeled residues in M1 helices, α1M236 and β3M227, and their homologs based on sequence alignment: α1L232, β3L231, γ2I242 and γ2L246 (Table 1). At each locus, we assessed tryptophan mutant functions and performed substituted cysteine modification-protection (SCAMP) experiments to probe interactions with etomidate, propofol, alphaxalone, and mTFD-MPAB. Our analysis addressed three key questions: 1) Do SCAMP results and/or tryptophan mutant sensitivity results for the study drugs agree with photolabeling at α1M236 and β3M227? 2) Do the α1-M1 contacts for etomidate and propofol or the β3-M1 contacts for mTFD-MPAB and propofol differ? 3) Do alphaxalone, propofol, or other anesthetics bind in the α1+ – γ2− interface? Materials and Methods Animals Female Xenopus frogs were used as a source of oocytes in accordance with the recommendations in the Guide for the Care and Use of Laboratory Animals of the National Institutes of Health. Approval for animal use in this study was obtained from the Massachusetts General Hospital Institutional Animal Care and Use Committee (protocol #2005N000051). Frogs were housed and maintained in a veterinarian-supervised facility and anesthetized in tricaine prior to oocyte collection. All efforts were made to minimize animal suffering. Materials R-mTFD-MPAB was a gift from Prof. Karol Bruzik, PhD (Dept of Medicinal Chemistry and Pharmacognosy, University of Illinois, Chicago, USA). It was stored as a 100 mM solution in DMSO and diluted in electrophysiology buffer to 4, 8, or 16 µM for experiments. Alphaxalone was purchased from Tocris Bioscience (Bristol, UK), stored as a 10 mM solution in DMSO, and diluted to 1.25, 2.5, or 5 µM in electrophysiology buffer for experiments. Propofol (2,6-diisopropylphenol) was purchased from Sigma-Aldrich (St. Louis, MO, USA), stored as a 10 mM solution in DMSO and diluted to 2.5, 5, or 10 µM in electrophysiology buffer for experiments. R-Etomidate was purchased from Hospira, Inc (Lake Forest, IL, USA) as a 2 mg/ml (~8.2 mM) solution in 35% propylene glycol:water and diluted to 1.6, 3.2, or 6.4 µM in electrophysiology buffer for experiments. We have previously shown that DMSO and propylene glycol at the dilutions used here produce no effects on GABAA receptor function 23. Para-cloromercuribenzenesulfonic acid sodium salt (pCMBS) was purchased from Toronto Chemical Research (Toronto, ON, Canada) and fresh stock solutions in electrophysiology buffer were prepared on the day of use, and kept on ice until final dilution. γ-Aminobutyric acid (GABA), picrotoxin, salts, and buffers were purchased from Sigma-Aldrich. GABAA Receptor Expression in Xenopus Oocytes Oocytes were prepared for use as previously described 15. Complementary DNAs encoding human α1, β3, and γ2L GABAA receptor subunits in pCDNA3.1 expression vectors (Thermo Fisher Scientific, Waltham, MA, USA) were used as mutagenesis templates. Tryptophan and cysteine mutations were introduced into cDNAs by site-directed mutagenesis using QuikChange kits (Agilent Technologies, Santa Clara, CA, USA). Selected clones were sequenced through the entire coding region, and a single clone for each mutant was chosen for subsequent use. Messenger RNAs were synthesized on linearized DNA templates using mMessage Machine kits (Ambion Thermo Fisher), purified, and mixed in a ratio of 1α:1β:3γ, then diluted in RNAase-free water to 1 ng/nl. Oocytes were injected with ~12 ng total mRNA mix and incubated in ND96 buffer (in mM: 96 NaCl, 2 KCl, 1 CaCl2, 0.8 MgCl2, 1 EGTA, 10 HEPES, pH 7.5) supplemented with ciprofloxacin (2 mg/ml) and amikacin (100 µg/ml) at 17 °C for 48 to 72 hours before electrophysiological studies. Two Electrode Voltage-Clamp Electrophysiology Electrophysiological experiments were performed in ND96 buffer at room temperature (21 to 23 °C). Oocytes were positioned in a low volume (30 µl) custom-built flow-cell and impaled with two borosilicate glass micro-electrodes filled with 3 M KCl (resistance < 1 MΩ). Oocytes were voltage-clamped at −50 mV (model OC-725C, Warner Instruments, Hamden CT, USA). Superfusion solutions based on ND96 were selected and delivered at a rate of 2–3 ml/min from glass reservoir syringes via PTFE tubing and a PTFE micro-manifold (MP-8, Warner Instruments). Solutions were selected by activating electrical valves (VC-8, Warner Instruments). Specialized software and a digital input/output interface (pClamp 8.0 and Digidata 1322, both from Molecular Devices, Sunnyvale, CA) were used to coordinate the delivery of different superfusion solutions and recordings of voltage and current signals. Currents were filtered at 1 kHz, digitized at 100 Hz, and stored on a computer disk for offline analysis. GABA concentration-responses Currents in voltage-clamped oocytes expressing GABAA receptors were exposed to solutions containing GABA (range 0.1 µM to 10 mM) with or without anesthetics for 10 to 20 s, followed by 5 minute ND96 wash. Normalization sweeps at 1 to 10 mM GABA alone, (i.e. maximum GABA for the specific receptor) were recorded every other or every third experiment. GABA concentration-responses in the presence of etomidate or mTFD-MPAB were studied using the same method with solutions of variable GABA combined with 3.2 µM etomidate or 8 µM mTFD-MPAB. Baseline responses were measured using anesthetic without GABA. Oocytes were not pre-exposed to anesthetics when co-applied with GABA, and maximal normalization sweeps were in either high GABA alone or high GABA plus anesthetic. At least 3 oocytes from two different frogs were used for each concentration response. Spontaneous receptor activity and maximal GABA efficacy Spontaneous activation of GABAA receptors (in the absence of GABA or anesthetics) was assessed by applying 2 mM picrotoxin to voltage-clamped oocytes. Outward currents that reversed during picrotoxin washout were assumed to represent spontaneously active channels. Spontaneous activity, if detected, was normalized to maximally activated inward GABA-elicited current in the same cell (n ≥ 3 cells). Maximal GABA efficacy for each receptor was determined by comparing peak currents elicited with high GABA to currents elicited with high GABA supplemented with 2.5 µM alphaxalone, which positively modulated all receptors in this study. GABA efficacy was calculated by normalizing GABA responses to GABA + alphaxalone responses, which we assumed represents 100% activation, in the same cell (n ≥ 3 cells). GABA EC5 enhancement Voltage-clamped oocytes expressing wild-type or mutant GABAA receptors were repetitively exposed for 20 s to GABA EC5 (eliciting ~ 5% of maximal GABA response) separated by 5 min wash until three stable peak responses (varying by less than 5%) were sequentially recorded. The oocyte was then exposed for 30 s to anesthetic, followed by 20 s exposure to a solution containing GABA EC5 combined with anesthetic at 2 × EC50 for loss-of-righting-reflexes (LoRR) in tadpoles: 2.5 µM alphaxalone 25, 3.2 µM etomidate 26, 5 µM propofol 27, or 8 µM mTFD-MPAB 28. For each receptor type (wild-type and 12 mutants) and four anesthetics, triplicate measurements of current response to GABA EC5 and GABA EC5 + anesthetic were obtained in at least four oocytes from two different frogs. Because receptors with the γ2L246W mutation displayed substantial spontaneous activity, 2 × EC50 anesthetic enhancement of GABA EC5 responses approached maximal GABA responses for all drugs. This receptors was also studied using 1 × EC50 for tadpole LoRR of each anesthetic. Substituted Cysteine Modification and Protection (SCAMP) Cysteine modification and protection were performed in the presence of maximally activating GABA, as previously described 23. Maximal GABA serves to 1) enhance anesthetic binding site occupancy in protection experiments, 2) assure in most cases that the mix of receptor states is similar in both control modification and protection studies, and 3) increase the rate of sulfhydryl modification. Each substituted cysteine mutant receptor was expressed in Xenopus oocytes, voltage clamped, and exposed to both GABA EC5 (low) and a maximally activating GABA concentration (high). After 5 minute wash, oocytes were then exposed for 30 s to ND96 containing high GABA plus pCMBS, a water-soluble cysteine modifying reagent, ranging in concentration from 1 µM to 1 mM, followed by 5 minute wash in ND96. Responses to low and high GABA were then repeated. We thus confirmed that pCMBS produced irreversible changes in receptor function (in most cases an increase in the low:high GABA response ratio), and identified pCMBS concentrations suitable for comparing initial rates of modification. For control modification rate experiments, voltage-clamped oocytes were repeatedly tested for responses to both EC5 and maximal GABA, then washed for 5 min in ND96, to assure that the response ratio was stable (< 5% change) before pCMBS exposure. Oocytes were then exposed for 5 to 10 s to solutions of maximal GABA plus pCMBS at concentrations estimated to produce about 10% of the maximal modification effect, followed by 5 minute wash, and re-testing for low and high GABA responses. At least three cycles of pCMBS exposure/wash/low:high GABA response testing were performed on each oocyte. A final modification cycle was performed using 10 × pCMBS concentration for 20 s to complete modification of receptors, and electrophysiological response was assessed as the maximal modification effect. For anesthetic protection experiments, a similar experimental protocol was used, except that oocytes were exposed to anesthetic for 30 s just before exposure to a solution of pCMBS + GABA + anesthetic. Post-modification wash and response tests were identical to control conditions (no anesthetic present). Anesthetic concentrations used in protection studies were 2 to 4 × LoRR EC50. For each cysteine mutant, at least 5 oocytes were studied in control modification experiments and at least 4 oocytes were studied in protection experiments. Group sample sizes were based both on prior experience and a power analysis performed with G*Power 3.08 software (Franz Faul, Universitat Kiel, Germany). Based on our experience with SCAMP, SD/mean ratios for modification rates range from 0.2 to 0.5 and in protection experiments we aimed to detect drops of more than 50% from control modification rates. We estimated sample sizes for two groups with respective means of 2 and 1, both with SD = 0.4 (an effect size of 2.5), in a one-tail t-test with α = 0.013 (adjusted for four drug comparisons to control) and β = 0.85, indicating a need for 5 samples per group. Data analysis and statistics Results in text and figures are mean ± sem unless otherwise indicated. GABA concentration-responses Digitized GABA concentration-response data was corrected for baseline leak currents and digitally filtered (10 Hz low-pass, Bessel function) using Clampfit 9.0 software (Molecular Devices). Peak currents were normalized to control (maximal currents), and combined GABA data from multiple cells (n ≥ 3) was fitted with logistic equations using Prism 5.02 (GraphPad Software Inc, La Jolla, CA): Eq. 1 Inorm=(1max−1min)/(1+10(LogEC50−Log[GABA]×nH))+1min where EC50 is the half-maximal activating GABA concentration, and nH is the Hill slope. Mean GABA EC50 and 95% confidence interval are reported. GABA EC50 shifts in the presence of anesthetics were calculated from the difference in log(EC50) values (control – anesthetic) with propagation of log(SD) errors 29. Mean GABA EC50 shift ratios and 95% confidence intervals were calculated. Statistical comparison of GABA EC50s and anesthetic shifts between mutants and wild-type was based on the calculated confidence intervals of the differences of means. Functional characteristics of mutant receptors Comparison of both spontaneous activity and GABA efficacy between mutants and wild-type was based on one-way ANOVA with post-hoc Dunnett’s tests (in Prism 5.02). EC5 enhancement data for the four equi-potent anesthetic concentrations in wild-type and all six tryptophan mutants was tabulated and analyzed with two-way ANOVA and Bonferroni posttests for wild-type vs. mutation for each anesthetic (Prism 5.02). SCAMP Apparent pCMBS modification rates were calculated from data for individual oocytes expressing cysteine mutants. Either normalized maximal GABA response (for α1β3M227Cγ2L) or normalized low:high GABA response ratio (for the other five cysteine mutants) was plotted against cumulative pCMBS exposure (M×s) and linear least squares analyses with y-axis intercepts fixed at 1.0 were applied. For each mutant, the resulting slopes from control and anesthetic protection studies were tabulated and compared using one-way ANOVA in Prism 5.02. Comparison of photolabeling with mutation-based approaches at α1M236 and β3M227 We treated photolabeling results as “gold standard” evidence of anesthetic contact with a residue. For each anesthetic at each residue studied, we categorized substituted tryptophan sensitivity as positive if EC5 enhancement was significantly reduced compared to wild-type. SCAMP results were categorized as positive if addition of anesthetic significantly reduced the initial rate of modification by pCMBS. We constructed 2 × 2 contingency tables and calculated the percentage agreement between each mutation-based method and photolabeling (i.e. concordance of positive and negative results), as well as Cohen’s kappa, a measure of agreement between methods that corrects for chance. Contingency analysis with Fisher’s exact test was used to calculate a conservative p-value, with the implicit null hypothesis being that mutation-based results are uncorrelated with photolabeling. Statistical significance was inferred for p < 0.05. Results Modulation of wild-type α1β3γ2L receptors by four intravenous general anesthetics We expressed GABAA receptors in Xenopus oocytes and characterized their function using two-electrode voltage clamp, assessing GABA concentration-response, maximal GABA efficacy, spontaneous activation, and modulation by intravenous general anesthetics (Table 2). To quantitatively compare the effects of multiple general anesthetics in GABAA receptors, we used equipotent drug concentrations based on loss-of-righting-reflexes (LoRR) tests in tadpoles. The EC50s for LoRR are 1.6 µM etomidate, 2.5 µM propofol, 4 µM mTFD-MPAB, and 1.25 µM alphaxalone 25–28. Wild-type α1β3γ2L GABA responses were similarly enhanced by equipotent 2 × EC50 anesthetic concentrations, measured by either the shift in GABA EC50s (Fig 2 shows results for etomidate and mTFD-MPAB) or enhancement of receptor activation at EC5 GABA (Fig 3 shows results for all four anesthetics). Functional characteristics and anesthetic sensitivity of α1-M1 Trp substitutions: α1M236Wβ3γ2L and α1L232Wβ3γ2L receptors Photolabel analogs of both etomidate and propofol form adducts with α1M236 7,9. We have previously described some of the functional characteristics of α1M236Wβ2γ2L GABAA receptors 15, which mimic the effects of bound anesthetic, including increased sensitivity to GABA, spontaneous channel activity, as well as reduced modulation by etomidate, quantified as the ratio of GABA EC50s in the absence vs. presence of anesthetic. We hypothesized that tryptophan substitutions within anesthetic binding sites may, as a general rule, mimic the effects of anesthetics and reduce modulation by drugs that occupy those sites. The functional characteristics of α1M236Wβ3γ2L receptors were very similar to those of α1M236Wβ2γ2L (Table 2), including very weak modulation by etomidate (Figs 2 and 3). mTFD-MPAB potently activated α1M236Wβ3γ2L receptors, while inducing a smaller GABA EC50 shift than in wild-type receptors (Fig 2, Table 2). This may be due to this receptor’s spontaneous activity. However, EC5 enhancement by mTFD-MPAB was similar in wild-type and α1M236Wβ3γ2L receptors (Fig 3). Propofol, and unexpectedly alphaxalone, also produced significantly less EC5 enhancement in this mutant than in wild-type (Fig 3). The α1 homolog of β3M227 is α1L232 (Table 1). A tryptophan mutation at this site was described in an earlier study of volatile anesthetic modulation 30. Oocyte-expressed α1L232Wβ3γ2L receptors were characterized by a low GABA EC50, low GABA efficacy, and no spontaneous activation (Table 2). Based on GABA EC50 shifts or EC5 enhancement metrics, modulation of α1L232Wβ3γ2L receptors by etomidate and propofol was significantly reduced, while modulation by mTFD-MPAB and alphaxalone was similar to wild-type (Table 2, Figs 2 and 3). Functional characteristics and anesthetic sensitivity of β3-M1 Trp substitutions: α1β3M227Wγ2L and α1β3L231Wγ2L receptors Both mTFD-MPAB and aziPm form photo-adducts with β3M227 8,9. The effects of mutations at β3M227 and β3L231 have not been reported previously. Oocyte-expressed α1β3M227Wγ2L receptors displayed no detectable spontaneous activity, GABA EC50 about twice that of wild-type, and high GABA efficacy (Table 2). Anesthetic modulation of α1β3M227Wγ2L receptors was similar to that in wild-type for etomidate, propofol, and alphaxalone, but significantly reduced for mTFD-MPAB (Table 2, Figs 2 and 3). The β3 homolog of α1M236 is β3L231 (Table 1). The functional characteristics of α1β3L231Wγ2L receptors included spontaneous channel gating similar to that in α1M236Wβ3γ2L, a low GABA EC50, and high GABA efficacy (Table 2). Unexpectedly, etomidate modulation of α1β3L231Wγ2L receptors was significantly less than in wild-type, while modulation by mTFD-MPAB, propofol and alphaxalone was comparable to effects in wild-type (Table 2, Figs 2 and 3). SCAMP in α1-M1: α1M236Cβ3γ2L and α1L232Cβ3γ2L receptors Basal leak and both low and high GABA responses in voltage clamped oocytes expressing wild-type α1β3γ2L GABAA receptors were unaffected by exposure to 1 mM pCMBS for up to 60 s (n = 4 oocytes; data not shown). We have previously described the functional effects of α1M236C mutations in GABAA receptors (see Table 3), the effects of pCMBS modification at α1M236C, and evidence that both etomidate and propofol protect this substituted sidechain from modification, while alphaxalone does not 21,31. For our current experiments, we first tested α1M236Cβ3γ2L receptors for sensitivity to anesthetics, confirming that GABA EC5 responses are enhanced similarly by all four study drugs (Table 3). For modification and protection experiments, we assessed low:high GABA response ratios, which increased by 8.9 ± 0.38-fold (n = 6) after maximal pCMBS modification. Compared to previous studies, we used lower concentrations of etomidate and propofol in protection experiments, and also tested protection with 8 µM mTFD-MPAB. In agreement with our prior studies, we found that addition of 2.5 µM alphaxalone dramatically increased the pCMBS modification rate relative to that in the presence of GABA alone (Fig 4). This is explained by observations that GABA alone activates only about 24% of α1M236Cβ3γ2L receptors, while pCMBS modification of this receptor is much faster in GABA-activated versus inactive receptors 21. Therefore, we used pCMBS + GABA + alphaxalone as the control condition for protection experiments with pCMBS + GABA + other anesthetics. These indicated that both etomidate and propofol protect α1M236C, while mTFD-MPAB does not (Fig 4). We and others have also previously described the functional effects of α1L232C mutations (see Table 3) and evidence that etomidate protects this substituted sidechain from pCMBS modification 21,32,33. All four anesthetics similarly enhanced GABA EC5 responses in α1L232Cβ3γ2L receptors (Table 3). By systematically testing various pCMBS concentrations, we found that very low concentrations (1 µM) of pCMBS produced irreversible enhancement of gating in α1L232Cβ3γ2L receptors (Fig 5A and B), in contrast to the inhibitory effects of 200 to 500 µM pCMBS that were previously reported 21,33. Maximal pCMBS modification increased the low:high GABA response ratio by 7.1 ± 0.47-fold (n =7). In comparison to pCMBS + GABA, addition of etomidate significantly slowed modification of α1L232Cβ3γ2L receptors (Fig 5B and C). Alphaxalone, propofol, and mTFD-MPAB did not significantly affect the rate of pCMBS modification in this mutant. SCAMP in β3-M1: α1β3M227Cγ2L and α1β3L231Cγ2L receptors Studies of cysteine substitutions at β3M227 and β3L231 have not been reported previously. The functional properties of α1β3M227Cγ2L receptors are summarized in Table 3. Modulation of EC5 responses in α1β3M227Cγ2L receptors by etomidate and other study drugs was similar to that in wild-type. The function of oocyte-expressed α1β3M227Cγ2L receptors was irreversibly modified by pCMBS (100 µM; Fig 6A and B), but unlike other cysteine mutants in this study, modification reduced receptor activation without altering GABA sensitivity (the ratio of responses to EC5 vs. high GABA remained constant). Maximal pCMBS modification reduced peak currents by 71 ± 5.4 % (n = 6). Protection experiments showed that both mTFD-MPAB and propofol significantly slowed modification of α1β3M227Cγ2L receptors, while alphaxalone and etomidate did not (Fig 6C). The functional properties of α1β3L231Cγ2L receptors are summarized in Table 3. This mutant was modulated similarly by all four anesthetics at equipotent concentrations. Modification by pCMBS resulted in enhanced GABA sensitivity based on the ratio of electrophysiological currents elicited with low vs. high GABA (Fig 6D and E). Maximal pCMBS modification increased this ratio 5.7 ± 0.44-fold (n = 6). Anesthetic protection experiments showed strong protection by mTFD-MPAB, but not by etomidate, propofol, or alphaxalone (Fig 6F). Comparison of tryptophan anesthetic sensitivity and SCAMP results with photolabeling at α1M236 and β3M227 Concordance between photolabeling, substituted tryptophan anesthetic sensitivity and SCAMP was assessed for the four anesthetics at the two photolabeled residues that we studied: α1M236 and β3M227. In this set of eight anesthetic-residue pairs, there were four positive photolabeling pairs and four negative pairs. Substituted tryptophan sensitivity was categorized as positive if EC5 enhancement by anesthetic in the mutant was significantly lower than in wild-type (Fig 3). SCAMP was categorized as positive if the anesthetic significantly slowed the initial rate of pCMBS modification at the substituted cysteine (Fig 4 and Fig 6C). The categorized results for all three methods are summarized in Table 4. The agreement between photolabeling and substituted tryptophan sensitivity was 75% (Cohen’s kappa = 0.5; p = 0.49 by Fisher’s exact test), with mismatches for propofol-β3M227 (a false negative) and alphaxalone-α1M236 (a false positive) interactions. The concordance between photolabeling and SCAMP results was 100%, and statistically significant (Cohen’s kappa = 1.0; p = 0.029 by Fisher’s exact test). Functional characteristics and anesthetic sensitivity of γ2-M1 Trp substitutions: α1β3γ2I242W and α1β3γ2L246W receptors Both substituted tryptophan sensitivity and SCAMP were used to determine if any of the study anesthetics bind near the γ2-M1 helix. Effects of mutations at γ2I242 and γ2L246 have not been reported previously. The functional properties of α1β3γ2I242W and α1β3γ2L246W receptors are summarized in Table 2. The γ2I242W mutation did not produce spontaneous receptor activation or enhance GABA sensitivity. Instead we observed a high GABA EC50 and reduced GABA efficacy in this mutant (Fig 7A). Oocyte-expressed α1β3γ2L246W receptors were characterized by ~11% spontaneous channel activation, low GABA EC50, and very high GABA efficacy (Table 2; Fig 7B). Modulation of α1β3γ2I242W by all four intravenous general anesthetics was similar to that observed in wild-type receptors (Fig 7C). In α1β3γ2L246W receptors, all the anesthetics produced a large amount of direct channel activation (e.g. Fig 7B) and GABA EC5 enhancement with pre-exposure to the anesthetic concentrations used in other mutants produced near-maximal activation, reducing our ability to discern differences between drugs. We therefore studied EC5 enhancement with half the usual anesthetic concentrations (i.e. 1 × EC50 for tadpole LoRR; Fig 7C). Under these altered conditions, the overall amount of enhancement was lower, and results indicated that none of the four anesthetics produced significantly more or less enhancement than the others. SCAMP in γ2-M1: α1β3γ2I242C and α1β3γ2L246C receptors The functional properties of oocyte-expressed α1β3γ2I242C and α1β3γ2L246C receptors (Table 3) were similar to wild-type (Table 2). Neither of the γ2-M1 cysteine mutations altered sensitivity to modulation by any of the four study anesthetics. Application of 10 µM pCMBS to α1β3γ2I242C receptors irreversibly enhanced GABA sensitivity (Fig. 8A and B). Maximal pCMBS modification increased the low:high GABA response ratio by 5.8 ± 0.37-fold (n = 8). None of the four anesthetic drugs significantly reduced the rate of pCMBS modification, even at twice the concentration used for most other cysteine mutants in this study (Fig 8C). Modification of α1β3γ2L246C receptors required high pCMBS concentrations (500 µM), and also enhanced GABA sensitivity (Fig 8D and E). Maximal pCMBS modification increased the low:high GABA response ratio by 5.0 ± 0.38-fold (n = 5). None of the study anesthetics significantly reduced the rate of pCMBS modification in α1β3γ2L246C receptors. Given the negative SCAMP results at both γ2I242 and γ2L246 with the four intravenous anesthetics, we also tested whether a flexible linear alcohol might bind in the α+ - γ− interface. Additional SCAMP experiments showed no protection by 120 µM n-octanol in either α1β3γ2I242C or α1β3γ2L246C receptors (n = 4 each, data not shown). Discussion Anesthetic photolabeling data in α1β3γ2L GABAA receptors remains limited. We aimed to extend the map of drug contacts and test the functional roles of residues using two mutant-based approaches: substituted tryptophan sensitivity and SCAMP. For two residues, α1M236 and β3M227, and four intravenous anesthetics, published photolabeling results were 100% concordant with SCAMP, but only 75% concordant with substituted tryptophan sensitivity. SCAMP experiments also indicated etomidate contact at α1L232 and mTFD-MPAB contact at β3L231, but no propofol or alphaxalone contact at these loci. At γ2I242 and γ2L246, both approaches consistently indicated no anesthetic interactions. SCAMP fully agrees with photolabeling evidence of selective anesthetic binding to inter-subunit GABAA receptor sites SCAMP is based on formation of a covalent bond between a sulfhydryl engineered into the target receptor and a chemical probe. SCAMP is thus analogous to photolabeling in requiring proximity between probe and site. Both photolabeling and functional studies indicate that anesthetics bind preferentially to GABA-bound open and desensitized states 14,34. Thus, our experiments were designed to promote formation of GABA-bound receptors with high anesthetic affinity, and were powered to detect large protection effects indicating site occupation. We extended our previous SCAMP studies in α1M236C and α1L232C 21 to include additional drugs, and investigated four new cysteine mutants in β3-M1 and γ2-M1. All six substituted cysteines were accessible to pCMBS, forming covalent adducts that irreversibly altered receptor function. In all but one case, cysteine modification enhanced receptor sensitivity to GABA (increased low:high GABA response ratio; Table 3), echoing the effects of tryptophan substitution at most of these positions (Table 2). The exception was β3M227C, where pCMBS modification reduced GABA responses. Notably, the β3M227W mutation reduced GABA sensitivity (Table 2). SCAMP results for α1M236C and β3M227C were in perfect accord with both direct and indirect (drug competition) anesthetic photolabeling studies (Table 4). Contingency analysis with Fisher’s exact test indicated that SCAMP is a sensitive and specific predictor of photolabeling results for these two residues and four anesthetics (four true positives, four true negatives, no false positives or negatives; p = 0.029). We can extend this analysis to include βM286, another residue photolabeled by both azietomidate and aziPm and where SCAMP evidence confirms propofol and etomidate contact, but no interaction with alphaxalone 7,9,12,20,22. Adding these two true positives and one true negative to our Fisher’s exact test analysis results in p = 0.0022. These results support SCAMP as a reliable technique to test putative anesthetic contact points beyond those identified with photolabels. SCAMP also has limitations as an approach to mapping ligand-receptor contact residues 14. Cysteine modification is frequently dependent on the receptor state. Establishing conditions where the mix of functional receptor states is similar in both control modification and protection experiments can be challenging 21. Protection studies may not be feasible or interpretable when cysteine-substitutions induce insensitivity to the ligand (possibly impaired binding) or when exposure to reactive probes causes little or no functional change 21,31. To infer steric interference from SCAMP results, allosteric inhibition of cysteine modification must be ruled out. We addressed this issue by studying multiple drugs that produce similar functional effects. SCAMP identifies additional anesthetic contact residues in α1-M1 and β3-M1 helices While α1L232 has not been photolabeled by anesthetic derivatives, β3L231 was photolabeled by a convulsant barbiturate 35. Our current SCAMP results indicate that α1L232C is protected by etomidate, confirming an earlier study using higher drug concentrations 21. Neither alphaxalone nor mTFD-MPAB protected α1L232C from modification. Despite evidence that propofol binds adjacent to α1-M1 and displaces azietomidate, α1L232C was not protected by propofol. Thus, etomidate and propofol sites in the β+ – α− interfaces overlap, but not at α1L232. Of note, aziPm also photolabels α1I239 9, but pCMBS does not affect the function of α1I239Cβ2γ2L receptors 21, making SCAMP studies unfeasible. Our data indicate that β3L231C is protected by mTFD-MPAB, extending the list of this drug’s likely contacts. However, while propofol displaces mTFD-MPAB photolabeling it does not protect β3L231C, again suggesting overlapping but non-congruent sites adjacent to β3-M1. Consistent with photolabeling results, neither etomidate nor alphaxalone protected β3L231C. Considered together, the above SCAMP results indicate that etomidate binds exclusively in the two β+ – α− interfaces near α1L232 and α1M236, while mTFD-MPAB binds exclusively in homologous α+ – β− and γ+ – β− sites abutting βM227 and βL231. Propofol binds to all four of these sites, adjacent to either α1M236 or βM227. Do M1 helix tryptophan substitutions mimic anesthetic binding in GABAA receptors? This study extended our earlier analysis of α1M236W and assessed five more tryptophan mutants in M1 helices. Both α1M236W and β2M286W mutations mimic the effects of anesthetic binding on GABAA receptors, including decreased GABA EC50, increased GABA efficacy, and spontaneous channel activation, all of which indicate enhanced channel gating 15. We hypothesized that these effects were produced when tryptophan sidechains partially filled the β+ – α− interfacial pockets where etomidate binds, and this approach has been applied to other transmembrane residues in putative anesthetic sites 17–19. Both β3L231W and γ2L246W mutations produced effects similar to α1M236W (Table 2). Thus, tryptophan substitution at the 10th residue after the conserved GYF sequence in any of the M1 helices of α1β3γ2L receptors (Table 1) produced gating effects that mimic anesthetic binding. Receptors with α1L232W mutations also displayed increased apparent GABA sensitivity, but not spontaneous channel activation or GABA efficacy higher than wild-type. On the other hand, β3M227W and γ2I242W produced decreases in GABA sensitivity and none of the W mutations at the 6th residue after the conserved GYF caused spontaneous receptor gating. Overall, these results indicate that the middle segments of all M1 helices of α1β3γ2 receptors are similarly linked to ion channel gating and suggest that all five adjacent inter-subunit pockets, including α+ – γ−, are potential allosteric modulator-agonist sites. Substituted tryptophan sensitivity does not consistently agree with photolabeling or SCAMP evidence of anesthetic binding interactions If Trp substitutions in M1 helices occlude adjacent inter-subunit anesthetic sites, they should reduce modulation by anesthetics occupying these pockets. In agreement with photolabeling, α1M236W reduced receptor sensitivity to both etomidate and propofol, while β3M227W reduced sensitivity to mTFD-MPAB. However, anesthetic sensitivities of α1M236Wβ3γ2L and α1β3M227Wγ2L receptors were not in full accord with photolabeling and SCAMP results at these sites and others (Table 4). Unexpectedly, α1M236W reduced sensitivity to alphaxalone (Fig 3). Interestingly, Henin et al 36 predicted cholesterol binding sites near all six of the M1 residues we studied, and Hosie et al 37 implicated αT237, immediately adjacent to αM236, as a contact for neurosteroids, based on altered tetrahydrodeoxycorticosterone sensitivity in mutants. However, SCAMP indicated no alphaxalone protection at αM236, and alphaxalone enhances azietomidate photolabeling at αM236, implying allosteric effects 12. Indeed, SCAMP provided no evidence of alphaxalone binding near any of the six residues we studied. Correlation with photolabeling is limited, because photolabeling with 6-aziP used β3 homomeric receptors (thus, we lack data for α or γ subunits), and mass spectroscopic analysis missed a sequence including β3M227 and β3L23110. The combined negative SCAMP and photolabeling results together suggest that mutant effects at αM236 and αT237 are indirectly (allosterically) coupled to neurosteroid sites. AziPm photolabeled β3M227 9 and SCAMP indicates propofol protection at β3M227C (Fig 6), but β3M227W did not reduce sensitivity to propofol (Figs 2 and 3). To explain this result, we suggest that propofol exerts most of its gating effects through the two sites that it shares with etomidate, and relatively weak effects through sites adjacent to βM227 that it shares with mTFD-MPAB. Thus, the β3M227W mutation could occlude propofol binding to α+ – β− and γ+ – β− sites while preserving propofol modulation mediated by β+ – α− sites. This hypothesis is supported by evidence that βN265 mutations reduce propofol binding and reduce most of its modulatory effects 31,38,39. For anesthetic interactions at α1L232 and β3L231, SCAMP and substituted tryptophan sensitivity agree in five of eight drug-residue pairs (Table 4). Discordant results were obtained at α1L232 for propofol and at β3L231 for both etomidate and mTFD-MPAB. No anesthetics occupy the α+ – γ− transmembrane interface The extracellular α+ – γ− interface of GABAA receptors forms the high-affinity benzodiazepine site 40,41, but no anesthetic photolabels incorporate in γ2-M1 in the transmembrane portion of this interface. In our current study, neither γ2I242W nor γ2L246W mutations selectively altered EC5 enhancement by the four intravenous drugs we studied. Moreover, SCAMP studies at both γ2I242C and γ2L246C indicated no protection by these anesthetics, even at twice the concentrations that protected residues in other inter-subunit pockets. Thus, we found no evidence of intravenous anesthetic binding in the α+ – γ− transmembrane interfacial pocket. We tested whether the α+ – γ− site was accessible to a small flexible drug, n-octanol, but observed no protection. Others have suggested that ivermectin, a macrocyclic lactone that modulates GABAA receptors, may bind in this interface 42. Conclusions Our SCAMP results are in remarkable agreement with anesthetic photolabeling studies in GABAA receptors, while identifying new drug interactions that indicate overlapping but non-congruent sites for etomidate/propofol in β+ – α− interfaces and mTFD-MPAB/propofol in α+ – β− and γ+ – β− interfaces. The functional characteristics of substituted tryptophan mutants appear useful for probing allosteric linkages to the channel gate, but unreliable for identifying drug binding contacts. SCAMP provided no evidence that alphaxalone binds near any of the six residues we studied. Finally, our studies in γ2-M1 indicate coupling to channel gating similar to that in the four inter-subunit anesthetic sites, but no anesthetic contacts. Thus, the α+ – γ− transmembrane interface in α1β3γ2L GABAA receptors is a potentially unique modulator site with no established ligands; in other words, an orphan site. We thank Youssef Jounaidi, Ph.D. (Instructor, Dept. of Anesthesia Critical Care & Pain Medicine, Massachusetts General Hospital, Boston, MA, USA) for his help with molecular biology, and Timothy Houle, Ph.D. (Faculty Member, Dept. of Anesthesia Critical Care & Pain Medicine, Massachusetts General Hospital, Boston, MA, USA) for expert advice on statistical analysis. Keith W. Miller, D.Phil. (Professor, Dept. of Anesthesia Critical Care & Pain Medicine, Massachusetts General Hospital, Boston, MA, USA), Douglas Raines, M.D. (Professor, Dept. of Anesthesia Critical Care & Pain Medicine, Massachusetts General Hospital, Boston, MA, USA) and Jonathan B. Cohen, Ph.D. (Professor of Neurobiology, Harvard Medical School, Boston, MA, USA) provided helpful comments on the manuscript. Funding: This work was supported by grants (GM089745 and GM058448) from the National Institutes of Health, Bethesda, MD, USA. Figure 1 GABAA receptor transmembrane inter-subunit anesthetic sites The diagram depicts the arrangements of α1 (yellow), β3 (blue), and γ2L (green) subunits and each subunit’s transmembrane four-helix bundle (M1 to M4). The ‘+’ and ‘–’ interfacial surfaces of each subunit, corresponding respectively to M3 and M1 aspects, are identified. The approximate position of photolabeled residues, α1M236 and β3M227 are labeled in magenta, while their homologs on other subunits (see Table 1) are labeled in black. We also depict the hypothesized inter-subunit sites for etomidate (red rhombi), mTFD-MPAB (R-5-allyl-1-methyl-5-(m-trifluoromethyl-diazirinylphenyl) barbituric acid; green rectangles), and propofol (white hexagons), based on photolabeling data. Figure 2 GABA concentration-responses and anesthetic-shifts in α1-M1 and β3-M1 tryptophan substituted GABAA receptor mutants The top panel shows wild-type peak current data (mean ± sem) for GABA alone (black circles), combined with 3.2 µM etomidate (red triangles), or combined with 8 µM mTFD-MPAB (R-5-allyl-1-methyl-5-(m-trifluoromethyl-diazirinylphenyl) barbituric acid; green diamonds). Normalization for control responses was to maximal GABA and to GABA plus anesthetic for anesthetic shift studies. The four other panels show similar data for two tryptophan-substituted α1-M1 mutants and two β3-M1 mutants (labeled in each panel). Fitted GABA EC50s and EC50 shifts in the presence of anesthetics are summarized in Table 2. Figure 3 Anesthetic EC5 enhancement in wild-type vs α1-M1 and β3-M1 substituted tryptophan GABAA receptor mutants The bar-graph depicts GABA EC5 enhancement ratios (mean ± sem) for five receptor types (x-axis labels) and four equi-potent anesthetic solutions: 3.2 µM etomidate (ETO; red), 8 µM mTFD-MPAB (R-5-allyl-1-methyl-5-(m-trifluoromethyl-diazirinylphenyl) barbituric acid; green), 5 µM propofol (PRO; white), and 2.5 µM alphaxalone (ALFAX; purple). The number of oocytes studied for each interaction is indicated by the numbers in each bar. Each drug’s effect in mutants was compared to the same drug effect in wild-type (by two-way ANOVA). Differs from wild-type at ** p < 0.01, *** p < 0.001. Figure 4 Substituted cysteine modification and anesthetic protection in α1M236Cβ3γ2L receptors The bar graph summarizes pCMBS modification rate data in the presence of GABA alone and in the presence of four anesthetics (x-axis labels: ALX is alphaxalone; ETO is etomidate; MPAB is R-5-allyl-1-methyl-5-(m-trifluoromethyl-diazirinylphenyl) barbituric acid; PRO is propofol). We have previously published data showing the functional effect of pCMBS modification in this mutant and protection by etomidate and propofol 21,31. Color coding by drug is the same as in Figure 3 and the number of cells studied for each condition is indicated by the numbers in each bar. This mutant is characterized by low GABA efficacy (Table 2) and pCMBS modification in the presence of alphaxalone represents a control modification condition with high channel open probability matching that in the presence of other anesthetics 21. ** Differs from the rate with pCMBS + GABA + alphaxalone at p < 0.01 (one way ANOVA). Figure 5 Substituted cysteine modification and anesthetic protection in α1L232Cβ3γ2L receptors Panel A shows a series of current sweeps recorded from a single oocyte expressing α1L232Cβ3γ2L receptors before and after a series of 10 s exposures to p-chloromercuribenzenesulfonate (pCMBS) + GABA (arrows). Red traces show current elicited by 3 µM GABA (~EC5) and the black traces show current elicited by 1 mM GABA (black bars above traces indicate GABA application). The final sweeps depict the effect of full modification by 10 µM pCMBS + GABA for 20 s (asterix and arrow). Panel B shows normalized low:high GABA response ratios and linear least squares fits for individual oocytes from all control modification studies (black symbols and lines) and in the presence of 3.2 µM etomidate (red symbols and lines). Panel C is a bar graph summarizing α1L232Cβ3γ2L modification rate data in control studies and in the presence of four anesthetics (x-axis labels: ALX is alphaxalone; ETO is etomidate; MPAB is R-5-allyl-1-methyl-5-(m-trifluoromethyl-diazirinylphenyl) barbituric acid; PRO is propofol). The number of cells studied for each condition is indicated by the numbers in each bar. *Differs from pCMBS + GABA at p < 0.05. Figure 6 Substituted cysteine modification and anesthetic protection in α1β3M227Cγ2L and α1β3L231Cγ2L receptors Panel A shows a series of traces recorded from a single oocyte expressing α1β3M227Cγ2L receptors. Currents were elicited with 2 mM GABA (black bars above traces indicate GABA applications) before and after a series of 10 s exposures to GABA + 100 µM p-chloromercuribenzenesulfonate (pCMBS; arrows). The final trace was recorded after modification with GABA + 1 mM pCMBS for 20 s. Panel B shows normalized peak current data and linear rate analyses for cells modified with pCMBS + GABA (black symbols and lines) and cells modified with pCMBS + GABA + 8 µM mTFD-MPAB (green symbols and lines). Panel C is a bar graph summarizing α1β3M227Cγ2L modification rate data in the absence and presence of four anesthetics (x-axis labels: ALX is alphaxalone; ETO is etomidate; MPAB is R-5-allyl-1-methyl-5-(m-trifluoromethyl-diazirinylphenyl) barbituric acid; PRO is propofol). Panel D shows a series of traces recorded from a single oocyte expressing α1β3L231Cγ2L receptors. Currents were elicited both 2 µM GABA (red traces) and 1 mM GABA (black traces) before and after a series of 10 s exposures to GABA + 25 µM pCMBS (arrows). Black bars above traces indicate GABA applications. The final trace was recorded after modification with GABA + 250 µM pCMBS for 20 s. Panel E shows normalized low:high GABA response ratios and linear least squares rate analyses for cells modified with pCMBS + GABA (black symbols and lines) and cells modified with pCMBS + GABA + 8 µM mTFD-MPAB (green symbols and lines). Panel F is a bar graph summarizing α1β3L231Cγ2L modification rate data in the absence and presence of four anesthetics (x-axis labels). In panels C and F, results statistically differing from pCMBS + GABA control are * p < 0.05 and ** p < 0.01. Figure 7 GABA concentration-responses and anesthetic modulation of α1β3γ2I242W and α1β3γ2L246W receptors Panel A shows peak current results (mean ± sem) for GABA-dependent activation of α1β3γ2I242W receptors with GABA alone (black circles) and in the presence of 3.2 µM etomidate (red triangles). Both data sets are normalized to 3 mM GABA responses, illustrating the low efficacy of GABA alone. Lines through data represent logistic fits (Eq. 1, methods). Fitted EC50 and shift results are reported in Table 2. Panel B shows peak current results (mean ± sem) for GABA-dependent activation of α1β3γ2L246W receptors with GABA alone (black circles) and in the presence of 3.2 µM etomidate (red triangles). Both data sets are normalized to 1 mM GABA responses. Lines through data represent logistic fits. Fitted results are reported in Table 2. Panel C is a bar graph summarizing GABA EC5 enhancement results for both α1β3γ2I242W and α1β3γ2L246W receptors. At equipotent concentrations, none of the anesthetics (x-axis labels: ALX is alphaxalone; ETO is etomidate; MPAB is R-5-allyl-1-methyl-5-(m-trifluoromethyl-diazirinylphenyl) barbituric acid; PRO is propofol) differ in their modulation of these two mutant receptors. Figure 8 Substituted cysteine modification and anesthetic protection in α1β3γ2I242C and α1β3γ2L246C receptors Panel A shows a series of traces recorded from a single oocyte expressing α1β3γ2I242C receptors. Currents were elicited with 3.5 µM GABA (red traces) and 1 mM GABA (black traces) before and after a series of exposures to GABA + 10 µM p-chloromercuribenzenesulfonate (pCMBS; arrows). Black bars above traces indicate GABA applications. The final trace was recorded after modification with GABA + 100 µM pCMBS for 20 s. Panel B shows normalized low:high GABA response ratios and linear least squares rate analyses for cells modified with pCMBS + GABA. Panel C is a bar graph summarizing α1β3γ2I242C modification rate data in the absence and presence of four anesthetics (x-axis labels: ALX is alphaxalone; ETO is etomidate; MPAB is R-5-allyl-1-methyl-5-(m-trifluoromethyl-diazirinylphenyl) barbituric acid; PRO is propofol). Panel D shows a series of traces recorded from a single oocyte expressing α1β3γ2L246C receptors. Currents were elicited both 1.5 µM GABA (red traces) and 1 mM GABA (black traces) before and after a series of exposures to GABA + 500 µM pCMBS (arrows). Black bars above traces indicate GABA applications. The final trace was recorded after modification with GABA + 1 mM pCMBS for 60 s. Panel E shows normalized low:high GABA response ratios and linear least squares rate analyses for cells modified with pCMBS + GABA. Panel F is a bar graph summarizing α1β3γ2L246C modification rate data in the absence and presence of four anesthetics (x-axis labels). None of the rates with anesthetics differed significantly from control. Table 1 GABAA Receptor M1 Helix Amino Acid Sequence Alignments Position after Conserved GYF 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 α1 G224 Y F V I Q T Y L232 P C I M236 T V I L S Q V S F W L N R E β3 G219 Y F I L Q T Y M227 P S I L231 I T I L S W V S F W I N Y D γ2 G234 Y F T I Q T Y I242 P C T L246 I V V L S W V S F W I N K D The aligned amino acid single-letter code sequences are from human genomic data for GABAA receptor α1 (UniProtKB P14867), β3 (UniProtKB P28472) and γ2 (UniProtKB P18507). The conserved pre-M1 GYF sequence is highlighted in pink. The two highlighted residues α1M236 and β3M227 have been photolabeled by derivatives of intravenous anesthetics. Table 2 Functional and Pharmacological Characteristics of α1β3γ2L GABAA Receptors with M1 Tryptophan Substitutions Receptor Type GABA EC50(µM) [95% CI] (n) GABA Efficacy mean ± se (n) Spont. Activation mean ± se (n) Etomidate-induced GABA EC50 Shift [95% CI] (n) MPAB-induced GABA EC50 Shift [95% CI] (n) α1β3γ2L 18 [16 to 20] (14) 0.88 ± 0.025 (5) < 0.005 (5) 16 [13 to 20] (5) 12 [9.7 to 15] (4) α1L232Wβ3γ2L 4.8 [3.6 to 6.4] * (3) 0.69 ± 0.036 ** (3) <0.005 (4) 2.2 [1.6 to 3.1] * (3) 7.4 [4.6 to 12.0] (3) α1M236Wβ3γ2L 1.5 [1.1 to 2.3] * (3) 0.97 ± 0.011** (6) 0.04 ± 0.014 * (4) 1.6 [1.0 to 2.6] * (3) 2.4 [1.4 to 4.4]* (3) α1β3M227Wγ2L 38 [30 to 47] * (3) 0.99 ± 0.013** (3) <0.005 (4) 12 [9.2 to 15] (3) 4.8 [3.8 to 6.2]* (3) α1β3L231Wγ2L 4.2 [3.7 to 4.8] * 0.91 ± 0.023 (3) 0.035 ± 0.0045 * (4) 4.4 [3.1 to 6.3] * (3) 7.8 [5.0 to 12] (3) α1β3γ2I242W 105 [91 to 121] * (3) 0.75 ± 0.042 ** (4) <0.005 (4) 15 [12 to 19] (3) – α1β3γ2L246W 5.3 [3.6 to 7.7] * (5) 0.97 ± 0.011* (3) 0.11 ± 0.017 ** (5) 4.9 [2.7 to 8.8] * (7) – MPAB is R-5-allyl-1-methyl-5-(m-trifluoromethyl-diazirinylphenyl) barbituric acid. Differs from wild-type at: * p < 0.05, ** p < 0.01, *** p < 0.001. Table 3 Functional and Pharmacological Characteristics of α1β3γ2L GABAA Receptors with M1 Cysteine Substitutions Receptor Type GABA EC50(µM) [95% CI] (n) GABA Efficacy mean ± se (n) Spont. Activation mean ± se (n) GABA EC5 Fold- Enhancement a mean [range] (n) Effect of pCMBS Modification α1L232Cβ3γ2L b 77 * [56 to 107] (5) 0.95 ± 0.03 ** (5) <0.005 (4) 9.8 [8.1 to 11.4] (12) Increase low:high GABA response ratio α1M236Cβ3γ2L b 360 * [260 to 510]* (6) 0.24 ± 0.06*** (6) 0.04 ± 0.014 ** (4) 10.6 [8.6 to 12] (15) Increase low:high GABA response ratio α1β3M227Cγ2L 29 * [25 to 33] (6) 0.65 ± 0.050 * (4) <0.005 (4) 10.1 [7.4 to 14.3] (12) Reduce high GABA response α1β3L231Cγ2L 53 * [39 to 71] (3) 0.66 ± 0.031 ** (3) <0.005 (4) 9.3 [5.8 to 12] (12) Increase low:high GABA response ratio α1β3γ2I242C 16 [13 to 19] (3) 0.94 ± 0.033 * (4) <0.005 (4) 9.3 [5.6 to 11.4] (12) Increase low:high GABA response ratio α1β3γ2L246C 14 [12 to 17] (6) 0.86 ± 0.034 (4) <0.005 (4) 12.0 [8.7 to 15] (12) Increase low:high GABA response ratio pCMBS is p-chloromercuricbenzenesulfonate. Differs from wild-type (see Table 2) at: * p < 0.05, ** p < 0.01, *** p < 0.001. a GABA EC5 Enhancement results are for all four study drugs at 2 × EC50 for tadpole LoRR. Each drug was tested in at least 3 oocytes. b GABA EC50, efficacy and spontaneous activation results are from Stewart et al 21. Table 4 Photolabelinga vs. Substituted Tryptophan Sensitivityb and SCAMPc in α1β3γ2L GABAA Receptor M1 Domains Drug Etomidate mTFD-MPAB Propofol Alphaxalone Residue W PL C W PL C W PL C W PL C α1L232 + – + – – – + – – – ND – α1M236 + + + – – – + + + + – – β3M227 – – – + + + – + + – – – β3L231 + – – – – + – – – – – – γ2I242 – – – – – – – ND – – ND – γ2L246 – – – – – – – ND – – ND – a Photolabeling at α1M236 and β3M227 (highlighted rows) is indicated by a bolded ‘+’ in the middle column (PL) under each anesthetic if the specified residue was an incorporation site for anesthetic analogs: R-(+)-azi-etomidate, R(−)-mTFD-MPAB, m-azi-propofol, or 6-azi-pregnanalone. The negative result for α1M236-alphaxalone was inferred from photolabeling competition using azietomidate. ‘ND’ indicates an absence of direct or indirect photolabeling data, due to missing subunits in the photolabeled receptors. b In the left column (W) under each drug, ‘+’ indicates that a Trp substitution significantly reduces enhancement of GABA EC5 responses by the anesthetic (see Figs 3 and 7). c SCAMP is substituted cysteine modification-protection. In the right column (C) under each anesthetic, ‘+’ indicates that the drug significantly inhibited the rate of covalent modification at the cysteine-substituted sidechain (see Figs 4–6 and 8). Summary Statement Anesthetic contacts in GABAA receptors are incompletely mapped. We showed that substituted cysteine modification-protection agrees with anesthetic photolabeling, and used this approach to test contacts between four anesthetics and all five inter-subunit transmembrane pockets. Conflict of interest: The authors have no conflicts of interest related to this work. 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PMC005xxxxxx/PMC5117680.txt
LICENSE: This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. 9710002 22013 Clin Liver Dis Clin Liver Dis Clinics in liver disease 1089-3261 1557-8224 27842768 5117680 10.1016/j.cld.2016.08.010 NIHMS812524 Article Herbal and Dietary Supplement Induced Liver Injury de Boer Ynto S. 12 Sherker Averell H. 3 1 Liver Diseases Branch, National Institute of Diabetes and Digestive and Kidney Diseases, National Institutes of Health, Bethesda, MD 2 Department of Gastroenterology and Hepatology, VU University Medical Center, Amsterdam, The Netherlands 3 Liver Diseases Research Branch, Division of Digestive Diseases and Nutrition, National Institute of Diabetes and Digestive and Kidney Diseases, National Institutes of Health, Bethesda, MD Correspondence to: Averell H. Sherker, MD, FRCPC, FAASLD, DDDN, NIDDK, NIH, 6011 Executive Blvd, Room 6003, Bethesda, MD 20852, Telephone: + 1 301 451 6207, Fax: +1 301 480 8300, averell.sherker@nih.gov; Additional Author Contact: Ynto S. de Boer, MD, De Boelelaan 1117, 1081 HV Amsterdam, Netherlands, Telephone: +31 20 444 4444, ynto.deboer@nih.gov, y.deboer@vumc.nl 24 8 2016 14 10 2016 2 2017 01 2 2018 21 1 135149 This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. Summary The increase in the use of herbal and dietary supplements (HDS) over the last decades has been accompanied with an increase in the reports of HDS associated hepatotoxicity. The spectrum of HDS induced liver injury is diverse and the outcome may vary from transient liver test elevations to fulminant hepatic failure resulting in death or requiring liver transplantation. There are no validated standardized tools to establish the diagnosis, but some HDS products do have a typical clinical signature that may help to identify HDS induced liver injury. Herbals Dietary supplements Liver Toxicity Drug-induced liver injury Introduction Epidemiology Herbs and botanicals, as well as their metabolites, constituents and extracts, are included in the definition of “dietary supplements” in United States Federal law.(1) The term “Herbal and Dietary Supplements” (HDS) is redundant but commonly used to categorize these products. Although regulated by the Food and Drug Administration, dietary supplements are not subject to the safety monitoring and approval process of pharmaceutical drugs. Despite the facts that these agents generally lack proof of efficacy and that their manufacturers are not permitted to make medical claims, these products have gained extremely wide acceptance and their use has increased over recent decades. During this time, the estimated number of supplements marketed in the United States has increased over ten-fold -- from ~4000 in 1993 to ~55000 in 2012.(2, 3) About half of the adult population in the United States reports having used at least one dietary supplement in the past month.(4, 5) These products are more commonly used by non-Hispanic whites, at older age and with higher levels of education.(6-9) The majority of alternative medicine users feel that the use of HDS products is consistent with their attitudes towards health and life, and that these agents contribute to their wellbeing.(10) The use of HDS is associated with considerable expense. In 2007, $14.8 billion was spent out of pocket on herbal or complementary nutritional products, equivalent to one-third of the out-of-pocket expenditures associated with prescription drug use in the United States.(11) Nationally, it is estimated that 23,000 emergency department visits each year can be attributed to adverse effects associated with the use of HDS.(12) While there have been well-documented outbreaks of acute liver injury associated with specific dietary supplements, the true incidence of HDS-induced liver injury (HILI) is difficult to estimate. In Spain, 2% of investigated cases of drug-induced liver injury have been attributed to HDS(13), while in Iceland the number is approximately 16%.(14) The NIH-funded Drug-Induced Liver Injury Network (DILIN) has recently reported that, of total DILI cases adjudicated between 2004 and 2013, attribution to HDS has increased from 7% to 20% (Figure 1).(15) Among patients presenting with acute liver failure, those whose disease was attributed to HDS use are more likely to undergo liver transplantation than those associated with prescription medicines (56.1 vs. 31.9%, P <0.005).(16) Regulation and quality control In the United States, manufacturers of dietary supplements containing ingredients that were introduced after October 15, 1994, are required to notify the FDA before marketing and to provide a rationale for the safety of the ingredients, such as historical use.(1) Safety testing or FDA approval of dietary supplements is not required before marketing. Only in case of serious adverse events (hospitalization or death) is post marketing notification of the FDA required.(17) Recent examples of HDS products that were withdrawn from the market include OxyElite Pro in 2013 (caused acute liver failure)(18) and Hydroxycut (hepatocellular injury with jaundice).(19) In the European Union (EU), herbal and dietary supplements are regulated under the Traditional Herbals Medicine Products Directive 2004/24/EC.(20, 21) This directive stipulates that if a product has been shown to be safely used over an acceptable long period (over 30 years with 15 years use within the EU), it may be registered through a simplified procedure if the product is not administered parenterally and does not require a medical prescription. In contrast to U.S. regulations, in Europe food supplements such as vitamin and mineral substances are regulated by the European Food Safety Authority (AFSA) according to Directive 2002/46/EC,(22) whereas herbal medical products are overseen by the Committee on Herbal Medicinal Products (HMPC) of the European Medicines Agency (EMA).(23) To further complicate the regulatory landscape, many HDS products are acquired online through the internet, where vendors and manufacturers may not be easily identifiable and enforcement is extremely difficult (Tables 1 and 2). Clinical presentation and Diagnosis HDS induced liver injury may manifest virtually the entire spectrum of acute and chronic liver disease. In epidemic outbreaks (e.g., Oxyelite Pro) affected individuals may present with a relatively consistent phenotype.(24) A small number of agents (e.g., anabolic steroids) have an idiosyncratic clinical presentation which may trigger a high index of suspicion, even in the absence of a disclosed history of exposure. More typically, sporadic cases present with hepatocellular, cholestatic or mixed pattern of liver injury with varying degrees of severity and hepatic dysfunction. Patients may present with asymptomatic liver enzyme elevations, nonspecific constitutional symptoms, symptoms typical of acute hepatitis (icterus, nausea, fatigue, right upper quadrant abdominal pain) or acute liver failure with hepatic encephalopathy. These cases may have an autoimmune phenotype, as the presence of autoantibodies was reported to be 29% in one series of patients with HDS induced liver injury.(25) Other causes for liver injury such as biliary obstruction (cholelithiasis and malignancy), viral hepatitis (hepatitis A, B, C, E, CMV and EBV), alcoholic and nonalcoholic steatohepatitis, autoimmune liver disease (autoimmune hepatitis [AIH], primary sclerosing cholangitis [PSC] and primary biliary cholangitis [PBC]), hemochromatosis and Wilson disease should be considered and excluded. Unlike prescription drugs, HDS are often perceived as ‘natural’ (and, by extension, harmless) products by patients and may not be considered relevant to disclose. Individuals who have been using a product for an extended period of time may legitimately discount its role in their acute illness, not recognizing that formulations may change without notice, sourcing of ingredients may vary, and that unregulated quality control processes may lead to significant lot-to-lot variations. Patients may be reluctant or embarrassed to share their use of alternative therapeutics with conventional medical practitioners and in some cases (e.g., anabolic steroids), consumers will deny use, knowing that the practice is illegal. Patients with liver disease should be questioned directly about their use of prescription medications, over-the-counter products, and HDS. If the diagnosis remains uncertain or the index of suspicion is high, the patient should be questioned about HDS use again. It may be helpful to ask the patient or a family member to bring all of their medications and supplements to the clinic or hospital. Figure 2 is a rolling suitcase full of HDS products brought to clinic (and being consumed) by a patient with marked jaundice and advanced subacute liver disease who repeatedly denied HDS use until told of her physician’s suspicion after she underwent liver biopsy. Figure 3 shows the pharmacopeia of HDS being used by a patient with liver injury, illustrating the challenges of ascribing causality to a specific agent. Even when there is a high degree of suspicion for HILI, it may be difficult to establish a diagnosis with a high degree of certainty. To address this issue, Naranjo et al. (1981) developed an Adverse Drug Reaction Probability Scale (ADRPS) to establish the probability of an adverse drug reaction, primarily in controlled-trials and studies.(26) The score is derived from 10 simple questions that can add up to a total score that ranges from −4 to 14.(26) Although widely used, this system was shown to have a limited applicability in estimating liver injury due to drugs.(27) Instead, they found that the Roussel Uclaf Causality Assessment Method (RUCAM), performed better (See Al Sehu, Xiaochao Ma, and R Venkataramanan’s article “Mechanisms of drug induced hepatotoxicity,” in this issue).(27-30) Pattern of injury As with ‘classical’ DILI, patients with liver injury due to HDS can be classified into hepatocellular, mixed or cholestatic liver injury. This pattern is defined by the R value ([ALT/ULN] ÷ [Alk P/ULN]), in which a value >5 is interpreted as hepatocellular, <2 as cholestatic and 2-5 as mixed hepatic injury. Across the world, HILI appears to be more commonly associated with an hepatocellular pattern of injury than prescription DILI.(14, 25, 31-35) In DILI, hepatocellular injury with jaundice has been described to have a more severe outcome than is seen in mixed or cholestatic patterns of injury (Hy’s Law). Unique aspects of HDS induced liver injury The mechanisms through which HDS products cause hepatoxicity are variable and specific to the substance consumed. In HILI, it is important to note that substances may be safe in their ‘natural’ form but highly concentrated preparations and synthesized chemicals, although marketed as natural, may be associated with toxicities (e.g., catechins found in green tea preparations and synthetic aegeline in OxyELITE Pro(36)). A major challenge in evaluating liver injury due to HDS products is the inaccuracies with respect to product labeling. Contrary to regulations, some products do not display a label listing ingredients. In the DILIN experience, it was found that 29 of 73 HDS products (40%) taken for various purposes (body building, weight loss, immune support and others) and causing liver injury, did not identify green tea extract (GTE) or any of its component catechins on the label despite containing catechins by analytic chemical methods.(37) Interestingly, 3 of 18 (17%) investigated products that did list catechins or GTE on the label did not contain these substances in detectable concentrations. In general, label-reported concentrations of GTE did not accurately reflect the actual contents. Adulteration of HDS products has been described. Tablets of the Chinese herbal product Jin Bu Huan Anodyne listed Polygala chinensis as its single effective ingredient, but were found to contain levo-tetrahydropalmatine, which is found in the plant genera Stephania and Corydalis but not in the genus Polygala.(38) This product was responsible for an outbreak of severe hepatotoxicity before it was removed from the market. Given the lack of regulatory oversight on production and manufacturing, there is a potential for contamination of HDS product. A report on the hepatotoxicity associated with Herbalife products identified bacterial contamination with Bacillus subtilis as a potential cause for the products’ hepatotoxicity profile(39). Hepatotoxicity associated with specific HDS Anabolics Marketed anabolic steroids are generally synthetic chemicals and are not HDS as strictly defined.(1) However, they are typically included in the discussion of HILI. Liver injury due to ingestion of anabolic steroids/bodybuilding compounds has a very typical clinical presentation. It mostly involves young men involved in bodybuilding, weight training, or athletics who, despite modest liver enzyme elevations, present with marked jaundice and pruritus.(15, 40) It typically has a relatively mild course and completely resolves, albeit often slowly, after the cessation of the product. Pruritus may be debilitating. The use of anabolic steroids or enhancing products is often emphatically denied by the patient, yet the diagnosis can be made confidently based on the presentation and clinical course. Frequently, the patient does not return for a scheduled follow-up visit when feeling better (“Jay’s Law”a). Patients should be warned that the use of these agents may be illegal. Black cohosh Black cohosh (Cimicifuga/Actaea racemosa) is an herbal extract that was traditionally used by Native Americans to treat a wide variety of symptoms, including joint aches, myalgia and gynecologic symptoms. Today it is primarily used for the treatment of post-menopausal symptoms. The mechanism of action is unknown, but there have been reports on hepatotoxicity with and without autoimmune features,(41-43) which has led to the publication of a cautionary statement by the US Dietary Supplement Information Expert Committee.(44) However, a more recent meta-analysis of five randomized, double-blind, controlled clinical trials found no evidence that isopropanolic extracts of black cohosh have any adverse effect on liver function.(45) Black cohosh has been known to be adulterated with other species of Actaea (Actaea pachypoda Ell. (white cohosh) and Actaea podocarpa DC. (yellow cohosh) from China which may be responsible for the hepatotoxicity reported.(46) Germander The blossoms of wall germander (Teucrium chamaedrys) have long been used in folk medicine in the Middle East and Mediterranean region as treatment for dyspepsia, obesity, diabetes and abdominal colic. Despite its wide use, it was found in the early 1990s that herbal preparations, in the form of tea or capsules, could cause significant liver injury. The injury is characterized by an hepatocellular pattern associated with marked jaundice, in the absence of immunoallergic or autoimmune features.(47) The latency to onset of injury is relatively short, usually within 30 days of starting the preparation. Although fatal cases and liver transplantation have been reported, the injury generally resolves after the cessation of the agent.(48) Re-exposure to germander leads to rapid recurrence of the injury.(47) The toxicity is thought to arise due to CYP3A4 activation of the component furan ring Teucrin A, which can then alkylate intracellular epoxide hydrolase, leading to formation of anti-microsomal epoxide hydrolase autoantibodies(49). It has been hypothesized that the anorexogenic properties of germander may actually relate to a mild hepatitis. Green tea Green tea (Camellia sinensis) contains polyphenols known as catechins (+-catechin, gallocatechin, epicatechin, epigallocatechin, epicatechin gallate, and epigallocatechin gallate). An intake of 2-3 cups of green tea per day will not generally lead to hepatotoxicity. However, HDS products such as SlimQuick, generally intended for weight loss may contain higher doses of GTE, which can induce hepatotoxicity.(50-53) Epigallocatechin gallate (EGCG) is the most abundant green tea polyphenol, and is believed to be the most active and potent hepatotoxic component.(50) Genomic investigation in outbred mice identified genes that were associated with EGCG toxicity. There is a suggestion that analogous human genetic variants may be associated with susceptibility to GTE hepatotoxicity.(54) Pyrrolizidine alkaloids Pyrrolizidine alkaloids are found in a large number of plants, including several used as HDS. Among these are Senecio, and Symphytum (Comfrey) species. Sinusoidal obstruction syndrome (SOS, previously known as hepatic veno-occlusive disease) was first described in 1954 among Jamaicans drinking “bush teas” brewed from Senecio.(55) Reports from South Africa(56) (Senecio-contaminated bread), India (57) (Crotalaria-contaminated cereal), Afghanistan(58) (Heliotropium-contaminated wheat) and the southwestern United States(59-61) (Comfrey used as HDS) have implicated pyrrolizidine alkaloids in SOS. Many reports describe the disease in children suggesting either an increased susceptibility or a dose effect.(62) Interestingly, the pulmonary vascular bed is also sensitive to the effects of pyrrolizidine alkaloids.(63) Sinosoidal obstruction syndrome may present as an acute, subacute or chronic liver injury characterized by weight gain, ascites and tender hepatomegaly. Hepatic sinusoidal cells appear to be the primary target of pyrrolizidine alkaloids. These cells are damaged and swell, impeding sinusoidal blood flow, inducing hemorrhage, and ultimately resulting in sinusoidal obstruction.(64) Kava kava Kava kava (Piper methysticum) is used to treat anxiety and depressive disorders. However, numerous worldwide reports of fulminant hepatotoxicity, both hepatocellular and cholestatic, have led to the withdrawal of distribution licenses in the US, Europe and Australia.(65-67) Both immunoallergic and idiosyncratic factors (including CYP2D6 deficiency), have been implicated. (65, 66) Traditional Chinese Medicine In the art of Traditional Chinese Medicine (TCM), specific herbs are selected in different preparations for their supposed properties to treat disease within the human body. TCMs have been used to treat conditions such as viral hepatitis for centuries. In China, currently, approximately 40% of cases of DILI are attributed to the use of TCMs, and have been responsible for cases of acute liver failure with associated coagulopathy.(68, 69) Proprietary mixes Herbalife In 2004, a report by Elinav et al. implicated ingestion of Herbalife products in in 12 patients who developed DILI, manifest as acute fulminant hepatitis.(70) Herbalife products consist of a wide range of different mixtures, usually being taken for the purpose of weight loss or general well-being. Identified ingredients include Solidago gigantea, Ilex paraguariensis, Petroselinum crispum, Garcinia cambogia, Spiraea, Matricaria chamomilla, Liquiritia, Foeniculum amare, Humulus lupulus, Chromium and numerous others. Additionally, the proprietary formula of these products, contain a wide range of listed and unlisted ingredients, which makes it challenging to identify a single responsible component with any degree of certainty.(71) In the initial cohort of cases implicated, the injury resolved spontaneously in 11 of 12 (92%) patients; one patient with preexisting chronic hepatitis B died after undergoing liver transplantation. Three patients developed recurrent liver test abnormalities after resuming ingestion of Herbalife products. Since then, several reports have shown similar associations of HILI with Herbalife products, also suggesting contamination with Bacillus subtilis as a potential cause for its hepatotoxicity profile.(39, 72) Employees of Herbalife have aggressively criticized reports of Herbalife-associated hepatotoxicity (73, 74), but their criticisms have been effectively rebutted.(75) OxyELITE Pro Between February 2012 and February 2014 the FDA received 55 reports of liver disease in consumers of OxyELITE Pro. The typical clinical course consisted of a severe acute hepatitis pattern of injury with a median time to onset of 60 days. Hospitalization was required in 33 (60%) cases and liver transplantation in 3 (5%).(76) In early 2013 the formula of OxyELITE Pro had been changed, substituting 1,3-Dimethylamylamine, which had been associated with cardiovascular toxicity, with aegeline.(76) Early reports of liver injury were from Hawaii, where an initial cluster of 7 patients was reported to develop liver injury in the period between May and September 2013.(24, 77) Following this report, other cases were identified in an outbreak investigation performed by the Hawaii Department of Health, Centers for Disease Control and Prevention (CDC) and FDA.(77) The product was recalled and the manufacturer was required to discontinue the distribution of OxyELITE Pro.(18) Aegeline, derived from the bark of the Bael tree in India, has long been used as a traditional remedy but the component implicated in the OxyELITE Pro outbreak was synthetic.(36) Hydroxycut Hydroxycut products are generally marketed and used as a weight loss supplements. Two published case series implicated the use of some Hydroxycut products to the occurrence of liver injury, presenting predominantly with an hepatocellular pattern of injury and symptoms of jaundice, fatigue, nausea, vomiting, and abdominal pain.(78, 79) Several Hydroxycut products were voluntarily recalled in 2009, following a published FDA warning related to the use of Hydroxycut.(19) Move Free Advanced Move Free Advanced is a widely distributed dietary supplement, sold over the counter in the United States for treatment of sore joints and to improve flexibility and mobility. The product contains glucosamine, chondroitin, hyaluronic acid, and proprietary Uniflex consisting of Chinese skullcap (Scutellaria baicalensis) and black catechu. In a 2010 report, the ingestion of Move Free was identified as a probable cause for the development of cholestatic hepatitis which resolved after discontinuation of the supplement.(80) In one patient, Move Free was not initially recognized as the agent responsible for the injury and the patient restarted the supplement, after which liver injury recurred. A liver biopsy performed at that time was consistent with acute drug induced liver injury.(81) In one patient, pulmonary infiltrates developed simultaneous with the hepatotoxicity and resolved completely with cessation of the supplement.(82) Diterpenoid compounds in Scutellaria baicalensis, have previously been shown to cause apoptosis in isolated rat hepatocytes, through reactive metabolites formed by CYP3A.(83) Conclusion/summary The increase in the use of herbal and dietary supplements (HDS) and a growing awareness of the potential for these agent to cause liver injury has been associated with an increase in reports of HDS associated hepatotoxicity. Limited regulatory oversight, inaccurate product labeling, adulterants and inconsistent sourcing of constituent ingredients may all contribute to the potential for toxicity. The spectrum of HDS induced liver injury is diverse and the outcome may vary from transient liver test abnormalities to acute hepatic failure requiring liver transplantation, or resulting in death. The most commonly implicated products include bodybuilding and weight loss products. There are no validated standardized tools to establish the diagnosis, but some HDS products do have a clear clinical signature that can make diagnosis almost certain. The keys to diagnosis are a high level of suspicion and a comprehensive workup to eliminate competing etiologies. Management is generally supportive and nonspecific. Figure 1 Increase of the proportion of enrolled DILI patients due to HDS products in the DILIN prospective study. Light gray bar represents medications, medium gray bar represents nonbodybuilding HDS, and dark gray bar represents bodybuilding HDS. From Navarro VJ, Barnhart H, Bonkovsky HL, et al. Liver injury from herbals and dietary supplements in the U.S. Drug-Induced Liver Injury Network. Hepatology. 2014;60(4):1399-408, with permission. Figure 2 This patient presented with jaundice and moderately severe subacute hepatitis. She denied any drug or HDS ingestion on repeated questioning over several visits. A liver biopsy was performed as liver tests were slow to improve, and was suspicious for hepatotoxicity. The patient was asked again about ingestions and she admitted that she was taking “one or two” HDS products. She wheeled this suitcase in to her next visit and admitted that she was regularly using all the products in the bag. Figure 3 A patient was referred with abnormal liver tests. He readily admitted to using HDS and brought in all of the products seen here. This illustrates the challenges of ascribing causality to a specific agent. (Courtesy of Dr. Victor Navarro) Table 1 Use and mechanism of specific HDS products Herbals Common use Mechanism and comments References Anabolic steroids bodybuilding, weight training, or athletics unknown (40) Black cohosh (Cimicifuga/Actaea racemosa) joint aches, myalgia and menopausal symptoms unknown possibly adultrated with Actaea pachypoda Ell. (white cohosh) and Actaea podocarpa DC. (yellow cohosh) (46) Chaparral (Larrea tridentata) antioxidant properties, anti- inflammatory, liver disease, skin disorders unknown possibly, interference with cyclo- oxygenase or CYP450, estrogen-like activity (84) Green tea extracts (Camellia sinensis) weight loss epigallocatechin gallate (EGCG) toxicity is possibly heightened in individuals with a genetic predisposition (54) Pyrrolizidine alkaloids/Comfrey (Senecio, Symphytum) natural home remedy hepatic sinusoidal cells are damaged, ultimately resulting in sinusoidal obstruction syndrome (55, 64) Germander (Teucrium chamaedrys) dyspepsia, obesity, diabetes and abdominal colic CYP3A4 dependent alkylation of microsomal protein leading to autoantibody formation (47-49) Greater celandine (Chelidonium majus) dyspepsia unknown (85) Kava Kava (Piper methysticum) gall bladder disease, biliary colic, cholelithiasis, and jaundice immunoallergic and idiosyncratic factors, including CYP2D6 deficiency (65, 66) Mistletoe (Viscum Album) asthma, infertility, hypertension mistletoe lectins have immunostimulating properties and a strong dose-dependent cytotoxic activity (86) Pennyroyal (Mentha pulegium, Hedeoma pulegoides) abortifacient oxidation of pulegone by cytochrome P450 into menthofuran, depletion of glutathione (87) Skullcap (Scutellaria baicalensis) arthritic symptoms CYP3A dependent apoptosis demonstrated in isolated rat hepatocytes (80-82) Jin Bu Huan sedation, analgesic adulteration with other plant genera (38) Ma huang stimulant, weight loss idiosyncratic ephidrine alkaloid toxicity (88) Table 2 Use and mechanism of specific HDS proprietary mixes Proprietary mixes Common use Mechanism and comments Reference s Herbalife weight-loss or improvement of well-being wide range of different products with listed and unlisted ingredients hepatotoxicity potentially due to contamination with Bacillus subtilis in some cases (39) OxyELITE Pro weight loss hepatotoxicity emerged after reformulation with synthetic aegeline product was recalled (18, 24) Hydroxycut weight loss different products, changing formulations voluntarily recalled in 2009 (79) Move Free Advanced See skullcap, table 1 (80-82) SlimQuick weight loss, see green tea extracts , table 1 (54) Key Points The increase in the use of herbal and dietary supplements (HDS) and a growing awareness of the potential for these agent to cause liver injury has been associated with an increase in reports of HDS associated hepatotoxicity. Limited regulatory oversight, inaccurate product labeling, adulterants and inconsistent sourcing of constituent ingredients may all contribute to the potential for toxicity. The spectrum of HDS induced liver injury is diverse and the outcome may vary from transient liver test abnormalities to acute hepatic failure requiring liver transplantation, or resulting in death. The most commonly implicated products include bodybuilding and weight loss products. There are no validated standardized tools to establish the diagnosis, but some HDS products do have a clear clinical signature that can make diagnosis almost certain. This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final citable form. Please note that during the production process errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain. The authors have nothing to disclose. a Observation made by Dr. Jay H. Hoofnagle in DILIN Causality Assessment, 2013. 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Bijwerking van een kruidenextract 19271447 43 Cohen SM O’Connor AM Hart J Merel NH Te HS Autoimmune hepatitis associated with the use of black cohosh: a case study Menopause 2004 11 5 575 7 Epub 2004/09/10 15356412 44 Mahady GB Low Dog T Barrett ML Chavez ML Gardiner P Ko R United States Pharmacopeia review of the black cohosh case reports of hepatotoxicity Menopause 2008 15 4 Pt 1 628 38 Epub 2008/03/15 18340277 45 Naser B Schnitker J Minkin MJ de Arriba SG Nolte KU Osmers R Suspected black cohosh hepatotoxicity: no evidence by meta-analysis of randomized controlled clinical trials for isopropanolic black cohosh extract Menopause 2011 18 4 366 75 Epub 2011/01/14 21228727 46 Verbitski SM Gourdin GT Ikenouye LM McChesney JD Hildreth J Detection of Actaea racemosa adulteration by thin-layer chromatography and combined thin-layer chromatography-bioluminescence J AOAC Int 2008 91 2 268 75 Epub 2008/05/15 18476337 47 Larrey D Vial T Pauwels A Castot A Biour M David M Hepatitis after germander (Teucrium chamaedrys) administration: another instance of herbal medicine hepatotoxicity Ann Intern Med 1992 117 2 129 32 Epub 1992/07/15 1605427 48 Dag MS Aydinli M Ozturk ZA Turkbeyler IH Koruk I Savas MC Drug- and herb-induced liver injury: a case series from a single center Turk J Gastroenterol 2014 25 1 41 5 Epub 2014/06/12 24918129 49 De Berardinis V Moulis C Maurice M Beaune P Pessayre D Pompon D Human microsomal epoxide hydrolase is the target of germander-induced autoantibodies on the surface of human hepatocytes Mol Pharmacol 2000 58 3 542 51 Epub 2000/08/23 10953047 50 Lambert JD Kennett MJ Sang S Reuhl KR Ju J Yang CS Hepatotoxicity of high oral dose (−)-epigallocatechin-3-gallate in mice Food Chem Toxicol 2010 48 1 409 16 Epub 2009/11/04 19883714 51 Bonkovsky HL Hepatotoxicity associated with supplements containing Chinese green tea (Camellia sinensis) Ann Intern Med 2006 144 1 68 71 Epub 2006/01/04 16389263 52 Mazzanti G Menniti-Ippolito F Moro PA Cassetti F Raschetti R Santuccio C Hepatotoxicity from green tea: a review of the literature and two unpublished cases Eur J Clin Pharmacol 2009 65 4 331 41 Epub 2009/02/10 19198822 53 Weinstein DH Twaddell WS Raufman JP Philosophe B Mindikoglu AL SlimQuick - associated hepatotoxicity in a woman with alpha-1 antitrypsin heterozygosity World J Hepatol 2012 4 4 154 7 Epub 2012/05/09 22567188 54 Church RJ Gatti DM Urban TJ Long N Yang X Shi Q Sensitivity to hepatotoxicity due to epigallocatechin gallate is affected by genetic background in diversity outbred mice Food Chem Toxicol 2015 76 19 26 Epub 2014/12/03 25446466 55 Bras G Jelliffe DB Stuart KL Veno-occlusive disease of liver with nonportal type of cirrhosis, occurring in Jamaica AMA Arch Pathol 1954 57 4 285 300 Epub 1954/04/01 13147641 56 Wilmot FC Robertson GW Senecio disease or cirrhosis of the liver due to Senecio poisoning Lancet 1920 2 848 9 57 Tandon RK Tandon BN Tandon HD Bhatia ML Bhargava S Lal P Study of an epidemic of venoocclusive disease in India Gut 1976 17 11 849 55 Epub 1976/11/01 1001974 58 Mohabbat O Younos MS Merzad AA Srivastava RN Sediq GG Aram GN An outbreak of hepatic veno-occlusive disease in north-western Afghanistan Lancet 1976 2 7980 269 71 Epub 1976/08/07 59848 59 Stillman AS Huxtable R Consroe P Kohnen P Smith S Hepatic veno-occlusive disease due to pyrrolizidine (Senecio) poisoning in Arizona Gastroenterology 1977 73 2 349 52 Epub 1977/08/01 873137 60 Bach N Thung SN Schaffner F Comfrey herb tea-induced hepatic veno-occlusive disease Am J Med 1989 87 1 97 9 Epub 1989/07/01 2741990 61 Ridker PM Ohkuma S McDermott WV Trey C Huxtable RJ Hepatic venocclusive disease associated with the consumption of pyrrolizidine-containing dietary supplements Gastroenterology 1985 88 4 1050 4 Epub 1985/04/01 3972224 62 Steenkamp V Stewart MJ Zuckerman M Clinical and analytical aspects of pyrrolizidine poisoning caused by South African traditional medicines Ther Drug Monit 2000 22 3 302 6 Epub 2000/06/13 10850397 63 Shubat PJ Banner W Jr. Huxtable RJ Pulmonary vascular responses induced by the pyrrolizidine alkaloid, monocrotaline, in rats Toxicon 1987 25 9 995 1002 Epub 1987/01/01 3124302 64 DeLeve LD Shulman HM McDonald GB Toxic injury to hepatic sinusoids: sinusoidal obstruction syndrome (veno-occlusive disease) Semin Liver Dis 2002 22 1 27 42 Epub 2002/04/03 11928077 65 Russmann S Lauterburg BH Helbling A Kava hepatotoxicity. Ann Intern Med 2001 135 1 68 9 Epub 2001/07/04 66 Stickel F Baumuller HM Seitz K Vasilakis D Seitz G Seitz HK Hepatitis induced by Kava (Piper methysticum rhizoma) J Hepatol 2003 39 1 62 7 Epub 2003/06/25 12821045 67 From the Centers for Disease Control and Prevention Hepatic toxicity possibly associated with kava-containing products--United States, Germany, and Switzerland, 1999-2002 JAMA 2003 289 1 36 7 Epub 2003/01/08 12515265 68 Zhao P Wang C Liu W Chen G Liu X Wang X Causes and outcomes of acute liver failure in China PLoS One 2013 8 11 e80991 Epub 2013/11/28 24278360 69 Zhao P Wang C Liu W Wang F Acute liver failure associated with traditional Chinese medicine: report of 30 cases from seven tertiary hospitals in China* Crit Care Med 2014 42 4 e296 9 Epub 2013/12/18 24335449 70 Elinav E Pinsker G Safadi R Pappo O Bromberg M Anis E Association between consumption of Herbalife nutritional supplements and acute hepatotoxicity J Hepatol 2007 47 4 514 20 Epub 2007/08/19 17692424 71 Teschke R Wolff A Frenzel C Schulze J Eickhoff A Herbal hepatotoxicity: a tabular compilation of reported cases Liver Int 2012 32 10 1543 56 Epub 2012/08/30 22928722 72 Johannsson M Ormarsdottir S Olafsson S Hepatotoxicity associated with the use of Herbalife Laeknabladid 2010 96 3 167 72 Epub 2010/03/04. Lifrarskadi tengdur notkun a Herbalife 20197595 73 Appelhans K Frankos V Shao A Misconceptions regarding the association between Herbalife products and liver-related case reports in Spain Pharmacoepidemiol Drug Saf 2012 21 3 333 4 author reply 5. Epub 2012/03/13 22407600 74 Appelhans K Najeeullah R Frankos V Letter: retrospective reviews of liver-related case reports allegedly associated with Herbalife present insufficient and inaccurate data Aliment Pharmacol Ther 2013 37 7 753 4 Epub 2013/03/06 23458533 75 Reddy KR Bunchorntavakul C Letter: retrospective reviews of liver-related case reports allegedly associated with Herbalife present insufficient and inaccurate data--authors’ reply Aliment Pharmacol Ther 2013 37 7 754 5 Epub 2013/03/06 23458534 76 Klontz KC DeBeck HJ LeBlanc P Mogen KM Wolpert BJ Sabo JL The Role of Adverse Event Reporting in the FDA Response to a Multistate Outbreak of Liver Disease Associated with a Dietary Supplement Public Health Rep 2015 130 5 526 32 Epub 2015/09/04 26327730 77 Johnston DI Chang A Viray M Chatham-Stephens K He H Taylor E Hepatotoxicity associated with the dietary supplement OxyELITE Pro - Hawaii, 2013 Drug Test Anal 2016 8 3-4 319 27 Epub 2015/11/06 26538199 78 Dara L Hewett J Lim JK Hydroxycut hepatotoxicity: a case series and review of liver toxicity from herbal weight loss supplements World J Gastroenterol 2008 14 45 6999 7004 Epub 2008/12/06 19058338 79 Fong TL Klontz KC Canas-Coto A Casper SJ Durazo FA Davern TJ 2nd Hepatotoxicity due to hydroxycut: a case series Am J Gastroenterol 2010 105 7 1561 6 Epub 2010/01/28 20104221 80 Linnebur SA Rapacchietta OC Vejar M Hepatotoxicity associated with chinese skullcap contained in Move Free Advanced dietary supplement: two case reports and review of the literature Pharmacotherapy 2010 30 7 750 258e 62e Epub 2010/07/01 20586134 81 Yang L Aronsohn A Hart J Jensen D Herbal hepatoxicity from Chinese skullcap: A case report World J Hepatol 2012 4 7 231 3 Epub 2012/08/03 22855699 82 Dhanasekaran R Owens V Sanchez W Chinese skullcap in move free arthritis supplement causes drug induced liver injury and pulmonary infiltrates Case Reports Hepatol 2013 2013 965092 Epub 2013/01/01 25431706 83 Haouzi D Lekehal M Moreau A Moulis C Feldmann G Robin MA Cytochrome P450-generated reactive metabolites cause mitochondrial permeability transition, caspase activation, and apoptosis in rat hepatocytes Hepatology 2000 32 2 303 11 Epub 2000/08/01 10915737 84 Sheikh NM Philen RM Love LA Chaparral-associated hepatotoxicity Arch Intern Med 1997 157 8 913 9 Epub 1997/04/28 9129552 85 Benninger J Schneider HT Schuppan D Kirchner T Hahn EG Acute hepatitis induced by greater celandine (Chelidonium majus) Gastroenterology 1999 117 5 1234 7 Epub 1999/10/27 10535888 86 Kienle GS Grugel R Kiene H Safety of higher dosages of Viscum album L. in animals and humans--systematic review of immune changes and safety parameters BMC Complement Altern Med 2011 11 72 Epub 2011/08/30 21871125 87 Thomassen D Slattery JT Nelson SD Menthofuran-dependent and independent aspects of pulegone hepatotoxicity: roles of glutathione J Pharmacol Exp Ther 1990 253 2 567 72 Epub 1990/05/01 2338648 88 Neff GW Reddy KR Durazo FA Meyer D Marrero R Kaplowitz N Severe hepatotoxicity associated with the use of weight loss diet supplements containing ma huang or usnic acid J Hepatol 2004 41 6 1062 4 Epub 2004/12/08 15582145
PMC005xxxxxx/PMC5117809.txt
LICENSE: This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. 9508162 20933 Inflamm Bowel Dis Inflamm. Bowel Dis. Inflammatory bowel diseases 1078-0998 1536-4844 27749455 5117809 10.1097/MIB.0000000000000922 NIHMS811343 Article A Low Neutrophil CD64 Index is Associated with Sustained Remission during Infliximab Maintenance Therapy Minar Phillip MD 1* Jackson Kimberly BA 1 Tsai Yi-Ting MS 1 Rosen Michael J. MD 1 Northcutt Michael MD 2 Khodoun Marat PhD 23 Finkelman Fred D. MD 3 Denson Lee A. MD 1 1 Department of Pediatrics, Division of Gastroenterology, Hepatology and Nutrition, Cincinnati Children’s Hospital Medical Center, Cincinnati, Ohio 2 Department of Internal Medicine, University of Cincinnati, Cincinnati, Ohio 3 Division of Cellular and Immunobiology, Cincinnati Children’s Hospital Medical Center, Cincinnati Ohio * to whom correspondence should be addressed: Phillip Minar, MD, Division of Pediatric Gastroenterology, Hepatology & Nutrition, Cincinnati Children’s Hospital Medical Center, MLC 2010, 3333 Burnet Avenue, Cincinnati, OH 45229, Tel: 513-803-4688, Fax: 513-636-5581, phillip.minar@cchmc.org 24 8 2016 11 2016 01 11 2017 22 11 26412647 This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. Background We have previously shown that CD64 surface expression on circulating neutrophils is significantly elevated in children with newly diagnosed Crohn’s disease (CD). Our primary aim was to investigate whether elevations in neutrophil CD64 in asymptomatic patients could be utilized to predict treatment failure during maintenance infliximab. Methods Pediatric CD subjects receiving maintenance infliximab in clinical remission (short pediatric CD activity index [shPCDAI] <15) were enrolled. We measured neutrophil CD64 expression (CD64 index, Trillium Diagnostics, LLC) and infliximab trough concentrations. Infliximab failure was defined as a shPCDAI>15 on two consecutive infusions, discontinuation of infliximab, hospitalization, endoscopic ulcerations or surgery during the following year of maintenance infliximab. Results We enrolled 36 subjects, 22/36 were male and 29/36 were white. Mean(SD) age at study entry was 15(4) years with a median of 14 (5–20) infusions prior to study entry. 4/36 were receiving a concurrent immunomodulator. Over one year, 15/36 were classified as infliximab failures. Asymptomatic subjects with a neutrophil CD64 index >1 at study entry had a higher probability of treatment failure compared to asymptomatic subjects with a CD64 index <1 (log-rank =.002). We found only neutrophil CD64 index >1 and non-white race were risk factors for treatment failure by univariate regression analysis. We found no difference in the mean infliximab trough concentration at study entry between treatment failures (2.8 μg/ml, SD 1.2) and subjects remaining in remission on infliximab (4.2 μg/ml, SD 3.4; p=.17). Conclusion Neutrophil CD64 index >1 is a significant risk factor for treatment failure during infliximab maintenance therapy. therapeutic drug monitoring biomarkers pediatrics Crohn’s disease Introduction The therapeutic strategy for Crohn’s disease (CD) is to rapidly induce clinical remission and maintain sustained, steroid-free remission by targeting mucosal healing (MH).1 Yet, despite effective induction treatments, the clinical course during the maintenance phase for many patients with CD waxes and wanes with incomplete intestinal healing likely contributing to the >60% lifetime risk of surgery in CD.2, 3 With the advent of the anti-TNFα agents, the likelihood of achieving MH was markedly improved in comparison to thiopurine monotherapy.4 MH, the absence of intestinal ulcerations viewed by endoscopy, has been associated with reduced incidence of CD related complications.5 Monitoring for MH by endoscopy, however, requires sedation, is costly and is associated with a small risk of complications. In contrast, multiple studies have shown that patient reported symptom indices are unreliable surrogates of MH as both the pediatric CD activity index (PCDAI) and short pediatric CD activity index (shPCDAI) poorly correlate with endoscopic scores of intestinal injury.6, 7 As enthusiasm spreads to adopt the treat-to-target therapeutic strategy, it is vital to further validate surrogate markers of MH as frequent use of endoscopy or abdominal imaging are impractical and costly. Infliximab has been shown to have excellent efficacy in moderate-severe pediatric CD, either used alone (monotherapy) or in combination with an immunomodulator such as 6-mercaptopurine or methotrexate.8–10 Although response rates during induction exceed 80%, a recent review found the probability of children with CD remaining on infliximab monotherapy at 5 years was 0.48 (±0.08).8, 10 Similar studies have shown that over 50% of patients receiving infliximab will require dose intensification (increased dose or frequency) to maintain response.11, 12 A recent retrospective investigation found that utilization of proactive therapeutic drug monitoring (TDM, drug monitoring in asymptomatic patients) prolonged infliximab durability as the authors showed ≥90% probability of remaining on infliximab in inflammatory bowel disease patients who achieved a trough concentration of ≥5 μg/ml.10 While studies have shown direct correlations between detectable infliximab trough concentrations, absence of drug antibodies and long-term efficacy,10, 11, 13 there is a paucity of compelling studies to recommend routine use of blood inflammatory biomarkers to improve infliximab durability. Only recently, Click et al. found that over two years, C-reactive protein (CRP) elevation in asymptomatic patients (which they designated as “silent CD”) was significantly associated with risk of hospitalization (adjusted hazard ratio 2.12, 95% confidence interval (CI) 1.13–3.98, p = .02).14 In our initial investigation, we found that the neutrophil Fcγ Receptor I (CD64) surface expression was a promising candidate biomarker to detect CD-related intestinal injury as we found a significant correlation between neutrophil CD64 index (a marker of CD64 expression) and endoscopic severity scores in CD.7 CD64 is a high affinity cell surface receptor for immunoglobulin (Ig)G1, IgG3 and is expressed by innate immune cells linking antibody specificity with effector cell functions such as clearance of immune complexes and antibody-dependent cell-mediated cytotoxicity.15 While inflammation or infection results in upregulation by interferon-γ, CD64 is an attractive biomarker for CD-related gut injury as neutrophil CD64 is minimally expressed during health.16 In a small cohort of CD patients receiving a variety of maintenance medications, we found asymptomatic patients with increased neutrophil CD64 expression (index >1) were more likely to flare over the following year compared to the asymptomatic group with a neutrophil CD64 index <1 (44% vs. 5%, p<.01).7 The primary aim of our prospective, observational study was to investigate the rate of treatment failures in CD children receiving maintenance infliximab. We hypothesized that asymptomatic CD patients with an elevated neutrophil CD64 at study entry were at a higher risk of treatment failure (clinical relapse, hospitalization, presence of endoscopic ulcerations, surgery, or the discontinuation of infliximab) compared to asymptomatic patients with a neutrophil CD64 index <1. Materials and Methods Patient Population We enrolled pediatric CD subjects receiving infliximab at Cincinnati Children’s Hospital Medical Center from 2013–2014. All subjects recruited for this longitudinal study were receiving a stable maintenance dose of infliximab (≥4 infusions) and were in steroid-free clinical remission. We utilized the shPCDAI (<15) to define clinical remission. Although subjects were recruited at varying time points during their maintenance regimen, all were prospectively followed for clinical relapse, hospitalization, surgery or discontinuation of infliximab for one year. We recorded clinical and demographic characteristics, including the CD phenotype according to the Paris Classification,17 and logged the shPCDAI at each infusion. The primary outcome was time to treatment failure one year from study enrollment. We defined treatment failure as a clinical relapse (shPCDAI ≥15 on two consecutive infusions), experiencing a CD complication (such as an intra-abdominal abscess or fistula development), having abdominal surgery for a CD-related complication, presence of endoscopic ulcerations (if performed during study period), a CD-related hospitalization or discontinuing infliximab therapy. The shPCDAI is a validated assessment to determine clinical activity in pediatric CD and is calculated by combining the adjusted scores from 6/9 measures (abdominal pain, number of stools, general well-being, extraintestinal manifestations, weight, and abdominal exam) from the PCDAI.18, 19 We calculated the shPCDAI at each infusion by recording the subject’s weight and providing the family or subject with a questionnaire to evaluate abdominal pain, number of daily stools (+/−blood), well-being and extraintestinal CD manifestations (rash, fever, mouth sores, and joint or eye complaints). As it was not feasible to perform an abdominal exam at each infusion for each subject, we included the abdominal exam documented during the previous clinic visit if the infusion did not coincide with a physician visit. We recorded all clinician initiated changes in the infliximab regimen; however, an infliximab intensification was not considered a treatment failure unless the subject had a shPCDAI ≥15 on two consecutive infusions. As this was an observational study, additional laboratory markers such as CRP, erythrocyte sedimentation rate (ESR), albumin, hemoglobin and platelet count were recorded if performed in conjunction with the infusion but were not mandated during the study. We also recorded the results of clinician-driven TDM and recorded the clinical decisions that followed. All clinician-driven TDM was conducted by Esoterix Laboratory Services, INC (Austin, TX). For primary hypothesis testing, we defined deep remission as asymptomatic (shPCDAI <15) and a neutrophil CD64 index <1 while silent CD was defined as asymptomatic with a neutrophil CD64 index >1. Biologic Assays Neutrophil CD64 index Blood samples were collected at study entry and prior to each infliximab infusion for one year. Measurement of CD64 surface expression on granulocytes was performed by quantitative flow cytometry on a FACSCalibur (BD Biosciences, San Jose, CA) using the Leuko64™ assay kit (Trillium Diagnostics, Brewer, ME20). The kit includes fluorescent beads and antibodies to CD64 and CD163. The lymphocyte, monocyte and granulocyte populations are defined by their forward and side scatter characteristics along with surface CD163 staining to further define the monocyte population. The CD64 index is calculated by the ratio of the mean fluorescent intensity (MFI) of the granulocytes to that of the calibration beads. The granulocyte specific index is referred as the Neutrophil CD64 index. Infliximab concentration We determined free infliximab concentration from blood drawn prior to the infliximab infusion at study entry and at each subsequent infusion. The infliximab concentration was measured by a quantitative enzyme-linked immunosorbent assay (ELISA) with a detection limit of 0.7 μg/ml (Immundiagnostik IDKmonitor®, Germany) following the manufacturer’s instructions with an inter-assay precision of 6% at 2.7 μg/ml, 4% at 5 μg/ml and 4% at 9.6 μg/ml. Concentrations below the cutoff value were calculated as 0.69 μg/ml and reported as undetectable. Antibodies to infliximab were not measured with this assay, however, the presence of antibodies to infliximab were logged if the subject had TDM with the commercial assay as part of their clinical care. Briefly, detection limit for antibodies to infliximab using the commercial assay (Esoterix Laboratory, LLC) is 22 ng/ml with the electrochemiluminescence immunoassay (ECLIA). Statistical Analysis Continuous variables are presented as mean (standard deviation, SD) or median (25–75% interquartile range) depending on the data distribution. We used the Student’s t test for normally distributed data and the Mann-Whitney U test for non-normally distributed data to detect differences between two continuous variables. The Fisher’s exact test was used for comparison of categorical data. We used Kaplan-Meier survival analysis to determine the one year risk of treatment failure between subjects with deep remission and silent CD with the log-rank test used to determine a difference between the two groups. The Cox proportional hazard regression analysis was used to evaluate the relationship between treatment failure and various subject specific covariates to produce hazard ratios and 95% confidence intervals. Both pre-selected (CD64, albumin, CRP, ESR) and post-hoc subject characteristics were included in the univariate model with covariates removed from our multivariable Cox regression analysis if they were nonsignificant by the Wald test (p<0.1). We tested the validity of assumption of the proportional hazards using statistical and graphing methods. Receiving operating characteristic analysis was performed to determine sensitivity, specificity, positive predictive value, and negative predictive value for a neutrophil CD64 index <1 and one-year treatment success. Statistical analysis for this study were performed using R (Core Team 2012, Vienna, Austria) with the ‘survival’ package used to perform Kaplan-Meier and Cox regression analyses. P value of <.05 was considered statistically significant. Ethical Considerations All subjects and/or their parents/guardians provided informed consent, with subjects over the age of 11 providing assent prior to collection of study data. The study was approved by the Institutional Review Board at Cincinnati Children’s Hospital Medical Center. Results Patient Demographics We enrolled thirty-six CD subjects receiving maintenance infliximab. This cohort included 22 males (61%) with a mean age of 15 (SD 4) years at study entry. The cohort had been receiving infliximab for a median of 14 (range 5–20 17) months with 28 (78%) subjects having an inflammatory (B1) phenotype and only 4 subjects on concurrent immunomodulator (three on methotrexate, one on 6-mercaptopurine) therapy. During the 52 weeks of follow up, 15 subjects were classified as treatment failures and 21 remained in steroid-free, clinical remission. Table 1 details the subject’s demographics and disease phenotypes by study outcome. The two most common reasons for treatment failure included an elevated shPCDAI on two consecutive visits (n=8) and infliximab discontinuation (n=3) with all three subjects having elevated antibodies to infliximab. The remaining treatment failures included one subject with an intra-abdominal abscess, one subject with mucosal ulcerations visualized by endoscopy, one subject undergoing ileal resection while one subject was hospitalized to receive intravenous corticosteroids for a severe CD flare. Although the two groups were very similar in terms of disease phenotype and length of time on infliximab, we found that the 20 of the 21 subjects (95.2%) who remained in remission for the follow up period were white in comparison to only 9/15 (60%) in the treatment failure group (Fischer Exact, p=.013). The six non-white included three African American and three biracial children (two were Asian/white and one subject was African American/white). There was no difference in the number of infusions, time (months) on infliximab prior to study entry or mean infliximab dose (p=0.22) between the two groups. Similarly, there was no difference in concurrent medication exposures (immunemodulators) or previous history of abdominal surgery (14.3% vs. 33.3%, p=.24) between the two groups. Serum biomarkers and treatment failures We found that the neutrophil CD64 index at study entry was significantly higher (median 1.00, min-max range 0.5–4.9) in the 15 subjects who subsequently flared compared to the median CD64 index from the 21 subjects who maintained remission (median 0.66, range 0.38–1.7, p =.03). We also found that the mean albumin at study entry was significantly lower 3.6 gm/dL (SD 0.3) in the treatment failure group compared to the subjects who remained in remission (4 mg/dL, SD 0.4, p <.01). We found there was no difference in the CRP or the infliximab trough between these two groups (Table 2, baseline measurements of CRP and ESR were available in 68% and 73% of the enrolled subjects at study entry). Time to Treatment Failure The primary aim of the study was to determine the rate of treatment failure in pediatric CD patients receiving maintenance infliximab who had a normal neutrophil CD64 index. Kaplan-Meier survival analysis was performed to evaluate the probability of treatment failure by separating asymptomatic subjects into CD64high (silent CD) and CD64low (deep remission). Subjects with a neutrophil CD64 index >1 were classified as CD64high (n=12) while those with a neutrophil CD64 index <1 were classified as CD64low (n=24). We found that CD64high subjects were significantly more likely to relapse over 52 weeks (log-rank =.002, Figure 1a) as compared to CD64low. The median time to treatment failure for subjects with a CD64 index >1 was 90 (57–253) days with 9/15 of the relapse events occurring in the first 4 months from study entry. The median survival time for the 24 subjects with a CD64<1 was 246 (174–335) days. With a true hazard ratio (relative risk) for CD64<1 (control) subjects to CD64>1 (experimental) subjects of 0.236, we post-hoc calculated a probability (power) of .906 with an alpha set at .05. We also found there was a significant negative correlation between the neutrophil CD64 index and days until treatment failure (Spearman r = −0.68, p=.007). In order to examine the strength of our findings, we conducted a sensitivity analysis by performing the same survival analysis for treatment failure utilizing the traditional markers of inflammation (including ESR, CRP and albumin). We found that there was no difference in the probability of treatment failure in our cohort when albumin <3.7 gm/dL (log-rank =.062, Figure 1b), CRP or ESR were tested. Finally, we evaluated the probability of infliximab failure after excluding subjects (n=4) with baseline elevations in CRP in order to control for confounding factors associated with a higher likelihood of failure. After controlling for CRP, we found the CD64high subjects continued to have a higher probability of infliximab failure compared to CD64low subjects (log-rank =.038) We performed a univariate cox regression analysis to further evaluate additional pre-selected and post-hoc patient specific characteristics that could have been associated with infliximab treatment failure. In addition to the neutrophil CD64, we found non-white race and albumin <3.7 gm/dL were associated with a higher probability of treatment failure (p value <.1, Table 3). We then performed a multivariable Cox regression analysis with these three variables and found that neutrophil CD64 index >1 and non-white race were the only significant risk factors (p<.05) for treatment failure in our cohort (Table 4). Neutrophil CD64 testing characteristics We found that 8/12 CD64high (pre-study median CD64 index 1.7, range 1.1–42.2) subjects relapsed compared to 7/24 CD64low subjects (median CD64 index 0.62, range 0.54–0.76). Using receiver operator characteristic curve analysis, a neutrophil CD64 index >1 had a sensitivity of 53.3%, specificity of 81%, positive predictive value of 66.7%, and negative predictive value of 70.8% for treatment failure over the following year (area under the curve 0.72, 95% CI 0.54–0.89, p=.029). The median neutrophil CD64 index at the time of treatment failure was 1.9 (range 0.83–3.2) with a mean infliximab trough of 1.9 (SD 1.2) μg/ml at the time the subject was classified as a treatment failure. In comparison, the mean infliximab trough for treatment responders at week 52 (or at censorship) was 3.4 (SD 2.8) μg/ml with a CD64 index of 0.88 (0.64–1.3). In figure 2, we have graphed the longitudinal assessments of neutrophil CD64 index and infliximab trough concentration at each infusion up until treatment outcome (treatment failure or continued remission) for one year with the dotted line representing a CD64 index =1. Neutrophil CD64 and TDM Although CD64high subjects were much more likely to lose response to infliximab, we found there was no difference in infliximab dose [CD64low, mean 6.5 (SD 2.7) vs. CD64high, 7.5 (SD 2.8) mg/kg, p=.3)], time on infliximab (months or number of infusions), or the infliximab trough concentration at study entry for these subjects compared to CD64low subjects. CD64high subjects had a mean infliximab trough at study entry of 2.5 (SD 1.6) μg/ml compared to a CD64low trough of 4.2 μg/ml (SD 3.2, p=.11). However, CD64low subjects had a higher mean albumin (4 gm/dl, SD 0.32) compared to a mean albumin of 3.5 gm/dL (SD 0.25, p<.001) in the CD64high group. As noted previously, we did not routinely measure antibodies to infliximab in all 36 subjects, however, 25/36 subjects had clinician-driven TDM (which included checking for drug antibodies) during the one year study. Overall, there were 16 events (14 subjects) of antibodies to infliximab during the study; all 16 events had concurrent detectable drug levels. There was no difference in the number of antibodies to infliximab events between the CD64high (41.7%) and CD64low (37.5%, p = 1.0) subjects. The median antibody to infliximab concentration was 69 (min-max 26–1478) ng/ml with only 4/16 of the antibodies to infliximab >100 ng/ml. In the four subjects with antibodies >100 ng/ml, the corresponding neutrophil CD64 index was 3.74, 2.79, 1.11 and 0.61 which directly correlated to the anti-infliximab antibody concentration (1478, 754, 292, 121 ng/ml, respectively). Likewise, there was a significant negative correlation between infliximab trough level and the neutrophil CD64 index (Spearman r = −0.36, p<.05) measured at study entry using the ELISA with a similar correlation between CD64 and infliximab troughs measured at subsequent infusions during the one year observational study (Spearman r = −0.35, p<.001, n=133). Finally, when we evaluated all infliximab trough measurements (repeated measures) for the 36 subjects, we found the 21 treatment responders had a median infliximab trough of 3.6 (1.6–7.3) μg/ml compared to 2.6 (1.5–3.6) μg/ml for the 15 treatment failures (p=.008). Discussion Patients with silent CD, defined by Click et al. as asymptomatic (treated) patients with an elevated CRP, were found to have a nearly 2-fold risk for hospitalization over the subsequent two years compared with asymptomatic CD patients with a normal CRP.14 In our longitudinal, observational study designed to evaluate infliximab efficacy in pediatric CD, we found a neutrophil CD64 index >1 in asymptomatic patients (“silent CD”) was not only associated with infliximab failure over one year but also correlated with lower infliximab trough concentrations during maintenance. In addition, in a secondary analysis, we found our survival testing (risk of treatment failure) remained statistically significant (log-rank =.038) after removing subjects in our cohort who had baseline elevations in CRP at study entry (as a method to control for possible clinically-silent but ongoing intestinal inflammation). While clinical remission remains a goal of CD therapy, the intestinal healing achieved with anti-TNF therapy has compelled clinicians to consider treating patients to “biologic remission.” Biologic remission remains a moving target in terms of its fundamental definition, however, many clinicians would agree that complete absence of intestinal ulcerations by endoscopy would suffice.5 However, it is vital to explore surrogate biomarkers (fecal and blood) of biologic remission as repeat endoscopy is a costly endeavor for CD patients. While we did not measure MH at the beginning of our study with endoscopy, we have previously found that the neutrophil CD64 index correlates significantly with the endoscopic severity score for CD (Spearman r = 0.66, p<.001) and have demonstrated that neutrophil CD64 measured during the course of therapy can be utilized to assess for disease progression.7 Although larger studies are needed, our results indicate that patients with a repeated CD64 index >1 require close follow-up as they were found to have a higher probability of earlier clinical relapse which is likely secondary to ongoing intestinal ulcerations. Our data also suggests neutrophil CD64 is a reliable surrogate biomarker of intestinal healing as we found subjects with sustained remission rarely had consecutive CD64 index measurements >1 (Figure 2a) and enjoyed longer infliximab durability. TDM has and will continue to improve the care of CD patients receiving infliximab, yet over-zealous TDM is likely impractical considering the financial cost and the prolonged testing turnaround time.21 With the significant negative correlation we found between the neutrophil CD64 index and the infliximab trough (Spearman r = −0.35, p<.001), we propose that frequent monitoring for silent CD (biologically active) with the neutrophil CD64 biomarker in CD patients who are receiving maintenance therapy will lead to an individualized, data-driven strategy to optimize medical therapy by targeting TDM to patients with persistent elevations in the CD64 index. From this study, we cannot conclude whether there is a direct relationship between CD64 elevations and infliximab immunogenicity given the small numbers of patients with antibodies to infliximab, however, we found it interesting that subjects with antibodies to infliximab >100 ng/ml had concurrent elevations in neutrophil CD64 (in 3 of 4 subjects). We hypothesize the cause for acute neutrophil CD64 elevation is the result of cumulative intestinal inflammation initiated by the presence of anti-TNF neutralizing antibodies. This is the first study to evaluate longitudinal assessments of the neutrophil CD64 surface expression in predicting infliximab failures. Our study, however, is not the first to propose an association between CD64 and infliximab treatment nonresponse. Wojtal et al., retrospectively, found that colonic CD64 (Fcγ Receptor I) mRNA expression was significantly increased in the inflamed intestinal segment of infliximab non-responders.22 The strength of our study derives from our access to a well-defined, closely monitored longitudinal pediatric cohort receiving infliximab infusions at the same hospital. In addition, our statistical analysis was robust and controlled for confounders such as infliximab trough values and additional biomarkers at study entry. Because neutrophil CD64 surface expression has been shown to be elevated during acute bacterial infections (e.g. Streptococcus spp. and sepsis)23 we used strict criteria to define treatment failure as a shPCDAI >15 on two consecutive infusions which could control for possible skewing of a symptom index by infections or functional gastrointestinal complaints. Stool cultures for enteric infections as well as testing for Clostridium difficile were clinician-driven, however, there was no evidence of active infection (by history, exam or testing) at study entry or during treatment in any of the subjects. We had to rely on the shPCDAI to define clinical remission at study entry as it is uncommon to perform endoscopy (to detect MH) in clinically quiescent pediatric patients and only six patients had a fecal calprotectin at study entry (another potential surrogate marker to assess baseline intestinal inflammation). Although the shPCDAI has been validated as a surrogate for clinical activity in pediatric CD, Turner et al. recently showed the shPCDAI and other pediatric activity indices demonstrated only modest capacity to distinguish between endoscopic healing and ongoing disease activity.24 We also found that it was unfeasible to score the abdominal exam component of the shPCDAI at each infusion as not every infusion corresponded to a clinic visit and therefore we had to rely on the previous documented physician exam to calculate the shPCDAI at each infusion which increased our risk of misclassification. While non-white race was found to be a risk factor for anti-TNF failure in our univariate regression model, we have not found the intensity of the neutrophil CD64 index to vary by race or gender in this or in any other pediatric CD cohorts. The anti-TNF agents are currently the most effective medical treatment for CD, yet, fewer than 50% will remain on infliximab monotherapy after five years.10 Recently, proactive TDM was shown to be highly effective in improving long-term efficacy with infliximab monotherapy.11 Our results show that repeated, longitudinal assessments of the neutrophil CD64 index can be utilized in clinical practice to closely monitor biologic activity and infliximab response in pediatric CD. In addition, our findings support that a persistently elevated neutrophil CD64 index in an asymptomatic patient should trigger closer follow-up for an opportunity to intervene with TDM, abdominal imaging, or repeat endoscopy before anti-TNF failure. This work was supported by NIH K23DK105229 (PM), the NASPGHAN Foundation/Crohn’s and Colitis Foundation of America Young Investigator Development Award (PM), NIH K23DK094832 (MR), and NIH R21AI103816 (FDF, LAD) Abbreviations CI Confidence interval CRP c-reactive protein CD Crohn’s disease ESR erythrocyte sedimentation rate MH mucosal healing shPCDAI short Pediatric Crohn’s disease activity index SD standard deviation TDM therapeutic drug monitoring TNF tumor necrosis factor Figure 1 Kaplan-Meier curves showing the proportion of Crohn’s subjects with treatment failure over one year. (A) Survivor analysis by the circulating neutrophil CD64 expression (index) at study entry and (B) survivor analysis by serum albumin at study entry. Figure 2 Neutrophil CD64 index scores and infliximab concentrations of individual study subjects at baseline and throughout the one year follow up by those who remained in remission (A, C) during the study and infliximab failures (B, D). The dotted line represents the cut off (≥1) for an abnormal neutrophil CD64 index in this study. Infliximab concentrations were measured serially prior to each infusion (trough) by an ELISA for (C) subjects remaining in remission and (D) infliximab failures. Table 1 Baseline characteristics by treatment outcome Remission (n=21) Treatment Failure (n=15) Female 7 (33%) 7(47%) White race 20 (95%)a 9 (60%) Age at diagnosis, years (SD) 11 (4) 12 (5) Age at study entry, years (SD) 16 (4) 14 (5) No. of infusions prior to entry, (SD) 14 (8) 13 (9) Months on infliximab prior, (SD) 26 (18) 18 (15) Infliximab dose at entry, mg/kg (SD) 6.3 (2.6) 7.5 (2.9) Crohn’s location  Ileum (L1) 4 1  Colonic (L2) 1 1  Ileocolonic (L3) 16 13  Perianal location (p) 6 2 Crohn’s behavior  Inflammatory (B1) 18 10  Stricturing (B2) 2 3  Penetrating (B3) 1 1  Both penetrating/stricturing (B2B3) 0 1 Concomitant medications  6-mercaptopurine 1 0  Methotrexate 1 2  5-ASA 4 2 a Fisher exact test <.05 Table 2 Blood biomarkers at study entry for the 36 clinically quiescent Crohn’s disease subjects receiving infliximab maintenance infusions. Biomarker Remission (n=21) Treatment Failure (n=15) p Neutrophil CD64, (range) 0.66 (0.38–1.7) 1.00 (0.5–4.9) .03 ESR mm/hr., (SD, n=27) 9 (4) 26 (27) .02 CRP mg/dL, (range, n=25) 0.29 (0.29–0.33) 0.29 (0.29–0.62) .24 Albumin gm/dL, (SD) 4 (0.4) 3.6 (0.3) <.01 Infliximab trough μg/ml, (SD) 4.2 (3.4) 2.8 (1.2) .17 Table 3 Univariate Cox regression to evaluate risk factors (at study entry) for treatment failure in asymptomatic subjects receiving maintenance infliximab. Covariate Hazard Ratio 95% CI p value Neutrophil CD64 index >1 4.43 1.6–12.4 .005 Female 1.5 0.53–4 .47 Non-white race 4.5 1.6–12.9 .005 <10 years old at diagnosis 0.68 0.23–2 .48 BMI z-score <0 1.4 0.47–3.9 .57 Penetrating or stricturing phenotype 1.8 0.62–5.3 .28 Perianal disease 0.52 0.12–2.3 .39 Previous surgery 2 0.7–6 .2 Received infliximab <1 year 1.6 0.57–4.7 .36 Study entry infliximab trough  <1 μg/ml 1.1 0.25–5.1 .88  <3 μg/ml 1.2 0.38–3.8 .75 Infliximab dose >5 mg/kg 1.8 0.6–5.2 .3 CRP >0.5 mg/dL 2.6 0.69–9.5 .16 ESR >10 mm/hr. 1.7 0.42–6.4 .47 Albumin <3.7 gm/dL 2.7 0.92–7.9 .071 Table 4 Multivariable Cox regression analysis to predict infliximab treatment failure. Covariate Hazard Ratio 95% CI p value Neutrophil CD64 index >1 9.2 2.7–32 <.001 Non-white race 8.5 1.9–39 .006 Albumin <3.7 gm/dL 0.76 0.19–3 .69 Financial disclosures: The authors have no financial, professional, or personal arrangement(s) with a company whose product figures prominently in the submitted manuscript or with a company making a competing product. 1 Baert F Moortgat L Van Assche G Mucosal healing predicts sustained clinical remission in patients with early-stage Crohn’s disease Gastroenterology 2010 138 2 463 8 quiz e10–1. Epub 2009/10/13 19818785 2 Hanauer SB Inflammatory bowel disease: epidemiology, pathogenesis, and therapeutic opportunities Inflammatory bowel diseases 2006 12 Suppl 1 S3 9 Epub 2005/12/27 16378007 3 Thia KT Sandborn WJ Harmsen WS Risk factors associated with progression to intestinal complications of Crohn’s disease in a population-based cohort Gastroenterology 2010 139 4 1147 55 Epub 2010/07/20 20637205 4 Colombel JF Sandborn WJ Reinisch W Infliximab, azathioprine, or combination therapy for Crohn’s disease The New England journal of medicine 2010 362 15 1383 95 Epub 2010/04/16 20393175 5 Shah SC Colombel JF Sands BE Systematic review with meta-analysis: mucosal healing is associated with improved long-term outcomes in Crohn’s disease Alimentary pharmacology & therapeutics 2016 43 3 317 33 26607562 6 Zubin G Peter L Predicting Endoscopic Crohn’s Disease Activity Before and After Induction Therapy in Children: A Comprehensive Assessment of PCDAI, CRP, and Fecal Calprotectin Inflammatory bowel diseases 2015 7 Minar P Haberman Y Jurickova I Utility of neutrophil Fcgamma receptor I (CD64) index as a biomarker for mucosal inflammation in pediatric Crohn’s disease Inflammatory bowel diseases 2014 20 6 1037 48 24788216 8 Hyams J Crandall W Kugathasan S Induction and maintenance infliximab therapy for the treatment of moderate-to-severe Crohn’s disease in children Gastroenterology 2007 132 3 863 73 quiz 1165–6. Epub 2007/02/28 17324398 9 Walters TD Kim MO Denson LA Increased effectiveness of early therapy with anti-tumor necrosis factor-alpha vs an immunomodulator in children with Crohn’s disease Gastroenterology 2014 146 2 383 91 Epub 2013/10/29 24162032 10 Grossi V Lerer T Griffiths A Concomitant Use of Immunomodulators Affects the Durability of Infliximab Therapy in Children With Crohn’s Disease Clinical gastroenterology and hepatology : the official clinical practice journal of the American Gastroenterological Association 2015 13 10 1748 56 25911120 11 Vaughn BP Martinez-Vazquez M Patwardhan VR Proactive therapeutic concentration monitoring of infliximab may improve outcomes for patients with inflammatory bowel disease: results from a pilot observational study Inflammatory bowel diseases 2014 20 11 1996 2003 25192499 12 De Bie CI Hummel TZ Kindermann A The duration of effect of infliximab maintenance treatment in paediatric Crohn’s disease is limited Alimentary pharmacology & therapeutics 2011 33 2 243 50 21083595 13 Afif W Loftus EV Jr Faubion WA Clinical utility of measuring infliximab and human anti-chimeric antibody concentrations in patients with inflammatory bowel disease The American journal of gastroenterology 2010 105 5 1133 9 Epub 2010/02/11 20145610 14 Click B Vargas EJ Anderson AM Silent Crohn’s Disease: Asymptomatic Patients with Elevated C-reactive Protein Are at Risk for Subsequent Hospitalization Inflammatory bowel diseases 2015 21 10 2254 61 26197446 15 Hoffmeyer F Witte K Schmidt RE The high-affinity Fc gamma RI on PMN: regulation of expression and signal transduction Immunology 1997 92 4 544 52 Epub 1998/03/14 9497497 16 Buckle AM Hogg N The effect of IFN-gamma and colony-stimulating factors on the expression of neutrophil cell membrane receptors J Immunol 1989 143 7 2295 301 Epub 1989/10/01 2476506 17 Levine A Griffiths A Markowitz J Pediatric modification of the Montreal classification for inflammatory bowel disease: the Paris classification Inflammatory bowel diseases 2011 17 6 1314 21 Epub 2011/05/12 21560194 18 Kappelman MD Crandall WV Colletti RB Short pediatric Crohn’s disease activity index for quality improvement and observational research Inflammatory bowel diseases 2011 17 1 112 7 20812330 19 Hyams JS Ferry GD Mandel FS Development and validation of a pediatric Crohn’s disease activity index Journal of pediatric gastroenterology and nutrition 1991 12 4 439 47 Epub 1991/05/01 1678008 20 http://www.trilliumdx.com/24/Leuko64. 21 Katz L Gisbert JP Manoogian B Doubling the infliximab dose versus halving the infusion intervals in Crohn’s disease patients with loss of response Inflammatory bowel diseases 2012 18 11 2026 33 Epub 2012/02/02 22294554 22 Wojtal KA Rogler G Scharl M Fc gamma receptor CD64 modulates the inhibitory activity of infliximab PloS one 2012 7 8 e43361 Epub 2012/09/01 22937039 23 Davis BH Olsen SH Ahmad E Neutrophil CD64 is an improved indicator of infection or sepsis in emergency department patients Arch Pathol Lab Med 2006 130 5 654 61 16683883 24 Turner D Levine A Walters TD Which PCDAI Version Best Reflects Intestinal Inflammation in Pediatric Crohn’s Disease? Journal of pediatric gastroenterology and nutrition 2016
PMC005xxxxxx/PMC5117824.txt
LICENSE: This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. 7508686 6347 Pain Pain Pain 0304-3959 1872-6623 27842048 5117824 10.1097/j.pain.0000000000000704 NIHMS813027 Article CaMKIIα underlies spontaneous and evoked pain behaviors in Berkeley sickle cell transgenic mice He Ying 13 Chen Yan 1 Tian Xuebi 1 Yang Cheng 1 Lu Jian 1 Xiao Chun 1 DeSimone Joseph 23 Wilkie Diana J. 4 Molokie Robert E. 1235 Wang Zaijie Jim 13* 1 Department of Biopharmaceutical sciences, University of Florida, Gainesville, FL 2 Division of Hematology/Oncology, Department of Medicine, University of Florida, Gainesville, FL 3 University of Illinois Sickle Cell Center, University of Florida, Gainesville, FL 4 Department of Biobehavioral Nursing Science, University of Florida, Gainesville, FL 5 Jesse Brown Veteran’s Administration Medical Center, Chicago, IL 60612 * Corresponding author: Zaijie Jim Wang, Ph.D., University of Illinois, Chicago, IL, 60607 (MC865), (312)996-0888 (voice); (312)996-0098 (fax); zjwang@uic.edu 28 8 2016 12 2016 01 12 2017 157 12 27982806 This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. Pain is one of the most challenging and stressful conditions to patients with sickle cell disease (SCD) and their clinicians. Patients with SCD start experiencing pain as early as three months old and continue having it throughout their lives. Although many aspects of the disease are well understood, little progress has been made in understanding and treating pain in SCD. This study aimed to investigate the functional involvement of Ca2+/calmodulin-dependent protein kinase II (CaMKIIα) in the persistent and refractory pain associated with SCD. We found non-evoked ongoing pain as well as evoked hypersensitivity to mechanical and thermal stimuli were present in Berkeley sickle cell transgenic mice (BERK mice), but not non-sickle control littermates. Prominent activation of CaMKIIα was observed in the dorsal root ganglia and spinal cord dorsal horn region of BERK mice. Intrathecal administration of KN93, a selective inhibitor of CaMKII, significantly attenuated mechanical allodynia and heat hyperalgesia in BERK mice. Meanwhile, spinal inhibition of CaMKII elicited conditioned place preference in the BERK mice, indicating the contribution of CaMKII in the ongoing spontaneous pain of SCD. We further targeted CaMKIIα by siRNA knockdown. Both evoked pain and ongoing spontaneous pain were effectively attenuated in BERK mice. These findings elucidated, for the first time, an essential role of CaMKIIα as a cellular mechanism in the development and maintenance of spontaneous and evoked pain in SCD, which can potentially offer new targets for pharmacological intervention of pain in SCD. Sickle cell disease pain spontaneous pain phosphorylation Ca2+/calmodulin-dependent protein kinase II 1. Introduction Sickle cell disease (SCD) is a group of autosomal recessive genetic disorders that are caused by mutations in the hemoglobin genes and result in polymerization of deoxyhemoglobin and red cell sickling. Pain is a life-long companion of people living with SCD and is a predictor of disease severity and mortality.39 A nationwide epidemiological study reported that over 60% of SCD patients have at least one pain crisis episode annually.39 In addition to severe acute pain that is associated with vaso-occlusive crises, chronic pain is also prevalent in SCD. A longitudinal diary survey found over half of patients with SCD reported the presence of chronic pain on more than 50% of the days.42 In our self-reported, computerized McGill Pain Questionnaire study conducted in the clinic for non-urgent visits (i.e., not on crisis days), over 60% of subjects reported continuous or constant pain.48 Strikingly, 90% of these subjects also chose pain quality descriptors that are consistent with the presence of neuropathic pain. On average, patients reported using 4.9 analgesics, yet at least one third of patients were not satisfied with their pain control.48 As better treatment and care are extending the life expectancy of patients with SCD, pain is increasingly becoming a big problem that negatively impacts the health and quality of life of these patients. Limited progress, however, has been made in understanding the basic neurobiological mechanisms underlying chronic pain in SCD. In this study, we employed Berkeley sickle cell transgenic mice (BERK mice),37 a model of severe SCD, to identify and characterize neurobiological mechanisms of chronic pain in SCD. BERK mice express exclusively human sickle hemoglobin and have a phenotype that closely mimics many features of severe SCD in humans, including severe hemolytic anemia, irreversibly sickled red cells, increased rigidity of erythrocytes, extensive multiple organ damage, vascular ectasia, intravascular hemolysis, exuberant hematopoiesis, cardiomegaly, glomerulosclerosis, visceral congestion, hemorrhages, multiorgan infarcts, pyknotic neurons, progressive siderosis, gallstones, and priapism.25,33,37 Ongoing spontaneous pain is frequently reported by patients with SCD; however, it is rarely studied in preclinical research.28 In our ongoing work with other, but not all, chronic pain conditions, we found the Ca2+/calmodulin-dependent protein kinase IIα (CaMKIIα) to be a critical molecular mechanism in experimental models of chronic inflammatory and nerve injury neuropathic pain.6,7,32 In this study, we examined the role of CaMKIIα in chronic pain behaviors including ongoing spontaneous pain in BERK mice. 2. Materials and methods 2.1. Materials 2-[N-(2-hydroxyethyl)]-N-(4-methoxybenzenesulfonyl)]amino-N-(4-chlorocinnamyl)-N-methylbenzylamine) (KN93) and 2-[N-(4-Methoxybenzenesulfonyl)]amino-N-(4-chlorocinnamyl)-N-methylbenzylamine (KN92) were purchased from Tocris Bioscience (Ellisville, MO). Lidocaine HCl (2%) was from Hospira (Lake Forest, IL). Other chemicals were purchased from Sigma-Aldrich (St. Louis, MO). CaMKIIα siRNA (sense, 5′-CACCACCAUUGAGGACGAAdTdT-3′, antisense, 5′-UUCGUCCUCAAUGGUGdTdT-3′) and scrambled RNA duplex control (sense, 5′-AUACGCGUAUUAUACGCGAUUACGAC-3′; antisense, 5′-CGUUAAUCGCGUAUAAUACGCGUAT-3′) were synthesized by Integrated DNA Technologies (Coralville, IW). Lidocaine, KN93, KN92 and RNA duplexes were administered intrathecally (i.t.) in a volume of 5 μL by percutaneous puncture through the L5–L6 intervertebral space.26,32 The RNAs were mixed with a transfection reagent i-Fect (Neuromics, Minneapolis, MN) at a ratio of 1:5 (w/v).7 2.2. Animals BERK mouse38 breeding colony was established from breeders that were obtained from the Jackson Laboratories (Bar Harbor, MA). These mice have been crossed once with C57Bl/6J mice in the Jackson Laboratories, so they have > 50% C57Bl/6J background. We used the following breeding schedule that has been found to be most efficient: female breeders: heterozygous for Hbb (non-sickle); male breeders: homozygous for Hbb (sickle). Genotyping was performed as previously published38 to obtain the BERK mice (sickle) and non-sickle wild-type control littermate mice. The latter serves as control for BERK mice. Age- and sex- matched adult mice (3–5 months old; 20–30g) were used in the study. Prior to actual experimental procedures, mice were provided with food and water ad libitum. Experiments were carried out in accordance with the International Association for the Study of Pain (IASP) recommendations and the NIH Guide for the Care and Use of Laboratory Animals after securing approval from the University of Illinois Institutional Animal Care and Use Committee. The researchers who performed tests were blinded to genotype information before and during the experiments. 2.3. Assessment of ongoing spontaneous pain The conditioned place preference (CPP) method was employed to unmask the ongoing spontaneous pain as we have previously described.21 The CPP apparatus (San Diego Instruments, San Diego, CA) consists of 3 Plexiglas chambers separated by manual doors. A center chamber (6 1/4″ W × 8 1/8″ D × 13 1/8″ H) connects the two end-chambers that are identical in size (10 3/8″ W × 8 1/8″ D × 13 1/8″ H), but can be distinguished by the texture of the floor (rough vs. smooth) and wall pattern (vertical vs. horizontal stripes). Movement of mice and time spent in each chamber were monitored by 4 × 16 photobeam arrays and automatically recorded in SDI CPP software. Preconditioning was performed across 3 days for 30 min each day when mice were exposed to the environment with full access to all chambers. On day 3, a pre-conditioning bias test was performed to determine whether a preexisting chamber bias exists. In this test, mice were placed into the middle chamber and allowed to explore open field with access to all chambers for 15 min. Data were collected and analyzed for duration spent in each chamber. Animals spending more than 80% or less than 20% of the total time in an end-chamber were eliminated (~ 10% of total animals) from further testing. A single trial conditioning protocol was used in the experiments. On conditioning day (day 4), mice first received vehicle control (saline, i.t.) paired with a randomly chosen chamber in the morning and, 4 h later, either KN93 (45 nmol, i.t.) or lidocaine (0.04 %, i.t.) was paired with the other chamber in the afternoon for 15 min (lidocaine) or 30 min (KN93). Whereas the pairing time with lidocaine was based on previous experience,21 pairing condition with KN93 was determined in pilot experiments. On the test day, 20 h after the afternoon pairing, mice were placed in the middle chamber of the CPP box with all doors open so the animals had free access to all chambers. The movement and duration that each mouse spent in each chamber were recorded for 15 min for analysis of chamber preference. Difference scores were calculated as (test time-preconditioning time) spent in the drug chamber. 2.4. Assessment of cold sensitivity Sensitivity to cold stimulus was examined as previously described.8 Mice were placed in individual Plexiglas containers to adapt to the environment for 30 min. A cold stimulus was applied by a brief application (1 s) of tetrafluoroethane to the ventral surface of left hindpaw. Mice were observed for 5 min and the number of licks and the duration of lifting of the sprayed paw were recorded. 2.5. Assessment of heat sensitivity Sensitivity to heat stimulus was determined by the following methods: 1) paw withdrawal latency to radiant heat using a plantar tester (UGO BASILE Model 7372, Stoelting, Wood Dale, IL).7,20 Mice were allowed to acclimate within Plexiglass enclosures on a clear glass plate maintained at 30°C. Radiant heat stimulation was applied to the center of the planter surface of the hindpaw and the latency to paw withdrawal was recorded. A cut-off time of 20s was applied to avoid tissue damage, which was appropriate as the mean control latency is about 12 sec, although the control baseline can be adjusted by varying the intensity of the stimulus. The presence and degree of hyperalgesia were determined by comparing the withdrawal latencies of the test animals and those of controls; 2) The hotplate test was conducted by placing the mice in a glass cylinder on a cold/hot plate analgesia meter (Stoelting) with floor temperature controlled to 50, 52 or 55°C and determining the latency to hindpaw licking or escaping. A 60, 45, and 30 s cutoff time was set for 50°C, 52°C, and 55°C plate temperature, respectively, to prevent injury; 3) The tail immersion test was performed by dipping the distal half of the tail into a water bath maintained at 48, 52, or 55 °C and recording the latency to a rapid tail flick response. A 15, 12, or 10 s cutoff was applied to 48, 52, or 55 °C test, respectively. 2.6. Assessment of mechanical sensitivity Non-noxious mechanical sensitivity was assessed by probing with von Frey filaments.7 Mice were placed in individual Plexiglas containers on a wire mesh platform and tested after 30 min acclimation to the environment. Calibrated von Frey filaments (Stoelting, Wood Dale, IL) were used to press upward to the midplantar surface of the hindpaw for 5 s or until a withdrawal response happened. Using the “up-down″ algorithm,11 50% probability of paw withdrawal threshold was determined. 2.7. Formalin-induced inflammatory pain model Tonic inflammatory pain was induced in BERK mice and non-sickle littermate controls (~ 3 months) by a subcutaneous injection of formalin (2% in saline, 20 μL/mouse) into the dorsal surface of the left hindpaw, as described previously.44,46 The hindpaw was observed for 60 min for the number and duration of paw flinching and the results tabulated for successive 5 min intervals. This test produces a distinct biphasic response. The total number of flinches during the early phase (0–10 min) and late phase (10.01–60 min) were summed, respectively. 2.8. Immunohistochemistry Immunostaining of spinal activated CaMKIIα (pCaMKIIα) was performed as described previously.7 After deep anesthesia with ketamine (100 mg/kg) and xylazine (5 mg/kg, i.p.), mice were initially perfused with phosphate buffer (0.1 M, pH 7.4) for 5 min, followed by 4% paraformaldehyde in phosphate buffer for 20 min (~10 mL/min). Spinal cord lumbar regions were dissected out and sectioned at 20 μm thickness with a cryostat. The floating sections were incubated with the primary antibody for pCaMKIIαThr286 (1:1000, Santa Cruz Biotechnology, Santa Cruz, CA) overnight at room temperature, followed by another incubation with biotinylated goat anti-rabbit IgG secondary antibody (1:200, Vector Laboratories, Burlingame, CA) at room temperature for 2 h. The sections were developed using Elite Vectastain ABC kit (Vector Laboratories). Diaminobenzidine (DAB) stained sections were imaged using Olympus IX71 inverted fluorescence microscope (Olympus Corp., Lake Success, NY) and quantified by the MetaMorph Imaging Software (Molecular Devises, Sunnyvale, CA). For each animal, 5–10 consecutive sections (depending on the size of the region) were imaged. For each group, 5 sections and 6 areas from each section were analyzed and averaged. 2.9. Immunoblotting The lumbar spinal cord and dorsal root ganglia (DRG) tissues were harvested for western blot analysis as previously described.23 Briefly, tissue samples were homogenized in a modified RIPA buffer (1% NP-40, 0.5% sodium deoxycholate, 0.1% sodium dodecyl sulfate (SDS), 5 mM EDTA, 1.0 mM NaF, 10mM sodium pyrophosphate, and 2 mM sodium vanadate in PBS, pH 7.4) in the presence of protease inhibitors and centrifuged (11,000g, 60 min). Supernatants were separated by 12% SDS-PAGE and electro-transferred onto PVDF membrane. The membrane was probed with a rabbit antibody against pCaMKIIα (1:1000, Santa Cruz Biotechnology) at room temperature overnight, followed by incubation with HRP-conjugated donkey anti-rabbit secondary antibody (1:1000, GE Healthcare, Marlborough, MA)at room temperature for 1 h. An enhanced chemiluminescence detection system (ECL, GE Healthcare) was applied for development. The membrane was then stripped and reprobed with a mouse anti-CaMKIIα antibody (1:1000, Santa Cruz Biotechnology) followed by a HRP-conjugated anti-mouse secondary antibody (1:1000, GE Healthcare) and developed as above. Finally, the membrane was stripped again and probed with a mouse anti-β-actin antibody (1:10,000, Sigma) followed by a HRP-conjugated anti-mouse secondary antibody (1:10,000, GE Healthcare). ECL signals were detected using a ChemiDoc system and analyzed using the Quantity One program (Bio-Rad). CaMKII immunoreactivity was expressed as the ratio of the optical densities of pCaMKIIα or CaMKIIα to those of β-actin. 2.10. Statistical Analysis All data are presented as Mean ± SEM. For evoked pain behavior data, differences between groups were analyzed using a one-way ANOVA (treatment) followed by Tukey post hoc test (multiple groups) or Student’s t test (two groups). To analyze the CPP data, two-way ANOVA (pairing vs. treatment) was applied followed by Bonferroni post hoc test. Difference scores were analyzed using Student’s paired t test by computing the differences between test time and preconditioning time for each mouse. Statistical significance was established at the 95% confidence limit. 3. Results 3.1. Presence of ongoing spontaneous pain in BERK mice Patients with SCD experience ongoing pain that is different from the sickle cell crisis pain. We established a conditioned place preference (CPP) paradigm that has been validated in mice to detect non-evoked pain in SCD mice.21 The chronic pain in mice with SCD may present as an aversive state, and the suppression of which may produce CPP, as we have observed in mice with tissue or nerve injury.10,22 First, we performed a preconditioning test to ensure that there was no existing chamber bias for any of the mice with different genotypes. After a single trial conditioning with saline and lidocaine, BERK mice spent significantly more time in the chambers that were paired with lidocaine (420 ± 32 s) than in saline-paired chamber (256 ±37 s, P < 0.01), indicating that lidocaine induced CPP in the sickle mice (Fig. 1A). On the contrary, non-sickle littermate mice spent equal amount of time in the saline (330 ± 25 s) or lidocaine (294 ± 34 s) paired chambers, suggesting the absence of lidocaine-CPP in the non-sickle mice (Fig. 1A). This observation was in agreement with what we reported for naïve ICR and C57Bl/6 mice in the absence of spontaneous pain.10,21,22. We also analyzed the different score for each mouse in each chamber. In comparison to the time spent in the chambers during pre-conditioning, the sickle mice displayed significant difference scores in lidocaine-paired chamber (P < 0.05). None of the other mice groups, including the sickle mice paired with saline treatment, exhibited significant difference scores after conditioning (Fig. 1B). These scores further confirmed the presence of ongoing spontaneous pain in BERK sickle cell mice. 3.2. Hypersensitivity to noxious cold stimulus in BERK mice Patients with SCD have enhanced pain sensitivity to cold environments.2,35,41,47 To assess the noxious cold hyperalgesia in BERK mice, the plantar surface of the left hindpaw was exposed to tetrafluoroethane for 1 s.8 Under this condition, it produced reflex responses as measured by the paw licking and lifting behaviors. We counted the number of licks occurred in 5 min triggered by the cold stimulus. As compared with the non-sickle littermates, BERK mice displayed significantly enhanced licking behavior, with an increased number of licks by more than 2.6 fold (P < 0.01, Fig. 2A). The total time of hindpaw lifting and licking in BERK mice (139.9 ± 5.0 s) was increased by around 3.5 fold of that in the non-sickle mice (40.5 ± 10.0 s) (P < 0.001, Fig. 2B). Consistent with the findings from other cold pain measurements from other investigators,24,34 these observations demonstrated the existence of cold-induced hypersensitivity in BERK mice. 3.3. Evoked mechanical and heat pain behaviors in BERK mice We also determined the baseline nociceptive response of BERK mice towards mechanical and heat stimuli. As compared with the age/sex-matched non-sickle control mice (1.52 ± 0.14 g), BERK mice displayed significantly reduced pain threshold (0.10 ± 0.05 g) to normally innocuous mechanical stimulus by von Frey filament probing (P < 0.001, Fig. 2C), indicative of the presence of tactile allodynia in BERK mice. In response to the radiant heat challenge, BERK mice exhibited decreased latencies to noxious heat stimuli applied to the hindpaw (6.32 ± 0.78 s in BERK mice vs. 11.97 ± 0.78 s in non-sickle mice, P < 0.001, Fig. 2D), indicating the presence of heat hyperalgesia. The enhanced thermal sensitivity was further confirmed in the tail-flick assay, as BERK mice consistently displayed shortened tail-withdrawal latencies to the water bath maintained at 48°C (6.28 ± 0.56 s in BERK mice vs. 8.35 ± 0.63 s in non-sickle mice, P < 0.05), 52°C (1.84 ± 0.11 s in BERK mice vs. 2.31 ± 0.15 s in non-sickle mice, P < 0.05), and 55°C (1.02 ± 0.07 s in BERK mice vs. 1.33 ± 0.09 s in non-sickle mice, P < 0.05) (Fig. 2E). In addition, BERK mice showed a significant decrease in the latency to noxious input in the hot plate test at 52 °C (6.61 ± 0.90 s in BERK mice vs. 8.90 ± 0.55 s in non-sickle mice, P < 0.05) (Fig. 2F). Therefore, these data indicated that BERK mice have pronounced evoked hypersensitivity to mechanical and heat stimuli. 3.4. Inflammatory pain sensitivity in BERK mice As seen in SCD patients, BERK mice have been reported to have increased inflammation and inflammatory mediators.1,17,33 A logical question to ask is whether BERK mice responded differently to commonly used inflammatory pain stimuli such as formalin. Intraplantar formalin injection induced typical biphasic spontaneous pain in both BERK mice and non-sickle littermate controls (Fig. 3A). There was no difference between the BERK and non-sickle mice in Phase I (1–10 min) response (P > 0.05, Fig. 3B). For Phase II (10.01–60 min), there was a significantly increased response in BERK mice (P < 0.05, Fig. 3A). 3.5. Activation of CaMKIIα in BERK mice We hypothesized that CaMKIIα, a key cellular protein kinase and regulator of neuronal activity, may play an important role in promoting chronic pain in SCD. As a first step to address this question, we determined CaMKIIα activity in the spinal cord and dorsal root ganglia (DRG) of BERK mice and non-sickle control mice. Western blot analysis showed the expression of activated or phosphorylated CaMKIIα (pCaMKIIα) was significantly elevated in the spinal cord in BERK mice (Fig. 4A). Compared with the non-sickle mice, the level of spinal pCaMKIIα in BERK mice increased by 1.7-fold (P < 0.01). On the other hand, the expression of total CaMKIIα in BERK and control mice were not different (P > 0.05). Similar observations were found in DRG region (Fig. 4B). There was a prominent activation of CaMKIIα in DRG of the sickle mice, with a 2.3-fold increase of pCaMKIIα as compared with that in the non-sickle mice. We further conducted immunohistochemical analysis in BERK mice. The pCaMKIIα immunoreactivity was found mostly in the superficial dorsal horn of the spinal cord (Fig. 4C). Quantitative analysis of pCaMKIIα immunoreactivity was performed by counting the number of positively stained cells using the MetaMorph Imaging Software. The percentage of pCaMKIIα-positive cells was drastically enhanced in the sickle mice (48%, 105/220,Fig. 4C, right panel) compared with that of non-sickle mice (29%, 45/155, Fig. 4C left panel). The latter was similar to the percentage of pCaMKIIα-positive spinal neurons in the Sprague-Dawley rat.4 These data clearly demonstrated that spinal CaMKIIα activity is enhanced in BERK sickle cell mice. 3.6. Pharmacologic intervention of CaMKIIα in BERK mice To assess a possible functional role of CaMKIIα in sickle cell pain, we examined the effect of KN93, a potent and cell permeable inhibitor of CaMKIIα in BERK and control mice. CPP test was performed first using KN93 as the pairing drug. If CaMKIIα participates in the ongoing spontaneous pain in BERK mice, its inhibition is expected to suppress ongoing pain and produce CPP. In these experiments, BERK mice demonstrated a strong preference for KN93-paired chamber (415 ± 14 s) over the saline chamber (311 ± 17 s, P < 0.05, Fig. 5A), after pairing with KN93 (45nmol, i.t.) for 30 min. In contrast, the non-sickle mice spent similar amount of time in the saline chamber (336 ± 20 s) and the KN93-paired chamber (361 ± 22 s) (P > 0.05). As compared before and after conditioning, BERK mice preferred to stay in the KN93-paired chamber as illustrated by the significant difference score generated in the KN93-paired chamber (P < 0.05, Fig. 5B). In addition, KN92, a kinase-inactive derivative of KN93 failed to produce CPP in either BERK or control mice (Fig. 5C–D). Since KN93 selectively elicited CPP in BERK mice, these data suggested a functional role for CaMKIIα in mediating ongoing spontaneous pain in SCD. We next examined the evoked pain behaviors in BERK and control mice after receiving a bolus injection of KN93 (45 nmol, i.t.).The mechanical hypersensitivity in BERK mice (0.06 ± 0.01 g) was transiently, but effectively, reversed by KN93 (Fig. 5E). With an initial onset at around 30 min, the peak anti-allodynic effect of KN93 was observed at 2 h, when the paw withdrawal threshold in BERK mice (1.55 ± 0.26 g, P < 0.001) was restored to a level that was indistinguishable from that in the non-sickle mice (1.59 ± 0.27g). In response to the radiant heat stimuli, spinal administration of KN93 was capable of reversing thermal hyperalgesia in BERK mice (Fig. 5F). Significant attenuation was achieved at 2 h (11.17 ± 1.15 s in BERK mice treated with KN93 vs. 6.33 ± 0.79 s in BERK mice treated with KN92, P < 0.01). Moreover, KN93 did not change mechanical and thermal sensitivity in the non-sickle mice (Fig. 5E–F). Neither did KN92 affect baseline nociception in BERK or the non-sickle mice. Therefore, inhibiting spinal CaMKIIα is effective in transiently reversing evoked hypersensitivity in BERK sickle cell mice. 3.7. CaMKIIα silencing in BERK mice To further investigate the essential role of CaMKIIα in sickle cell pain, siRNA targeting CaMKIIα (i.t.) was applied to knock down the expression of CaMKIIα. This approach is known to produce a highly selective repression of the target protein. BERK and non-sickle littermate mice received CaMKIIα siRNA or scrambled RNA duplex (2 μg/injection, twice per day for 3 consecutive days, i.t.). Sensitivities to mechanical and thermal stimuli were measured daily. Treatment with CaMKIIα siRNA gradually attenuated mechanical allodynia (Fig. 6A) and thermal hyperalgesia (Fig. 6B) in BERK mice. When tested 24 h after first siRNA treatment, thermal hyperalgesia was significantly reversed in BERK mice (6.03 ± 0.33 s in siRNA group vs. 2.90 ± 0.37 g in scrambled RNA group, P < 0.01, Fig. 6B). After 3 days’ treatment, CaMKIIα knockdown was confirmed in the spinal cord by western blot analysis (Fig. 6A insert). In BERK mice, mechanical hypersensitivity was completely reversed (0.96 ± 0.11 g in siRNA group vs. 0.10 ± 0.03 g in scrambled RNA group, P < 0.001, Fig. 6A). Meanwhile, thermal hyperalgesia in BERK mice was significantly suppressed by CaMKIIα siRNA and lasted for 5 d (Fig. 6B). On the other hand, CaMKIIα siRNA did not alter mechanical or thermal sensitivity in the non-sickle mice (Fig. 6A–B). Furthermore, BERK and non-sickle mice were subjected to the CCP paradigm to investigate ongoing spontaneous pain on Day 4. BERK mice treated with scrambled RNA spent significantly more time in the lidocaine-paired chamber (412 ± 44 s) than in the saline chamber (231 ± 38 s) (P < 0.05, Fig. 6C), similar to BERK mice without any treatment (Fig. 1). BERK mice received 3d CaMKIIα siRNA failed to show preference for saline- (344 ± 36 s) or lidocaine-paired (340 ± 41 s) chambers (P > 0.05), which was in stark contrast to BERK mice received scrambled RNA or BERK mice received no treatment (Fig. 1). Lidocaine didn’t produce CPP in the non-sickle mice treated with CaMKIIα siRNA or scrambled RNA. Analysis of difference scores confirmed that CaMKIIα siRNA disrupted lidocaine-CPP in BERK mice (Fig. 6D). Since persistent ongoing spontaneous pain and evoked hypersensitivities were no longer present in BERK mice after knocking down spinal CaMKIIα, these data strongly indicated that CaMKIIα is required for chronic pain behaviors in SCD. 4. Discussion Pain in SCD is characterized by the presence of chronic pain with episodes of acute pain crises. The neurobiology of chronic pain in SCD is poorly understood. Studies employing animal models of SCD become an indispensable approach in vivo to unravel the complicated molecular mechanisms in the central and peripheral nervous systems. Early murine models of SCD, such as HbSAD mice and HbS/HbS-Antilles mice expressed a “supersickling” variant of HbS and developed organ and tissue characteristics of SCD. However, these mice retain the production of mouse globins, which interfere significantly with the sickling of erythrocytes. To overcome this limitation, the recent creation of transgenic mice, such as BERK mice completely replace mouse hemoglobins with human hemoglobins, producing a phenotype that closely mimics many features of severe SCD in humans.25,33,37 In the present study, we profiled two distinctive pain components (ongoing spontaneous pain and evoked pain) in BERK mouse. When asked to characterize their pain, patients described daily, chronic pain without any known stimulus.42,48 As a dominant clinical manifestation, it is imperative to investigate the presence of ongoing spontaneous pain in animal models of SCD. Our study is the first to demonstrate the presence of ongoing spontaneous pain in BERK mice using the CPP paradigm that we have validated in mice with chronic tissue inflammation or nerve injury.21 Indeed, a single trial conditioning with lidocaine was sufficient to produce CPP selectively in BERK mice, but not non-sickle mice (Fig 1). This is not only in agreement with the clinic characteristics of pain in patients, but also the first study to demonstrate the feasibility of applying CPP paradigm to detect ongoing spontaneous pain in a transgenic mouse model. BERK mice showed heightened responses to formalin in the second phase, but not the first phase, suggesting a central mechanism. Unlike the Phase I that is mostly due to direct activation of primary afferent nociceptors, the second phase is considered as an index for inflammatory response involving central mechanisms.44 To identify heat hypersensitivity in BERK mice, we used three different types of heat stimuli with varying intensities. These results corroborated with each other to demonstrate that BERK mice displayed prominent heat hyperalgesia as well as mechanical allodynia, as have been reported previously by two other groups,24,30 reflecting the presence of fully developed evoked pain behaviors in mice with SCD. The enhanced responses and/or lowered thresholds to heat and mechanical stimuli were also found in patients with SCD by thermal and mechanical quantitative sensory testing.2,12 Allodynia to noxious cold was also found in the study. In an operant assay using two plates with different temperature settings, BERK mice spent less time on the plate set at 23 °C than that at 30 °C.49 Another group observed changes in mouse facial expression, body length and back curvature in response to noxious cold (4 °C).34 Together with the findings of the current study, it is clear that BERK mice exhibited hypersensitivity to both mild and extremely cold stimuli, which was also reported by patients with SCD.2,12,35 Our findings provided the first evidence that CaMKIIα is a critical mediator for chronic pain in SCD. CaMKIIα is a multifunctional, Ca2+/calumodulin (CaM) activated serine/threonine protein kinase that is a key component of intracellular Ca2+ signaling pathways.9,16,31 It is involved in a variety of Ca2+-mediated cellular processes including the biosynthesis of neurotransmitters, hormone secretion, neurotransmitter release, gene expression and neuronal plasticity.18,31 Autophosphorylation at threonine 286/287 of CaMKIIα renders the kinase fully active even in the absence of Ca2+. Robust activation of CaMKIIα was identified in the spinal cord of BERK mice (Fig. 4), suggesting a correlation between increased CaMKIIα activity and persistent pain state in SCD. Moreover, spinal inhibition or knock-down of CaMKIIα was able to abolish both ongoing spontaneous pain and evoked hypersensitivities in BERK mice, further illustrating a functional role of spinal CaMKIIα in promoting chronic pain in SCD. CaMKIIα is specifically expressed in the superficial laminae in the spinal dorsal horn and in the small to medium diameter primary sensory neurons in the primary afferent, where nociceptive signals are transmitted and processed.3,4 CaMKIIα activity was significantly increased in the spinal cord within minutes after an intradermal injection of capsaicin.13 Spinally administered KN93 inhibited the enhanced response in the spinal nociceptive neurons and changes in exploratory behavior evoked by capsaicin.13 KN93 selectively and directly binds to the CaM-binding site of CaMKII, preventing the activation of CaMKII.43 We have previously reported that CaMKIIα is required for the initiation and/or maintenance of chronic inflammatory pain, L5/L6 nerve ligation-induced neuropathic pain, and opioid-induced hyperalgesia.6,7,32 Furthermore, CaMKIIα has been reported to contribute to hyperalgesia priming for transition from acute to chronic pain.14,15 Establishing CaMKIIα mechanisms will open a new scientific arena to explore in future studies the upstream and downstream signaling components of CaMKIIα-mediated pain transmission in SCD. Both the release of Ca2+ from intracellular storages and Ca2+ influx from extracellular sources as a result of receptor or ion channel activation may activate CaMKIIα. Activation of the transient receptor potential vanilloid 1 (TRPV1) or the N-methyl-D-aspartate (NMDA) receptors can lead to Ca2+ influx and CaMKII activation.27,47 The latter, in turn, phosphorylates and activates the TRPV1 and the NMDA receptors.19,29 Therefore, there exist potential feed-forward loops to keep CaMKIIα-mechanisms active after the original Ca2+ signaling has subsided or disappeared, which is crucial to maintain chronicity in pain conditions such as that in SCD. Hargreaves and colleagues found that capsaicin increased CaMKIIα activity in TRPV1-positive neurons in rat trigeminal ganglion neurons.40 In these trigeminal ganglion neurons, capsaicin- or n-arachidonoyl-dopamine (NADA)-evoked calcitonin gene-related peptide (CGRP) release was inhibited by KN93.40 Indeed, TRPV1has been identified as a contributor to the mechanical hypersensitivity in SCD. TRPV1 antagonist A-425619 attenuated mechanical hypersensitivity in BERK mice 30–60 minutes after administration (i.p.), implicating a unique TRPV1-mediated mechanism for mechanical hypersensitivity in SCD.24 Several other mechanisms have also been proposed for SCD pain. BERK mice were found to have decreased expression of the mu opioid receptor and increased immunoreactivity for CGRP, substance P, and several activators of neuropathic and inflammatory pain, which may contribute to hyperalgesia.5,30 These investigations found that morphine, the cannabinoid receptor agonist CP 5594015, or inhibitors of mast cell activation attenuated chronic pain behaviors in BERK mice.30,45 As an intracellular protein kinase, CaMKIIα may be activated by some of these inflammatory or pronociceptive mediators, although future studies are needed to investigate potential interactions. In summary, we characterized pain behaviors in BERK mice using age- and sex-controlled non-sickle littermate mice as controls. Moreover, a CaMKIIα-mediated cellular mechanism for chronic pain in SCD was identified by two complementary approaches employing pharmacological inhibition and genetic silencing. These findings may lead to translational research targeting CaMKIIα for alleviating chronic pain in SCD. The latter is poorly managed in the clinic because it is frequently refractory to the currently available pain medications, underscoring an urgent need for novel medications for treating chronic pain in SCD. Although specific inhibitors of CaMKIIα have not made to the clinical testing, we have previously identified a FDA-approved antipsychotic drug trifluoperazine as a potent inhibitor of CaMKIIα.6,32 In a small mechanism-based translational study, trifluoperazine was not only found to be safe, but also showed some promise in alleviating chronic pain after a single dose in patients with SCD.36 Additional studies with trifluoperazine and other CaMKIIα inhibitors may ultimately lead to rational designing, identifying, and optimizing clinically useful treatment for the chronic pain in SCD. This work was supported by a grant (R01HL098141) from the National Heart Lung and Blood Institute (NHLBI), National Institutes of Health (NIH). Y.H. is a Sickle Cell Scholar supported by U01HL117658 from NHLBI. Its contents are solely the responsibility of the authors and do not necessarily represent the official views of the NHLBI or NIH. Figure 1 Lidocaine induced conditioned place preference (CPP) in BERK sickle cell mice. (A) BERK mice spent significantly more time in lidocaine-paired chamber, whereas the non-sickle control littermates showed no chamber preference to lidocaine. ** P < 0.01, saline paired vs. lidocaine paired group, two-way ANOVA followed by Bonferroni post hoc test; n = 6. (B) Difference score analysis confirmed that the sickle mice, but not non-sickle mice produced CPP to lidocaine. * P < 0.05, test time vs. preconditioning time in the lidocaine paired chamber, paired t test; n = 6. Figure 2 Evoked pain behaviors displayed in BERK sickle cell mice. A cold stimulus was applied by a brief (1 s) spray of tetrafluoroethane to the ventral surface of hindpaw. (A) The number of licks and (B) the duration of lifting of the sprayed paw were recorded. *** P < 0.001, “sickle” group vs. “non-sickle”, n = 9. (C) When compared with the non-sickle control littermates, BERK mice exhibited significantly reduced threshold of response to probing by von Frey filaments, P < 0.001, n = 12. (D) BERK mice showed significantly reduced withdrawal latency to radiant heat, indicating the presence of thermal hyperalgesia, ***P < 0.001 vs. “non-sickle” mice group, n = 12. (E) In the tail immersion test performed at 48, 52, or 55 °C. BERK mice showed reduced latencies to a rapid tail flick response as compared with non-sickle control mice. *P < 0.05, n = 9. (F) BERK mice showed significantly reduced withdrawal latency to the hot plate maintained at 52 °C, * P < 0.05 vs. “non-sickle” group, n = 9. Figure 3 BERK sickle cell mice responded to the inflammatory pain stimulus induced by a subcutaneous injection of formalin (2% in saline, 20 μL/mouse) into the dorsal surface of the left hindpaw. (A) Mice paw flinching was observed for 60 min, the number of flinches was recorded for successive 5 min intervals. (B) The total number of flinches during the early phase (0–10 min) and late phase (10.01–60 min) were summed, respectively.* P < 0.05 “sickle” vs. “non-sickle” group, n = 10. Figure 4 Activation of CaMKIIα was observed in BERK sickle cell mice. Western blot analysis showed significant increase of phosphorylated CaMKIIα (pCaMKIIα) in the spinal cord (A) and DRG (B) of BERK mice as compared with the non-sickle control mice, ** P < 0.01, n =3. (C) Compared with the non-sickle mice (left panel), elevated immunohistochemical staining of pCaMKIIα was found in the superficial lamina region of the dorsal spinal cord in the sickle cell mice (right panel). Quantitative analysis of pCaMKIIα immunoreactivity was performed by counting the number of positively stained cells using the MetaMorph Imaging Software. Figure 5 KN93 suppressed chronic pain in BERK sickle cell mice. (A) KN93 (45nmol in 5 μL saline, i.t.) produced CPP in the sickle mice. The sickle mice spent significantly more time in KN93-paired chamber, whereas the non-sickle control mice showed no chamber preference, spending similar amount of time in saline- and KN93-paired chambers. (B) Difference scores confirmed the presence of KN93-CPP in the sickle mice, but not the non-sickle control mice. * P < 0.05; n = 6.(C) KN92, an inactive analog of KN93 (45 nmol in 5 μL saline, i.t.), did not produce CPP in the sickle mice. Neither the sickle mice nor the non-sickle mice exhibited chamber preference. (D) Difference scores confirmed the absence of KN92-CPP in the sickle mice. n = 6. Mice paw withdrawal threshold to von Frey filament probing (E) and withdrawal latency to radiant heat (F) were measured before (0) and 0.5, 1, 2, 4 and 24 h after the injection of KN93 (45 nmol in 5 μL of saline, i.t.). * P < 0.05, ** P < 0.01, ***P < 0.001, compared with the “non-sickle w/KN93” group; # P < 0.05, ## P < 0.01, ### P < 0.001, compared with the “sickle w/KN92” group; n = 6. Figure 6 CaMKIIα knockdown by siRNA reversed mechanical allodynia (A), thermal hyperalgesia (B) and ongoing spontaneous pain (C–D) in BERK sickle cell mice. Mice were treated with CaMKIIα siRNA or scrambled (scr) RNA duplex (2 μg, i.t. twice per day for 3 days). Mechanical and thermal sensitivities were tested daily. * P < 0.05, ** P < 0.01, ***P < 0.001, compared with the “non-sickle w/siRNA” group; # P < 0.05, ## P < 0.01, ### P < 0.001, compared with the “sickle w/scr” group; scr: scrambled RNA duplex; n = 6. Arrows indicated siRNA/scr injections. The expression of CaMKIIα was reduced by 3d-treatment with CaMKIIα siRNA, compared with the same treatment with scrambled siRNA (A-insert). (C) When tested on Day 4 by lidocaine-CPP paradigm, spontaneous ongoing pain was present in “sickle w/scr” mice, but not “sickle w/siRNA” mice. (D) Difference score confirmed the absence of chamber preference in BERK mice after CaMKIIα siRNA treatment, * P < 0.05, n = 6. 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PMC005xxxxxx/PMC5118062.txt
LICENSE: This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. 101217933 32339 J Neural Eng J Neural Eng Journal of neural engineering 1741-2560 1741-2552 27705958 5118062 10.1088/1741-2560/13/6/066002 NIHMS822278 Article Chronic In Vivo Stability Assessment of Carbon Fiber Microelectrode Arrays Patel Paras R. a Zhang Huanan b Robbins Matthew T. a Nofar Justin B. c Marshall Shaun P. d Kobylarek Michael J. a Kozai Takashi D. Y. efgh Kotov Nicholas A. abij Chestek Cynthia A. aklm a Department of Biomedical Engineering, University of Michigan, Ann Arbor, MI, United States b Department of Chemical Engineering, University of Michigan, Ann Arbor, MI, United States c Psychology Department, University of Michigan, Ann Arbor, MI, United States d Department of Mechanical Engineering, University of Michigan, Ann Arbor, MI, United States e Department of Bioengineering, University of Pittsburgh, Pittsburgh, PA, United States f Center for the Neural Basis of Cognition, University of Pittsburgh, Pittsburgh, PA, United States g McGowan Institute for Regenerative Medicine, University of Pittsburgh, Pittsburgh, PA, United States h NeuroTech Center of the University of Pittsburgh Brain Institute, University of Pittsburgh, Pittsburgh, PA, United States i Department of Materials Science and Engineering, University of Michigan, Ann Arbor, MI, United States j Department of Macromolecular Science and Engineering, University of Michigan, Ann Arbor, MI, United States k Department of Electrical Engineering and Computer Science, University of Michigan, Ann Arbor, MI, United States l Neurosciences Program, University of Michigan, Ann Arbor, MI, United States m Robotics Program, University of Michigan, Ann Arbor, MI, United States 16 10 2016 05 10 2016 12 2016 01 12 2017 13 6 066002066002 This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. Objective Individual carbon fiber microelectrodes can record unit activity in both acute and semi-chronic (∼1 month) implants. Additionally, new methods have been developed to insert a 16 channel array of carbon fiber microelectrodes. Before assessing the in vivo long-term viability of these arrays, accelerated soak tests were carried out to determine the most stable site coating material. Next, a multi-animal, multi-month, chronic implantation study was carried out with carbon fiber microelectrode arrays and silicon electrodes. Approach Carbon fibers were first functionalized with one of two different formulations of PEDOT and subjected to accelerated aging in a heated water bath. After determining the best PEDOT formula to use, carbon fiber arrays were chronically implanted in rat motor cortex. Some rodents were also implanted with a single silicon electrode, while others received both. At the end of the study a subset of animals were perfused and the brain tissue sliced. Tissue sections were stained for astrocytes, microglia, and neurons. The local reactive responses were assessed using qualitative and quantitative methods. Main results Electrophysiology recordings showed the carbon fibers detecting unit activity for at least 3 months with average amplitudes of ∼200 μV. Histology analysis showed the carbon fiber arrays with a minimal to non-existent glial scarring response with no adverse effects on neuronal density. Silicon electrodes showed large glial scarring that impacted neuronal counts. Significance This study has validated the use of carbon fiber microelectrode arrays as a chronic neural recording technology. These electrodes have demonstrated the ability to detect single units with high amplitude over 3 months, and show the potential to record for even longer periods. In addition, the minimal reactive response should hold stable indefinitely, as any response by the immune system may reach a steady state after 12 weeks. Flexible electrodes Minimal injury High density array Neural electrodes 1. Introduction Recording stable, low-noise, high-amplitude unit activity in the motor cortex is crucial for the long-term stability of any brain machine interface (BMI) system [1–9] and can be equally important in many neuroscience studies [10–13]. To accomplish this goal, a system of electrodes should ideally elicit little to no immune response, have the capacity to concurrently record from a large population of neurons to either access more information content or to better understand local population dynamics, and demonstrate the ability to chronically record neural activity. The initial insertion of any electrode is a traumatic event to the local cellular network and vasculature and is greatly influenced by insertion speed [14,15], location [16], and technique [17,18]. If the electrode is removed soon after insertion, the local area will heal [19,20]. Permanent implantation of the electrode leads to the eventual formation of a localized glial scar comprised chiefly of astrocytes and microglia [20–32]. Accompanying the scar is a varying degree of neuronal cell death within the immediate vicinity of the electrode [20,21,25,30]. The persistence of the scar can be attributed to multiple factors including the continual release of inflammatory factors by the locally activated glial cells [27,28,33] and a breached blood brain barrier that cannot completely heal, therefore allowing the infiltration of pro-inflammatory cells and chemokines [19,34,35]. The impact that these chemokines have on the local environment has been shown through the use of genetic knockouts. The removal of monocyte chemoattractant protein 1 led to improved neuronal density [36] while caspase-1 knockout mice demonstrated significantly better recording quality as compared to wild type mice [37]. One way to mitigate the inflammatory response is through a reduced probe footprint. The reduction in probe size has been shown to reduce the mechanical strain on nearby neurons [37], lessen the long-term glial response, and improve the survival rates of the local neuronal population [38–40]. It should be noted that these studies demonstrating an improved tissue response made use of hard materials, such as silicon [39,40], and softer materials, such as SU-8 and parylene [38]. While an electrode's material properties may play an important role in bridging the mechanical mismatch between an implant and the brain, the previous studies on electrode dimensions point to probe size as being a more critical factor. We have recently proposed a multi-electrode array design using carbon fibers as the basis for the recording electrode [41,42]. Carbon fiber electrodes are small (d = 6.8 μm), and with the addition of a parylene-c insulating coating (t = 800 nm), the overall diameter is only increased to 8.4 μm. In addition, this electrode material is extremely amenable to creating high density arrays and with a site coating of poly(3,4-ethylenedioxythiophene) (PEDOT) has been shown to record high quality unit activity [41,43,44]. This work evaluates the longevity of these arrays, by first testing two different formulations of the site coating material, PEDOT, using an accelerated aging test. Carbon fiber arrays functionalized with parylene-c and PEDOT were further evaluated by chronically implanting them into rat motor cortex. Additionally, some animals were implanted with a commercially available planar silicon electrode in the contralateral hemisphere's motor cortex. Impedance and electrophysiology recordings were taken on a regular basis and analyzed to demonstrate the carbon fiber's viability as a chronic electrode technology. Lastly, a subset of animals were perfused and stained to quantitatively analyze the glial response and neuronal density surrounding both electrode types. 2. Materials & Methods 2.1 Soak Test 2.1.1 Probe Assembly Printed circuit boards (PCBs) for accelerated soak testing were first roughened in the non-trace and non-bond pad areas with a Dremel tool, to allow for better adherence of the final epoxy coating (figure 1(a)). Once roughened, eight individual carbon fibers (T-650/35 3K, Cytec Thornel, Woodland Park, NJ), with length of approximately 1 cm, were placed on the individual bond pads using conductive silver epoxy (H20E, Epoxy Technology, Billerica, MA) (figure 1(b)). The conductive epoxy was then oven cured using the manufacturer's recommended settings. The silver epoxy bond was then covered with insulating epoxy (353NDT, Epoxy Technology, Billerica, MA) and oven cured using the manufacturer's recommended settings (figure 1(c)). Probes were then insulated with a conformal coating of parylene-c (t=800 nm) using a Parylene Deposition System 2010 (SCS Coatings, Indianapolis, IN). After insulation, the tips of each probe were cut to re-expose a bare carbon fiber site. At this site, one of two solutions was electrodeposited. The first was a solution of 0.01 M 3,4-ethylenedioxythiophene (483028, Sigma-Aldrich, St. Louis, MO):0.1 M sodium p-toluenesulfonate (152536, Sigma-Aldrich, St. Louis, MO). The second solution was composed of 0.01 M 3,4-ethylenedioxythiophene (483028, Sigma-Aldrich, St. Louis, MO):0.1 M polystyrene sulfonate (m.w. 70.000, 222271000, Acros, NJ). For each solution the electrodeposition was carried out by applying 100 pA/channel for 600 seconds to form a layer of poly(3,4-ethylenedioxythiophene):sodium p-toluenesulfonate (PEDOT:pTS) or poly(3,4-ethylenedioxythiophene):polystyrene sulfonate (PEDOT:PSS). All channels to be coated with a given solution were shorted together during the electrodeposition step and the current delivered was scaled accordingly. 2.1.2 Accelerated Soak Test Setup Boards with parylene-c and PEDOT:pTS or PEDOT:PSS coated carbon fibers were mounted to the underside of a jar lid (figure 1(d)). The lids were then secured to jars that contained 1× phosphate buffered saline (PBS) solution (BP3994, Fisher, Waltham, MA) (figure 1(e)). The 1× PBS was at a level such that only the fibers were submerged and not the entire printed circuit board. The jars were then lowered into a water bath maintained at 60 °C. At each time point the fibers were removed from the heated 1× PBS and rinsed once with deionized water. Next, the fibers' impedances were recorded. Once recordings were complete the assembly was returned to the heated 1× PBS. According to works by Green et al. [45] and Hukins et al. [46], equation (1) can be used to determine the aging time that the fibers have undergone: (1) t37=tT×Q10(T−37)/10 Where t37 is the simulated aging time at 37 °C, tT is the amount of real time that the samples have been kept at the elevated temperature, T, and Q10 is an aging factor that is equal to 2, according to ASTM guidelines for polymer aging [47]. Calculating the simulated time for tT = 1 and T = 60 °C results in t37 = 4.92. This value of 4.92 is the acceleration factor and all real time measurements are scaled by this amount to obtain the simulated time. 2.1.3 Electrochemical Impedance Spectroscopy (EIS) EIS measurements were taken with a PGSTAT12 Autolab (EcoChemie, Utrecht, Netherlands), controlled by vendor-supplied NOVA software. Measurements were obtained by applying a 10 mVRMS signal from 10 Hz to 31 kHz. Custom Matlab (Mathworks, Natick, MA) scripts were used to determine frequency specific impedance values. All reported values are mean ± standard error of the mean. 2.2 Chronic Electrode Implantation 2.2.1 Carbon Fiber Array Preparation Carbon fiber arrays were fabricated as previously described [42]. Briefly, individual fibers were secured to bare traces (152.4 μm pitch) of a custom made PCB with silver epoxy that was then heat cured. This exposed contact was then coated with a heat cured insulating epoxy to protect the connection between the fiber and trace. Once fully assembled, all carbon fiber arrays for neural recordings were coated with an 800 nm thick insulating layer of parylene-c using a Parylene Deposition System 2010 (SCS Coatings, Indianapolis, IN). Probe tips also received a site coating of PEDOT:pTS with the same formula and deposition parameters used on the fibers that underwent soak testing. The final preparation step was a coating of poly(ethylene glycol) (PEG) as described in [42]. 2.2.2 Surgery for Chronic Implantation of Carbon Fibers and Silicon Probes Chronic implantation of carbon fiber arrays (figure 2(a)) and silicon probes (figure 2(b)) used adult male Long Evans rats (n=3 rats with only carbon fibers, 3 with both electrodes, and 2 with only silicon probes) weighing 300 – 350 g. Rats were first anesthetized using 5% isoflurane (v/v) for induction and then 1 – 3% isoflurane (v/v) for maintenance. The head was then shaved and triple swabbed using alternating applications of betadine and 70% ethanol. Ointment was applied to the eyes to keep them from drying during surgery. Once mounted in the stereotax, the shaved area was swabbed one more time with betadine and 70% ethanol. A subcutaneous injection of lidocaine (4 mg/mL) was given at the incision site at a maximum dosage of 4 mg lidocaine per 1 kg of body weight. After incision, the skin flaps were pulled away using hemostats and the skull surface cleaned. A burr bit (19008-07, Fine Science Tools, Foster City, CA) was used to drill seven holes around the periphery of the skull for seven bone screws (19010-00, Fine Science Tools, Foster City, CA). Next, 2 mm × 3 mm craniotomies were made over the left and right motor cortex using coordinates from a reference atlas [48]. Before resecting the dura, a layer of Kwik-Sil (World Precision Instruments, Sarasota, FL) was applied to the skull at the posterior, anterior, and leftmost sides. Following the resection of the dura on the rightmost craniotomy, the PEG coated carbon fiber array was brought to the surface of the brain. The exposed fibers were implanted according to methods previously described [42]. The silicon probes (A1×16-3mm-50-177-HZ16_21mm, NeuroNexus Technologies, Ann Arbor, MI) were 3 mm in length with sixteen 177 μm2 iridium sites spaced 50μm apart, starting from the tip. To implant the silicon probe, a small metal rod was attached to the stereotactic manipulator and positioned above the rat's skull. A drop of melted PEG was applied to the very tip of the rod. The base of the silicon probe was then positioned to rest in the still liquid PEG, which secured the probe as it solidified. The dura over the leftmost craniotomy was resected and the probe was implanted to the desired depth. The polyimide cable connecting the probe to the PCB was secured to the nearest bone screws using Kwil-Sil. After the Kwil-Sil had cured, the PEG was dissolved away using sterile Lactated Ringer's. Additional Kwik-Sil was then applied to the skull at the lateral side of the rightmost craniotomy, forming a complete barrier around both craniotomies. The Kwik-Sil barrier was flooded with either Kwik-Cast (World Precision Instruments, Sarasota, FL), petroleum jelly, or alginate [49]. Reference and ground wires from both PCBs were attached to the posterior most bone screw. The PCBs were then anchored to all of the skull's bone screws using dental acrylic. The skin flaps were brought up over the dental acrylic headcap on each side and sutured together at the anterior and posterior ends. Triple antibiotic ointment was liberally applied around the headcap. Animals were then removed from the stereotax and allowed to recover on a heated pad placed under their cage. During surgery, animal vitals were monitored using a pulse-oximeter and rectal temperature probe. All procedures and post-operative care complied with the University of Michigan's University Committee on Use and Care of Animals. A detailed breakdown of each animal's implant(s) and implant depth can be found in table 1. 2.2.3 Electrophysiology Recordings and Spike Sorting Electrophysiology recordings using chronic implants of carbon fiber arrays and silicon probes were done while the rats were awake and moving about freely in their cage. All acquisition of electrophysiology recordings were taken using a ZC16 headstage, RA16PA preamplifier, and RX5 Pentusa base station (Tucker-Davis Technologies, Alachua, FL). During data acquisition, the pre-amplifier high pass filtered at 2.2 Hz, anti-aliased filtered at 7.5 kHz, and sampled at a rate of ∼25 kHz. Each recording session lasted 5 or 10 minutes. Recording sessions were imported into Offline Sorter (Plexon, Dallas, TX) and first high-pass filtered (250 Hz corner, 4th order Butterworth). Each channel was manually thresholded and the resultant waveforms sorted by a trained operator. Sorted waveforms belonging to the same neuronal unit were averaged together to obtain a peak-to-peak amplitude for that unit, which was averaged with all other unit peak-to-peak amplitude values to obtain the mean value for each recording day for each probe type. All reported values are mean ± standard error of the mean. 2.2.4 Noise Floor and Signal-to-Noise Ratio Calculations To determine the noise floor for each recording channel, a trained operator picked out five 100 ms snippets of filtered electrophysiology recording data that did not contain sorted units and did not display amplifier saturation indicative of a motion artifact. The snippets of data, best characterized as non-spiking neural activity, were then joined together in a single 500 ms block which was used to calculate VRMS-Channel. The signal-to-noise ratio (SNR) of each sorted unit was calculated by dividing the peak-to-peak voltage of the waveform by 3·VRMS-Channel. All reported noise and SNR values are mean ± standard error of the mean. 2.2.5 Channel Exclusion and Count It was discovered throughout the study that certain datasets were corrupted by either the use of a broken headstage or from fibers themselves that showed signs of breakage. A full explanation of these types of problems and how they were mitigated can be found in the supplementary section. The primary goal in removing corrupted datasets or channels was to avoid skewing the analysis in any one direction. The number of channels used for impedance analysis at each time point can be seen in figure S1. The number of channels used for calculating the percentage of channels with units and the noise levels at each time point can be seen in figure S2. The number of units detected used for amplitude analysis at each time point can be seen in figure S3. 2.3 SEM Imaging A FEI Nova 200 Nanolab Focused Ion Beam Workstation and Scanning Electron Microscope (FEI, Hillsboro, OR) was used for SEM imaging. Prior to imaging, samples were gold sputter coated with a SPI-Module Sputter Coater (SPI Supplies, West Chester, PA). 2.4 Histology 2.4.1 Perfusion and Tissue Staining At day 91, 2 animals were transcardially perfused with 250 – 300 mL of 1× phosphate buffered saline (PBS) (BP3994, Fisher Scientific, Waltham, MA) followed by 250 – 300 mL of 4% (w/v) paraformaldehyde (P6148, Sigma Aldrich, St. Louis, MO) in 1× PBS. Extracted brains were then soaked in 4% (w/v) paraformaldehyde for an additional 24 hours. Once fixed, the tissue was cryoprotected by successive 24 hour long soaks in 10%, 20%, and finally 30% (w/v) sucrose (BP220, Fisher Scientific, Waltham, MA) in 1× PBS. If the tissue sample had not sunk to the bottom of the solution after 24 hours, additional time was given before moving to the next higher concentration of sucrose. Next, tissue was embedded in Optimal Cutting Tissue Compound (4583, Sakura, Netherlands) and frozen to -20 °C. The frozen sample was sectioned into 20 μm slices using a Microm 550 Cryostat (Fisher Scientific, Waltham, MA) and mounted directly onto slides. A hydrophobic barrier using a PAP pen (22312, Ted Pella, Redding, CA) was drawn around each slice and allowed to dry. To stain the slices they were first rinsed with 1× PBS for 10 minutes. Next, slices were blocked with 10% goat serum (S-1000, Vector Labs, Burlingame, CA) in 1× PBS for one hour at room temperature. Slices were then incubated in a primary antibody solution containing one or more of the following: Rabbit anti-Iba1 (1:500 dilution) (019-19741, Wako, Richmond, VA), Rabbit anti-GFAP (1:500 dilution) (Z033429-2, Dako, Carpinteria, CA), or Mouse anti-Neun (1:500 dilution) (MAB377, Millipore, Billercia, MA), mixed with 0.3% Triton X-100 (T8787, Sigma Aldrich, St. Louis, MO) and 3% goat serum in 1× PBS, overnight in a covered chamber. The next day, slices were triple rinsed with 1× PBS, with each wash allowed to sit for 10 minutes. Slices were then incubated in a solution of Alexa 488 Goat anti-Rabbit IgG (1:200 dilution) (A-11034, Invitrogen, Grand Island, NY), Alexa 555 Goat anti-Mouse IgG (1:200 dilution) (A-11031, Invitrogen, Grand Island, NY), 0.2% Triton X-100, and 5% goat serum in 1× PBS at room temperature for two hours. The slices were then rinsed twice with 1× PBS with each rinse lasting 10 minutes. Slides were then cover slipped using Prolong Gold (P36930, Invitrogen, Grand Island, NY) and allowed to dry overnight before imaging. 2.4.2 Confocal Imaging & Processing A LSM 510-META Laser Scanning Confocal Microscope (Zeiss, Oberkochen, Germany) was used to image the stained slices. Pixel-based image intensity analytics was performed using previously published custom MATLAB script I.N.T.E.N.S.I.T.Y. v1.1 [50]. Laser, imaging, and PMT settings were constant between contralateral hemispheres in each slice. Gain and contrast settings were altered during image processing. Briefly, to prevent holes in the tissue (such as major blood vessels and shuttle tracts) from artificially reducing the average activity-dependent fluorescence, background noise intensity threshold was calculated from 5% of the corners of each image. To calculate the background noise intensity threshold, pixels with intensity greater than one standard deviation dimmer than mean pixel intensity were considered “signal” and removed from the threshold calculation. The threshold was then determined by calculating the pixel intensity of one standard deviation below the mean of the remaining pixel intensities. Bins with intensity values dimmer than average intensities of the control images were considered tissue “holes”. Using MATLAB, the center of the silicon or carbon fiber track (15 μm × 123 μm or 8.4 μm diameter, respectively) was identified on each image, after which the script generated masks every 25 μm of rounded rectangles or concentric rings, respectively (see I.N.T.E.N.S.I.T.Y. v1.1 readme). Carbon fiber probe tracks were identified as holes in the tissue surrounded by an increased intensity “cloud” of anti-mouse secondary antibody label over non-cellular features. Weak cross-talk between anti-mouse secondary antibodies and rat primary antibodies likely indicate implant sites where rat IgG entered the brain parenchyma from insertion injury related to blood brain barrier leakage. The tissue reactions to single fibers have been previously characterized [41], and the summation of the tissue response from multiple shanks influence the overall tissue health and recording performance. Therefore, the tissue reaction was quantified as a summation of neighboring shanks similar to electrophysiology performance metrics, instead of disentangling overlapping bins. The average intensity for all pixels above the background noise intensity threshold in each bin was calculated and then normalized against the background to calculate the Signal-to-Noise Intensity Ratio (SNIR) in each bin as follows; (2) SNIR=AvgI>TAvgN where AvgI>T is the mean intensity of all pixels above the noise threshold (>T) in each bin, and AvgN is the mean noise floor intensity. This means, SNIR=1 represents the noise floor. Therefore, it is expected that the SNIR does not asymptote to 1 unless there is no staining signal in the corresponding bin. Data were averaged for each implant type and time point, and then reported as mean and standard error. Neurons were counted on I.N.T.E.N.S.I.T.Y. v1.1 binned images using the built in cell counting function in ImageJ. NeuN density was calculated by counting NeuN positive cells in each bin divided by the total area of the tissue in each bin after the area of the holes were removed. 3. Results 3.1 Accelerated Soak Test Previous work has shown that parylene-c coated carbon fibers with only an exposed carbon tip site are unable to record unit activity due to the high site impedance [41]. To alleviate this issue, PEDOT:PSS was electrodeposited at the tip of each site which greatly reduced the site impedance [41,51]. Recent studies by Green et al. have demonstrated that other formulations of PEDOT are more stable over time when compared to PEDOT:PSS [45,52]. To determine the best site coating for the carbon fiber electrodes, an accelerated soak test was carried out between the original PEDOT:PSS (n=8 fibers) formulation and a different formulation, PEDOT:pTS (n=23 fibers) [45]. In addition to determining the best site coating, the values from this study will establish a baseline that can be compared to later chronic animal implants. Prior to PEDOT deposition the impedance values at 1 kHz were 3809.0 ± 426.7 kΩ and 6781.8 ± 655.3 kΩ, respectively, for the PEDOT:pSS and PEDOT:pTS coated fibers. The large difference in pre-deposition impedances is likely attributable to the uneven surface of the exposed fibers, which results from the manual cutting process used to re-expose the tips after parylene-c coating. At day 0, when the initial PEDOT depositions took place, both sets of impedance values at 1 kHz (PEDOT:PSS 142.8 ± 23.2 kΩ and PEDOT:pTS 117.9 ± 28.4 kΩ) were similar (figure 3), mitigating any differences in the pre-deposition impedances. As time progressed, the average impedance of the PEDOT:PSS coated fibers increased faster than those coated with PEDOT:pTS. On the final day of testing (35 days in real time, 172.2 days in simulated time) the fibers coated with PEDOT:PSS had an average impedance (1921.4 ± 344.5 kΩ) double that of the PEDOT:pTS coated fibers (840.5 ± 117.7 kΩ). During the repeated measurements carried out over the course of 35 days, one PEDOT:PSS coated fiber and three PEDOT:pTS coated fibers were accidentally broken off of the test boards, which resulted in lower sample sizes over the duration of the study. SEM images (figures 4(a) and 4(b)) show good adherence of both PEDOT formulations to the carbon fiber tip's outer edges. A visible void of PEDOT can be seen in the center of both PEDOT formulations, which may help to explain the steady increases in impedance. Based on the impedance results, all chronic implants of carbon fibers received a site coating of PEDOT:pTS. 3.2 Chronic Implant Impedance To assess the longevity and viability of the carbon fiber arrays, 5 Long Evans rats were implanted chronically with carbon fiber arrays (n=75 fibers) in the right motor cortex. Two of those rats were also implanted with silicon electrodes (n=2 electrodes with 16 sites each) in the left motor cortex. In addition, 3 more rats were implanted with only silicon electrodes (n=2 electrodes with 16 sites each and 1 with 15 sites.). A detailed breakdown of each animal's implant type, duration, and depth, can be found in table 1. For all performance metrics, no differences were noted between animals that received one or both probe types. Impedance measurements were taken every day for the first 13 days, every other day from days 13 to 31, and then every third day from days 31 to 91. For the two animals continued out to day 154, measurements were taken once a week after day 91. One animal, ZCR22, was sacrificed at day 73 for histological and surgical technique evaluations. The pre-implant 1 kHz impedances (figure 5(a)) at day 0 for the carbon fibers was 128.1 ± 12.0 kΩ while those of the silicon probes were 1118.5 ± 17.4 kΩ. At day 1, post-implantation impedances for carbon fibers increased to 621.9 ± 14.8 kΩ while the silicon sites also increased to 2018.3 ± 17.6 kΩ. The impedance for both sets of probes continued upward until day 12 for the carbon fibers and day 15 for the silicon probes. At these time points the impedance values were 2044.2 ± 171.1 kΩ for the carbon fibers and 3493.7 ± 90.5 kΩ for the silicon probes. Following the initial increases in impedance, the carbon fiber electrodes saw a leveling off in the impedance values which fluctuated between 1500 – 2500 kΩ from days 11 to 91. The silicon probes saw greater changes after day 9 with average impedance values ranging from approximately 2000 kΩ to just below 4000 kΩ. The large variation in average impedance for the silicon probes before and after day 31 is likely due to the drop in electrode sample size after day 31. On the final days of recording, the carbon fiber electrodes had a mean 1 kHz impedance of 2268.3 ± 253.7 kΩ at day 154 while the silicon probes had a mean 1 kHz impedance of 2742.5 ± 126.5 kΩ at day 91. The differences in recording site sizes between the carbon fibers (36.3 μm2) and silicon probes (177 μm2) can potentially skew the impedance results as a larger site size typically results in lower impedance. When scaled for area (figure 5(b)), carbon fibers at 40 days onwards average approximately 80,000 kΩ μm2, outperforming the silicon probes which averaged 500,000 kΩ μm2. While the silicon probes used here were not functionalized with PEDOT, other studies using the same site size coated with PEDOT found chronic 1 kHz impedance reaching an average of 2210 kΩ (figure 5(a), green) or 391,170 kΩ μm2 (figure 5(b), green) between days 6 & 8 [53]. Two animals, ZCR16 and ZCR17, were not sacrificed at day 91 and were recorded from for an additional two months. Recordings were taken at one week intervals during this extended period. The carbon fiber electrode impedance values rose slightly during this period and fluctuated between 2000 – 3000 kΩ. 3.3 Chronic Unit Activity Electrophysiology recordings followed the same points as those used for the impedance measurements. On day 1 post-implant, 65.3% of the implanted carbon fiber electrodes detected unit activity with a mean peak-to-peak amplitude of 142.1 ± 10.4 μV (figures 6(a) and 6(b)). At the same time point, the silicon electrodes detected unit activity on 3.2% of the electrodes sites with an average peak-to-peak amplitude of 59.8 ± 9.8 μV. By day 6, mean unit amplitude on the 40.3% of carbon fiber electrodes with activity continued to climb to 186.4 ± 17.1 μV while the silicon electrodes showed a small climb in activity with 6.4% of electrode sites detecting units with an average peak-to-peak amplitude of 150.2 ± 20.4 μV. At day 13, the number of carbon fiber electrodes with detectable units had slightly increased to 41.3% with an average detected peak-to-peak amplitude that was maintained at 208.1 ± 22.1 μV. During this same period, the silicon electrode detection rate remained in the single percentage range and at day 13, 3.17% of electrode sites showed an average peak-to-peak amplitude of 103.8 ± 27.0 μV. Following this initial spike during the first two weeks post-implant, the carbon fiber electrodes demonstrated mean peak-to-peak unit activity that stayed within the range of 150 – 250 μV through day 91. During this same period, the silicon electrodes had a very low detection rate of < 5%. When single units were detected, the mean peak-to-peak amplitude was typically between 50 – 150 μV. At day 91, 48.7% of the remaining carbon fiber implanted sites were still able to detect units with a mean peak-to-peak amplitude of 194.7 ± 21.5 μV, while 5.7% of silicon sites detected average peak-to-peak amplitude of 89.0 ± 3.6 μV. Waveforms representative of the unit activity detected for each electrode type can be seen in figure 6(c). The two animals that were carried out to day 154 showed some continued unit activity until day 112, with 27.8% of the sites detecting a mean peak-to-peak unit amplitude of 115.8 ± 23.5 μV. After this time point, no units were detected across the remaining carbon fiber electrodes. The loss of detectable unit activity is likely due to brain tissue swelling into the craniotomy, which was discovered post-mortem. Amplitude values obtained by averaging the largest unit on each carbon fiber channel across time (figure 6(d)) compare favorably to those seen in chronic implants of Utah arrays in primates [4]. 3.4 Baseline Activity and Signal-to-Noise Ratio In addition to unit activity, the baseline activity level (figure 7(a)) was quantified for both implant types. This was in turn was used to calculate the signal-to-noise ratio (SNR) (figure 7(b)) for both electrode styles. Baseline activity levels for both the carbon fiber electrodes and silicon electrodes rose for roughly the first 11 days. The initial levels for the carbon fiber electrodes (8.9 ± 0.4 μVRMS) and silicon electrodes (6.9 ± 0.2 μVRMS) were similar at day 1 and initially peaked at days 11 (15.9 ± 0.8 μVRMS) and 10 (10.8 ± 0.2 μVRMS), respectively. After this time, both sets of baseline activity stayed remarkably consistent with the carbon fibers displaying a noise level around 15 μVRMS and the silicon electrodes around 10 μVRMS, with some slight day-to-day variations. SNR levels for the carbon fiber electrodes initially started at 5.5 ± 0.4 and decreased to 3.3 ± 0.3 at day 6. After this time the average SNR increased and was largely maintained between 3.5 and 5 with some days deviating from this pattern. At day 91, when 4 animals remained in the study, average SNR was still 3.8 ± 0.4. After this time point SNR values rapidly dropped off (figure S4) as the remaining animals (n=2) showed decreased unit activity amplitude as seen in figure 6(b). 3.5 Histological Analysis of Implants The microglial response to the silicon electrode is punctuated by a higher density of cells immediately surrounding the implant site (figure 8(a)). This result is typical of that seen by other groups [20,26,28,54] and agrees with previous results [41]. The global response to the carbon fiber array (figure 8(b)) is markedly different from the silicon implant. While some variability and Iba1 activity can be observed across the array implant region, such as the lower right region of the array showing signs of elevated activity, the standard error on the silicon intensity shows substantially greater variability. Analysis of all microglia images (n=2 images/electrode type) from the silicon electrodes show a consistently elevated, and at times significant (p<0.05), level of activity when compared to the microglial response surrounding the carbon fibers (figure 8(g)). The difference between silicon and carbon fiber is more dramatic when examining GFAP astrocyte activity. A representative image of astrocytic activity shows the formation of a tight scar in the immediate vicinity of the silicon electrode site, with elevated activity that extends outward by as much 1000 μm (figure 8(c)). In contrast, the implant site of the carbon fiber array (figure 8(d)) shows no visible scarring regions and limited fluctuation in GFAP intensity from baseline levels. This is further corroborated by intensity analysis of all astrocyte histology images (n=2 images/electrode type), where the silicon electrodes show a sustained astrocytic response that continues out to 1000 μm from the implant site (figure 8(h)). Closer examination revealed that around the silicon implant, one animal showed a compact microglial sheath surrounded by a large activated astrocyte ring (figures S5(i) & S5(k)), while the other exhibited a more evenly distributed elevated GFAP activity. Despite this large variability in tissue reaction, elevated GFAP activity was commonly observed at the 300-400 μm radius and showed significant difference (p<0.05) compared to carbon fiber response profile, which remained steady around baseline at all distances (figure 8(h)). Neuronal signal intensity shows a marked decrease in the area surrounding the silicon electrode (figure 8(e)). In contrast, the neuronal population surrounding the carbon fibers are well distributed and healthy with no immediately obvious declines in signal intensity (figure 8(f)). Measured normalized neural density (n=4 images/electrode type) confirm these observations with the neural density of the silicon electrodes climbing upwards as distance increases (figure 8(i)). The carbon fibers do start with a high neuronal density. This is in part due to the small tissue area in the inner bin and the relatively large tissue hole from the probe track (relative to the bin area). While the inner bins show large error bars, this data shows that neurons trend closer to the probe track of carbon fibers than the silicon shanks. At further distances, the normalized density levels off to approximately 1 and the standard errors decrease leading to significant differences (p<0.05) (figure 8(i)). All histology images can be found in figure S5. 3.6 SEM Imaging of Explanted Carbon Fiber Electrodes Carbon fiber electrodes from chronic implants were explanted at the end of each animal's time point and imaged (figures 9(a) – 9(d)) to better understand any physical changes the electrodes underwent. Figures 9(a) and 9(b) highlight possible parylene-c delamination along the shank of the carbon fiber electrodes. This delamination, especially near the tip site can affect the probes ability to detect local activity. Figure 9(c) shows what may be a thin coating of biological material that could affect the PEDOT:pTS coating. In addition, the center of the electrode tip demonstrates a void similar to that seen with the soak test fibers (figure 4). This void may initially be caused by an uneven PEDOT:pTS electrodeposition, where more PEDOT:pTS is deposited around the edges [51]. As the PEDOT degrades, the center shows the most pronounced change as it likely has the thinnest coating [51]. This center voiding phenomenon is also seen in figure 9(d). 4. Discussion 4.1 Accelerated Aging Evaluation This work first sought to validate a new site tip coating for the carbon fiber arrays. Accelerated soak tests were implemented to rapidly assess the viability of PEDOT:pTS as compared to PEDOT:PSS. For the first 70 simulated days, the impedances of both sets of fibers remained similar. After this time point the PEDOT:PSS fibers saw a more rapid increase in impedance as compared to the PEDOT:pTS coated fibers. The overall increase in impedance can be attributed to the slow degradation of both PEDOT formulations [45,55]. This is corroborated by SEM images which show a lack of PEDOT in the center of the electrodes. The greater stability of the PEDOT:pTS coating agrees well with results seen by others [45] and led to the decision to switch to a different formulation of PEDOT for the site coating. Using even more stable formulations of PEDOT such as those that use carbon nanotubes [56] will be explored in future studies. In addition, the use of electroplated metals such as platinum [57–60], gold [61], or iridium [62], may also serve as a more stable coating. 4.2 In Vivo Assessment of Carbon Fibers and Silicon Electrodes Impedance levels for both probe types increased dramatically over the course of the first three weeks. These results are typical for chronically implanted electrodes [43,55,63–66]. Historically, this increase in impedance has been largely attributed to the glial scar creating a resistive layer around the probe [28,65,67]. Unfortunately, the lack of a macroscopic scar seen in previous carbon fiber work [41] and confirmed here, makes it difficult to account for the impedance increase seen with the carbon fibers. We propose a more nuanced model, which argues that even the largest of glial scars cannot fully account for the impedance rise seen in implanted Utah arrays [68], which are made of stable materials [69], have similar impedance values to the carbon fiber arrays, and in our own case where the carbon fibers do not create a traditional macroscopic scarring response [41]. Instead, dramatic increases in impedance can best be accounted for by an extremely thin resistive layer (∼0.5 μm) made up of biological material, such as cells or proteins, that is directly adhering to the recording site's surface [68]. Determining a first order approximation of this hypothesized thin layer's resistivity can be accomplished using the following equation: (3) R=ρLA where R = impedance at 1 kHz, ρ = resistivity, L = length or thickness, and A = area of the probe interface. It can be assumed that the probes' own internal resistances are unchanging in the first three weeks, which is a reasonable approximation for implanted metal electrodes and for the carbon fiber site coatings given the results from the soak test. Therefore, any change in resistance can be attributed to the thin adherence layer. The area of the carbon fiber electrodes was scaled by a factor of 10 to conservatively account for the PEDOT:pTS coating's increase on effective surface area [70]. This may be particularly true for porous electrode materials such as PEDOT, where its increased electrochemical surface area can be decreased by biofouling, which clogs the porous matrix [71]. Calculating the resistivity from our own results [68], leads to the values seen in table 2. Across all probe types the resistivity of the adherence layer is within the same order of magnitude and similar in value. The leveling off of all impedance values after approximately the 3rd week is likely due to the adherence layer reaching a steady state in thickness and coverage. The large unit amplitudes seen immediately and well after week 3 on the carbon fiber electrodes indicate that this thin adhesion layer is not severely affecting the ability of the fibers to record activity. Baseline activity levels rose in a similar time course to that of the 1 kHz impedance values for both probe types, though the increase was more pronounced for the carbon fibers, which is counterintuitive given the lower impedance of the carbon fibers over time. This however, can be explained by separating the elements that contribute to overall background activity. Baseline activity is a combination of thermal and biological sources [72,73]. The lower overall impedance of the carbon fiber electrodes should lead to a lower thermal noise level; however, the overall baseline level for the fibers is larger than that of the silicon electrodes. This indicates the presence of a biological component that is larger for the carbon fiber electrodes which also points to a greater survival rate of neurons around the carbon fibers as compared to the silicon electrodes. This is also reflected by the carbon fibers' consistent ability to detect unit activity. The greater number of neurons around the carbon fiber electrodes may not always be detected as individual units, but can still contribute to the overall baseline activity, indicating a healthier local tissue environment. This is also supported by the sparse number of units detected on the silicon probes, which may possibly be suffering from mechanical failures [74]. Additionally, the silicon probes used here had small site sizes of 177 μm2, which other works have also demonstrated as having limited ability to detect unit activity [53]. This is in contrast to previous studies which used 703 μm2 [43] or 1250 μm2 [41] site sizes that were able to chronically detect unit activity. Nevertheless, on average, the amplitude of single units detected on the silicon probes was stable, albeit smaller than those detected on the carbon fibers during the 90 day implantation period. The high unit amplitudes and relatively low baseline activity levels also contribute to a high SNR on the carbon fiber electrodes. This SNR remained stable for the first three months after an initial drop off. This drop off was caused by an increasing baseline activity level (figure 7(a)) and not decreasing unit amplitude, which was rising during the same period (figure 6(b)). Overall, the carbon fiber arrays were able to detect unit activity until day 112, or week 16, after which no more activity was detected. This can be partially attributed to the low number of animals (n=2) at the later time point. In addition, explanted brains from many of the animals showed swelling of the cortex into the craniotomy which likely caused the electrodes to move and not record from their target layer. Unfortunately, this swelling also made it difficult to separate the headcap from the brain without damaging the tissue, which ultimately led to a much lower number of animals that were available for histology. It is important to note however, that the large unit amplitudes detected on the carbon fiber electrodes point to a minimal if not non-existent scar around the electrode. This is further corroborated by histology analysis in figure 8. These images show the formation of a scar around the silicon electrodes coupled with some decreased neuronal density and no evident scar around the carbon fiber arrays coupled with a healthy neuronal population. It is possible that the neuronal density in the bin immediately adjacent to the carbon fiber probe is slightly elevated due to the volumetric displacement of the tissue caused by the carbon fiber probes (figure 8(i)). In this case, large standard deviations in the 0-25 μm bin around the carbon fiber probes suggests that this only occurs in a percentage of probe tracks when the probe displaced the neuron. The decreases in the error bars in subsequent bins suggest that the tissue strain around the carbon fiber probes dramatically decreases by the 25-50 μm bin, and is indistinguishable by a 50 μm radius. Similar results can be observed in previous in vivo neurons around carbon fiber implants [37]. This reduced strain in the tissue and neurons may contribute to the improved recording performance, since it is understood that tissue strain adversely impacts neuronal health [35]. While previous studies show that histology can be a poor predictor of electrophysiological performance [37], these histology results correlate well with the electrophysiology results seen in this study. 5. Conclusions This work has demonstrated the ability of carbon fiber electrodes to chronically record unit activity in the rat motor cortex up to 16 weeks. The units detected were of large amplitude and showed a high SNR. The carbon fibers greatly outperformed silicon electrodes with comparable site sizes and were also shown to detect a larger level of biological noise, indicating a healthier local tissue environment. This is also corroborated by the quality of detected unit activity. It is important to note that the stability of detected unit activity was not tracked across time as this was beyond the scope of the current study, but more analysis will be needed in this area to assess the viability of these electrodes for BMI applications. In addition, while both electrode types were implanted directly in the motor cortex no specific muscle group or region was targeted. This in turn may have led to a lower yield as this study relied on spontaneous awake activity and not activity associated with a specific task, which may have resulted in a higher electrode yield. Further work will seek to improve the performance of the PEDOT and parylene-c coatings. Methods to reduce brain swelling and shield the carbon fibers from mechanical damage are being explored with improved array packaging and fabrication. Improvements in all of these areas could lead to high density recording arrays that cause minimal damage to the surrounding tissue and record high quality unit activity for many years. Supplementary Material JNEaa3f87_Supplementary information.pdf Figure S1. Number of channels used for impedance results. For the silicon electrodes, the jump in channel count from day 23 to 25 was due to eight channels from ZCR22 being incorporated after a headstage had been repaired. The brief dip at day 55 was due to a missed time point. The decline at day 73 was due to another animal being removed from the study with four remaining until day 91. For the carbon fibers all dips and immediate recoveries, except at day 55 which was a missed time point, were due to impedance values that indicated a poor connection. Drops that occur without an immediate recovery are from channels being removed from the study due to breakage. The drop-off at day 91 is from the sacrificing of all remaining animals except for two that continued to day 154. Figure S2. Number of channels used for electrophysiology and noise results. For the silicon electrodes, the jump in channel count from day 23 to 25 was due to eight channels from ZCR22 being incorporated after a headstage had been repaired. The brief dip at day 55 was due to a missed time point. The decline at day 73 was due to another animal being removed from the study with four remaining until day 91. For the carbon fibers, the continual decline in channel count was due to channels being removed as their 10 Hz impedance magnitudes matched those of known broken channels. The two exceptions to this were day 55, which was a missed time point, and after day 91 when only two animals remained. Figure S3. Number of units detected for each probe type. For each probe type, the number of units detected on the valid electrophysiology channels from figure S2, is plotted over time. Figure S4. Chronic baseline activity and SNR to day 154. (a) Recorded baseline activity levels (mean ± standard error of the mean) for both carbon fiber and silicon electrodes for all 154 days. (b) The SNR (mean ± standard error of the mean) for all units detected on the carbon fiber electrodes for all 154 days. Figure S5. Chronic histology from carbon fiber arrays and silicon electrodes. The yellow reactangle depicted in the silicon electrode images show the approximate size and position of the electrode. In the images for the carbon fiber array the outlined yellow profile depicts the footprint of the array. (a), (b), (i), & (j) Microglia staining around implanted electrodes. More elevated responses can be seen around the silicon electrodes. (e), (f), (k), & (l) Astrocyte staining around implanted electrodes. More elevated responses can be seen around the silicon electrodes. (c), (d), (g), & (h) Neuron staining around implanted electrodes. Decreased intensity can be seen around the silicon electrodes and no obvious decreases in the carbon fiber array images. This work was financially supported by the National Institute of Neurological Disorders and Stroke (1RC1NS068396-01, 1U01NS094375-01, & 1R01NS094396) and the McKnight Foundation. The authors would like to thank Daryl Kipke for contributions to the experimental design. The authors would also like to thank Karen Schroeder for paper comments and assistance with statistical analysis & Kip Ludwig for assistance with recording and impedance analysis. Additional thanks to Peter Caintic for assistance with data analysis. Figure 1 Soak test probe assembly and setup (a) Areas between and surrounding the bond pads have been roughened. (b) Silver epoxy on each bond pad for the carbon fibers. (c) Exposed bond pads with carbon fibers are covered with insulating epoxy. (d) Four PCBs with functionalized fibers are secured to the underside of the soak jar's lid. (e) Lids are secured to jars containing 1× PBS. Jars are then placed in a heated water bath. Figure 2 Images of implanted electrodes (a) Carbon fiber array used in implants. (b) Silicon probe, NeuroNexus A1×16-3mm-50-177-HZ16_21mm, with sixteen 177 μm2 iridium sites spaced 50 μm apart, used in implants. Figure 3 PEDOT soak test Impedance values (mean ± standard error of the mean) at 1 kHz for PEDOT:PSS and PEDOT:pTS coated carbon fiber electrodes over the simulated time from the accelerated soak test. Figure 4 SEM images of PEDOT coated and soak tested fibers (a) SEM image of a PEDOT:pTS coated carbon fiber aged to simulated day 172.2 showing PEDOT still at the tip, but with a possible void or loss of PEDOT:pTS in the center. (b) SEM image of a PEDOT:PSS coated carbon fiber aged to simulated day 172.2 showing similar properties to that of the PEDOT:pTS coated fiber. Figure 5 Chronic implant impedances (a) Impedance values (mean ± standard error of the mean) for each probe type across time. Both electrode types saw an approximately 2 MΩ increase in impedance within the first two weeks. Values for the carbon fibers then leveled off while the silicon electrode values dropped before leveling off. Impedance values for 177 um2 silicon sites coated with PEDOT are shown in green [53]. The number of channels used for impedance analysis at each time point can be seen in figure S1. (b) Impedance values scaled by geometric surface area (mean ± standard error of the mean) for each probe type across time. Carbon fibers increased to approximately 80,000 kΩ·μm2 before leveling off, while the silicon electrode values peaked at about 650,000 kΩ·μm2 before steadying at approximately 500,000 kΩ·μm2. Similar to (a), values for 177 um2 silicon sites coated with PEDOT are shown in green [53]. Figure 6 Chronic unit amplitudes and percentage of channels with units (a) On average 20% to 40% of viable carbon fiber electrodes detected unit activity across time, while silicon electrodes did so with a peak of 9.5% at day 10 and most other days detecting no unit activity. After day 91 only two rats remained in the study and the loss of their unit activity is likely explained by brain tissue swelling into the craniotomy which was discovered post mortem. The exact number of channels used for calculating the percentage of channels with units at each time point can be seen in figure S2. (b) Carbon fiber electrodes detected an average unit amplitude of 200 μV across three months. Units detected on silicon electrodes had a mean amplitude of 50 – 100 μV. All values are mean ± standard error of the mean. The exact number of units detected and used for amplitude analysis at each time point can be seen in figure S3. (c) Representative time course of detected unit activity on two different channels, one for each electrode type. (d) The mean of the largest unit detected on each carbon fiber or silicon electrode was calculated for each time point. Figure 7 Chronic baseline activity and SNR (a) Recorded baseline activity levels (mean ± standard error of the mean) for both carbon fiber and silicon electrodes for the first 91 days. Both baseline trends rise during the first two weeks of recording and then level off to steady state values. Carbon fibers demonstrate a higher overall recorded baseline level than silicon, which can be explained by a larger biological background contribution as evidenced by the high amplitude recordings reported in previous sections. (b) The SNR (mean ± standard error of the mean) for all units detected on the carbon fiber electrodes for the first 91 days. After an initial drop-off within the first week, values level off and hold between 3.5 and 5. The exact number of channels used for calculating the noise levels and SNR at each time point can be seen in figure S2. Figure 8 Chronic histology images and analysis (a) & (b) Iba1 (microglia) staining around the implanted carbon fiber array and silicon electrode in ZCR19. Formation of a scar is well defined around the silicon electrode but no so around the carbon fiber array. Yellow rectangles show location and approximate size of implanted electrodes. (c) & (d) GFAP (astrocyte) staining around the implanted carbon fiber array and silicon electrode in ZCR19. Increased glial activity can be observed surrounding the silicon electrode with no obvious uptick in activity around the carbon fiber array. (e) & (f) NeuN (neuron) staining around the implanted carbon fiber array and silicon electrode in ZCR19. Neural density appears much more diminished around the silicon electrode as compared to the carbon fiber array. (g) Signal-to-noise intensity ratio of Iba1 staining around each electrode type (n=2 images/electrode type). Compared to the carbon fiber arrays the silicon electrodes maintain a more elevated level of Iba1 activity for almost all distances. (h) Signal intensity analysis of GFAP staining around each electrode type (n=2 images/electrode type). Similar to (g), the silicon electrodes show more GFAP activity as far out as 1000 μm from the implant site. (i) Normalized neural density around each electrode type (n=2 images/electrode type), illustrating the healthy neuronal population surrounding the carbon fiber arrays and a lack of neurons around the silicon electrodes. *indicates significance at p<0.05. Figure 9 SEM images of chronically implanted carbon fibers (a) & (b) SEM images of chronically implanted carbon fibers that may be experiencing parylene-c delamination. (c) & (d) SEM images of chronically implanted carbon fiber with a loss of surface roughness at the electrode tip indicating a loss of PEDOT in the center, the attachment of a thin adherence layer, or a combination of both. Table 1 Animal implant information Probe implant depth and duration for each animal. Animal Name Carbon Fiber Depth Silicon Probe Depth Days in study ZCR16 1.56 mm No Implant 154 ZCR17 1.505 mm No Implant 154 ZCR18 1.505 mm No Implant 91 ZCR19 1.495 mm 1.45 mm 91 ZCR22 1.45 mm 1.45 mm 73 ZCR28 1.5 mm 1.5 mm 91 ZCR29 No Implant 1.5 mm 91 ZCR30 No Implant 1.5 mm 91 Table 2 Adherence layer resistivity Calculated resistivity values for adherence layers on each probe type are shown to be on the same order of magnitude and similar in value. 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PMC005xxxxxx/PMC5118073.txt
LICENSE: This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. 9207397 2425 Plant J Plant J. The Plant journal : for cell and molecular biology 0960-7412 1365-313X 27337377 5118073 10.1111/tpj.13249 NIHMS798233 Article Investigating inducible short-chain alcohol dehydrogenases/reductases clarifies rice oryzalexin biosynthesis Kitaoka Naoki 1 Wu Yisheng 2 Zi Jiachen 3 Peters Reuben J. * Roy J. Carver Department of Biochemistry, Biophysics, and Molecular Biology, Iowa State University, Ames, IA 50011, U.S.A * Corresponding author: rjpeters@iastate.edu 1 Current address: Department of Biomolecular Sciences, Graduate School of Life Sciences, Tohoku University, Sendai 980-8577, Japan 2 Current address: Conagen Inc., Bedford, MA 01730, U.S.A. 3 Current address: Biotechnological Institute of Chinese Materia Medica, College of Pharmacy, Jinan University, Guangzhou, Guangdong 510632, China 1 7 2016 1 9 2016 10 2016 01 10 2017 88 2 271279 This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. Summary Rice (Oryza sativa) produces a variety of labdane-related diterpenoids as phytoalexins and allelochemicals. The production of these important natural products has been partially elucidated. However, the oxidases responsible for production of the keto groups found in many of these diterpenoids have largely remained unknown. Only one short-chain alcohol dehydrogenase/reductases (SDRs), which has been proposed to catalyze the last step in such a pathway, has been characterized to-date. While rice contains >220 SDRs, only the transcription of five has been shown to be induced by the fungal cell wall elicitor chitin. This includes the momilactone A synthase (OsMAS/SDR110C-MS1), with the other four all falling in the same SDR110C family, further suggesting roles in diterpenoid biosynthesis. Here biochemical characterization with simplified substrate analogs was first used to indicate potential functions, which were then supported by further analyses with key biosynthetic intermediates. Kinetic studies were then employed to further clarify these roles. Surprisingly, OsSDR110C-MS2 more efficiently catalyzes the final oxidation to produce momilactone A that was previously assigned to OsMAS/SDR110C-MS1, and we speculate that this latter SDR may have an alternative function instead. On the other hand, two of these SDRs clearly appear to act in oryzalexin biosynthesis, with OsSDR110C-MI3 readily oxidizing the 3α-hydroxyl of oryzalexin D, while OsSDR110C-MS3 can also oxidize the accompanying 7β-hydroxyl. Together, these SDRs then serve to produce oryzalexins A – C from oryzalexin D, essentially completing elucidation of the biosynthesis of this family of rice phytoalexins. diterpenoids oxidases phytoalexins allelochemicals biosynthesis Introduction Upon exposure to microbial pathogens plants produce an arsenal of antibiotic natural products, known as phytoalexins (Hammerschmidt 1999), which are considered to be an important part of the defense response (Bednarek and Osbourn 2009). Thus, the production of these metabolites is a subject of significant interest, as these compounds and/or the genes controlling their biosynthesis might serve as markers for molecular breeding, particularly in important crop plants, such as rice (Oryza sativa). One particularly interesting aspect of such plant natural products biosynthesis has been the observation of gene clusters containing unrelated genes encoding biosynthetic enzymes from a common metabolic pathway in certain cases (Nutzmann and Osbourn 2014). Rice has served as a model cereal crop plant, including for investigation of phytoalexins, which appear to be almost all terpenoids (Schmelz et al. 2014). In particular, labdane-related diterpenoids whose biosynthesis is related to that of the gibberellin phytohormones in the characteristic use of a copalyl diphosphate synthase (CPS) to initiate their production from the general diterpenoid precursor (E,E,E)-geranylgeranyl diphosphate (Zi et al. 2014). These natural products have been suggested to serve as antibiotics against the fungal blast pathogen Magneportha oryzae [i.e., the momilactones, oryzalexins and phytocassanes (Peters 2006)] and bacterial leaf blight pathogen Xanthomonas oryzae [i.e., the oryzalides, oryzadiones and related compounds (Toyomasu 2008)], as well as allelochemicals that inhibit the growth of other plants [i.e., momilactone B (Kato-Noguchi and Peters 2013)]. The rice genome contains two biosynthetic gene clusters associated with labdane-related diterpenoid biosynthesis, one on chromosome 4 that appears to be dedicated to the production of momilactones (Shimura et al. 2007, Wilderman et al. 2004), while the other on chromosome 7 has been associated with the production of phytocassanes (Prisic et al. 2004, Swaminathan et al. 2009), although there is evidence that this cluster has a more general role in such biosynthesis – e.g., production of the oryzalexins and oryzalides as well (Wang et al. 2012a, Wu et al. 2011, Wu et al. 2013). In both cases, there is a gene encoding a CPS and at least one for a kaurene synthase-like (KSL) cyclase specific for the stereoisomer of CPP produced by the co-clustered CPS, along with several encoding cytochrome P450 (CYP) mono-oxygenases that will act on the resulting multicyclic diterpene olefins (e.g., Figure 1). Notably, the chromosome 4 cluster also contains a gene encoding a short-chain alcohol dehydrogenase/reductase (SDR), which has been suggested to catalyze the last step in momilactone A biosynthesis, oxidation of a 3β-hydroxyl to the characteristic keto group (Atawong et al. 2002), leading to its designation as the rice momilactone A synthase, OsMAS (Shimura, et al. 2007). A number of other rice labdane-related diterpenoid phytoalexins also contain keto groups. While the CYPs that catalyze the initial addition of oxygen to form the relevant hydroxyl group have been identified in many cases, the enzyme catalyzing subsequent oxidation to a carbonyl has remained unknown. For example, CYP701A8 and CYP76M8 consecutively oxygenate ent-sandaracopimaradiene at C3α and then C7β, respectively, forming the di-hydroxy oryzalexin D (Wu, et al. 2013), further oxidation of which at C3 and/or C7 forms oryzalexins A – C (Peters 2006). Similarly, CYP76M7 can introduce a C11α hydroxyl group into ent-cassadiene, with the subsequently formed C11-keto found in all the phytocassanes (Swaminathan, et al. 2009), while CYP701A8 can introduce a C3α-hydroxyl, with either this or the derived 3-keto group found in all phytocassanes (Wang et al. 2012b), and CYP71Z7 can introduce a C2α-hydroxyl, which also can be further oxidized to a keto – e.g., as in phytocassane D (Wu, et al. 2011). While there are over 220 SDRs in rice (Moummou et al. 2012), it has already been shown that transcription of the genes encoding the relevant upstream enzymes for labdane-related diterpenoids are inducible (Schmelz, et al. 2014). A particularly broad view was provided by microarray based analysis of the transcriptional response of rice cell culture to induction with the fungal cell wall elicitor chitin (Okada et al. 2007). Notably, this study found significant accumulation of mRNA for five SDRs, including OsMAS. Here biochemical analysis of these SDRs was carried out and used to suggest their roles in rice labdane-related diterpenoid phytoalexin biosynthesis, leading most particularly to clarification of the production of oryzalexins. Results The inducible rice SDRs The SDRs form one of the largest enzymatic super-families and are highly diverse. Hence, the SDRs have been divided into phylogenetically distinct broad classes and more specific families to assist functional annotation (Persson et al. 2009). All five of the chitin-inducible SDRs contain the TGxxxGxG coenzyme binding and YxxxK catalytic motifs that place them in the classical SDR class (Kavanagh et al. 2008), as well as a specific Asp indicating a preference for NAD+ over NADP+ (Kallberg et al. 2002)(Figure S1). More specifically, these all fall within the vascular plant specific SDR110C family, members of which generally oxidize terpenoid or phenolic compounds. Even more particularly, these inducible OsSDR110C family members are divided between two clades therein (Figure 2), one defined by OsMAS and that is termed here the momilactone synthase (MS) clade, and another simply annotated monocot I and termed here the MI clade (Moummou, et al. 2012). According to this nomenclature, OsMAS can be termed OsSDR110C-MS1 (referred to hereafter as MS1), while the other clearly inducible clade member is OsSDR110C-MS3 (MS3). Similarly, those from the MI clade are largely found in a tandem array of 13 such genes on chromosome 7, and the chitin inducible members of this are OsSDR110C-MI2 (MI2), OsSDR110C-MI3 (MI3) and OsSDR110C-MI4 (MI4). Full-length mRNA corresponding to all five of these SDRs have been reported from a previous large-scale cDNA sequence project and were obtained from this source (Kikuchi et al. 2003). In addition to OsMAS, the momilactone biosynthetic gene cluster contains an adjacent and closely related SDR (OsSDR110C-MS2; hereafter MS2), which appears to have arisen by tandem gene duplication and shares >94% sequence identity with MS1 (Miyamoto et al. 2016). While the transcript of this gene was not reported to accumulate in response to chitin, it does not appear to have been separately represented on the microarray. Accordingly, it seemed plausible that this SDR might play a role in momilactone biosynthesis and/or other labdane-related diterpenoid phytoalexin biosynthesis. Thus, MS2 was also investigated here. Due to difficulties in cloning this, presumably in part as a result of the exact identity at both the 5' and 3' ends of the coding regions of this and MS1, a synthetic gene was obtained instead. Initial biochemical analyses with simplified substrate analogs The full length SDRs were recombinantly expressed as N-terminal 6xHis-tagged proteins in Escherichia coli strain C41 and purified via affinity chromatography. Recombinant protein was obtained for all these SDRs except MI4, which was not expressed well and, thus, not further investigated here. Based on previous work, a variety of mono-hydroxylated labdane-related diterpenes are readily available (Kitaoka et al. 2015, Swaminathan, et al. 2009, Wang, et al. 2012a, Wang et al. 2011, Wang, et al. 2012b, Wu, et al. 2011, Wu, et al. 2013). Hypothesizing that activity against these various hydroxyl groups might highlight potential roles for these SDRs in phytoalexin biosynthesis, these diterpene alcohols were tested as potential substrates (Figure 3). For example, 11α-hydroxy-ent-cassadiene provides the alcohol that presumably is oxidized as an early step in phytocassane biosynthesis (Figure 1), while 3β-hydroxy-syn-pimaradiene presents the relevant alcohol that is oxidized to form momilactone A (Figure 3). All assays also included 1 mM NAD+ to provide this necessary enzymatic co-factor, with organic extracts analyzed by GC-MS to detect the presence of oxidized products (i.e., a new peak with an apparent molecular ion of m/z = 286, relative to the m/z = 288 observed with the mono-hydroxylated diterpene precursors). While none of the SDRs reacted with 11α-hydroxy-ent-cassadiene, four of them reacted with 3β-hydroxy-syn-pimaradiene to varying degrees, with only MI2 unable to oxidize this (Table 1 and Figure S2). Surprisingly, MS1 was actually somewhat less active than not only MS2, but also MI3 with this latter substrate, which provides the relevant alcohol for the originally suggested reaction. Indeed, MS1 exhibited greater turnover with the alternative substrate 2α-hydroxy-ent-cassadiene, which was further oxidized by the other SDRs, with the exception of MI2 again (Table 1 and Figure S3). Similarly, these same four SDRs were able to oxidize both 3α-hydroxy-ent-cassadiene and 3α-hydroxy-ent-sandaracopimaradiene to varying degrees as well, although only MS3 was able to oxidize 7β-hydroxy-ent-sandaracopimaradiene (Table 1 and Figures S4 – S6). These initial results suggest that these SDRs are mostly likely to play roles in momilactone and/or oryzalexin biosynthesis, with any role in the production of phytocassanes occurring at later steps for which the relevant intermediates have not yet been identified and, thus, are not yet available. SDRs in momilactone biosynthesis The ability of multiple SDRs to catalyze oxidation of 3β-hydroxy-syn-pimaradiene suggested that the analogous step in momilactone A biosynthesis might be mediated by more than just MS1. This possibility was investigated by directly assaying these with 3β-hydroxy-syn-pimaradien-19,6β-olide, the penultimate intermediate in momilactone A biosynthesis (Atawong, et al. 2002), and originally reported MS1 substrate (Shimura, et al. 2007). Consistent with the results from assays with the simplified substrate analog 3β-hydroxy-syn-pimaradiene, not only MS1, but also MS2, MS3 and MI3 were able to produce momilactone A from 3β-hydroxy-syn-pimaradien-19,6β-olide (Figure 4, Table 1). Nevertheless, kinetic analysis demonstrated that MS1 and MS2 from the momilactone biosynthetic gene cluster exhibited significantly higher catalytic efficiency for this reaction than MS3 and MI3, for which kinetic constants could not be obtained due to poor substrate affinity (see Table 2). Somewhat surprisingly, MS2 exhibited much higher (>20-fold) catalytic efficiency than MS1, with both higher affinity (i.e., lower KM) and rate of catalysis (i.e., kcat). SDRs in oryzalexin biosynthesis The ability of these SDRs to catalyze oxidation of the 3α and/or 7β hydroxylated derivatives of ent-sandaracopimaradiene suggested that these might play a role in oryzalexin biosynthesis. In particular, the oxidation of oryzalexin D to oryzalexins A – C, which was investigated by directly assaying these SDRs with oryzalexin D (Figure 5). Again consistent with the results from the simplified substrate analogs, the same four SDRs were found to oxidize oryzalexin D (Table 1). In each case a new product was observed in which the apparent molecular ion was m/z = 302, representing oxidation of a single hydroxyl of oryzalexin D (m/z = 304). In addition, MS3 yielded two additional products, another with an apparent molecular ion of m/z = 302, and one with an apparent molecular ion of m/z = 300, presumably representing oxidation of both hydroxyl groups (i.e., oryzalexin C). Given that only MS3 was able to oxidize 7β-hydroxy-ent-sandaracopimaradiene, while all four SDRs can oxidize 3α-hydroxy-ent-sandaracopimaradiene, it seemed likely that the common SDR product was selectively oxidized at C3 (i.e., oryzalexin B). This was verified by scaling up the in vitro enzyme reaction to produce sufficient amounts for NMR analysis. Briefly, 0.5 mg of oryzalexin D was obtained by metabolic engineering of E. coli, as previously described (Wu, et al. 2013). This was converted to the common oxidized product with MS1. After extraction and purification, 0.2 mg of this compound was isolated. The resulting 1H-NMR data matched that reported for oryzalexin B rather than oryzalexin A (Kono et al. 1985). Accordingly, the remaining MS3 product is then oryzalexin A, resulting from oxidation of the 7β-hydroxyl group, again consistent with the activity observed with the corresponding simplified substrate analog. To further investigate the relevance of the observed activity to oryzalexin biosynthesis, kinetic analysis was carried out for all four SDR with oryzalexin D. Notably, MS3 and MI3 exhibited much higher catalytic efficiency (>100-fold) with this substrate than MS1 and MS2, the reverse of what is observed with the 3β-hydroxy-syn-pimaradien-19,6β-olide intermediate in momilactone biosynthesis (Table 2). Discussion The studies described here provide some insight into the roles played by the investigated inducible SDRs in rice labdane-related diterpenoid biosynthesis. While all four SDRs that exhibit activity will react with multiple labdane-related diterpenoids (Table 1), such promiscuity is not entirely unexpected (Wu et al. 2007). Moreover, their ability to react with the simplified substrate analogs employed here provided useful suggestions regarding potentially relevant biosynthetic activity, with subsequent kinetic analyses indicating distinct roles for these oxidases (Table 2). Perhaps clearest are the results indicating that MS3 and MI3 catalyze oxidation of the 7β- and/or 3α-hydroxyl groups, respectively, in production of oryzalexins A – C (Figure 6). This is particularly indicated by the strong catalytic efficiency exhibited by these OsSDR110C family members with oryzalexin D (Table 2), and their relatively weak activity with the corresponding mono-hydroxylated derivatives of ent-sandaracompimaradiene argues that oryzalexin D is the relevant precursor to oryzalexins A – C (i.e., rather than proceeding via oxidation and then secondary hydroxylation). Although it remains unclear if there is a preferential route to the fully/dually oxidized oryzalexin C (i.e., via oryzalexin A or B), given that both are observed, and the promiscuity exhibited by MS3, it seems likely that either route can be utilized in planta. Accordingly, these results essentially complete elucidation of the oryzalexin family of phytoalexins. The location of MS1 and MS2 in the momilactone biosynthetic gene cluster imply a role for these in the production of momilactone A and/or B. Somewhat surprisingly, MS2 exhibits higher catalytic efficiency for oxidation of 3β-hydroxy-syn-pimaradien-19,6β-olide to momilactone A than MS1 (Table 2), which was previously suggested to carry out this reaction (Shimura, et al. 2007). Indeed, MS1 actually exhibits higher catalytic efficiency for oxidation of oryzalexin D to oryzalexin B, and both MS1 and MS2 actually seem to have higher affinity for oryzalexin D than 3β-hydroxy-syn-pimaradien-19,6β-olide (Table 2). Thus, while MS2 presumably is responsible for the final step in production of momilactone A, it will be of interest to further probe if MS1 has a different role in momilactone or other rice diterpenoid phytoalexin biosynthesis. Finally, although it seems likely that oxidation of an 11α-hydroxyl group occurs early in phytocassane biosynthesis given the presence of an 11-keto group in all of these phytoalexins, the relevant SDR does not appear to be among those investigated here. On the other hand, the ability of the investigated SDRs to readily oxidize simplified substrate analogs suggests that these SDRs might be relevant to the oxidation of 2α- and 3α-hydroxyl groups that presumably represent latter steps in phytocassane biosynthesis. Nevertheless, it will be necessary to carry out further studies to identify the presumably early acting C11 oxidase. While all three members of the MS clade from rice have already been investigated here, of particular interest in these future studies will be the twelve as of yet uncharacterized members of the MI clade from the SDR110C family found in rice. Material and methods General Unless otherwise noted, chemicals were purchased from Fisher Scientific (Loughborough, Leicestershire, UK), and molecular biology reagents from Invitrogen (Carlsbad, CA, USA). Gas chromatography (GC) was performed with a Varian (Palo Alto, CA) 3900 GC equipped with an HP-5MS column (Agilent, 0.25 μm, 0.25ID, 30 m) and 1.2 L mL/min He flow rate, with detection via a Saturn 2100 ion trap mass spectrometer (MS) in electron ionization mode (70 eV). Samples (1 μL) were injected in splitless mode with the injection port at 250 °C and oven at 50 °C, after holding for 3 min. at 50 °C the oven temperature was raised at 15 °C/min. to 300 °C, where it was held for an additional 3 min. MS data from 90 to 600 mass-to-charge ratio (m/z) was collected from 14 min. after injection until the end of the run. GC with flame ionization detection (GC-FID) was carried out with an Agilent 6890N GC also equipped with an HP-5MS column and using the same temperature program. High pressure liquid chromatography (HPLC) was carried out with an Agilent 1100 HPLC system equipped with auto-sampler, fraction collector and diode-array detector, run in reversed phase at 0.5 mL/min with a ZORBAX Eclipse XDB-C8 column (150 x 4.6 mm, 5 μm), using deionized water (dH2O) and acetonitrile (AcN). NMR spectra were recorded at 25 °C on a Bruker Avance 700 spectrometer (1H 700 MHz; 13C 174 MHz) equipped with a 5-mm HCN cryogenic probe for 1H and 13C, using standard experiments from the Bruker TopSpin v1.3 software. Compounds were dissolved in 0.5 mL deuterated chloroform (CDCl3) and placed in microtubes (Shigemi; Allison Park, PA) for analysis, with chemical shifts referenced using the known chloroform (13C 77.23, 1H 7.24 ppm) signals offset from trimethyl-silane. Substrate preparation Oryzalexin D, 3α-hydroxy-ent-(sandaraco)pimara-8(14),15-diene, 7β-hydroxy-ent-sandaracopimaradiene, 2α-hydroxy-ent-cassa-12,15-diene, 3α-hydroxy-ent-cassadiene, 11α-hydroxy-ent-cassadiene, and 3β-hydroxy-syn-pimara-7,15-diene were produced using a bacterial metabolic engineering system and purified as previously described (Kitaoka, et al. 2015, Swaminathan, et al. 2009, Wang, et al. 2012a, Wang, et al. 2011, Wang, et al. 2012b, Wu, et al. 2011, Wu, et al. 2013). 3β-Hydroxy-syn-pimara-7,15-dien-19,6β-olide was prepared by reduction of momilactone A as previously described (Kato et al. 1977). Briefly, lithium aluminium hydride (0.5 mg) was added to anhydrous ether solution (1 mL) containing 0.5 mg momilactone A. After continuously stirring at room temperature for 10 minutes, water was slowly poured into the reaction mixture. This was then twice extracted with an equal volumne of ether, and the combined organic phase was dried over Na2SO4 and dried in vacuo. The residue was resuspended in 50% AcN/dH2O, and purified by HPLC. After loading the sample, the column was washed for 2 min. with 50% (v/v) AcN/dH2O, with a gradient from 2 – 25 min. raising the AcN to 100%, and the column washed from 25 – 35 min. with 100% AcN. Fractions containing 3β-hydroxy-syn-pimaradien-19,6β-olide were identified by GC-MS analysis, pooled and dried under N2. Structural analysis was carried out using 1D 1H, DQF-COSY, HSQC, HMBC and NOESY spectra acquired at 700 MHz and 13C spectra acquired at 174 MHz. Correlations from the HMBC spectra were used to propose the majority of the structure, while connections between protonated carbons were obtained from DQF-COSY to complete the partial structure and assign proton chemical shifts. NOESY spectra provided Nuclear Overhauser Effect (NOE) cross-peak signal between the proton on C3 and that on C5 to assign the stereochemistry at C3. The 1H-NMR spectrum (700 MHz, CDCl3): δ 5.82 (1H, dd, J = 17.7, 11.7 Hz, H15), 5.64 (1H, d, J = 5.0 Hz, H5), 4.95 (1H, d, J = 17.7 Hz, H16Z), 4.90 (2H, m, H-6, H16E), 3.62 (1H, m, H3), 2.15 (1H, d, J = 11.7 Hz, H14b), 2.04 (1H, m, H2a), 1.99 (1H, dd, J = 11.7, 2.0 Hz, H15), 1.78 (1H, m H2b), 1.77 (1H, d, J = 3.9 Hz, H5), 1.64 (1H, m, H11b), 1.63 (1H, m, H9), 1.52 (1H, m, H12a), 1.52 (3H, s, H18), 1.50 (1H, m, H12b), 1.36 (1H, m, H1a), 1.31 (1H, m, H1b), 1.28 (1H, m, H11a), 1.04 (3H, s, H20), 0.84 (3H, s, H17). The 13C-NMR spectrum (174 MHz, CDCl3): 181.9 (C19), 149.6 (C8), 149.1 (C15), 114.4 (C7), 110.0 (C16), 74.6 (C6), 74.4 (C3), 51.3 (C9), 47.3 (C14), 46.9 (C5), 44.5 (C4), 40.1 (C13), 37.6 (C12), 33.1 (C10), 31.7 (C1), 29.4 (C2), 23.8 (C20), 22.9 (C18), 22.6 (C11), 21.9 (C17). Recombinant construct and protein purification OsMAS/SDR110C-MS1, OsSDR110C-MS3, OsSDR110C-MI2, OsSDR110C-MI3, and OsSDR110C-MI4 were obtained from the KOME rice cDNA databank (GeneBank accessions AK103462, AK110700, AK107157, AK070585, and AK06856, respectively). After several attempts to clone OsSDR110C-MS2 (GeneBank accession AK240900) were unsuccessful, resulting in only amplification of MS1, which has identical sequences at both the 5' and 3' ends of the coding region (corresponding to the primers used here), an alternative version was obtained by gene synthesis (GeneScript), with codon optimization for expression in E. coli (see supporting data for sequence). These were cloned into pENTR/SD/D-TOPO, and then transferred to pDEST17 by LR recombination before verification by complete gene sequencing. The resulting expression vectors were transformed into E. coli C41 OverExpress (Lucigen). The resulting recombinant bacteria were grown in 50 mL NZY medium at 37 °C overnight, and these cultures used to inoculate 1 L NYZ medium, and also shaken at 37 °C until their OD600 reached ~0.6–0.8. The culture was then induced with 1 mM isopropyl β-D-1-thiogalactopyranoside (IPTG), shaken at 16 °C for 16 hours. The bacteria were harvested by centrifugation and resuspended in 20 mL lysis buffer (50 mM Bis-Tris, 150 mM KCl, 20 mM Mg2SO4, 10% glycerol, 1 mM DTT, pH6.8). The cells were lysed by brief sonication and the soluble enzyme fraction was obtained by centrifugation (15,000 g, 25 min, 4 °C). The soluble enzyme fraction was incubated (rotating) with a slurry of Ni-NTA resin (2 mL) for 2 hours at 4 °C. The resin was washed by 20 mL wash buffer (50 mM Bis-Tris, 150 mM KCl, 20 mM imidazole, pH 6.8) and then eluted by 5 mL elution buffer (50 mM Bis-Tris, 150 mM KCl, 250 mM imidazole, pH 6.8). The imidazole was removed by dialysis, using 12–15 KDa cut-off membrane (Spectrum Chemical and Laboratory Products, Gardena, CA), twice against 1 L dialysis buffer (20 mM Tris-HCl, 150 mM KCl, 10% glycerol, pH 7.8). The resulting SDRs were utilized for enzymatic assays. Enzymatic assays Initial assays were conducted with 0.5 μM SDR, 50 μM substrate and 1 mM NAD+ in 0.5 mL Tris-HCl buffer (100 mM Tris-HCl, pH 8.0) with 10% (v/v) glycerol. After incubating at 30 °C for 1 hour, the reaction mixture was extracted thrice with 0.5 mL n-hexanes. The organic extracts were combined, dried under N2 gas and resuspended in 80 μL hexanes for analysis by GC-MS. Control assays were conducted without enzyme. Oxidation of the simplified substrate analogs was demonstrated by the reduction in m/z of the molecular ion from 288 to 286 in the mass spectra of the SDR and NAD+ dependent product peaks. Oxidation of 3β-hydroxy-syn-pimara-7,15-dien-19,6β-olide was verified by comparison of the SDR and NAD+ dependent product peak to a previously reported authentic sample of momilactone A (Xu et al. 2012). Kinetic analysis was carried out using 10–40 nM recombinant SDR in 0.5 mL assays run for 5–10 min at 30 °C, as determined by preliminary analyses to lie within the linear response range. The oxygenated diterpene substrates were added in varying concentrations (10–300 μM). To stop the reaction, assay vials were placed on ice and the enzymatic products immediately extracted with n-hexanes as above, and quantified by analysis with GC-FID. Verification of oryzalexin B Oryzalexin D (0.5 mg) was oxidized by MS1 as described above (40 nM SDR and 50 μM substrate), with the assay run overnight at 30 °C. This was then extracted trice with an equal volumne of hexanes, and the pooled extract was dried under N2 gas, and the residue redissolved in 50% AcN/dH2O for HPLC purification. After loading the sample, the column was washed for 2 min. with 50% (v/v) AcN/dH2O, with a gradient from 2 – 7 min. raising the AcN to 100%, and the column washed from 7 – 20 min. with 100% AcN. Fractions containing oryzalexin B were identified by GC-MS analysis, pooled and dried under N2 gas. The structure was confirmed by comparison of the 1H-NMR spectrum (700 MHz, CDCl3) with that previously reported (Kono, et al. 1985): δ 5.70 (1H, dd, J = 17.5, 10.3 Hz), 5.51 (1H, br.s), 4.87 (1H, d, J = 17.5 Hz), 4.86 (1H, d, J = 10.3), 4.18 (1H, br.s), 2.56 (1H, td, J = 14.5, 6.0 Hz), 2.26 (1H, dt, J = 14.5, 3.7 Hz), 2.1 (1H, t, J = 7.5 Hz), 1.98 (1H, dd, J = 11.8, 4.2 Hz), 1.93 (1H, ddd, 13.3, 5.7, 3.3 Hz), 1.20 ~ 1.69 (7H), 1.03 (3H, s), 0.992 (3H, s), 0.987 (3H, s), 0.90 (3H, s). Supplementary Material Supp FigS1-S6 Figure S1. Alignment of SDRs investigated in this report. Figure S2. SDR activity with the simplified substrate analog 3β-hydroxy-syn- pimaradiene. Figure S3. SDR activity with the simplified substrate analog 2α-hydroxy-ent-cassadiene. Figure S4. SDR activity with the simplified substrate analog 3α-hydroxy-ent-cassadiene. Figure S5. SDR activity with the simplified substrate analog 3α-hydroxy-ent- sandaracopimaradiene. Figure S6. SDR activity with the simplified substrate analog 7β-hydroxy-ent- sandaracopimaradiene. This work was supported in part by a grant from the NIH (GM109773 to R.J.P.). Figure 1 Biosynthetic gene clusters and prospective pathways for phytocassanes A – F and momilactones A & B. Figure 2 The rice SDR110C family. Phylogenetic analysis of the two main clades (*, inducible transcript accumulation; underlined, biochemical characterization). Almost all of the members of the monocot I (MI) clade are found in a tandem gene array. Figure 3 Simplified substrate analogs of oxo group containing rice diterpenoids. Figure 4 SDR catalyzed oxidation of the precursor 3β-hydroxy-syn-pimaradien-19,6β-olide (Pre) to momilactone A (MA), as indicated by GC-MS chromatograms. Figure 5 GC-MS chromatograms and mass spectra demonstrating SDR activity with oryzalexin D. Figure 6 Biosynthesis of oryzalexins A – C from oryzalexin D by MI3 and MS3 indicated by the results reported here. Table 1 OsSDR110C activity against oxygenated diterpenes.a Substrate MS1 MS2 MS3 MI2 MI3 3β-hydroxy-syn-pimaradien-19,6β-olide +++ +++ ++ – +++ 3β-hydroxy-syn-pimaradiene +/− +++ + – +++ oryzalexin D +++ +++ +++ – +++ 3α-hydroxy-ent-sandaracopimaradiene +/− + ++ – +++ 7β-hydroxy-ent-sandaracopimaradiene – – + – – 2α-hydroxy-ent-cassadiene +++ +++ +++ – + 3α-hydroxy-ent-cassadiene ++ ++ +++ – ++ 11α-hydroxy-ent-cassadiene – – – – – a Conversion rates: +++, > 50%; ++, 16–49%; +, 1–15%; +/−, <1%; –, not detectable. Table 2 OsSDR110C kinetic parameters with biosynthetic intermediates. Substrate SDR110C- KM (μM) kcat (s−1) kcat/KM (s−1 M−1) 3β-hydroxy-syn-pimaradien-19,6β-olide MS1 900 ± 400 (8 ± 3) x10−2 9 x101 MS2 200 ± 100 (4 ± 1) x10−1 2 x103 oryzalexin D MS1 60 ± 15 (2 ± 1) x10−2 3 x102 MS2 60 ± 20 (2.3 ± 0.3) x10−2 4 x102 MS3 40 ± 20 1.9 ± 0.2 5 x104 MI3 14 ± 10 2.7 ± 0.4 2 x105 Atawong A Hasegawa M Kodama O 2002 Biosynthesis of rice phytoalexin: enzymatic conversion of 3β-hydroxy-9β-pimara-7,15-dien-19,6β-olide to momilactone A Biosci Biotechnol Biochem 66 566 570 12005050 Bednarek P Osbourn A 2009 Plant-microbe interactions: chemical diversity in plant defense Science 324 746 748 19423814 Hammerschmidt R 1999 PHYTOALEXINS: What Have We Learned After 60 Years? Annual review of phytopathology 37 285 306 Kallberg Y Oppermann U Jornvall H Persson B 2002 Short-chain dehydrogenases/reductases (SDRs) European journal of biochemistry / FEBS 269 4409 4417 Kato T Aizawa H Tsunekawa M Sasaki N Kitahara Y Takahashi N 1977 Chemical transformations of the diterpene lactones momilactones A and B J Chem Soc, Perkin Trans I 250 254 Kato-Noguchi H Peters RJ 2013 The role of momilactones in rice allelopathy J Chem Ecol 39 175 185 23385366 Kavanagh KL Jornvall H Persson B Oppermann U 2008 Medium- and short-chain dehydrogenase/reductase gene and protein families : the SDR superfamily: functional and structural diversity within a family of metabolic and regulatory enzymes Cellular and molecular life sciences : CMLS 65 3895 3906 19011750 Kikuchi S Satoh K Nagata T Kawagashira N Doi K Kishimoto N Yazaki J Ishikawa M Yamada H Ooka H Hotta I Kojima K Namiki T Ohneda E Yahagi W Suzuki K Li CJ Ohtsuki K Shishiki T Otomo Y Murakami K Iida Y Sugano S Fujimura T Suzuki Y Tsunoda Y Kurosaki T Kodama T Masuda H Kobayashi M Xie Q Lu M Narikawa R Sugiyama A Mizuno K Yokomizo S Niikura J Ikeda R Ishibiki J Kawamata M Yoshimura A Miura J Kusumegi T Oka M Ryu R Ueda M Matsubara K Kawai J Carninci P Adachi J Aizawa K Arakawa T Fukuda S Hara A Hashidume W Hayatsu N Imotani K Ishii Y Itoh M Kagawa I Kondo S Konno H Miyazaki A Osato N Ota Y Saito R Sasaki D Sato K Shibata K Shinagawa A Shiraki T Yoshino M Hayashizaki Y 2003 Collection, mapping, and annotation of over 28,000 cDNA clones from japonica rice Science 301 376 379 12869764 Kitaoka N Wu Y Xu M Peters RJ 2015 Optimization of recombinant expression enables discovery of novel cytochrome P450 activity in rice diterpenoid biosynthesis Appl Microbiol Biotechnol 99 7549 7558 25758958 Kono Y Takeuchi S Kodama O Sekido H Akatsuka T 1985 Novel phytoalexins (oryzalexins A, B and C) isolated from rice blast leaves infected with Pyricularia oryzae Part II: Structural studies of oryzalexins Agric Biol Chem 49 1695 1701 Miyamoto K Fujita M Shenton MR Akashi S Sugawara C Sakai A Horie K Hasegawa M Kawaide H Mitsuhashi W Nojiri H Yamane H Kurata N Okada K Toyomasu T 2016 Evolutionary trajectory of phytoalexin biosynthetic gene clusters in rice Plant J Moummou H Kallberg Y Tonfack LB Persson B van der Rest B 2012 The plant short-chain dehydrogenase (SDR) superfamily: genome-wide inventory and diversification patterns BMC Plant Biol 12 219 23167570 Nutzmann HW Osbourn A 2014 Gene clustering in plant specialized metabolism Curr Opin Biotechnol 26 91 99 24679264 Okada A Shimizu T Okada K Kuzuyama T Koga J Shibuya N Nojiri H Yamane H 2007 Elicitor induced activation of the methylerythritol phosphate pathway towards phytoalexin biosynthesis in rice Plant Mol Biol 65 177 187 17634747 Persson B Kallberg Y Bray JE Bruford E Dellaporta SL Favia AD Duarte RG Jornvall H Kavanagh KL Kedishvili N Kisiela M Maser E Mindnich R Orchard S Penning TM Thornton JM Adamski J Oppermann U 2009 The SDR (short-chain dehydrogenase/reductase and related enzymes) nomenclature initiative Chem Biol Interact 178 94 98 19027726 Peters RJ 2006 Uncovering the complex metabolic network underlying diterpenoid phytoalexin biosynthesis in rice and other cereal crop plants Phytochemistry 67 2307 2317 16956633 Prisic S Xu M Wilderman PR Peters RJ 2004 Rice contains two disparate ent-copalyl diphosphate synthases with distinct metabolic functions Plant Physiol 136 4228 4236 15542489 Schmelz EA Huffaker A Sims JW Christensen SA Lu X Okada K Peters RJ 2014 Biosynthesis, elicitation and roles of monocot terpenoid phytoalexins Plant J 79 659 678 24450747 Shimura K Okada A Okada K Jikumaru Y Ko KW Toyomasu T Sassa T Hasegawa M Kodama O Shibuya N Koga J Nojiri H Yamane H 2007 Identification of a biosynthetic gene cluster in rice for momilactones J Biol Chem 282 34013 34018 17872948 Swaminathan S Morrone D Wang Q Fulton DB Peters RJ 2009 CYP76M7 is an ent-cassadiene C11α-hydroxylase defining a second multifunctional diterpenoid biosynthetic gene cluster in rice Plant Cell 21 3315 3325 19825834 Toyomasu T 2008 Recent Advances Regarding Diterpene Cyclase Genes in Higher Plants and Fungi Biosci Biotechnol Biochem 72 1168 1175 18460786 Wang Q Hillwig ML Okada K Yamazaki K Wu Y Swaminathan S Yamane H Peters RJ 2012a Characterization of CYP76M5-8 indicates metabolic plasticity within a plant biosynthetic gene cluster J Biol Chem 287 6159 6168 22215681 Wang Q Hillwig ML Peters RJ 2011 CYP99A3: Functional identification of a diterpene oxidase from the momilactone biosynthetic gene cluster in rice Plant J 65 87 95 21175892 Wang Q Hillwig ML Wu Y Peters RJ 2012b CYP701A8: A rice ent-kaurene oxidase paralog diverted to more specialized diterpenoid metabolism Plant Physiol 158 1418 1425 22247270 Wilderman PR Xu M Jin Y Coates RM Peters RJ 2004 Identification of syn-pimara-7,15-diene synthase reveals functional clustering of terpene synthases involved in rice phytoalexin/allelochemical biosynthesis Plant 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PMC005xxxxxx/PMC5118074.txt
LICENSE: This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. 7503062 4443 J Am Geriatr Soc J Am Geriatr Soc Journal of the American Geriatrics Society 0002-8614 1532-5415 27626617 5118074 10.1111/jgs.14347 NIHMS784760 Article Self-reported Sleep Problems Prospectively Increase Risk of Disability: Findings from the Survey of Midlife Development in the United States (MIDUS) Friedman Elliot M. PhD 1 1 Department of Human Development and Family Studies, Purdue University, West Lafayette, IN Corresponding Author: Elliot M. Friedman, PhD, Department of Human Development and Family Studies, 1202 West State Street, West Lafayette, IN 47907, Ph: 765-496-6378, FAX: 765-496-1144, efriedman@purdue.edu 10 5 2016 14 9 2016 11 2016 01 11 2017 64 11 22352241 This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. Objectives To determine whether subjective poor sleep prospectively increases functional limitations and incident disability in a national sample of adults living in the United States. Design Prospective cohort Setting Longitudinal Survey of Midlife Development in the United States (MIDUS) Participants Young, middle aged, and older men and women (age 24–75) surveyed in 1995–1996 (MIDUS 1) and followed up in 2004–2006 (MIDUS 2). Complete data were available for 3,620 respondents. Measurements Data were from telephone interviews and self-administered questionnaires. Participant reported chronic sleep problems within the prior month; functional limitations were assessed using the Functional Status Questionnaire. Demographic (age, sex, race), socioeconomic (educational attainment), health (chronic conditions, depression), and health behavior (obesity, smoking) covariates were assessed to reduce potential confounding. Results Approximately 11% of the sample reported chronic sleep problems at both MIDUS waves. Average numbers of basic and intermediate ADL limitations increased significantly between MIDUS 1 (basic: .06; intermediate: .95) and MIDUS 2 (basic: .15; intermediate: 1.6; P<.001). Adjusted regression models estimating change in ADL scores showed that chronic sleep problems at MIDUS 1 predicted significantly greater increases in both basic (incident rate ratio (IRR) = 1.55, P<.001) and intermediate (IRR = 1.28, P<.001) ADL limitations. In those with no functional limitations at baseline, logistic regression models showed that chronic sleep problems significantly increased the odds of incident basic (OR = 2.33, CI:1.68,3.24, P<.001) and intermediate (OR = 1.70, CI: 1.21,2.42, P<.01) ADL disability. Conclusion Reports of chronic sleep problems predicted greater risk of both onset of and increases in functional limitations 9–10 years later. Poor sleep may be a robust and independent risk factor for disability in adults of all ages. subjective sleep ADLs MIDUS disability INTRODUCTION Disability rates in older adults have declined in recent years,1,2 due principally to medical and technological advances and to broad improvements in socioeconomic indicators, including poverty and educational attainment.3 Nonetheless, inability to perform daily activities remains common. Estimates from the National Health Interview Surveys and the National Long-Term Care Survey show that 15%–20% of adults over age 65 have at least one functional limitation.1,2 Further improvements in disability rates will largely rest on changes in lifestyle factors. Obesity4 and physical inactivity,5 for example, are robustly linked to increased risk of disability,1,6 and rates of both are high in aging adults; these factors threaten to slow or stall the downward trends in disability rates. Another lifestyle factor – sleep – has received relatively little attention as a predictor of disability, despite well-documented links between sleep problems and a range of adverse health outcomes, including mortality.7–10 This study examines the prospective associations between self-reported sleep problems and activities of daily living (ADL) in a national sample of middle-aged and older adults living in the United States. Two lines of research converge on sleep as a compelling focus for understanding disability risk. First, sleep quality tends to decline with age. Objective assessments show significant age-related declines in sleep duration, sleep efficiency, rapid eye movement (REM), and stage 3/4 sleep coupled with significant increases in sleep latency and stage 1–2 sleep.11 Subjective complaints of poor sleep also tend to increase with age.12,13 Second, both quantitative (e.g. number of hours slept per night) and qualitative (e.g. complaints of poor sleep) aspects of sleep are linked to morbidity and mortality in older adults.7,8,14 Subjective reports of impaired sleep, for example, significantly increased the risk of subsequent heart attack, stroke, and cardiac mortality in older men and women with primary acute myocardial infarction from the Stockholm Heart Epidemiology Program.14 A regional longitudinal study in Sweden found that sleep complaints at baseline predicted greater risk of coronary artery disease15 and diabetes16 in men 12 years later. Few studies have examined the prospective links between sleep complaints and disability. A recent study of 908 older Catholic clergy in the United States found that poor subjective sleep significantly increased risk of disability at follow-up 9.6 years later.17 The current study extends this earlier work by examining the prospective associations of sleep complaints and disability in a representative national sample of men and women in the US: the Survey of Mid-Life Development in the United States (MIDUS)18. We hypothesized that subjective report of sleep problems would increase the risk of both increases in functional limitations and incident disability in those with no functional impairments at baseline. The MIDUS sample is community dwelling, making the results applicable to the general adult population of the US. The broad age range of the MIDUS sample, spanning 5 decades from mid-20s to mid-70s, also makes it possible to determine whether the links between poor sleep and functional impairment are limited to older adults or extend to mid-life and younger adults as well. Finally, while the main analyses in this study involve self-reported functional limitations, these are bolstered by supplemental analyses using objective assessments of functional status available for sub-samples of MIDUS participants. METHODS Participants Data are from the first two waves of MIDUS, a longitudinal study of the physical and mental health of middle-aged and older adults.18 The first wave of data collection (MIDUS 1; N = 7,108) included a national probability sample of non-institutionalized English-speaking adults living in the contiguous United States recruited by random digit dialing (RDD; n = 3,487), a sample of monozygotic and dizygotic twin pairs from a national twin registry (n = 1,914), oversamples from five metropolitan areas (n = 757), and siblings of individuals from the RDD sample (n = 950). Respondents completed telephone interviews and self-administered questionnaires (SAQ). A follow-up study was completed 9–10 years later (MIDUS 2). Mortality-adjusted retention from the original study was 75%. Complete data for the present analyses were available for 3,620 participants. Compared to the full longitudinal sample, the analytical sample had fewer female respondents, was better educated, and had fewer functional limitations at baseline; they were comparable on all other key variables. Collection of data for both waves of MIDUS and analyses for the current study were approved by the Institutional Review Boards at the University of Wisconsin-Madison and Purdue University, respectively. Measures Sleep complaints were assessed using a single questionnaire item: “In the past 12 months, have you experienced or been treated for chronic sleeping problems?” A dichotomous variable was used in all models. Information on basic and intermediate activities of daily living came from the Functional Status Questionnaire.19 Respondents were asked how much health limited their ability to do a number of activities. Basic ADL limitations were determined from two items: “bathing or dressing yourself” and “walking one block.” Intermediate ADL limitations were determined from seven items: “lifting or carrying groceries,” “climbing several flights of stairs,” “bending, kneeling, or stooping,” “walking more than a mile,” “walking several blocks,” “vigorous activities (e.g., running, lifting heavy objects),” and “moderate activities (e.g., bowling, vacuuming).” Response ranged from 1=Not at all to 4=A lot. To determine the number of activities for which respondents reported at least some degree of limitation, responses of “Some” or “A lot” of limitation were scored ‘1’ and other responses ‘0.’ Responses were then summed into separate scores for basic and intermediate ADLs with possible scores of 0–2 for basic and 0–7 for intermediate scales. Total scores at both MIDUS 1 and MIDUS 2 were calculated and used to examine changes in numbers of functional limitations over time. Dichotomous variables for presence or absence of any limitations were also created for logistic regression models estimating incident functional limitations between MIDUS 1 and MIDUS 2. A set of demographic, socioeconomic, health, and health behavior covariates was included in all models to reduce the likelihood of confounding. These included age, sex, race, and educational attainment (dummy coded variables for high school degree or GED, some college, and college degree or more). To assess health, a variable for 12 chronic medical conditions was used in all analyses. Information on 9 of these conditions came from participant responses to self-administered questionnaire items; participants were asked whether they had experienced or received treatment for any of the following conditions in the prior 12 months: chronic obstructive pulmonary disease (COPD), arthritis or other joint conditions, AIDS, hypertension, diabetes, tuberculosis, neurological disorders, stroke, ulcer. Presence of heart problems and cancer were determined from single items in the telephone interview. Participants were asked whether they had had heart trouble suspected or confirmed by a doctor and whether they had ever had cancer. Possible scores ranged from 0–12. Variables for obesity and smoking were included to control for health behaviors. Body mass index (BMI) was calculated from participant measurement of height and weight and dummy coded variables for normal weight (BMI<24.99), overweight (BMI between 25.00 and 29.99) and obese (BMI>=30.00) were created. Smoking status was assessed using dummy-coded variables indicating non-smoker, ex-smoker, and current smoker. Finally, as depressed individuals are more likely to report both poor sleep20 and greater functional impairment,21 likely depression was determined using the short form of the Composite International Diagnostic Interview (CIDI).22 Respondents were scored as positive for depressed affect if they indicated 1) that they felt sad, blue, or depressed and that “The feeling of being sad, blue, or depressed lasted ‘All day long’ or ‘Most of the day’ and 2) that they felt this way “Everyday” or “Almost every day.” They were scored as positive for anhedonia if they reported a loss of interest in most things lasting “All day long” or “Most of the day” and that this feeling was “Everyday” or “Almost every day.” A dichotomous variable indicating likely clinical depression (i.e. positive scores for both depressed affect and anhedonia) was included in all models. Statistical analyses Longitudinal increases in ADL limitations were estimated in separate Poisson regression models. Poisson modeling was appropriate because the outcome measures (numbers of limitations) were counts rather than continuous variables. Incident rate ratios (IRR) comparing the rate of functional limitations in respondents with sleep problems to those without were determined; these are interpreted in a similar fashion as odds ratios. All models adjusted for age, sex, race, educational attainment, and functional limitations at MIDUS 1. To control for the possible influences of coincident illness, obesity, and depressive symptoms on functional abilities, MIDUS 2 measures of number of chronic medical conditions, smoking status, BMI, and depression were included in all models. Poisson models used data from the full longitudinal sample. Binary logistic regression models were used to estimate the odds of incident basic and intermediate ADL disability between MIDUS 1 and MIDUS 2, adjusted for covariates. In these models, the analytical samples were limited to respondents with no functional limitations at MIDUS 1 (n = 3,244 for basic ADLs, and n=1,329 for intermediate ADLs). Models were estimated using Stata 13.0 (Statacorp., College Station, TX). Given age-related changes in both sleep complaints and disability risk, and to determine whether the associations between sleep and ADL limitations varied with age, we conducted additional analyses that included interaction terms for sleep problems and age as predictors of longitudinal changes in ADL and incident ADL impairments. Clustered robust standard errors were applied to account for familial relatedness among the twins and siblings in the sample. A threshold for statistical significance was set at alpha = 0.05 in all models. RESULTS Descriptive statistics for the full analytical sample are shown in Table 1. Sociodemographic characteristics are from MIDUS 1. Mean age was 46.5 years, slightly more than half the sample was female, 6.3% were non-White, and 35.9% had completed a 4-year college degree or more. Data on other variables were from both MIDUS 1 and MIDUS 2. Between the two data collection points the average number of basic (MIDUS 1 = 0.06; MIDUS 2 = 0.15; t(3,619)=−12.2, p<.001) and intermediate ADL limitations (MIDUS 1 = 0.95; MIDUS 2 = 1.61; t(3,619)=−20.2, p<.001) rose significantly while the fraction of the sample reporting sleep problems did not change significantly (MIDUS 1 = 11.3; MIDUS 2 = 10.7; χ2=0.91, p=0.33). Of those who reported sleep problems at MIDUS 1, 38.9% continued to report sleep problems at MIDUS 2 (data not shown). The fraction of people who met criteria for depression on the CIDI-SF declined significantly between MIDUS 1 (12.0 %) and MIDUS 2 (10.1%; χ2=10.32, p=.001), and average number of chronic conditions increased significantly between MIDUS 1 and MIDUS 2 (t(3,619)=28.89, p<.001). Poisson regression models were used to estimate the increase in basic and intermediate ADL limitations associated with reporting poor sleep at MIDUS 1 adjusted for MIDUS 1 sociodemographic characteristics and initial levels of functional limitations and MIDUS 2 health, health behavior, and depression. As shown in Table 2, reporting chronic sleep problems at MIDUS 1 was associated with significantly increased rates of both basic and intermediate ADL limitations. Compared to those without sleep complaints, respondents who reported chronic sleep problems in the prior year showed a 55% increase in basic (p<.001) and a 28% increase in intermediate ADL limitations (p<.001). Greater risk of increases in functional impairments was also associated with greater age, being female, being White (intermediate ADLs only), not having completed a 4-year college degree or more, greater numbers of chronic medical conditions, obesity, higher scores on the CIDI depression scale, and smoking either currently or in the past. The likelihood of incident disability between MIDUS 1 and MIDUS 2 was estimated using logistic regression models; analytical samples were limited to those respondents without ADL limitations at MIDUS 1. As shown in Table 3, compared to those with no sleep complaints, respondents who reported chronic sleep problems at MIDUS 1 were more than twice as likely to develop basic ADL limitations (p<.001) and 70% more likely to develop intermediate ADL limitations (p<.05). Age, being female, low educational attainment, being overweight or obese, more chronic conditions, depression, and smoking were all associated with likelihood of incident functional limitations at MIDUS 2. Analyses that included age X sleep problems interaction terms showed that age significantly moderated the association of MIDUS 1 sleep problems and longitudinal increases in intermediate ADL limitations. Specifically, the rate of increases in limitations among younger and middle-aged adults (e.g. 45 year-olds) who reported sleep problems (increase of 1.04 limitations) was double that of peers with no sleep complaints (2.13 increase; interaction effect: IRR = 0.98, p<.001). This interaction is displayed in Figure 1. Age did not moderate the association between sleep problems and change in basic ADL limitations. Analytical refinements We probed these results in four ways to rule out potential alternative explanations of the observed associations. First, 39% of full analytical sample reported chronic sleep problems at both MIDUS 1 and MIDUS 2. It is possible that the observed longitudinal associations for sleep complaints are accounted for by coincident poor sleep and functional limitations at MIDUS 2. To test this possibility, all regression models were re-estimated with an additional adjustment for sleep complaints at MIDUS 2. Inclusion of MIDUS 2 sleep complaints slightly reduced the coefficients for MIDUS 1 sleep complaints, but the associations remained robust (p<.001 in both basic and intermediate ADL models). In the logistic regression models, the likelihood that someone with chronic sleep problems would develop basic ADL limitations at MIDUS 2 declined from 133% that of someone without sleep complaints to 78%, but the effect remained statistically significant (p=.001). For intermediate ADL limitations, the odds declined from 79% to 69% and became marginally significant (p=.05). In all of these analyses, the coefficients and odds ratios associated with sleep problems at MIDUS 1 were consistently larger than those associated with sleep problems at MIDUS 2 (data not shown). Second, as sleep complaints were assessed using a single item that was subjective and global in nature, we compared these responses to scores on a widely used measure of sleep quality, the Pittsburgh Sleep Quality Index23 (PSQI; this measure was only used in a sub-sample of MIDUS 2 respondents (n = 1,063), so it was unavailable for longitudinal analyses). The PSQI is a 24-item scale assessing 7 different sleep components: subjective sleep quality, sleep latency, sleep duration, habitual sleep efficiency, sleep disturbances, use of sleeping medication, and daytime dysfunction. Compared to respondents without sleep problems, those who reported sleep problems at MIDUS 2 had significantly higher scores on the PSQI (M = 9.47 vs. 5.47, t(997) = 153.81, p<.001), indicating significantly poorer sleep quality. Third, use of sleep medication in the context of sleep complaints may contribute to functional limitations. The only variable available at MIDUS 1 referred to the use of sedatives without a doctor’s prescription; 105 MIDUS 1 respondents (2.3% of the sample) reported taking such medication, and inclusion of this variable in longitudinal models did not affect the relationship between MIDUS 1 sleep problems and MIDUS 2 functional limitations (data not shown). MIDUS 2 data, in contrast, included a specific question about the use of sleeping pills as part of the PSQI. To gauge the association of sleep medication use and ADLs cross-sectionally at MIDUS 2, we regressed numbers of basic and intermediate ADL limitations (separate models) on the 7 individual PSQI components, adjusted for age, sex, race, and education. The results showed that only the sleep disturbance (assessing trouble sleeping) and daytime dysfunction (assessing sleepiness during waking hours) components were associated with ADL limitations (p<.001 for both); use of sleep medication was not independently associated with either type of ADL (data not shown). Finally, sleep problems and functional limitations were both assessed using self-report measures, raising the possibility that unobserved subjective factors may underlie both sets of ratings. To probe this issue, we examined an objective measure of functional status – a 50 foot timed walk – and potential longitudinal effects of sleep complaints; walk time was measured in a sub-sample of MIDUS 2 respondents (n = 1,063). Linear regression models predicting walk time adjusted for sociodemographic, health, and health behavior covariates showed that on average respondents who reported chronic sleep problems at MIDUS 1 took more than 1 second longer to walk 50 feet than those who slept better (15.4 vs. 14.2 sec; p<.05); this association remained significant after adjusting for sleep problems at MIDUS 2 (p<.05). DISCUSSION The prospect of disability is a signature concern among aging adults, and as the population ages a better understanding of the causes of disability is increasingly important for individual health and quality of life as well as policies designed to improve overall population health. These analyses focused on subjectively poor sleep as a potential risk factor for disability. Reports of chronic sleep problems were associated with increases in basic and intermediate ADL limitations and with significantly greater odds of developing functional limitations at follow-up. In the case of basic ADL limitations, reporting poor sleep more than doubled the risk of incident disability. These associations were observed after accounting for a set of established disability risk factors, including advancing age, low educational attainment, chronic medical conditions, obesity, depression, and smoking. Moreover, with the exception of cross-time increases in intermediate ADL limitations, the relationship between sleep problems and disability did not vary with age (and for intermediate ADLs, differences based on sleep problems were more evident among younger and middle aged adults than older adults). Collectively, these results suggest that poor subjective sleep is a robust and independent risk factor for functional limitations, and that this risk is not limited to later life. Impaired or insufficient sleep has been linked to a variety of diseases and associated risk factors. Population-based studies have consistently shown that routine sleep duration that is shorter or longer than the optimal amount (typically 7 hours a night) predicts greater risk of mortality.8–10,24 Objectively assessed low sleep quality, often associated with disruptions due to sleep-disordered breathing, increases the risk of hypertension, diabetes, cardiovascular disease, stroke, disability, and mortality.25–28 Subjective sleep ratings have also been linked to a range of adverse health outcomes, including diabetes, cardiovascular disease, and cardiac mortality.14–16 In spite of these associations, relatively few studies have focused on disability risk associated with poor sleep, and fewer still have involved representative population samples. Regional studies in Italy29 and China30 have linked low subjective sleep quality to greater risk of disability, and a recent study in the US reported greater risk of incident disability in members of the clergy who reported sleep problems.17 The current study of a larger, community-based, nationally representative sample with a broader age range now adds robust support to the conclusion that poor sleep is an independent risk factor for disability in aging adults. Poor sleep may lead to impaired function by way of a number of paths. Physical activity, for example, is protective against functional decline in aging men and women. Subjective reports of poor sleep are linked to fatigue31 that is often sufficient to limit daily activities in older adults.32 Physical activity in adults who sleep poorly may thus be reduced to levels that increase risk of functional limitations. Poor sleep is also linked to dysregulation of diverse physiological systems. For example, studies using both objective and subjective assessments show that naturally occurring poor sleep is associated with higher circulating levels of inflammatory proteins.33–37 In parallel experimental studies, sleep restriction reliably produces elevated levels of inflammation both acutely and chronically.38–41 Inflammation in turn is linked prospectively with increased risk of disability,42 and experimental studies highlight a role for inflammatory proteins in the loss of muscle tissue that can result in sarcopenia43,44 and associated functional limitations. Poor sleep has also been shown to increase risk of obesity prospectively,36,45,46 and obesity increases risk of disability.6 There are thus multiple behavioral and physiological routes by which sleep may be linked to subsequent disability risk, although specific mechanisms have yet to be elucidated. This study has several important limitations. Principally, sleep problems and functional limitations were both reported by MIDUS respondents rather than assessed using objective measures. This leaves open the possibility that their associations are explained by one or more unmeasured variables that capture a common subjective dimension. A number of observations from the current study make this possibility less likely. In the sub-sample of respondents who completed an objective assessment of functional status – the timed walk – those who reported sleep problems 9–10 years earlier were significantly slower, independent of current sleep problems. Moreover, sleep problems were claimed by many MIDUS 1 respondents who reported no functional limitations, suggesting some independence between these measures, and those who did report sleep problems were twice as likely to develop substantial limitations in the intervening years. Finally, those who reported sleep problems had an average score on the PSQI, a widely used measure of sleep and sleep pathology, that was almost double that of people who reported none. All of these observations increase confidence that the observed links between sleep problems and functional status are not spurious. Another issue worth noting is that subjective reports of poor sleep often do not match the results of objective sleep assessments.13,47,48 Nonetheless, subjective complaints of poor sleep are meaningfully linked to health outcomes independently of objectively determined sleep patterns,49 the implication being that subjective and objective assessments capture unique aspects of sleep that are both important for understanding how sleep affects health. Against these limitations are substantial strengths, including a large, nationally representative sample, a large time difference between the waves of data collections for assessing long-term change, and the availability of data with which to control for confounding and to probe for alternative explanations. The current results suggest that subjective reports of poor sleep significantly increase disability risk independently of demographic characteristics, socioeconomic status, health, or health behavior, and that such risk extends to middle-aged men and women as well as older adults. These results add to a growing literature citing the importance of sleep to good health and the resulting need for effective ways to promote good sleep in the general population.50 This research was supported by grant R01-AG041750 (to EMF) from the National Institute on Aging. The MIDUS I study (Midlife in the U.S.) was supported by the John D. and Catherine T. MacArthur Foundation Research Network on Successful Midlife Development. The MIDUS II research was supported by a grant from the National Institute on Aging (P01-AG020166) to conduct a longitudinal follow-up of the MIDUS I investigation. Figure 1 Age X sleep problems interaction predicting longitudinal change in intermediate ADLs. Sleep problems were more likely to produce greater increases in intermediate ADL limitations among younger and middle-aged adults (<65 years old) than among older adults. Table 1 Descriptive statistics for longitudinal sample (N = 3,620). MIDUS 1 (1995–1996) MIDUS 2 (2004–2006) Variable Mean (SD) Range % Mean (SD) Range % Age 46.5 (12.5) 20–75 -- -- -- Sex (% female) 55.2 -- -- -- Race (% non-White) 6.3 -- -- -- Educational attainment  High school or GED 35.0 -- -- --  Some college 29.1 -- -- --  College or more 35.9 -- -- -- BADLs  Number of limitations 0.06 (0.3) 0–2 0.15 (0.4) 0–2  % with 1 or more BADLs 5.01 12.18 IADLs  Number of limitations 0.95 (1.8) 0–7 1.61 (2.2) 0–7  % with 1 or more IADLs 35.53 48.94 CIDI-SF depression (% Positive) 12.0 10.1 Chronic conditions 0.8 (1.1) 0–8 1.4 (1.5) 0–10 BMI categories  <25.00 (Normal weight) 41.4 32.3  25.00–29.99 (Overweight) 37.6 39.4  >=30.00 (Obese) 21.0 28.3 Smoking status  Current smoker 25.2 19.5  Ex-smoker 40.7 48.9  Never smoked 34.1 31.6 Sleep problems (% yes) 11.3 10.7 Table 2 Basic and Intermediate ADL limitations at MIDUS 2 regressed on MIDUS 1 sleep problems, functional limitations, and covariates (N = 3,620). Estimates were from Poisson regression models, and incident rate ratios (IRR) are shown for ease of interpretation. Basic ADLs Intermediate ADLs Variable IRR [95% CI] IRR [95% CI] Age 1.03*** [1.02,1.04] 1.02*** [1.02,1.03] Sex (female=1) 1.30*** [1.08,1.56] 1.29*** [0.07,0.15] Race (non-White=1) 0.88 [0.64,1.21] 0.85** [0.76,0.94] Educational attainment  High school or GED 1.90*** [1.50,2.41] 1.30*** [1.22,1.39]  Some college 1.42** [1.10,1.85] 1.10* [1.02,1.18]  College or more REF. REF. ADLs at wave 1 1.88*** [1.62,2.19] 1.16*** [1.14,1.17] Chronic conditions (MIDUS 2) 1.30*** [1.24,1.37] 1.17*** [1.15,1.19] BMI categories (MIDUS 2)  <25.00 (Normal weight) REF. REF.  25.00–29.99 (Overweight) 1.13 [0.89,1.44] 1.12** [1.04,1.20]  >=30 (Obese) 1.80*** [1.42,2.28] 1.52*** [1.42,1.63] CIDI-SF depression (MIDUS 2) 1.42** [1.12,1.79] 1.19*** [1.10,1.28] Smoking status (MIDUS 2)  Never smoked REF. REF.  Ex-smoker 1.26* [1.04,1.53] 1.11*** [1.05,1.18]  Current smoker 1.52** [1.19,1.94] 1.41*** [1.31,1.52] Sleep problems (MIDUS 1) 1.55*** [1.26,1.90] 1.28*** [1.20,1.37] * p<.05; ** p<.01; *** p<.001 Table 3 Logistic regression models predicting functional limitations at MIDUS 2. Odds ratios and 95% confidence intervals are shown. Basic and Intermediate ADL limitations were estimated in separate models. Only cases with no limitations at MIDUS 1 were included. Basic ADLs (n = 3,244) Intermediate ADLs (n = 1,329) Variable Odds Ratio [95% CI] Odds Ratio [95% CI] Age 1.04*** [1.03,1.05] 1.04*** [1.03,1.05] Sex (female=1) 1.73*** [1.32,2.27] 1.49*** [1.22,1.82] Race (non-White=1) 0.82 [0.46,1.46] 0.90 [0.61,1.35] Educational attainment  High school or GED 2.29*** [1.64,2.46] 1.39** [1.10,1.76]  Some college 1.55* [1.09,2.22] 1.21 [0.96,1.53]  College or more REF. REF. Chronic conditions (MIDUS 2) 1.54*** [1.40,1.69] 1.40*** [1.29,1.52] BMI categories (MIDUS 2)  <25.00 (Normal weight) REF. REF.  25.00–29.99 (Overweight) 1.42* [1.01,1.99] 1.38** [1.11,1.73]  >=30.00 (Obese) 2.81*** [1.99,3.97] 2.32*** [1.78,3.02] Depression (MIDUS 2) 1.42# [0.97,2.08] 1.82** [1.30,2.57] Smoking status (MIDUS 2)  Never smoked REF. REF.  Ex-smoker 1.55** [1.17,2.06] 1.01 [0.82,1.25]  Current smoker 2.14*** [1.49,3.08] 2.26*** [1.69,3.01] Sleep problems (MIDUS 1) 2.33*** [1.68,3.24] 1.70** [1.21,2.42] # p=.07; * p<.05; ** p<.01; *** p<.001 Conflict of Interest: The editor in chief has reviewed the conflict of interest checklist provided by the authors and has determined that the authors have no financial or any other kind of personal conflicts with this paper. Author Contributions: Lead author was responsible for all phases of the study, from conceptualization to data analysis to writing the manuscript. 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PMC005xxxxxx/PMC5118090.txt
LICENSE: This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. 8912860 1403 Am J Reprod Immunol Am. J. Reprod. Immunol. American journal of reproductive immunology (New York, N.Y. : 1989) 1046-7408 1600-0897 27753461 5118090 10.1111/aji.12589 NIHMS818217 Article Up-regulation of miR-203 expression induces endothelial inflammatory response: potential role in preeclampsia Wang Yuping Dong Qin Gu Yang Groome Lynn J. Department of Obstetrics and Gynecology, Louisiana State University Health Sciences Center – Shreveport, Shreveport, LA 71130 Address correspondence to: Yuping Wang, MD, PhD., Department of Obstetrics and Gynecology, Louisiana State University Health Sciences Center, Shreveport, LA 71130, (318)-675-5379 (work) and (318)-675-4671 (fax), ywang1@lsuhsc.edu 7 10 2016 18 10 2016 12 2016 01 12 2017 76 6 482490 This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. Problem To determine if miR-203 mediates endothelial inflammatory response in preeclampsia. Method of study Maternal vessel miR-203 expression was assessed by in situ hybridization. Suppressor of cytokine signaling-3 (SOCS-3) and ICAM expression was determined by immunostaining. Subcutaneous fat tissue sections from normal and preeclamptic pregnant women were used. MiR-203 induced inflammatory response was evaluated by measurements of IL-6, IL-8, ICAM, and VCAM expression and production, and neutrophil adhesion in endothelial cells (EC) transfected with miR-203 precursor, pre-miR-203. SOCS3 expression was also determined. Results Up-regulation of miR-203 and ICAM expression and down-regulation of SOCS-3 expression was demonstrated in maternal vessel endothelium in preeclampsia. Over-expression of miR-203 resulted in down-regulation of SOCS-3 expression and increases in production of IL-6, IL-8, ICAM and VCAM, and neutrophil adhesion in ECs. Conclusion As miR-203 is an inflammatory microRNA, increased miR-203 production/ expression in ECs could diminish anti-inflammatory activity and increase endothelial inflammatory response in preeclampsia. miR-203 SOCS-3 endothelial cells adhesion molecule inflammatory response preeclampsia Introduction Preeclampsia is a hypertensive and multi-system disorder in human pregnancy. Although the cause of preeclampsia is not clear, increased systemic endothelial inflammatory responsiveness is believed to be a major pathophysiological event of maternal vascular dysfunction in preeclampsia. Elevated maternal levels of inflammatory cytokines such as IL-6, IL-8, IL-16, and TNFα [1, 2] and endothelial adhesion molecules ICAM and VCAM [3] are all considered hallmarks of increased vascular inflammatory response in preeclampsia [4]. Moreover, increased inflammatory response also contributes to increased endothelial solute permeability [5, 6] and oxidative stress [7] in this pregnancy disorder. The impact of preeclampsia on women to their long-term health outcome is further emphasized by the findings of increased risk of cardiovascular diseases and intensiveness of inflammatory responses later in life in women who had preeclampsia during their pregnancy [8, 9]. However, the underlying cellular and molecular mechanism of increased inflammatory response in preeclampsia remains unclear. Cytokine signaling is negatively regulated by a family of proteins named suppressor of cytokine signaling (SOCS). The SOCS family has 8 members, including SOCS-1 to SOCS-7 and cytokine-induced STAT inhibitor (CIS). These molecules modulate cytokine signaling through several mechanisms, which include inactivation of Janus kinases (JAKs), blocking access of STATs to receptor binding sites, and ubiquitination of signaling proteins and their subsequent targeting to the proteasome [10, 11]. Among the SOCS family members, SOCS-3 has been well characterized to regulate IL-6, leptin, and erythropoietin through binding to their receptors [12, 13]. We previously reported that SOCS-3 expression was down-regulated in both maternal leukocytes and vascular endothelium in women with preeclampsia [14]. SOCS-3 expression was also reduced in placental trophoblasts in preeclampsia [15]. Although down-regulation of SOCS-3 activity/expression may lead to alteration of cytokine signaling and increased inflammatory responses, little is known about the mechanism of SOCS-3 regulation in vascular endothelial cells. Emerging evidence has shown that numerous microRNAs (miRNAs) are able to regulate immune and inflammatory responses and dysregulation of miRNA expression closely links to increased inflammatory responses [16]. For example, miR-146 regulates IL-2 expression and activation [17]. MiR-155 promotes Th17 relevant cytokines and is induced during macrophage inflammatory response [18]. Increased miR-203 expression is found to be associated with down-regulation of SOCS-3 expression in infected gingival epithelial cells [19]. In contrast, silencing miR-203 reverses the inhibition of SOCS-3 expression [19]. Moreover, over-expression of miR-203 significantly increases IL-6 and MMP-1 production in synovial fibroblasts [20]. However, the role of miR-203 associated with endothelial inflammatory response has never been studied in preeclampsia. To test the hypothesis that increased miR-203 expression may lead to down-regulation of SOCS-3 expression and result in increased endothelial inflammatory responses in preeclampsia, we determined miR-203 expression in maternal vessels from normal and preeclamptic pregnancies and assessed anti-inflammatory effects of SOCS-3 on endothelial cells. The role of miR-203 mediated endothelial inflammatory response was further evaluated by IL-6, IL-8 and ICAM expression and production, and neutrophil-endothelial adhesion in endothelial cells. Materials and Methods Sample collection Maternal subcutaneous fat tissue was collected during cesarean section delivery from normal and preeclamptic pregnancies. Freshly obtained subcutaneous fat tissue was fixed immediately with 10% formalin and then embedded with paraffin. Tissue sections were used for detection of miR-203 expression, and SOCS-3 and ICAM expression. Collection of subcutaneous fat tissue was approved by IRB at Louisiana State University Health Sciences Center – Shreveport (LSUHSC-S), LA. Normal pregnancy was defined as pregnancy with blood pressure (<140/90mmHg), absence of proteinuria and obstetrical and medical complications. Diagnosis of preeclampsia was defined as follows: sustained systolic blood pressure of ≥ 140 mmHg or a sustained diastolic blood pressure of ≥ 90mmHg on two separate readings; proteinuria measurement of 1+ or more on dipstick, or 24 hour urine protein collection with ≥ 300mg in the specimen. Smokers were excluded. None of the study subjects had signs of infection. To avoid clinical phenotypic differences in preeclamptic patients, patients complicated with HELLP syndrome (hemolysis, elevated liver enzyme and low platelet count), diabetes and/or renal disease were excluded. Subcutaneous fat tissue from 5 normal and 5 preeclamptic women were used in this study and the clinical characteristics of study subjects are presented in Table 1. Detection of miR-203 expression by in situ hybridization (ISH) MiR-203 expression was determined by in situ hybridization on formalin-fixed, paraffin-embedded subcutaneous fat tissue sections using the miRCURY LNA™ microRNA ISH Optimization Kit (FFPE) (product number 90010) purchased from Exiqon (Vedbaek, Denmark). The Kit contains 5′-DIG and 3′-DIG labeled LNA™ scrambled miRNA control probe (5′-DIG/gtgtaacacgtctatacgccca /DIG-3′) that was used as negative control and 5′-DIG labeled LNA™ U6 snRNA control probe (5′-DIG/cacgaatttgcgtgtcatcctt/DIG-3′) that was used as positive control. The miRCURY LNA™ 5′-DIG and 3′-DIG labeled detection probe specific to hsa-miR-203 (probe number 88079-15, 5′-DIG/tagtggtcctaaacatttca/DIG-3′) was also purchased from Exiqon. The staining procedure was performed following the manufacturer’s instruction. A concentration of 100nM for hsa-miR-203 probe was used in the assay. Counter staining was carried out with Nuclear Fast Red (Vector Laboratories, Burlingame, CA). Stained slides were then reviewed under an Olympus microscope (Olympus IX71), and images were captured by PictureFrame computer software (Uptronics, Sunnyvale, CA) and recorded to a microscope linked PC computer. Immunohistochemistry Maternal vessel endothelium expression for SOCS-3 and ICAM were examined by immunohistochemistry (IHC) of subcutaneous tissue sections as previously described [14]. Primary monoclonal antibody against SOCS-3 (ab16030) was purchased from Abcam Inc. (Cambridge, MA) and antibody for ICAM (SC-7891) was from Santa Cruz (San Diego, CA). The antibody concentration of 1.0μg/ml was used for both SOCS3 and ICAM staining. Stained slides were counterstained with Gill’s formulation hematoxylin. Tissue sections stained with secondary antibody only were used as controls. All slides stained with the same antibody were processed at the same time. Stained tissue slides were reviewed under an Olympus microscope, and images were captured. Endothelial isolation and culture Human umbilical cord vein endothelial cells (HUVECs) from normal term placentas were isolated as previously described [21, 22] and used in the study. Cells were cultured with endothelial growth medium (Lonza, Allendale, NJ) supplemented with hydrocortisone, ascorbic acid, bovine brain extract, epidermal growth factor (EGF), gentamicin sulfate amphotericin (GA-1000), and fetal bovine serum (FBS). HUVECs at passage 2 were used for pre-mir-203 transfection or SOCS-3 gene transfer experiments. Pre-miR-203 transfection miR-203 over-expression was carried out by transfection of pre-miR-203 (miR-203 precursor, AM17100) (Ambion) in endothelial cells using LipofectAMINE RNAiMAX transfection reagent (Invitrogen). Pre-miR-203 at a concentration of 50nM was used in the transfection assay. Cells transfected with pre-miR negative control (a random sequence miRNA) served as control. Total RNA was extracted by TRIzol reagent approximately 40h after transfection. miR-203 expression and mRNA expression for IL-6, IL-8, and ICAM were then determined by RT-PCR. Expression of U6 snRNA was determined and served as an endogenous control for miRNA-203 expression and GADPH was determined and served as an endogenous control for IL-6, IL-8, and ICAM mRNA expression. The primer sequences and accession number for miR-203, U6, IL-6, IL-8, ICAM, and GADPH are presented in Table 2. Primers for miR-203 (HP300235) and U6 (HP300001) were purchased from OriGene Technologies, Inc. (Rockville, MD). Primers for IL-6, IL-8, ICAM, and GADPH were synthesized by Integrated DNA Technologies (IDT, www.idtdna.com). For SOCS-3 expression, cells were lysed 24, 48, and 72hrs after pre-miR-203 transfection using protein lysis buffer containing 50mmol/L Tris, 0.5% NP40, 0.5% Triton X-100 with protease and phosphatase inhibitors. Total cellular protein was then collected and SOCS-3 protein expression was then determined. Protein expression Protein expression for SOCS-3 was determined by Western blot. Briefly, 10μg of total cellular protein was subject to electrophoresis (Bio-Red, Hercules, CA) and then transferred to nitrocellulose membranes. After blocking, the membrane was probed with SOCS-3 antibody (same antibody used for IHC) and then followed by a matched secondary antibody. An enhanced chemiluminescent (ECL) detection kit (Amersham Corporation, Arlington Heights, IL) and X-ray film were used to visualize the bound antibody. The membrane was then stripped and re-probed with β-actin antibody (Sigma). After scanned, the density of bands was analyzed by NIH Image J analysis program. β-actin expression was used to normalize SOCS-3 expression. Data were presented as mean ± SE from 4 independent experiments. Endothelial IL-6, IL-8, and ICAM production Endothelial production of IL-6, IL-8, and ICAM were measured in cell culture medium by enzyme-linked immunosorbent assay (ELISA). ELISA kits of IL-6, IL-8, and ICAM were purchased from R&D Systems, Inc. (Minneapolis, MN). All samples were measured in duplicate in each assay. All assays were carried out according to the manufacturer’s instructions. Within assay variations were <7% for all the assays. Myeloperoxidase (MPO) assay for neutrophil-endothelial adhesion MPO activity was assessed as an index of neutrophil adhesion. Neutrophils were isolated from healthy non-pregnant volunteers as previously described [23]. Neutrophil-endothelial adhesion assay was performed approximately 40h after pre-mir-203 transfection or 48h after SOCS-3 gene transfer. Freshly isolated neutrophils were applied to endothelial cells 30min after treatment with TNFα. The plates were then washed twice with 1.0ml PBS, and reaction was initiated by adding following reagents to each well in order: 750μl 80mM K2HPO4 (pH=4.5), 50 μl fresh 10%HETAB, 100 μl 16mMTMB. MPO activity was then measured by a VERSAmax microplate reader (Molecular Devices, Walpole, MA) at a wavelength of 450nm. Construction of SOCS-3/ZsGreen1 GFP vector Plasmid pZsGreen1-N1 (Clontech, Mountain View, CA) was used to construct SOCS-3 vector, pSOCS-3. Briefly, open reading frame of human SOCS-3 was amplified from human cDNA by polymerase chain reaction (PCR) using oligonucleotide to create restriction sites for Nhe I and Kpn I at 5′ and 3′ end of SOCS-3 sequence using following primers: sense primer 5′-AGCGCTAGCACCATGGTCACCCACAGCAAGTTTCC-3′ and antisense primer 5′-GGTGGTACCCAAAGCGGGGCATCGTACTG-3′. Restriction sites for Nhe I (5′GCTAGC3′) and Kpn I (5′GGTACC3′) are underlined, respectively. PCR was performed using pfx Taq polymerase (Invitrogen). PCR product and the vector pZsGreen1-N1 were digested with Nhe I (New England BioLabs, Inc. Ipswich, MA) and Kpn I (New England BioLabs, Inc.). After ligation, competent Ecoli-Top10 (Invitrogen, Carlsbad, CA) was transformed with plasmid and selected positive clones were amplified. SOCS-3 sequence was verified by Mclab (South San Francisco, CA). SOCS-3 gene transfer Electroporation was performed for SOCS-3 gene transfer. HUVECs at passage 2 were used for all experiments. For SOCS-3 (pSOCS-3/ZsGreen1) gene transfer, an aliquot of 20μg of plasmid DNA mixed with 5×106 cells in 600μl buffer per 4mm electroporation cuvette. A fixed electroporation was given with a capacitance of 950uf and 250v using a Bio-Rad Gene Pulser instrument (Bio-Rad, Hercules, CA). Cells transfected with ZsGreen1 vector only were used as control. Cell surface adhesion molecule ICAM and VCAM expression (see below), and neutrophil-endothelial adhesion assay were performed 24 hours after SOCS-3 gene transfer. Cells were also lysed with lysis buffer and total cellular protein was also collected for SOCS-3 protein expression determined by Western blot. Endothelial surface molecule ICAM and VCAM expression Endothelial surface molecule ICAM and VCAM expression was determined in cells transfected with SOCS-3 gene as previously described [21]. Briefly, cells were grown in 24 well/plate and fixed with 1% paraformaldehyde and then incubated with a primary antibody (mouse anti-human) to ICAM-1 (CD54) or VCAM-1 (CD106). Horseradish peroxidase-goat anti-mouse immunoglobulin G (Sigma) was used as the secondary antibody. Hydrogen peroxide (0.003%) and 3,30,5,50-tetramethylbenzidine (TMB) (0.1mg/ml) were used as substrate and color generation. The reaction was terminated by addition of 100μl of 8N H2SO4 to each well. Cells that reacted with secondary antibody only were used as background. After reaction, plates were read at 450 nm by VERSAmax microplate reader (Molecular Devices, Sunnyvale, CA, USA). All samples were tested in triplicate. Statistical Analysis Statistical analysis was performed with ANOVA or paired t-test by computer software Prism 5 (GraphPad Software, Inc. La Jolla, CA). Student-Newman-Keuls test was used as post hoc tests. Data is expressed as mean ± SE. A probability level of less than 0.05 was considered statistically significant. Results Endothelial miR-203 expression is increased in preeclampsia To determine if endothelial cells express miR-203 and whether altered miR-203 expression is present in preeclampsia, miR-203 expression was examined by in situ hybridization in subcutaneous fat tissue sections. Our results showed that miR-203 expression was weakly expressed in vessel endothelium in tissues from normotensive pregnant women, but strongly expressed in vessel endothelium in 4 out of 5 tissues from women with preeclampsia. Figure 1A shows representative miR-203 expression in maternal vessel endothelium from 2 normal and 2 preeclamptic subjects. An imaging panel showing miR-203 expression in maternal vessel endothelium from each study subject (5 normal and 5 preeclampsia) is presented in supplement Figure 1. These pictorial data clearly show miR-203 expression is up-regulated in maternal vessel endothelium in preeclampisa. Since SOCS-3 is a target of miR-203 and ICAM is an indicator of increased inflammatory response in endothelial cells, endothelial expression of SOCS-3 and ICAM was examined. As shown in Figure 1B, endothelial SOCS-3 expression was markedly reduced, which was consistent with our previous findings of reduced SOCS-3 expression in women with preeclampsia [14]. In contrast, endothelial ICAM expression was markedly increased in maternal vessels from women with preeclampsia compared to those from normal pregnant controls. These results suggest that up-regulation of miR-203 expression was associated with reduced SOCS-3 expression and increased ICAM expression in maternal vessel endothelium in women with preeclampsia. Over-expression of miR-203 results in down-regulation of SOCS-3 expression in endothelial cells SOCS-3 is an important cellular anti-inflammatory regulator. miR-203 targets SOCS-3 [24]. To determine if increased miR-203 production/expression could down-regulate SOCS-3 expression in endothelial cells, endothelial cells were transfected with miR-203 precursor, pre-mir-203, and cells were collected 24, 48, and 72hrs after pre-mir-203 transfection. Total protein and RNA were extracted. As shown in Figure 2, mature miR-203 expression was markedly increased in cells transfected with pre-mir-203 compared to that in control cells (Figure 2A). In contrast, SOCS-3 expression was significantly reduced in cells transfected with pre-mir-203 and this inhibitory effect was in a time-dependent manner. The bar graph shows relative SOCS-3 protein expression in endothelial cells at 24, 48, and 72hrs after pre-mir-203 transfection, p<0.05, Figure 2B. Data are means ± SE from 4 independent experiments. Over-expression of miR-203 promotes endothelial inflammatory response As shown in Figure 1, increased miR-203 expression and increased ICAM expression were seen in maternal vessel endothelium. To further determine the consequences of increased miR-203 expression in endothelial cells, mRNA expression for IL-6, IL-8, and ICAM was examined in cells with or without transfection of pre-mir-203. Similar to miR-203 expression, mRNA expression for IL-6, IL-8 and ICAM was also significantly increased in cells transfected with pre-mir-203, Figure 3A. We further determined endothelial production of IL-6, IL-8, and ICAM by measuring IL-6, IL-8, and ICAM concentrations in cell culture medium. In this experiment, fresh medium was replaced 40 hours after pre-mir-203 transfection, and then medium was collected at 2, 4, and 8hrs and measured for IL-6, IL-8, and ICAM production by ELISA. Consistent with up-regulation of IL-6, IL-8 and ICAM mRNA expression, endothelial production of IL-6, IL-8 and ICAM were all significantly increased in cells transfected with pre-mir-203 compared to control cells and the increased IL-6, IL-8 and ICAM production was in a time-dependent manner, Figure 3B. These results clearly show that increase in miR-203 expression/production promotes endothelial expression and production of inflammatory cytokines and adhesion molecules. Figure 3C shows neutrophil adhesion assessed by measuring of neutrophil myeloperoxidase (MPO) activity in endothelial cells transfected with pre-mir-203. Cells transfected with scramble pre-mir served as control. 40hrs after pre-mir-203 transfection, cells were treated with or without TNFα at a concentration of 50ng/ml for 2hrs and then freshly isolated neutrophils (1×105 cells/well in 24 well plate) were added to the cell culture. MPO activity was then determined. Our results showed that neutrophil adhesion was significantly increased in cells transfected with pre-mir-203 vs. control cells, p<0.05, Figure 3C. The increased neutrophil adhesion to endothelial cells was further increased in cells treated with TNFα. These results provide further evidence that up-regulation of miR-203 expression promotes endothelial inflammatory response. SOCS-3 decreases endothelial inflammatory response As shown in Figure 2 and 3, down-regulation of SOCS-3 expression was relevant to increased IL-6, IL-8, and ICAM expression and production in endothelial cells transfected with pre-miR-203. SOCS-3 is a target of miR-203. Reduced SOCS-3 expression has been demonstrated in maternal vessel endothelium in preeclampsia [14]. To further investigate if SOCS-3 modulates inflammatory response in endothelial cells, we constructed a SOCS-3/ZsGreen1 vector and transferred it into endothelial cells to determine if increase in SOCS-3 expression could increase anti-inflammatory activity in endothelial cells. Cells transfected with empty GFP vector were used as control. Cell adhesion molecule ICAM and VCAM expression and neutrophil-endothelial adhesion assay were performed 24hrs after SOCS3 gene transfer. Our results showed that SOCS-3 expression was increased in endothelial cells transfected with SOCS-3 gene (Figure 4A). In contrast, ICAM and VCAM expression were significantly reduced in cells transfected with SOCS-3 compared to control cells, p<0.01 (Figure 4B). Moreover, increased neutrophil-endothelial adhesion induced by TNFα were also significantly suppressed in cells transfected with SOCS-3 gene compared to those of controls, p<0.05 and p<0.01, respectively, Figure 4C. Discussion In the present study, we, for the first time, showed increased miR-203 expression in maternal vessel endothelium in women with preeclampsia compared to that in normal pregnant controls. We further found that over-expression of miR-203 expression could down-regulate cytokine suppressor SOCS-3 expression in endothelial cells, which was accompanied by increased endothelial inflammatory response. This was demonstrated by increased endothelial expression/production of IL-6, IL-8 and ICAM and increased neutrophil-endothelial adhesion in cells with over-expression of miR-203. The observation of up-regulation of ICAM expression in maternal vessel endothelium from preeclampsia is consistent as previously reported by Leik et al [25]. Thus, our findings are significant and provide new evidence that altered miR-203 expression could contribute to increased endothelial inflammatory response in preeclampsia. Although the number of maternal vessel samples in each group was small with different gestational age at delivery and primigravida between normal and preeclamptic pregnancies, and range of BMI within each of the groups, we believe that our ISH finding of increased miR-203 expression in maternal vessel endothelium from preeclampsia is reliable because the consistency of miRNA expression tested by ISH and real-time PCR was demonstrated in our previous published placental miRNA works [26]. MiRNAs have been recognized as a class of novel inflammatory regulators by modification of target genes at different levels through anti-inflammatory or pro-inflammatory signaling cascades in the cardiovascular system. Studies have shown that many miRNAs are involved in endothelial inflammation by directly or indirectly targeting the genes that regulate leukocyte recruitment. For example, miR-126 could inhibit VCAM-1 expression and limit leukocyte adherence to endothelial cells [27], while TNF-induced endothelial miR-31 and miR-17-3p expression could in turn suppress endothelial E-selectin and ICAM-1 expression induced by TNF stimulation [28]. An animal study has also shown that miR-181b inhibition exacerbated endotoxin-induced NF-κB activity, leukocyte influx, and lung injury [29]. Moreover, up-regulation of miR-146a, miR-9, miR-204 and miR-367 expression in senescent endothelial cells was also reported, and their predicted target genes include Toll-like receptor signaling (TLR) pathway, which is well known to play a pivotal role in inflammatory response, a key feature of senescence (inflammaging) [30]. It seems very likely that alteration of anti-inflammatory miRNA expression/production could directly disturb protective machinery of anti-inflammatory adaptive inflammatory responses. MiR-203 was considered a skin- and keratinocyte-specific miRNA that was originally reported to be associated with common chronic inflammatory disorders in skin [31]. Up-regulation miR-203 expression was reported in psoriasis-affected skin plaques [32] and in diabetic foot ulcer skin tissues [33]. In the present study, we found increased miR-203 expression was in line with reduced SOCS-3 expression and increased ICAM expression in maternal vessel endothelium in women with preeclampsia compared to normal pregnant controls. Altered miR-203 expression was also reported in maternal plasma and placental tissue from preeclampsia [34]. It would be ideal to corroborate the findings of increased miR-203 in maternal vessel endothelium from preeclamptic pregnant women using a second approach such as real-time PCR. However, it is unlikely to obtain or isolate endothelial cells from systemic vasculature from pregnant women and to quantify the difference in miR-203 expression between normal and preeclamptic pregnancies, but our ISH results (supplement Figure 1) clearly showed that miR-203 expression is markedly increased in maternal vessel endothelium from preeclamptic pregnancies compared to that from normal pregnant women. Because SOCS-3 is a target of miR-203 [24] and SOCS-3 is an anti-inflammatory mediator, we then tested the consequences of miR-203 mediated inflammatory response in endothelial cells and determined effects of increased miR-203 expression on SOCS-3 and ICAM expression, and endothelial inflammatory response in cells transfected with miR-203 precursor, pre-miR-203. As we expected, miR-203 expression was dramatically increased in cells transfected with pre-mir-203. Moreover, cells transfected with pre-miR-203 resulted in a time-dependent down-regulation of SOCS-3 expression, which is inversely related to increased mRNA expression and production of inflammatory cytokine IL-6 and IL-8 and endothelial adhesion molecule ICAM in endothelial cells. These findings clearly showed consequences of miR-203 up-regulation mediated increased inflammatory responsiveness in endothelial cells. MiR-203 mediated increased endothelial inflammatory response was further assessed by neutrophil-endothelial adhesion assay in endothelial cells transfected with miR-203 precursor pre-miR-203 in the presence or absence of TNFα. We found significant increases in neutrophil adhesion to endothelial cells, in which cells were transfected with pre-miR-203 compared to cells transfected with control pre-miRNA. We further found that pre-miR-203 could promote increased neutrophil adhesion to endothelial cells induced by TNFα. These data further demonstrate that increase in endothelial miR-203 expression could stimulate endothelial inflammatory response. We also noticed that pre-miR-203 transfection could induce TNFα expression in endothelial cells (data not shown). Although we did not validate the targeting effects of miR-203 on TNFα in endothelial cells, a study conducted by Primo et al, by screening a panel of cytokines that are up-regulated in psoriatic skin induced by miR-203, demonstrated that miR-203 could regulate inflammatory cytokine production of TNFα, IL-24, IL-15, and IL-17A, etc [35]. Their study suggests that miR-203 could serve to fine-tune cytokine signaling and may dampen skin immune responses by altering key pro-inflammatory cytokines [35]. SOCS-3 is an important anti-inflammatory mediator. Down-regulation of SOCS-3 expression by miR-203 is associated with increased endothelial inflammatory response. To further study endothelial anti-inflammatory activity mediated by SOCS-3, SOCS-3 gene transfer was used as a testing model, and endothelial ICAM and VCAM expression and neutrophil-endothelial adhesion were then determined. Our results clearly showed that endothelial ICAM and VCAM expression was significantly reduced in cells transfected with SOCS-3 gene. Moreover, over-expression of SOCS-3 could also suppress TNFα-induced increased neutrophil adhesion to endothelial cells. This data implies that down-regulation of SOCS-3 and increased inflammatory response in maternal vasculature could be consequences of increased miR-203 expression in preeclampsia. Taken together, in this study we found that increased miR-203 expression is associated with reduced anti-inflammatory mediator SOCS-3 expression and increased endothelial adhesion molecule expression in maternal vessel endothelium in preeclampsia. We also demonstrated that over-expression of miR-203 resulted in increased inflammatory cytokines IL-6 and IL-8 and endothelial adhesion molecule ICAM expression/production and promoted neutrophil-endothelial adhesion. These findings provide considerable evidence that increased miR-203 expression could contribute to increased endothelial inflammatory response in preeclampsia. Supplementary Material Supp Fig S1 This study was supported in part by grants from National Institute of Health, NHLBI R01 HL65997 and NICHD R21HD076289 to Yuping Wang. Figure 1 Expression of miR-203, SOCS-3, and ICAM in maternal vessel endothelium in normal and preeclamptic pregnancies Subcutaneous fat tissue sections were used. A: Representative images for miR-203 expression in maternal vessels from 2 normal and 2 preeclamptic pregnancies. miR-203 expression was not expressed in maternal vessels from normal pregnancies. However, strong miR-203 expression was observed in vessel endothelium in preeclampsia. a and c: normal; b and d: preeclampsia; e: negative control; and f: positive control U6 staining. a–d: bar = 50micron and e–f: bar = 100 micron. B: Representative images for SOCS-3 and ICAM expression in maternal vessels from normal and preeclamptic pregnancies. SOCS-3 expression was markedly reduced and ICAM expression was markedly increased in maternal vessel endothelium from preeclampsia compared to normal pregnant controls. SOCS-3 and ICAM expression was undetectable in tissue sections stained with secondary antibody only (not shown). a and b: SOCS-3; c and d: ICAM. a and c: normal pregnancies; b and d: preeclampsia. bar = 50micron. Figure 2 Transfection of miR-203 precursor results in up-regulation of miR-203 expression and down-regulation of SOCS-3 expression in endothelial cells A: miR-203 expression was dramatically increased in endothelial cells transfected with pre-miR-203. U6 expression was determined as internal control for each sample. Lane 1–3: control cells were transfected with pre-mir control and lane 4–6: cells were transfected with pre-miR-203. B: The upper sequences show the miRNA response elements (MREs) of miR-203 to the 3′ UTR of SOCS-3 mRNA that was predicted by TargetScan and miRBase Target. Red lined indicates the “seed” regions. The blot shows that SOCS-3 protein expression in endothelial cells transfected with pre-miR-203 at 24, 48, and 72hrs compared to untransfected control cells (C). Down-regulation of SOCS-3 expression was time-dependent in endothelial cells transfected with pre-miR-203. The bar graph was expressed as mean ± SE from 4 independent transfection experiments. * p<0.05: pre-miR-203 transfected cells vs. C. Statistical analysis was done by ANOVA and Newman-Keuls test was used as post hoc tests. Figure 3 Increased IL-6, IL-8, and ICAM expression and production, and increased neutrophil-endothelial adhesion in endothelial cells transfected with pre-miR-203 A: mRNA expression for IL-6, IL-8, and ICAM was increased in endothelial cells transfected with pre-miR-203 compared to control cells. Lane 1–3: control cells transfected with pre-miR control and lane 4–6: cells transfected with pre-miR-203. B: Consistent with mRNA expression, IL-6, IL-8, and ICAM production was also significantly increased in cells transfected with pre-miR-203 compared to cells transfected with pre-miR controls. In this experiment, medium was changed 40hrs after transfection and newly added medium was then collected at 2, 4, and 8hrs and medium concentrations for IL-6, IL-8, and ICAM were measured by ELISA. IL-6, IL-8 and ICAM production was time-dependent increased in cells with or without pre-miR-203 transfection. However, cells transfected with pre-miR-203 produced significantly more IL-6, IL-8 and ICAM than cells transfected with control pre-miR. Data are presented as means ± SE from 6 independent experiments, * p<0.05 and ** p<0.01: pre-miR-203 transfected cells vs. control cells at each time point (tested by paired t-test). ˆ p<0.05 and ˆˆ p<0.01: control cells at 8hrs vs. 2hrs, and ## p<0.01: pre-miR-203 transfected cells at 4hrs or 8hrs vs. 2hrs (tested by ANOVA and Newman-Keuls test was used as post hoc tests), respectively. C: MPO activity in endothelial cells transfected with pre-miR-203 with or without TNFα stimulation. Cells transfected with pre-miR control served as control. Neutrophil-endothelial adhesion was significantly increased in cells transfected with pre-miR-203 and further increased when TNFα was present in the culture. Data are expressed as mean ± SE from 3 independent experiments each in triplicate. * p<0.05 and ** p<0.01: pre-miR-203 transfected cells vs. controls; # p<0.05: pre-miR-203 transfected cells treated with TNFα vs. without TNFα treatment (by paired t-test), respectively. Figure 4 Reduction of ICAM and VCAM expression and neutrophil-endothelial adhesion in endothelial cells transfected with SOCS-3 gene A: SOCS-3 protein expression is increased in ECs transfected with SOCS-3 gene compared to control cells. Total cellular protein was collected 48hrs after transfection. B: Adhesion molecule ICAM and VCAM expression in ECs with or without transfection of SOCS-3 gene. Cells transfected with SOCS-3 expressed less ICAM and VCAM compared to the control cells, Data are presented as means ± SE from 4 independent experiments, ** p<0.01: SOCS-3 transfected cells vs. control cells. C: Neutrophil-endothelial adhesion assessed by MPO activity in ECs with or without transfection of SOCS-3 gene. Data are presented as means ± SE from 4 independent experiments. In control cells, MPO activity was dose-dependently increased in cells treated with TNFα, ˆ p < 0.05 and ˆˆ p < 0.01: cells treated with TNFα vs. untreated cells. Data was analyzed by ANOVA with Student-Newman-Keuls test as post hoc test. MPO activity was significantly reduced when cells were transfected with SOCS-3 gene compared to the control cells treated with same dose of TNFα, * p<0.05 and ** p<0.01, respectively. Paired t-test was used for data analysis. MPO activity was not statistically significant in cells transfected with SOCS-3 with or without treatment of TNFα (analyzed by ANOVA). Table 1 Clinical information of study subjects from which maternal vessels were examined in the study Variables Normal (n=5) Preeclampsia (n=5) p value Maternal age (years) 29 ± 7 (20–37) 26 ± 5 (20–33)   0.4633 Racial Status  White 1 0 ND  Black 3 5 ND  Other 1 0 ND BMI 35 ± 11 (23–51) 34 ± 8 (26–44)   0.8683 Blood Pressure (mmHg)  Systolic   113 ± 11 (101–130) 164 ± 15 (148–182) 0.0003  Diastolic 70 ± 7 (60–78) 102 ± 7 (93–113)     <0.0001   Primigravida 0 4 ND Proteinuria N/A 1 – 4+ ND Uric acid N/A 6.7±1.9 (4.1–9.4) ND Gestational Age  at delivery (weeks)     37+3 ± 2+2 (34+3–39+5) 31+6 ± 3+4 (28–36+2) 0.0317 Data are expressed as mean ± SD (range). ND: not determined. Table 2 Primer sequences used in the study Gene Name Primer Sequences Accession # miR-203a-3p Forward: 5′-GTGAAATGTTTAGGACCAC-3′ MIMAT0000264 Reverse: 5′-GAACATGTCTGCGTATCTC-3′ U6 Forward: 5′-CTCGCTTCGGCAGCACAT-3′ NR_004394.1 Reverse: 5′-TTTGCGTGTCATCCTTGCG-3′ IL-6 Forward: 5′-AAAGAGGCACTGGCAGAAAA-3′ NM_000600 Reverse: 5′-AGCTCTGGCTTGTTCCTCCTCAC-3′ IL-8 Forward: 5′-TCTGCAGCTCTGTGTGAAGG-3′ NM_000584 Reverse: 5′-ACTTCTCCACAACCCTCTGC-3′ ICAM-1 Forward: 5′-GCTTTCCGGCGCCCAACGTGATTCTGA-3′ NM_000201 Reverse: 5′-ACTCACACAGGACACGAA GCTCCCGGGTCT-3′ GADPH Forward: 5′-CAAAAGGGTCATCATCTCTGC-3′ NM_002046 Reverse: 5′-AGTTGTCATGGATGACCTTGG-3′ 1 Lyall F Greer IA Boswell F Macara LM Walker JJ Kingdom JCP The cell adhesion molecule, VCAM-1, is selectively elevated in serum in pre-eclampsia: does this indicate the mechanism of leucocyte activation? Br J Obstet Gynaecol 1994 101 485 487 7517182 2 Haller H Ziegler E-M Homuth V Drab M Eichhorn J Nagy Z Busjahn A Vetter K Luft FC Endothelial adhesion molecules and leukocyte integrins in preeclamptic patients Hypertension 1997 29 291 296 9039117 3 Taylor RN Crombleholme WR Friedman SA Jones LA Casal DC Roberts JM High plasma cellular fibronectin levels correlate with biochemical and clinical features of preeclampsia but cannot be attributed to hypertension alone Am J Obstet Gynecol 1991 165 895 901 1951550 4 Redman CWG Sacks GP Sargent IL Preeclampsia: An excessive maternal inflammatory response to pregnancy Am J Obstet Gynecol 1999 180 499 506 9988826 5 Wang Y Gu Y Granger DN Roberts JM Alexander JS Endothelial junctional protein redistribution and increased monolayer permeability in HUVECs isolated during preeclampsia Am J Obstet Gynecol 2002 186 214 220 11854638 6 Zhang Y Gu Y Li H Lucas MJ Wang Y Increased endothelial monolayer permeability is induced by serum from women with preeclampsia but not by serum from women with normal pregnancy or that are not pregnant Hypertens Pregn 2003 22 121 131 7 Davidge ST Oxidative stress and altered endothelial cell function in preeclampsia Sem Reprod Endocrinol 1998 16 65 73 8 Bellamy L Casas JP Hingorani AD Williams DJ Pre-eclampsia and risk of cardiovascular disease and cancer in later life: systematic review and meta-analysis BMJ 2007 335 7627 974 17975258 9 Freeman DJ McManus F Brown EA Cherry L Norrie J Ramsay JE Clark P Walker ID Sattar N Greer IA Short- and long-term changes in plasma inflammatory markers associated with preeclampsia Hypertension 2004 44 708 714 15452036 10 Krebs DL Hilton DJ SOCS proteins: negative regulators of cytokine signaling Stem Cells 2001 19 378 387 11553846 11 Alexander WS Starr R Metcalf D Nicholson SE Farley A Elefanty AG Brysha M Kile BT Richardson R Baca M Zhang JG Willson TA Viney EM Sprigg NS Rakar S Corbin J Mifsud S DiRago L Cary D Nicola NA Hilton DJ Suppressors of cytokine signaling (SOCS): negative regulators of signal transduction J Leukoc Biol 1999 66 588 592 10534114 12 Alexander WS Hilton DJ The role of suppressors of cytokine signaling (SOCS) proteins in regulation of the immune response Annu Rev Immunol 2004 22 503 529 15032587 13 Howard JK Flier JS Attenuation of leptin and insulin signaling by SOCS proteins Trends Endocrinol Metab 2006 17 365 371 17010638 14 Wang Y Lewis DF Gu Y Zhao S Groome LJ Elevated maternal soluble gp130 and IL-6 levels and reduced gp130 and SOCS-3 expressions in women with preeclampsia Hypertension 2011 57 336 342 21173340 15 Zhao S Gu Y Dong Q Fan R Wang Y Altered IL-6 receptor, IL-6R and gp130, production and expression and decreased SOCS-3 expression in placentas from women with preeclampsia Placenta 2008 29 1024 1028 18986700 16 O’Connell RM Rao DS Baltimore D microRNA regulation of inflamatory responses Annu Rev Immunolm 2012 30 295 312 17 Sonkoly E Ståhle M Pivarcsi A MicroRNAs and immunity: novel players in the regulation of normal immune function and inflammation Semin Cancer Biol 2008 18 131 140 18291670 18 O’Connell RM Kahn D Gibson WS Round JL Scholz RL Chaudhuri AA Kahn ME Rao DS Baltimore D MicroRNA-155 promotes autoimmune inflammation by enhancing inflammatory T cell development Immunity 2010 33 607 619 20888269 19 Moffatt CE Lamont RJ Porphyromonas gingivalis induction of microRNA-203 expression controls suppressor of cytokine signaling 3 in gingival epithelial cells Infect Immun 2011 79 2632 2637 21536793 20 Stanczyk J Ospelt C Karouzakis E Filer A Raza K Kolling C Gay R Buckley CD Tak PP Gay S Kyburz D Altered expression of microRNA-203 in rheumatoid arthritis synovial fibroblasts and its role in fibroblast activation Arthritis Rheum 2011 63 373 381 21279994 21 Wang Y Adair CD Coe L Weeks JW Lewis DF Alexander JS Activation of endothelial cells in preeclampsia: Increased neutrophil-endothelial adhesion correlates with up-regulation of adhesion molecule P-selectin in human umbilical vein endothelial cells isolated from preeclampsia J Soc Gynecol Investig 1998 5 237 243 22 Jaffe EA Nachman RL Becker CG Minick CR Culture of human endothelial cells derived from umbilical veins. Identification by morphologic and immunologic criteria J Clin Invest 1973 52 2745 2756 4355998 23 Wang Y Adair CD Weeks JW Lewis DF Alexander JS Increased neutrophil-endothelial adhesion induced by placental factors is mediated by platelet-activating factor in preeclampsia J Soc Gynecol Investig 1999 6 136 141 24 Wei T Orfanidis K Xu N Janson P Ståhle M Pivarcsi A Sonkoly E The expression of microRNA-203 during human skin morphogenesis Exp Dermatol 2010 19 854 856 20698882 25 Leik CE Walsh SW Neutrophils infiltrate resistance-sized vessels of subcutaneous fat in women with preeclampsia Hypertension 2004 44 72 77 15148293 26 Gu Y Sun J Groome LJ Wang Y Differential miRNA expression profiles between the first and third trimester human placentas Am J Physiol Endocrinol Metab 2013 304 E836 843 23443922 27 Harris TA Yamakuchi M Ferlito M Mendell JT Lowenstein CJ MicroRNA-126 regulates endothelial expression of vascular cell adhesion molecule 1 Proc Natl Acad Sci U S A 2008 105 1516 1521 18227515 28 Suárez Y Wang C Manes TD Pober JS Cutting edge: TNF-induced microRNAs regulate TNF-induced expression of E-selectin and intercellular adhesion molecule-1 on human endothelial cells: feedback control of inflammation J Immunol 2010 184 21 25 19949084 29 Sun X Icli B Wara AK Belkin N He S Kobzik L Hunninghake GM Vera MP MICU Registry Blackwell TS Baron RM Feinberg MW MicroRNA-181b regulates NF-κB-mediated vascular inflammation J Clin Invest 2012 122 1973 1990 22622040 30 Olivieri F Lazzarini R Recchioni R Marcheselli F Rippo MR Di Nuzzo S Albertini MC Graciotti L Babini L Mariotti S Spada G Abbatecola AM Antonicelli R Franceschi C Procopio AD MiR-146a as marker of senescence-associated pro-inflammatory status in cells involved in vascular remodelling Age (Dordr) 2013 35 1157 1172 22692818 31 Sonkoly E Ståhle M Pivarcsi A MicroRNAs: novel regulators in skin inflammation Clin Exp Dermatol 2008 33 312 315 18419608 32 Sonkoly E Wei T Janson PC Sääf A Lundeberg L Tengvall-Linder M Norstedt G Alenius H Homey B Scheynius A MicroRNAs: novel regulators involved in the pathogenesis of psoriasis? PLoS One 2007 2 e610 17622355 33 Liu J Xu Y Shu B Wang P Tang J Chen L Qi S Liu X Xie J Quantification of the differential expression levels of microRNA-203 in different degrees of diabetic foot Int J Clin Exp Pathol 2015 8 13416 13420 26722550 34 Yang S Li H Ge Q Guo L Chen F Deregulated microRNA species in the plasma and placenta of patients with preeclampsia Mol Med Rep 2015 12 527 534 25738738 35 Primo MN Bak RO Schibler B Mikkelsen JG Regulation of pro-inflammatory cytokines TNFα and IL24 by microRNA-203 in primary keratinocytes Cytokine 2012 60 741 748 22917968
PMC005xxxxxx/PMC5118104.txt
LICENSE: This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. 9304420 2335 Nucl Med Biol Nucl. Med. Biol. Nuclear medicine and biology 0969-8051 1872-9614 27744117 5118104 10.1016/j.nucmedbio.2016.07.008 NIHMS822981 Article Targeted therapy of osteosarcoma with radiolabeled monoclonal antibody to an insulin-like growth factor-2 receptor (IGF2R) Geller David S. 123 Morris Jonathan 1 Revskaya Ekaterina 4 Kahn Mani 1 Zhang Wendong 1 Piperdi Sajida 2 Park Amy 2 Koirala Pratistha 237 Guzik Hillary 5 Hall Charles 6 Hoang Bang 123 Yang Rui 123 Roth Michael 23 Gill Jonathan 23 Gorlick Richard 237 Dadachova Ekaterina 348 1 Department of Orthopaedic Surgery, Montefiore Medical Center and The Children’s Hospital at Montefiore, Bronx, NY, USA 2 Department of Pediatrics, Montefiore Medical Center and The Children’s Hospital at Montefiore, Bronx, NY, USA 3 Albert Einstein College of Medicine, Bronx, NY, USA 4 Department of Radiology, Nuclear Medicine, Montefiore Medical Center, Bronx, NY, USA 5 Analytical Imaging Facility, Albert Einstein College of Medicine, Bronx, NY, USA 6 Department of Epidemiology and Population Health, Albert Einstein College of Medicine, Bronx, NY, USA 7 Department of Molecular Pharmacology, Albert Einstein College of Medicine, Bronx, NY, USA 8 Department of Microbiology and Immunology, Albert Einstein College of Medicine, Bronx, NY, USA Requests for reprints: David S. Geller, M.D., Department of Orthopaedic Surgery, Montefiore Medical Center, 3400 Bainbridge Avenue, Bronx, NY 10467. Phone: 718-920-4429; dgeller@montefiore.org 23 10 2016 30 7 2016 12 2016 01 12 2017 43 12 812817 This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. Introduction Osteosarcoma overall survival has plateaued around 70%, without meaningful improvements in over 30 years. Outcomes for patients with overt metastatic disease at presentation or who relapse are dismal. In this study we investigated a novel osteosarcoma therapy utilizing radioimmunotherapy (RIT) targeted to IGF2R, which is widely expressed in OS. Methods Binding efficiency of the Rhenium-188(188Re)-labeled IGF2R-specific monoclonal antibody (mAb) to IGF2R on OS17 OS cells was assessed with Scatchard plot analysis. Biodistribution studies were performed in heterotopic murine osteosarcoma xenografts. Tumor growth was compared over a 24-day period post-treatment between mice randomized to receive 188Re-labeled IGF2R-specific murine mAb MEM-238 (188Re-MEM-238) or one of three controls—188Re-labeled isotype control mAb, unlabeled MEM-238,or no treatment. Results Results demonstrate the radioimmunoconjugate had a high binding constant to IGF2R. Both 188Re-MEM-238 and the isotype control had similar initial distribution in normal tissue. After 48 hours 188Re-MEM-238 exhibited a 1.8 fold selective uptake within tumor compared to the isotype control (p=0.057). Over 24 days, the tumor growth ratio was suppressed in animals treated with RIT compared to unlabeled and untreated controls (p=0.005) as demonstrated by a 38% reduction of IGF2R expressing osteosarcoma cells in the RIT group (p=0.002). Conclusions In conclusion, given the lack of new effective therapies in osteosarcoma, additional investigation into this target is warranted. Advances in Knowledge High expression of IGF2R on osteosarcoma tumors, paired with the specificity and in vivo anti-cancer activity of 188Re-labeled IGF2R-specific mAb suggests that IGF2R may represent a novel therapeutic target in the treatment of osteosarcoma. Implications for Patient Care This targeted approach offers the benefits of being independent of a specific pathway, a resistance mechanism, and/or an inherent biologic tumor trait and therefore is relevant to all OS tumors that express IGF2R. OS Radioimmunotherapy Insulin-like Growth Factor-2 Receptor (IGF2R) Rhenium-188 INTRODUCTION Osteosarcoma (OS) is the most common non-hematologic primary bone malignancy [2, 3]. Additionally it is the most common primary malignant bone tumor and the fifth most common primary malignancy among adolescents and young adults [4]. Unfortunately, overall 5 year survival has plateaued at approximately 70%, with no meaningful improvement realized in over 30 years [3-6]. Patients with metastatic disease have poor outcomes, with pulmonary and osseous metastases portending an overall survival of less than 40% and 20%, respectively. Recent studies have demonstrated an inability to improve outcomes using conventional chemotherapy strategies, underscoring the need for novel treatment approaches [7]. Overexpression of the cation-independent mannose-6-phosphate/insulin-like growth factor-2 receptor (IGF2R) has been demonstrated across a panel of OS cell lines [1]. Additionally, a single nucleotide polymorphism (SNP) within a haplotype block in IGF2R has been associated with an increased risk of developing OS [8], however, the role of IGF2R in the pathogenesis of OS is still being investigated. Although IGF2R is expressed normally across a wide array of tissue types, the consistent overexpression of IGF2R in OS suggests it may serve as a valuable therapeutic target. Radioimmunotherapy (RIT) is a method of delivering cytotoxic radiation therapy in a targeted fashion whereby an antigen-specific antibody is bound to either an α- or β-emitting radioisotope [9, 10]. The technique has been successfully employed in a number of challenging oncologic settings [11, 12]. RIT delivers cytocidal radiation to the targeted cell, is less affected by the multidrug resistance ensuing mechanisms than chemotherapy, and does not depend on the immune status of a patient or microenvironmental fluctuations the way immunotherapy with naked antibodies or T cells does. It permits for systemic administration, antibody-mediated specificity, and physical cytocidal damage in a manner which is well-tolerated by the patient. The purpose of this study was to investigate a novel therapeutic approach to OS, using IGF2R-targeted RIT. We have selected 188-Rhenium (188Re), a powerful β-emitter (Emax=2.01 meV) with relatively short physical half-life of 16.9 hrs for radiolabeling the IGF2R-specific antibody. 188Re has been successfully used in both pre-clinical and clinical RIT with insignificant side effects [12 and references therein]. We hypothesized that 188Re-labeled IGF2R-specific mAb will serve to effectively target OS tumor cells and that 188Re will be able to deliver high tumoricidal doses to the tumors without toxicity to healthy tissues. EXPERIMENTAL DESIGN Cell lines OS-17 is a well-characterized pediatric preclinical testing program patient-derived OS xenograft model, obtained from a primary femoral tumor and grown continuously in SCID mice [13, 14]. Tumor authentication was performed on the cell morphologically and via differentiation markers. Cell lines were grown in Eagle’s Minimum Essential Medium and supplemented with 10% FBS and a combination of 100 U penicillin with 0.1 mg/mL streptomycin (P/S). Cells were grown in a humidified condition of 95% air and 5% CO2 at 37°C. Once confluent, cells were washed with PBS twice, trypsinized and re-suspended in media. Approximately 3 million cells in 150 μL of media were implanted per animal. Animal Model Experiments were performed with the approval of the Albert Einstein College of Medicine Institutional Animal Care and Use Committee and in accordance with the institutional animal welfare policy. Six- to eight-week old female CB17 SCID mice weighing approximately 20 g (Taconic Biosciences) were housed in a pathogen-free barrier facility until tumor implantation. Twenty mice per experiment underwent heterotopic implantation of OS-17 in the right flank [14, 15]. Tumors were allowed to grow until palpable, measuring approximately 5 mm in diameter. Radioisotopes and Radiolabeling of Antibodies The IGF2R-specific murine mAb MEM-238 and the isotype matching control mAb MOPC21 (Abnova, Novus Biologics) were reduced using 75 molar excess of dithiothreitol (DTT) over the antibody by adding 5-10 μL of 3 mg/mL DTT in water to the mAbs to generate SH groups on the mAbs [16]. The mixture was left to react for 40 minutes at 37°C. The mAb was washed to remove excess dithiothreitol with 2×1.5 mL of ammonium acetate buffer in a Centricon-30 microconcentrator (Amicon). The β-emitting isotope 188Re in the form of Na188ReO4, was eluted with normal saline from a 188W/188Re radionuclide generator (Isotope Technologies). The 188ReO4− was reduced for 60 minutes at 37°C with 20 mg/mL SnCl2 in 0.1 M HCl in the presence of 50 mg/mL sodium gluconate. The reduced 188Re was then incubated with the DTT-treated antibodies for 60 min at 37°C as in [16]. The radiolabeling yields for 188Re-mAbs were measured by instant thin layer chromatography (ITLC) by developing silica gel (SG) 10 cm strips in saline. In this system the radiolabeled antibodies stay at the point of application while free 188Re moves with the solvent front. The average radiolabeling yield for either 188Re-mAbs was 85±5%. The radiolabeled mAbs were purified by HPLC using a TSK gel G4000SW size exclusion column (Tosoh Biosciences, Japan) eluted with PBS at 1 ml/min using Waters HPLC system equipped with UV (Waters 2487) and radiation (Bioscan Flow-Count) flow-through detectors. Biodistribution As murine and human IGF2Rs are not homologous, the mAb MEM-238 to human IGF2R can only bind specifically to IGF2R in OS17 xenografts. Thus, the biodistribution was performed to assess whether IGF2R-specific mAb will localize in the tumor preferentially when compared to non-specific isotype matching control MOPC21. The in vivo stability of the radiolabeled mAbs could also be assessed in such experiment. . The IGF2R-specific murine mAb MEM-238 and isotype matching control mAb MOPC21 were radiolabeled with 188Re as above. Mice were randomized and administered 50 μCi via an intraperitoneal injection, with ten mice receiving 188Re-MEM-238 and ten receiving 188Re -MOPC21. At 24 hours post-injection, 5 mice from each group were sacrificed and their tumors, blood and major organs were harvested, weighed and counted for radioactivity in a gamma counter using a dosimetry approach developed specifically for the laboratory rodent models, accounting for both for γ- and β-radiation. [17, 18] At 48 hours post-injection, the remaining 5 mice were sacrificed and similar harvesting and measurements were performed. The percentage of the injected radiolabeled mAb dose per gram of tissue (ID/g, %) was calculated for each animal. Binding Sites The Scatchard transformation was used to assess the number of IGF2R binding sites expressed on OS-17 cells [19]. OS17 cells were cultured and for each concentration of radiolabeled mAb, approximately 8 million cells were included. The experiment was performed twice using 0.0025, 0.005, 0.010, and 0.020 nM concentrations of radiolabeled 188Re MEM-238 and MOPC21 mAbs. The calculation of association constant Ka and the number of IGF2R binding sites per OS-17 cell were performed as previously reported. [19] In Vivo RIT Studies Following OS-17 implantation and growth to 5 mm in diameter, the mice were randomized into 4 groups. Group 1 received 300 μCi of 188Re-MEM-238, group 2 received 300 μCi of 188Re-MOPC21, group 3 received unlabeled (cold) MEM-238, and group 4 was left untreated. This dose level was chosen as it proved to be effective for other 188Re-antibody combinations in RIT of experimental cervical cancer [20]. Intraperitoneal injections were performed as previously described. Tumor volume was calculated every 3 days. Electronic calipers were utilized to measure the 3 largest diameters of the mass. Volume was calculated utilizing the equation for spheroid volume (V=Π·d1·d2·d3/6). To normalize the variability in tumor size between each animal, tumor volume ratio was utilized. Tumor growth ratio (TGR) was calculated by dividing the difference between the initial tumor volume at the start of the experiment (Vo) and the calculated tumor volume (Vn), divided by the initial tumor volume: TGR=(Vo-Vn)/Vo [21]. The calculated TGRs were plotted against time. The experiment was performed twice, initially over a 14-day period (Supplemental Figure 1s.) and thereafter over a 24-day period. Histologic Analysis The tumors were harvested at the conclusion of the RIT study. Tumors were fixed in 4% paraformaldehyde, decalcified, and embedded in paraffin blocks. Paraffin-embedded tissue slides were heated at 60°C for 1 hour, de-paraffinized using xylenes and rehydrated using graded alcohols. Endogenous peroxidase activity was quenched using 0.3% hydrogen peroxide in methanol. Antigenic proteins were unmasked by heat induced antigen retrieval method using sodium citrate buffer. The tissue was blocked with 10% normal goat serum in 1% bovine serum albumin (BSA) in tris-buffered saline (TBS), and stained with 10 μg/mL MEM-238 IGF2R mAb diluted in 1% BSA in TBS overnight at 4°C. Commercially available paraffin-embedded placenta tissue (BioChain Institute, Hayward, CA) was used as the positive control, and MOPC-21 IgG1 diluted in the same diluent as above was used instead of the primary antibody as the isotype negative control. Detection of the antibody-binding reaction was performed with biotinylated secondary antibody coupled with streptavidin-horseradish peroxidase. Avidin biotinylated enzyme complex (Vectastain ABC System; Vector Laboratories) was used according to the manufacturer’s instructions. The tissue was treated with 3,3’-diaminobenzidine (Vector Laboratories) to visualize the antibody binding and counterstained with hematoxylin. The tissue was then dehydrated with alcohol, permeated with xylenes and mounted with Permount organic mounting solution (Fisher Scientific). Staining technique was optimized by comparison with positive and negative controls. Stained slides were viewed using a PerkinElmer P250 High Capacity Slide Scanner (SIG #1S10OD019961-01, TissueScope™, Huron Digital Pathology) and staining patterns were contrasted quantitatively utilizing 3-D imaging analysis software (Volocity® 6.3, PerkinElmer). The total pixels of the tissue and the total number of brown pixels on each slide were counted. The total number of brown pixels was divided by the total number of pixels of tissue on each slide. Three slides per group were evaluated and results for each group were averaged. Statistical Methodology Power analysis for the in vivo cytotoxicity studies was estimated using PASS version 11 (NCSS, Inc.) using simulations of different tumor volumes based on pilot data and conservative assumptions regarding the groups treated with the radiolabeled antibodies. All simulations showed power of at least 83% with only five animals per group because of the large differences between treated and untreated animals. Thus, 5 mice per group were utilized in the in vivo studies. The differences between the biodistribution groups were analyzed using the Kruskal-Wallis and/or the Mann-Whitney tests. Differences between the treatment groups were similarly analyzed using the Kruskal-Wallis and/or the Mann-Whitney tests. Immunohistochemical analysis was performed by comparing the fraction of stained pixels using an overdispersed logistic model. A two-sided p value <0.05 was considered statistically significant for all studies. RESULTS OS-17 cells demonstrate a high binding efficacy for IGF2R-specific mAb The results of the Scatchard plot used to characterize and validate the binding affinity of the IFG2R specific murine mAb and the isotype matching control mAb demonstrated that there are 1,800 binding sites for 188Re-MEM-238 mAb with an association constant, ka, of 5.8 × 1010 M−1 (Figure 1). The slope for 188Re-MOPC21 mAb was not significantly different from zero, indicating there was no observed specific binding to OS-17 cells. IGF2R labeled mAb preferentially localizes to tumor cells The distribution of 188Re -MEM-238 in normal tissue was not significantly different from that of the isotype control, indicating that it was stable in vivo and as a result did not preferentially pool within any specific anatomic location. Importantly, when compared with the isotype control, 188Re-MEM-238 preferentially localized within the tumor after 48 hours, at which point complete separation of the two groups was apparent. The radiolabeled IGF2R antibody exhibited a 1.8 fold selective uptake within tumor tissue compared to the isotype control. This difference approached statistical significance (p=0.057, Figure 2). The clearance of 188Re-MEM-238 from blood was faster than that of the control 188Re-MOPC21. Treatment with 188Re-labeled IGF2R-specific mAb results in tumor growth suppression in vivo The effect of both specific and non-specific radionuclide therapy was evident, with Group 1 (188Re-MEM-238) and Group 2 (188Re-MOPC-21) demonstrating a clear decrease in both absolute tumor volume (p<0.001) and tumor growth ratio (p=0.001) compared with that of the unlabeled control groups, (unlabeled MEM-238 and untreated) in which tumor grew aggressively. The pilot RIT experiment, performed over a 14-day period (Figure 1S), demonstrated a strong trend to suppress tumor growth in the 188Re-MEM-238 treated group compared to the control groups. In the follow-up 24-day RIT experiment (Figure 3) the average tumor growth ratio (TGR) was 4.8 for the 188Re-MEM-238 group, as compared to 13.7 for the 188Re-MOPC-21 group, 29.6 for the unlabeled MEM-238 group, and 30.4 for the untreated group. A whisker plot of day 24 TGR demonstrates the range of values for each treatment arm of the experiment (Figure 2S). The TGR of Group 1 (188Re-MEM-238) was compared to that of Group 3 (unlabeled MEM-238) and Group 4 (untreated), demonstrating suppression of tumor growth in Group 1 (188Re-MEM-238, p=0.005). The specific effect of 188Re-MEM-238 utilized in Group 1 appeared more profound than that of control Group 2 (188Re-MOPC-21), reaching a non-significant trend (p=0.057). Treatment with 188Re-labeled IGF2R-specific mAb induces cytotoxicity in OS cells expressing IGF2R Treatment with 188Re-MEM-238 (Group 1) resulted in 37.4% staining of total pixels after 24 days, (Figure 4A), suggesting a substantial tumoricidal effect on IGF2R-expressing OS cells. Treatment with 188Re-MOPC21 (Group 2) resulted in 44.4% staining of total pixels (Figure 4B), suggesting a partial effect on IGF2R-expressing OS cells. Robust IGF2R staining was visualized in tumor treated with unlabeled MEM-238 (Group 3, Figure 4C) and in untreated tumor (Group 4, Figure 4D), in which 60.8% and 59.6% of total pixels were stained respectively, suggesting minimal to no effect on IGF2R-expressing OS cells. Staining of 188Re-MEM-238 (Group 1) was significantly different from that of unlabeled MEM-238 (Group 3) and untreated (Group 4, p=0.002). The difference between the188Re-MOPC21 (Group 2) and the 188Re-MEM-238 (Group 1) did not reach significance. DISCUSSION This study demonstrates the feasibility of targeting IGF2R with RIT in a heterotopic murine OS model. Scatchard plot analysis demonstrated a moderate number of available IGF2R binding sites and tight Ab binding, reflected by the high binding constant [19]. Since efficacy of RIT is directly proportional to the mAb’s binding constant, high RIT efficacy was predicted. It should be noted that in RIT studies where similar antigen levels on the surface of the targeted cells were observed in vitro [22,23], the RIT was nevertheless successful in killing the targeted cells. In the future, use of αemitters should also be explored for IGF2R-targeted RIT of osteosarcoma to counteract the relatively low number of binding sites. The radioimmunoconjugate demonstrated preferential localization to tumor tissue at 48 hours when compare to the isotype control. Finally, the use of RIT for the treatment of OS resulted in the suppression of tumor growth within the described model. The summation of these findings suggests that IGF2R has the potential to be an effective target for the treatment of OS and that 188Re-labeled IGF2R-specific mAb may offer a useful approach for the treatment of OS, particularly in patients with metastatic or refractory disease. Currently, there is a paucity of therapeutic options available to patients who fail first-line therapy and the addition of conventional chemotherapeutic agents to the backbone of methotrexate, doxorubicin, and cisplatin is unlikely to significantly improve overall survival. Novel approaches are needed for patients who demonstrate local or distant relapse and arguably for patients who respond poorly to standard chemotherapy. Techniques such as stereotactic body radiotherapy, proton therapy, and immune-modulated radiotherapy have changed the landscape of radiation therapy and overcome some of its historical challenges [24]. To date, the gold standard treatment for OS unequivocally remains complete resection and cytotoxic chemotherapy [2, 5]. However, radiotherapy is utilized in patients for whom complete resection is not feasible, such as in patients with tumors in the axial skeleton. In such cases, radiotherapy, in combination with standard chemotherapy, has been reported to result in higher overall survival then with chemotherapy alone [25, 26]. Newer radiation modalities are proving to be important for palliative management of pulmonary and osseous disease [24, 27, 28]. Although radiation therapy is not currently a part of first-line therapy, there is precedence for its use in scenarios where conventional strategies are insufficient. Radionuclide therapy for the treatment of osseous metastases from carcinoma and OS has been previously explored. Samarium-153 and Radium-223 (Alpharadin) act as calcium mimetics targeting bone cortical surfaces and areas of high bone turnover. Samarium-153 lexidronan is approved as a palliative agent for pain associated with osteoblastic metastases in hormone resistant prostate carcinoma [29] while Alpharadin has improved median overall survival by 3.6 months in patients with metastatic prostate cancer [30]. Lastly, there is an open phase I trial in OS patients with osteoblastic tumors [29], underscoring its relevance as a therapeutic modality. The effectiveness of combining radionuclides and monoclonal antibodies [31] has been well-documented for both hematopoietic and solid tumors [32-34]. The incorporation of RIT in the treatment of OS is founded on its reliable surface overexpression of IGF2R. IGF2R’s consistent overexpression on the tumor’s surface and mAb localization within the tumor at 48 hours both suggest it is a useful target. Binding studies additionally demonstrate high efficacy of IGF2R, further supporting this contention. RIT acts through the direct-targeted mechanism and also exerts a “cross-fire” effect, whereby proximate non-IGF2R binding cells are impacted as well. This may prove very relevant in the setting of a genetically variable and unstable entity such as OS, as it obviates the need for all tumor cells to possess the target and could rely on a more heterogeneous expression pattern. The current study demonstrates the effect of utilizing IGF2R as a reliable target as demonstrated by 188Re-labeled IGF2R-specific mAb mediated growth suppression and decreased expression of IGF2R immunohistochemical staining. Regardless of whether RIT ultimately develops into a clinically relevant modality, the current study serves as a proof of concept for IGF2R-targeted therapy. Limitations of this study include the relatively short experimental time course. As an initial study, a 24-day time course was felt to be sufficient to characterize preliminary results. However, a longer time course may yield additional information relevant to toxicity, resistance, and durability. The evaluation of human OS was accomplished by using immunocompromised animals. Although the model is well-described and validated, it is difficult to know to what extent the immune response, or lack thereof, contributed to these results. While dictated by the described power analysis, the relatively small sample size utilized likely contributes to the lack of significance in the difference seen between targeted and non-specific RIT treatment, particularly since one animal in each group died at an early time-point. Future studies should incorporate more OS cell lines and should evaluate biodistribution across a greater number of time points. Finally, our antibody was specific only to human IGF2R and future use of an antibody with human and murine specificity will permit for a more comprehensive assessment of anti-tumor effect and associated toxicity. Based on the limitations of the current study, a broader and longer-term study is warranted. Current findings serve as proof-of-principles and the foundation for a more comprehensive investigation. This targeted approach offers the benefits of being independent of a specific pathway, a resistance mechanism, and/or an inherent biologic tumor trait and therefore is relevant to all OS tumors that express IGF2R. It is recognized that this is an entirely different approach to treating this malignancy, but given the lack of effective new treatments it may prove to be of tremendous value, in particular to patients with metastatic disease for whom there is often no useful therapy. The current frustration with unimproved survival rates and the absence of a clearly beneficial second line therapy strongly stand in favor of alternative approaches that may provide a subset of patients a meaningful, though incremental, improvement. Supplementary Material Figure 1 Scatchard plot demonstrating non-specific binding of MOPC21 and specific binding for MEM-238. Figure 2 The biodistribution of radioactivity post-injection across selected SCID mouse organs following the administration of 188Re-labeled IGF2R-specific mAb (MEM-238) and 188Re-labeled control mAb (MOPC21): A) 24 hrs; B) 48 hrs Figure 3 Tumor growth ratio over a 24 day-period demonstrated marked suppression of tumor growth by 188Re-MEM-238 (Group 1). The non-specific control 188Re-MOPC21 mAb (Group 2) produced a lesser effect on tumor growth suppression. The tumors treated with unlabeled mAb (Group 3) and untreated tumors (Group 4) demonstrate uninhibited growth. Figure 4 Immunohistochemical staining demonstrated minimal IGF2R-staining intensity following treatment with 188Re-MEM-238 (A), moderate IGF2R-staining following treatment with 188Re-MOPC21 (B), and robust IGF2R-staining in both tumors treated with unlabeled MEM-238 (C) or in tumor untreated (D). Findings suggest that OS cells expressing IGF2R have been killed by the RIT treatment. This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final citable form. Please note that during the production process errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain. Conflicts of Interest: Richard Gorlick is a member of the Scientific Advisory Board of Oncolytics, which has no relationship to the subject of the current paper. No potential conflicts of interest were disclosed by any of the other authors associated with this manuscript. 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PMC005xxxxxx/PMC5118106.txt
LICENSE: This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. 8712028 5753 Mol Microbiol Mol. Microbiol. Molecular microbiology 0950-382X 1365-2958 27542978 5118106 10.1111/mmi.13485 NIHMS816375 Article UAP56 is a conserved crucial component of a divergent mRNA export pathway in Toxoplasma gondii Serpeloni Mariana 123§ Jiménez-Ruiz Elena 3§ Vidal Newton Medeiros 4 Kroeber Constanze 3 Andenmatten Nicole 3 Lemgruber Leandro 3 Mörking Patricia 1 Pall Gurman S. 3 Meissner Markus 3* Ávila Andréa R. 1* 1 Instituto Carlos Chagas, FIOCRUZ, Curitiba, Brasil 2 Departamento de Biologia Celular e Molecular, Universidade Federal do Paraná, Curitiba, Brazil 3 Wellcome Trust Centre for Molecular Parasitology, Institute of Infection, Immunity & Inflammation, College of Medical, Veterinary and Life Sciences, University of Glasgow, United Kingdom 4 National Center for Biotechnology Information, National Library of Medicine, National Institutes of Health, Bethesda, USA * To whom correspondence should be addressed: ARA: Tel: +55 (41)33163230 aravila@fiocruz.br. MM: Tel: +44(0)141 3306201; Markus.Meissner@glasgow.ac.uk § Equally contribution 17 9 2016 14 9 2016 11 2016 01 11 2017 102 4 672689 This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. SUMMARY Nucleo-cytoplasmic RNA export is an essential post-transcriptional step to control gene expression in eukaryotic cells and is poorly understood in apicomplexan parasites. With the exception of UAP56, a component of TREX (Transcription Export) complex, other components of mRNA export machinery are not well conserved in divergent supergroups. Here we use Toxoplasma gondii as a model system to functionally characterize TgUAP56 and its potential interaction factors. We demonstrate that TgUAP56 is crucial for mRNA export and that functional interference leads to significant accumulation of mRNA in the nucleus. It was necessary to employ bioinformatics and phylogenetic analysis to identify orthologs related to mRNA export, which show a remarkable low level of conservation in T. gondii. We adapted a conditional Cas9/CRISPR system to carry out a genetic screen to verify if these factors were involved in mRNA export in T. gondii. Only the disruption of TgRRM_1330 caused accumulation of mRNA in the nucleus as found with TgUAP56. This protein is potentially a divergent partner of TgUAP56, and provides insight into a divergent mRNA export pathway in apicomplexans. Graphical Abstract mRNA export pathway conditional Cas9 system Toxoplasma gondii INTRODUCTION Nucleo-cytoplasmic RNA export is an essential post-transcriptional pathway to control gene expression in eukaryotic cells. In Metazoan and Fungi, the nuclear export of most RNA species (such as microRNAs, ribosomal rRNAs, small nuclear RNAs and transfer RNAs) requires specific exportins and the small GTPase Ran. In contrast, nuclear export of bulk messenger RNAs (mRNAs) is Ran-exportin independent (Cullen, 2003, Kohler & Hurt, 2007). The mRNA export machinery is tightly coupled to mRNA splicing and includes different sets of mRNA binding proteins and nucleoporins (Kohler & Hurt, 2007, Rodriguez-Navarro et al., 2004, Wolyniak & Cole, 2008). In general proteins of THO complex associate with mRNA and recruit processing and export factors resulting in the formation of the Transcription/Export (TREX) complex (Strasser et al., 2002). TREX complex interacts with the spliceosome and mature mRNAs are exported through the nuclear pore complex (NPC) by binding to the heterodimeric receptor Mex67:Mtr2/TAP:p15, in an Ran-independent manner (reviewed by (Katahira, 2015, Wickramasinghe & Laskey, 2015)). The mRNAs are then released for translation into the cytoplasm by ATP-dependent helicase Dbp5/DDX19 (Kohler & Hurt, 2007, Nino et al., 2013). While mRNA export is well understood in opisthokonts, in the case of early divergent supergroups, such as Chromalveolata and Excavata, proteins involved in this pathway are not conserved. The only exception is Sub2 (UAP56), a DEAD-box helicase and member of TREX complex (Serpeloni et al., 2011b). While a role of UAP56 in mRNA processing has been suggested for the apicomplexa Plasmodium falciparum (Shankar et al., 2008), its role in mRNA export remains unknown. Using the apicomplexan Toxoplasma gondii as model, we show that knocking-out TgUAP56 led to a significant block of mRNA export, suggesting the presence of a specific mRNA export route akin to other eukaryotes. However, the identification of interaction partners of this crucial protein was not straightforward using standard search analysis due to low conservation of the components. Instead, we employed bioinformatics and phylogenetic analysis to identify T. gondii orthologs of factors that have been described as essential for mRNA export in opisthokonts. We identified some orthologs and discovered that these proteins sequences are very divergent in comparison with orthologs from other species. We predicted we would find the main mRNA export receptor in eukaryotes, Mex67, however our bioinformatics and phylogeny analysis failed to reveal its ortholog in T.gondii. Therefore, it may be possible that in apicomplexans, unlike in opisthokonts, mRNA is exported by a non-conserved export pathway in an Exportin/Ran-dependent manner. To dissect the factors involved in mRNA export in T. gondii, and to discriminate between Ran-dependent and -independent routes, we used reverse genetic strategies to interfere with specific components of both pathways. As part of these strategies we developed a conditional Cas9/CRISPR in T.gondii to target a subset of potential candidates in order to identify factors involved in mRNA export. Functional interference with GTPAse Ran and the exportin CRM1 does not lead to bulk mRNA export defects, suggesting that mRNA export is Exportin/Ran-independent in T. gondii, consistent with other eukaryotes. In addition other orthologs analyzed in this work, including Exportin/Ran-independent factors, were not crucial for mRNA export pointing to the presence of potential unique components for mRNA export in T. gondii. Functional interference with TgRRM_1330, which interacts with TgUAP56 and seems to be a divergent ortholog of Yra1/Aly, led to a phenocopy of TgUAP56 KO. Here we discuss that TgUAP56 and the divergent TgYra1 may be the first components of a divergent mRNA export pathway operating in apicomplexan parasites, and how these can be used empirically to identify other components that to date could not be identified through in silico sequence-based homology screens. RESULTS UAP56 is crucial for mRNA export in T. gondii We have previously shown that most components central to the Ran-independent mRNA export pathway are not conserved in organisms that divergent early during evolution (Serpeloni et al., 2011b). One exception that is conserved in all eukaryotes is the DEAD-box helicase UAP56, which is also involved in splicing of pre-mRNAs (Libri et al., 2001, Fleckner et al., 1997, Thakurta et al., 2007, Jensen et al., 2001, Strasser & Hurt, 2001). In order to reconstruct the phylogeny of UAP56 orthologs sequences across eukaryotes, we surveyed 43 representative species of different eukaryotic groups. The data presented in Figure S1 show that UAP56 protein phylogeny resembles the eukaryotic species phylogeny. The orthologs protein of UAP56 in T. gondii, TgUAP56, is annotated as a DEAD-box polypeptide DDX39 (ID TGME49_216860 at ToxoDB, GI 237843393 at NCBI) and is 78.6 and 72.8 % similar to orthologs in human cells (Hsa_UAP56) and yeast (Sce_Sub2), respectively. Multiple sequence alignments of TgUAP56 and representative sequences from other eukaryotic groups demonstrate high sequence conservation along the entire protein including two RNA helicase domains. To characterize the function of TgUAP56, we generated transgenic parasites expressing TgUAP56 N-terminally fused to ddFKBP-GFP (Breinich et al., 2009) (dd-GFP-TgUAP56). The ddFKBP domain allows conditional stabilization of the fusion protein in the presence of the ligand Shield-1 (Shld1) (Banaszynski et al., 2006). We verified that incubation of transgenic parasites with 1 μM results in stabilization of dd-GFP-TgUAP56. Furthermore, dd-GFP-TgUAP56 co-localizes with endogenous TgUAP56 in the nucleus, as shown by immunofluorescence analysis using a polyclonal antibody raised against the trypanosome ortholog (Serpeloni et al., 2011a), which specifically detects TgUAP56 (Figure 1A-i, ii). dd-GFP-TgUAP56 stabilization is very efficient and the protein can be detected as early as 6 hours after addition of 1 μM Shld1, reaching a peak at 36 h (Figure 1B-i). We found that overexpression of dd-GFP-TgUAP56 efficiently interferes with parasite growth indicating functional interference with endogenous TgUAP56 and an essential role for this protein (Figure S2A). We speculated that block of parasite growth is caused by interference with mRNA export. Indeed, the incubation of parasites for 48 hours in presence of Shld1 caused an obvious nuclear accumulation of mRNA that co-localizes with dd-GFP-TgUAP56 (Figure 1B-ii). To exclude that the phenotype observed after overexpression of dd-GFP-TgUAP56 is due to a non-specific interference with the mRNA export pathways, we used an inducible gene-swap strategy (Andenmatten N., 2013) to generate a conditional knockout for uap56 (cKOuap56). This strategy is based on site-specific recombination by DiCre, which catalyzes excision of DNA flanked by loxP sites after induction with rapamycin (Bargieri et al., 2013, Andenmatten N., 2013). Parental DiCre strain was transfected with cKOuap56 plasmid to generate a stable cell line for conditional knockout of uap56 gene (cKOuap56 strain). Upon induction, excision of uap56 results in replacement of the reporter gene mcherry under control of the endogenous promoter and hence knockout parasites can be identified based on red fluorescence (Figure 1C-i). We confirmed correct homologous recombination of the uap56-LoxP cassette in the original uap56 locus by gDNA PCR analysis (Figure S2B-i,primers set 1 and 2, A and C comparison). uap56 gene excision was confirmed at genomic level by gDNA PCR analysis after 24 hours induction with rapamycin (Figure S2B-ii, primers set 1 and 2, A and B comparison). Real-time quantitative PCR and immunoblot assays were performed to analyze uap56 mRNA and TgUAP56 protein levels, respectively, at specific time points after rapamycin induction. Non-induced and induced parasites of parental DiCre strain have normal levels of uap56 mRNA in the presence of rapamycin at all time points tested (Figure S2C-i). In the case of induced parasites of cKOUAP56 strain, uap56 mRNA levels decreased drastically 48 hours after addition of rapamycin (Figure S2C-ii). In good agreement, the levels of TgUAP56 protein significantly decreased after 24 hours of rapamycin incubation and after 48 hours it is virtually undetectable (Figure 1C-ii). The nuclear accumulation of poly(A)+ RNA is observed after 48 hours when levels of TgUAP56 are undetectable (Figure 1C-iii). The incubation of parasites in presence of 50 nM rapamycin has no toxic effect on parasites as demonstrated previously (Andenmatten et al., 2013). In our case, the treatment of rapamycin itself in the parental DiCre strain did not affect the expression levels of TgUAP56 (Figure S2E-i) or the export of mRNAs (Figure S2E-ii). In addition, the detection of mcherry expression after rapamycin incubation confirmed that uap56-loxP was excised successfully (Figure 1C-iii). Furthermore, we confirmed that TgUAP56 is essential, since uap56 excision caused a lethal phenotype (Figure S2D). Importantly, a similar mRNA accumulation in the nucleus was observed after dd-GFP-TgUAP56 stabilization, demonstrating that this phenotype is specific and therefore an essential role for TgUAP56 in mRNA export. Next we surveyed a selection of genes by a semi-quantitative PCR analysis developed by Suvorova et al, 2013 (Suvorova et al., 2013), using primers spanning an intron as listed in Table S2 to assess if TgUAP56 plays an important role in mRNA-splicing. Parasites of parental DiCre and cKOuap56 strains were incubated with 50 nM of rapamycin for 24 and 48 hours before extraction of total RNA. gDNA extracted from cKOuap56 strain was used as a reference for intron-containing pre-spliced mRNAs. PCR data did not show accumulation of pre-mRNA for any of the genes analyzed indicating that uap56 knockout does not affect mRNA splicing (Figure 1D). Bioinformatic and phylogenetic analysis provide the identification of ortholog proteins in T. gondii Since TgUAP56 is related to mRNA export in T. gondii, we decided to systematically probe the genome of the parasite in order to identify proteins that are potentially related to TgTREX (T. gondii TREX complex) and downstream events. Our first approach was based on protein sequence search and phylogenetic reconstruction. The general criteria to choose the candidates were: a) evidence of Sub2/UAP56 interaction partners and/or b) they are essential for mRNA export in humans or yeast. Sub2/UAP56 and Yra1/Aly are known partners that are part of TREX complex in opisthokonts and are loaded onto mRNAs in a splicing-dependent manner (for reviews, see (Masuda et al., 2005, Reed & Hurt, 2002, Custodio et al., 2004)). TREX can recruit the RNA export receptor Mex67:Mtr2 to spliced mRNAs (Hurt et al., 2004, Hackmann et al., 2014, Iglesias et al., 2010, Gilbert & Guthrie, 2004) and it is known that TAP:p15 can be targeted to spliced mRNPs directly to a spliceosome U2AF35 subunit and this interaction is conserved across metazoan species (Zolotukhin et al., 2002). In addition to these RNA binding proteins, Npl3 and Gbp2, the latter associated with TREX complex, can recruit mRNA export receptor Mex67:Mtr2 to mRNAs also and are crucial for formation of export-competent mRNP (Hurt et al., 2004, Hackmann et al., 2014, Iglesias et al., 2010, Gilbert & Guthrie, 2004). Besides, mutants of npl3 show strong mRNA-export defects (Lee et al., 1996, Krebber et al., 1999, Strasser & Hurt, 2000, Gilbert & Guthrie, 2004, Gwizdek et al., 2006, Gilbert et al., 2001) and overexpression of Gbp2 is toxic and causes a nuclear retention of bulk poly(A)+ RNA (Windgassen & Krebber, 2003). Our approaches allowed the identification of orthologs of most proteins cited above in T. gondii, although low sequence conservation is observed in Kinetoplastida and Apicomplexa (Table 1, Figures S4–7). However, this approach did not allow the identification of a T. gondii ortholog of Mex67, the specific receptor of mRNA export in yeast. Based on the fact that GTPase Ran and CRM1 are required for the export of proteins and a subset of mRNAs in some eukaryotes (Cullen, 2003, Wickramasinghe & Laskey, 2015) (reviewed by (Delaleau & Borden, 2015)), we used the T. gondii orthologs to assess if mRNA export was Ran-dependent in T. gondii. Exportin CRM1 and its cofactor GTPase Ran are highly conserved throughout eukaryotic phylogeny (Figures S8 and 9) (Serpeloni et al., 2011b)). To analyze the potential role of the candidates in mRNA export we took advantage of the conditional gene disruption by ddCas9, as described below. Conditional Cas9 expression allows identification of mRNA export mutants The recent adaptation of CRISPR/Cas9 in T. gondii parasites is a powerful technology to generate direct knockouts for non-essential genes in a rapid and reliable manner (Shen et al., 2014, Sidik et al., 2014). Transient expression of Cas9 might be helpful to rapidly identify certain phenotypes (Harding et al., 2016), but constitutive expression of Cas9 might lead to artifacts. To overcome this limitation we designed a conditional nuclear Cas9 fused to ddFKBP to allow precise regulation of Cas9 expression levels (Figure S3A). ddCas9 is detectable as early as 1 hour after addition of Shld1 (Figure 2A) and localizes mainly to a defined region within the nucleus in all parasites. Longer stabilization leads to Cas9 localization throughout the nucleus of the parasite (Figure 2B, Figure S3B). Importantly, while short incubation times, up to 4 hours, with Shld1 did not significantly affect parasite viability, longer stabilisation leads to accumulation of ddCas9 and appearance of aberrant parasites (Figure S3B). To minimise toxicity and off-target effects caused by over-stabilisation of ddCas9, conditional mutants were generated by incubation of parasites with 1 μM of Shld1 for 4 hours. To validate the efficiency and specificity of conditional ddCas9, we stably transfected RHddCas9 with 2 different sgRNA-expression vectors (Table S2, Figure S3C) targeting gap40 (gliding associated protein 40) and reproduced the highly specific phenotype in the inner membrane complex (IMC) biogenesis caused by deletion of gap40 through conventional KO strategies (Harding et al., 2016). In the absence of Shld1 RHddCas9-gap40sgRNA clonal strains generated from the 2 different vectors showed no deficit. Addition of Shld1 resulted in efficient disruption of gap40; presenting typical gap40KO phenotype in ~ 65% of the induced population for both clones (Figure S3D). We confirmed the essentiality of gap40 for parasite growth (Figure 2C) and the typical collapse of the IMC (Figure 2D), which is detected as early as 24 hours after induction. Using PCR analysis we confirmed that the RHddCas9 parental strain and non-induced RHddCas9-gap40 sgRNA strain had no mutations in gap40. In contrast, specific mutations in gap40 gene (deletions/insertions) were identified in gDNA from RHddCas9-gap40sgRNA incubated with Shld1 at the exact position targeted by the gap40 sgRNA sequence (Figure S3E). As a negative control we used a sgRNA targeting an exogenous sequence not present in the T. gondii genome (lacZ gene). Neither parental RHddCas9 strain nor RHddCas9-lacZsgRNA strain showed any alteration in parasite morphology or growth in the presence or absence of Shld1 (not shown). Disruption of uap56 led to the same poly(A)+ RNA nuclear accumulation (Figure 2E), as seen for TgUAP56 overexpression and uap56 conditional deletion using the DiCre system (see Figure 1). This phenotype is related to TgUAP56 function, since the absence of the protein leads to mRNA export blocking (Figure 2F-i, ii). This phenotype was not observed in RH-ddCas9 or RH-ddCas9gap40 gRNA strains (Figure 2E), demonstrating the specificity of gene disruption using the ddCas9 strategy. This strategy proves to be an useful tool to analyze the function of genes. However, we observed several caveats that make this tool cumbersome to use in a higher throughput scale (see discussion). Next, we stably introduced sgRNA-expression vectors targeting each potential mRNA export candidate into RHddCas9 (Table S2). Interestingly only the disruption of a RNA recognition motif-containing protein (TGME49_291330, named here as TgRRM_1330) resulted in a similar phenotype as observed for disruption of uap56 (Figure 3). In this case, we observed severe nuclear accumulation of poly(A)+ RNA ultimately leading to the death of the parasite (not shown). In RHddCas9-uap56 gRNA and RHddCas9-TgRRM_1330 gRNA strains mRNA export blocking events were up to 46% and 38% of vacuoles, respectively. In contrast, components of the Ran-dependent export pathway do not seem to be required for mRNA export in T. gondii (Figure 3). Identification of a RNA recognition motif-containing protein as a novel factor for mRNA export in T. gondii The results obtained by ddCas9 dependent disruption were further confirmed by overexpression studies, based on ddFKBP-GFP as described above for TgUAP56. For most of the candidates analyzed, overexpression also resulted in lethal phenotypes without any mRNA export defects (Figure 4). Concomitant with the results obtained for ddCas9-mediated gene disruption, the overexpression of TgRRM_1330 resulted in mRNA export defect (Figure 5A, B) and consequent death of parasites (Figure 5C), as observed for TgUAP56 overexpression. Even though TgRRM_1330 sequence is not conserved, the protein contains a RNA binding domain that is conserved in orthologs of Yra1/Aly, an essential component of mRNA export in yeast (Figure S4), and the experimental data suggest that TgRRM_1330 is potentially a highly divergent functional homologue of Yra1/Aly. In summary, disruption and overexpression of CRM1 and GTPase Ran (components of Ran-dependent pathway) did not show any mRNA export defect in T. gondii. However, TgUAp56 and TgRRM_1330 were found to be shown to be essential for bulk mRNA export, suggesting that T. gondii operate in a Ran independent pathway as found in higher eukaryotes. TgUAP56 and TgRRM_1330 form a functional complex To test the hypothesis that TgRRM_1330 is a partner of TgUAP56 we performed co-localization and immunoprecipitation analysis. For this purpose, we imaged the nucleus of tachyzoites with super-resolution and immune-electron microscopy. Maximum projection of SR-SIM image of TgUAP56 (in red) and dd-GFP-TgRRM_1330 (in green) show a high co-localization rate, with a similar distribution over the nucleus (stained with DAPI, in blue). The graph shows the same localization of the red signal over the green signal, both together with the localization of the DAPI signal (Figure 5D-i). Ultrastructural observation showed a labeling of TgUAP56 (arrows) together with TgRRM_1330 (arrowheads) near areas of dense chromatin in the nucleus of T. gondii tachyzoites (Figure 5D-ii). The interaction between dd-GFP-TgRRM_1330 and TgUAP56 was furthermore confirmed by immunoprecipitation (Figure 5D-iii). This interaction was not observed with dd-GFP (control strain) or with dd-GFP-TgCRM1, as expected (data not shown). DISCUSSION mRNA export is well studied in higher eukaryotes where TREX complex has an important role, including UAP56 and adaptor proteins (for review see (Muller-McNicoll & Neugebauer, 2013)). However, several proteins involved in this pathway are not conserved throughout the eukaryotic phylogeny with the exception of UAP56, including in early divergent eukaryotes (Serpeloni et al., 2011b). We previously demonstrated that this protein is a component of mRNA export pathway in Trypanosomes (Serpeloni et al., 2011a). Here we confirmed the UAP56 ortholog in T. gondii, named TgUAP56. The most divergent sequence is Tryp-Sub2 ortholog (66.1% similarity). Considering that Tryp-Sub2 is a component of the mRNA export pathway (Serpeloni et al., 2011a), it would be reasonable to hypothesize that TgUAP56 has the same role as a basic component of the mRNA export pathway. However, phylogenic relationship is not a guarantee for functional conservation. In this work we present experimental data supporting that UAP56 is an essential factor for mRNA export in T. gondii. TgUAP56 is exclusively nuclear and dispersed all over the nuclei in a punctuate pattern, similar to observations in other eukaryotes (Gatfield et al., 2001, Serpeloni et al., 2011a, Sahni et al., 2010). TgUAP56 overexpression results in a dominant negative phenotype leading to parasite death due to a block of mRNA export. Similarly, overexpression of UAP56 in Caenorhabditis elegans and human cells impairs mRNA export and leads to nuclear retention of poly(A)+ mRNAs (Strasser & Hurt, 2001, Luo et al., 2001) (MacMorris et al., 2003). The specificity of the overexpression effect was confirmed by conditional knockout for uap56, where nuclear accumulation of poly(A)+ RNAs was prominent after 48 hours and consequently parasites were unable to grow and died within the host cell. These results agree with previous observations in yeast, Drosophila melanogaster and trypanosomes where the depletion of UAP56 orthologs resulted in growth arrest and robust accumulation of poly(A)+ mRNAs within the nucleus (Gatfield et al., 2001, Strasser & Hurt, 2001) (Serpeloni et al., 2011a). Together these data demonstrate the essential role of TgUAP56 in mRNA export in T. gondii. We also investigated if TgUAP56 is involved in mRNAs splicing since this protein was originally associated with the splicing machinery (reviewed in Linder and Stutz, 2001 (Linder & Stutz, 2001)). Our approach was based on the strategies used previously for the characterization of the splicing factor TgRRM1 (Suvorova et al., 2013), where the authors showed that a selected list of genes of T. gondii were mis-spliced in the absence of TgRRM1. Importantly, we did not observe any interference in mRNA splicing of these targets in the absence of TgUAP56. Therefore, TgUAP56 appears to be exclusively required for mRNA export, potentially releasing spliced mRNAs from adaptor proteins. This idea is corroborated by studies in other model organisms that indicate that Sub2/UAP56 also plays an essential role in mRNA export (Gatfield et al., 2001, Jensen et al., 2001, Luo et al., 2001, Strasser & Hurt, 2001, Dias et al., 2010, Steckelberg & Gehring, 2014). Since UAP56 is a necessary and specific component of a specialized mRNA export complex in mammals, the identification of homologous proteins in parasites would point to the presence of a similarly specialized pathway in apicomplexans. For this purpose, we decided to use a genetic screen based on the Cas9/CRISPR system. In T. gondii, CRISPR/Cas9 technology has been used successfully in several occasions (Shen et al., 2014, Sidik et al., 2014). However, constitutive expression of Cas9 in T. gondii seems to be toxic. In higher eukaryotes, different strategies for controlling the activity of Cas9 have been employed including the tetracycline inducible system (Zhu et al., 2014), splitting the Cas9 in half (Wright et al., 2015, Zetsche et al., 2015) and, very recently, a conditional Cas9 system based on the fusion with a destabilization domain (FKBP12-L106P) (Geisinger et al., 2016). Here we succeeded to generate parasites that allow regulation of Cas9 activity using the ddFKBP-system (Herm-Gotz et al., 2007) and we show that specific conditional disruption of essential genes is feasible using this approach. Our phenotypic assays using ddCas9 demonstrated that it allows the identification of specific phenotypes. As a proof of concept, we reproduced the phenotype caused by deletion of gap40 (Harding et al., 2016) and confirmed that disruption of this gene using ddCas9 causes the typical collapse of the IMC, while mRNA export is not affected. In contrast, disruption of uap56 caused a block in mRNA export, corroborating our previous findings after conditional deletion of the gene using DiCre and overexpression analysis. However, while ddCas9 can be successfully employed to screen for specific phenotypes, such as mRNA export as shown here, it should be used with caution, when screening for general growth phenotypes. In our experience disruption of non-essential genes resulted sometimes in abnormal parasites (data not shown), a phenomenon we are currently investigating. Furthermore, overexpression of ddCas9 over extended periods results in parasites with aberrant morphology, further complicating employment of this system. Therefore, a thorough downstream analysis using additional reverse genetic tools is required to confirm identified phenotypes. Despite these disadvantages, the ddCas9 system allowed us to efficiently analyze different candidates. The selection of candidates for genetic analysis was based on searching for orthologs of proteins that have been described in mRNA export in opisthokonts. Among all the proteins analyzed, only the ortholog of Mex67 was not identified. In this case, PSI-BLASTP searches resulted in spurious hits corresponding to only the Leucine-rich region of Mex67, no hits corresponding to NTF2-Like and TAP C-terminal domains were found. It may not be surprising since Mex67 is not a highly conserved protein in divergent groups (Kramer et al., 2010, Serpeloni et al., 2011b). The only description of Mex67 in protozoa shows that it is a divergent protein with an essential motif that is absent from all other Mex67 orthologues known (Dostalova et al., 2013, Kramer et al., 2010). Consequently, all the candidates bar Mex67 were studied by functional interference. Our results showed that TgU2_6910, TgRRM_2620 and TgSF2_9530, that are T. gondii orthologs of factors involved in Ran-independent mRNA export pathway in opisthokonts, are not crucial for mRNA export although they are essential proteins for parasite survival. These data point to the lack of a conserved mRNA export pathway in T. gondii. Interestingly, the lack of a conserved pathway has also been observed for the protozoa Trypanosoma brucei albeit Mex67 is a functional mRNA receptor in these parasites. Some authors have proposed the hypothesis of an evolutionarily divergent mechanism for mRNA export (Schwede et al., 2009, Dostalova et al., 2013, Obado et al., 2016) and a shared platform for transport for rRNA and mRNA has been suggested (Neumann et al., 2010, Buhlmann et al., 2015). Based on this, we decided to address if mRNA export in T. gondii would be dependent on exportin (CRM1) and GTPase Ran since they are conserved proteins throughout eukaryote phylogeny and there are evidences of CRM1/Ran involvement in export of specific mRNA and rRNA (for review see (Kohler & Hurt, 2007)). The disruption of both genes did not block the export in bulk of mRNA, suggesting that it is potentially a Ran-exportin independent route. These results together with the identification of TgUAP56 indicate the presence of a specific mRNA export pathway as described for other organisms. We still cannot affirm that Mex67 is absent in T. gondii but undoubtedly the protein structure is very distinct of the receptors described so far. Our genetic approaches identified TgRRM_1330, a RNA binding protein that is essential and specific component of mRNA export in T. gondii. Interestingly, this protein contains a RNA-binding domain that is also present in Yra1/Aly, a component of TREX that interacts with UAP56 orthologs in opisthokonts (Strasser & Hurt, 2000, Luo et al., 2001, Dufu et al., 2010). In good agreement with this, we demonstrate that TgRRM_1330 interacts with TgUAP56 in T. gondii. TgRRM_1330 was not detected using standard BLAST searches, however using PSI-BLAST with 2 iterations it was possible to recover this yeast Yra1 ortholog candidate with a significant E-value (5e-17). The identity of TgRRM_1330 with the yeast (Yra1) and human (Aly) protein is only 21.5% and 24.9% respectively, supporting the idea that mRNA export pathway in T. gondii might contain divergent components. Indeed, apicomplexans and other parasites have acquired particular features in relation to mRNA metabolism during evolution and further evidence is required to check if the presence of divergent components would correspond to distinct mechanisms of mRNA export in comparison with the pathway of opisthokonts. Our results provide the first insights into components of mRNA export in apicomplexan parasites and the description of interacting partners that are crucial for the divergent pathway. These essential proteins can serve as a handle to identify interacting proteins in further investigations. EXPERIMENTAL PROCEDURES Identification of candidate genes in Toxoplasma gondii In order to identify putative ortholog proteins involved in the RNA export pathway in T. gondii, we used previously described proteins in the literature from yeast, human and P. falciparum as query sequences. The list of queries used is as following: Sub2 (GI: 6320119), Yra1 (GI: 6320589), Mex67 (GI: 6325088), GTPase Ran GSp1 (GI: 6323324) and CRM1 (GI: 398366207) from yeast; U2AF35 (GI: 68800128) from human; and Npl3 (PF10_0217) and Gbp2 (PF10_0068) from P. falciparum. We performed BLASTP searches with E-value threshold of 1e-03. To be considered orthologs in T. gondii, identified proteins should satisfy the reciprocal best hit criteria. Alternatively, PSI-BLAST with inclusion threshold of 0.005 was used to identify a candidate ortholog sequence of yeast Yra1 in T. gondii. Identification of orthologs genes in eukaryotes Putative ortholog proteins identified in T. gondii were used as query sequences in BLASTP searches (E-value threshold 1e-03) against the RefSeq database to identity orthologs in 43 representative species from the major eukaryotic groups as listed on Table S1: Metazoans, Fungi, Amoebozoa, Plants, Apicomplexans, Kinetoplastids and Parabasilids. To be considered orthologs, identified proteins should satisfy the reciprocal best hit criteria. Sequence and domain analysis Identity and similarity percentages were obtained using needle program from the EMBOSS package (Rice et al., 2000), which finds the optimal global alignment of two sequences. Protein domain searches were performed running hmmscan program from HMMER package (Eddy, 1998) against the collection of Hidden Markov models downloaded from the Pfam database version 27.0 (Finn et al., 2014). Phylogenetic analysis Multiple sequence alignments of orthologs sequences were done using MAFFT version 7 with the following parameters: -localpair -maxiterate 1000 –reorder (Katoh & Standley, 2013). Phylogenetic analysis was conducted using the approximately maximum likelihood method implemented in the FastTree 2.1 program (Price et al., 2010) with default parameters. The tree was rendered using FigTree v1.4 (http://tree.bio.ed.ac.uk/software/figtree/). Cloning of DNA constructs All oligonucleotides used in this study are listed in Table S2. The TgUAP56 gene swap-vector (loxPUap56loxP-mCherry-HX) was generated by cloning uap56 ORF (TGME49_216860), amplified directly from cDNA with F/R primers using ApaI and loxP-NsiI sites respectively. The amplified fragment was placed upstream of mcherry sequence, replacing tub8 of parental plasmid (unpublished vector). Uap56 5′UTR was amplified from genomic DNA (gDNA) with F/R primers using KpnI and loxP-ApaI sites respectively. The amplified fragment was placed upstream of the uap56 cDNA for the transcription of uap56 gene to be driven by the endogenous promoter present in 5′UTR. Finally, 3′UTR of uap56 was amplified from gDNA using F/R primers using SacI restriction site for cloning. The plasmid was linearized with KpnI before RH DiCre ΔKu80 strain transfection. To generate conditional ddCas9 plasmid (p5RT70DDmycFlagCas9) the synthetic cas9 expressing cassette from Lourido’s lab (Addgene ID 52694(Sidik et al., 2014)) was cloned into plasmid p5RT70ddmycGFPPfMyoAtailTy-HX (Hettmann et al., 2000) using NcoI-NotI restriction sites. The plasmid was linearized with NotI before transfection into the RH Δhxgprt strain. A single guide RNA (sgRNA) cassette for each candidate synthesized by GeneScript was inserted into a plasmid including the DHFR resistant cassette (pU6-gRNA-crisprRNA). The 20 nucleotides of the guide RNA (gRNA) were designed using the online software E-CRISP (http://www.e-crisp.org/E-CRISP/designcrispr.html) aiming for exons close to the 5′ end and maintaining NGG as PAM sequence. The plasmids were linearized with NotI before transfection into the ddCas9 strain. The Overexpression vectors were generated by cloning each ORF (TgUAP56 (TGME49_216860), TgCRM1 (TGME49_249530), TgSF2_9530 (TGME49_119530), TgRRM_2620 (TGME49_062620), TgRan (TGME49_248340), TgRRM_1330 (TGME49_291330), TgU2_6910 (TGME49_236910)), amplified directly from cDNA with F/R primers using appropriate restriction sites, into p5RT70ddmycGFPPfMyoAtailTy-HX (Hettmann et al., 2000). The plasmids were linearized with KpnI before transfection into the RH Δhxgprt strain. Parasite parental and transgenic strains T. gondii tachyzoites (RH Δhxgprt – RH strain (Donald R.G., 1996) and RH DiCre ΔKu80 strain - DiCre strain (Pieperhoff et al., 2015), and transgenic strains generated in this study) were cultured on human foreskin fibroblasts (HFF) and maintained in Dulbecco’s modified Eagle’s medium (DMEM) supplemented with 10% fetal calf serum, 2 mM glutamine and 25 μg/mL gentamicin. Freshly released parasites (~5x107) were transfected and selected in presence of mycophenolic acid and xanthine (Donald R.G., 1996) or pyrimethamine to generate stable lines as previously described (Donald & Roos, 1993). RH Δhxgprt parasites were transfected individually with overexpression plasmids to generate clonal lines for overexpression of all candidates. The RH DiCre ΔKu80 strain was transfected with loxPUap56loxP-mCherry-HX plasmid to generate TgUAP56 knockout strain (cKOuap56) based on a previously used gene-swap strategy (Andenmatten N., 2013). RHΔhxgprt parasites were transfected with p5RT70DDmycFlagCas9 plasmid to generate a conditional Cas9 expressing strain (ddcas9). This parental cell line was transfected with individual synthetic pU6-gRNA-crisprRNAs plasmids (listed on Table S2) to generate ddCas9 strains for each target candidate. Analysis of mutations caused by ddCas9/CRISPR Targeting Genomic DNA was extracted from induced and non-induced parasites using the DNeasy Blood and Tissue kit following manufacturer procedures (Qiagen cat# 69506). PCR primers flanking the predicted target site were used to amplify amplicons using High Fidelity Platinum® Taq DNA Polymerase (ThermoFisher cat# 11304-011), PCR primers listed in Table S2. Amplicons were cloned into pGEM-T Easy Vector System (Promega cat# A1360) using standard cloning and amplification procedures prior to sequencing (LIGHTRUN™ Sequencing Service at GATC, Germany) using T7 and SP6 primers (Table S2). Sequences were analyzed using BioEdit software version 7.2.5. (Tom Hall. Ibis Biosciences. Carlsbad, CA, USA). Immunoblot assays Parasites were incubated in culture media supplemented with or without 1 μM Shld1 (overexpression assays and Cas9-mediated disruption assays) or 50 nM of rapamycin (inducible knockout assay). Protein extracted from parasites were prepared for Western Blot analysis as described previously (Hettmann C., 2000), using 12% polyacrylamide gels under reducing condition with 100 mM DTT. Equal number of parasites was loaded per experiment. Polyclonal anti-Tryp-Sub2 (1:1000) (Serpeloni et al., 2011a), monoclonal anti-GFP (1:500) (Roche, #cat11814460001) and monoclonal anti-flag (1:500) (Fisher/Thermo Scientific, #cat 11525702) antibodies were used for specific protein detection respectively. Monoclonal anti-aldolase (1:10.000) (Starnes et al., 2006) was used as loading control. ImageJ software with the densitometry plugin (Version 1.6, National Institutes of Health, Bethesda, MD) was used for protein quantification. Fluorescent in situ hybridization (FISH) and Immunofluorescence assays Intracellular parasites were grown in the absence or presence of 0.1–2 μM Shld1 (overexpression assays), 1 μM Shld1 (Cas9-mediated disruption assays) or 50 nM of rapamycin (inducible knockout assay). To detect poly(A)+ RNA in T. gondii FISH assays were performed as previously described (Lirussi & Matrajt, 2011, Serpeloni et al., 2011a). Tachyzoite-infected HFF cells grown on glass coverslips were fixed with 4% formaldehyde in PBS for 20 minutes at room temperature and permeabilized with 0.2% Triton X-100 in 2× SSPE(SSPE 2X: 300 mM NaCl, 20 mM phosphate buffer pH 7.4, 2 mM EDTA) for 20 minutes. The parasites were washed 3 times with 2X SSPE and blocked with hybridization solution (HS) (10% Dextran, SSPE 2X, 35 % formamide, 0,5 mg/mL tRNA) for 30 minutes at 37 0C in a humidified chamber. Further, 1ng/μL of the probe (oligodT conjugated with Alexa488 or Alexa555, synthesized by Invitrogen) was added in HS and denatured for 3 minutes at 65 0C before hybridization with the cells. The cells were incubated with the probe for 16 hours at 37 0C in the humidified chamber. After the hybridization, the cells were washed with 2× SSC followed by 1× SSC for 15 minutes each (1× SSC : 0.15M NaCl, 0.015M Na3Citratex-2H2O pH 7.4). For IF assays, cells were blocked and permeabilized with PBS containing 3% bovine serum albumin and 0.2% Triton X-100 for 20 minutes before incubation with primary antibody for one hour at RT. Anti-TrypSub2, (Serpeloni et al., 2011a), anti-IMC1 or IMC3 (1:1000) and anti-flag (1:200) (Fisher/Thermo Scientific, #cat 11525702) antibodies were used for immunolocalization. Post primary antibody hybridization Cells were incubated with the secondary antibodies (Alexa 594-conjugated anti-rabbit (Invitrogen, #cat A11012); Alexa 488 or 594-conjugated goat anti-mouse antibodies (Invitrogen #cat A-11001 and A11005, respectively)) diluted to 1:3000 and incubated for 1 hour at RT. Cells were washed (buffer) several times and mounted onto slides with DAPI Fluoromount (Southern Biotech UK, #cat 0100–20). We combine immunofluorescence and FISH assays. For this, the immunofluorescence protocol was used and a fixation step with PFA 4% fixation followed by incubation oligodT conjugated with Alexa (as described for FISH) was included before the incubation with secondary antibodies. Image acquisition was conducted using a 100X or 63X oil objective on a Zeiss Axioskop 2 fluorescence microscope with an Axiocam MRm CCD camera using Zen software (Zeiss). Further image processing was performed using ImageJ 1.34r software and Photoshop CS6 (Adobe Systems Inc). Immunofluorescence signals quantification was performed with ImageJ software with densitometry plugin (Version 1.6, National Institutes of Health, Bethesda, MD). Super-resolution structure illumination microscopy was performed using a Zeiss Elyra PS.1 super-resolution microscope equipped with a sCMOS PCO camera. The Plan-Apochromat 63×/1.4 Oil DIC lens was used, and Z-stacks were acquired in 5 rotations using the ZEN Black Edition Imaging software (Zeiss). Images were then processed in ZEN Black Edition Imaging software (Zeiss), using the structural illumination manual processing tool, with a noise filter of −6.0, and an output as SR-SIM. Colocalization and fluorescence intensity analysis were carried out in FIJI software (Schindelin et al., 2012). Immunoelectron Microscopy For the immunocytochemistry, infected cells were fixed overnight in 4% paraformaldehyde and 0.2% glutaraldehyde in phosphate buffer. The samples were washed in phosphate buffer and dehydrated in ascending ethanol solutions. After a progressive infiltration process with LR White resin, the polymerization was carried out in gelatin capsules under ultraviolet light. Formvar-coated nickel grids with ultrathin sections were incubated with blocking solution (3% BSA, 0.02% Tween 20, in phosphate buffer) for 1 hour. The grids were incubated with the primary antibody anti-GFP (1:20, Roche, #cat11814460001) diluted in blocking buffer for 1 hour followed by several washes in blocking buffer. The grids were then incubated with 10 nm gold-conjugated anti-mouse secondary antibody (1:10, Aurion, Netherlands) for 1 hour, followed by several washes with blocking buffer. The grids were incubated with anti-TrypSub2 primary antibody (1:50, polyclonal (Serpeloni et al., 2011a)) for 1 hour, followed by several washes in blocking buffer. The grids were then incubated with 15 nm gold-conjugated Protein A (Aurion, Netherlands) for 1 hour, followed by washes in blocking buffer and phosphate buffer. The material was stained with uranyl acetate prior observation in a Tecnai T20 transmission electron microscope (FEI, Netherlands). Images were analyzed and processed in FIJI (Schindelin et al., 2012) and Adobe Photoshop. Real-time PCR (qPCR) Total RNA was isolated in duplicate from RH DiCre ΔKu80 and cKOuap56 strains incubated with 50 nM rapamycin at different points using RNeasy® Mini Kit (Qiagen) according to the manufacturer’s direction and MIQE criteria (Bustin et al., 2009). Contaminating DNA was digested with 1 U DNAse RNAse-free (Promega) per μg RNA. 1 μg RNA was reverse transcribed using random primers (Invitrogen) and ImProm-II™ Reverse Transcription System (Promega) as default protocol. To access uap56 mRNA levels, we performed real-time PCR reactions in triplicate using SYBR green master mix (Applied Biosystems) on AB7500 (Applied Biosystems, Invitrogen). mRNA levels were normalized to reference tubulin mRNA levels, using primers described previously (Dalmasso et al., 2009). The relative expression levels were calculated based on the Livak method (Livak & Schmittgen, 2001) and percentage of uap56 mRNA levels was analyzed by media of total mRNA per time. Growth assays Plaque assays were performed as described previously (Roos DS, 1994). Monolayers of HFF grown in 6 well plates were infected with 200 tachyzoites per well. Parasites were incubated with 0.1–2 μM of Shld1 (overexpression assays) or 50 nM of rapamycin (inducible knockout assay). For ddCas9 assays, cells were incubated with 1 μM of Shld1, after 24 hours this was replaced with fresh DMEM without Shld1. For inducible knockout assays, the cells were incubated with 50 nM of rapamycin for 24 hours. After this time, the cells were washed and maintained with DMEM. After 108 hours of incubation at 37 °C, 5% CO2, cells were fixed for 10 minutes with 100% methanol at −20 °C, stained with Giemsa for 10 minutes and washed once with PBS. Images were taken using a Zeiss microscope (Axiovert 200M) with a 4× objective and plaque size was determined using Axiovision software (Zeiss). Analysis of mRNA processing by splicing The analysis of mRNA splicing was performed by analytical PCR for seven selected genes as previously described (Suvorova et al., 2013). Total RNA was purified using RNeasy® Mini Kit (Qiagen) from RH DiCre ΔKu80 and cKOuap56 strains after 24 and 48 hours of incubation with rapamycin. The RNA was reverse transcribed using random primers (Invitrogen #cat 48190-011) and the target sequences were amplified by PCR using specific primers that span an intron, as listed on Table S2. gDNA was used as reference to distinguish between properly spliced (S) and pre-spliced (PS) species. mRNAs from the following genes were analyzed: RNA polymerase II p8.2 subunit (TGME49_217560), RNA polymerase II p19 subunit (TGME49_271300), RNA polymerase II p23 subunit (TGME49_240590), imc1 (TGME49_231640), imc15 (TGME49_275670), imc5 (TGME49_224530), and transcription factor iid (TGME49_258680). Tubulin was used as loading control and the primers were described previously (Dalmasso et al., 2009). Immunoprecipitation We performed immunoprecipitation experiments using the dd-GFPTgRRM_1330 strain to determine whether TgUAP56 co-immunoprecipitates with dd-GFP-TgRRM_1330. Intracellular tachyzoites were incubated with 0.5 μM of Shld1 for 2 hours and then homogenized in a salt buffer [10 mM Trisodium Citrate, 20 mM HEPES, pH 7.4, 1 mM MgCl2, 10 μM CaCl2, 0,1% CHAPS, 0,5% Nonidet P-40 (NP-40), phosphate inhibitor cocktail (P-5726; Sigma, St. Louis, MO)]. The samples were centrifuged at 15,000 xg for 10 min and the supernatant was incubated with α-GFP antibody (Roche) with protein G-agarose beads (CAT) for 2 hours at 4°C. The beads were washed four times in the same buffer solution and antigens were eluted from the beads with 60 μl of 2× Laemmili SDS buffer. Samples were boiled for 5 min before SDS-PAGE separation. Supplementary Material Supp info We would like to thank Prof. Gary Ward (University of Vermont, US) and Dr. Marc Jan Gubbels (Boston College, US) for kindly providing IMC antibodies. We would also like to thank Dr. Sebastian Lourido (Whitehead Institute, US) for the Toxoplasma gondii Cas9 vector (Addgene ID 52694). This work was supported by the Programa Estratégico de Apoio à Pesquisa em Saúde (PAPES/FIOCRUZ, Brazil) [407775/2012-9 –CNPq]; Fundação Araucária [145/2015]; CAPES Foundation, Ministry of Education of Brazil (CAPES, Brazil) [PDSE Fellowship 9445-12-9]; National Counsel of Technological and Scientific Development (CNPq, Brazil) [PDE Fellowship 249741/2013-0]; This work was supported by an ERC-Starting grant (ERC-2012-StG309255-EndoTox) and the Wellcome Trust 087582/Z/08/Z Senior Fellowship for MM. The Wellcome Trust Centre for Molecular Parasitology is supported by core funding from the Wellcome Trust (085349)).This research was partially supported by the Intramural Research Program of the National Library of Medicine, National Institutes of Health. NMV’s postdoctoral fellowship is funded by a partnership between Conselho Nacional de Desenvolvimento Cientifico e Tecnologico and the National Institutes of Health, Figure 1 Localization and functional analysis of TgUAP56 A. Analysis of dd-GFP-TgUAP56 expression. i) In non-induced parasites (- Shld1), only the endogenous protein (TgUAP56) is detected by Western blot using polyclonal antibody against Tryp-Sub2 (Serpeloni et al., 2011a), renamed here as α-TgUAP56. Both TgUAP56 and dd-GFP-TgUAP56 are detected by this antibody after incubation with 1 μM of Shld1 for 6 hours. Aldolase: Loading control. ii) In the immunofluorescence assay dd-GFP-TgUAP56 is nuclear and colocalizes with endogenous TgUAP56 protein, in red. Nuclear and apicoplast DNA staining with DAPI: in blue. Scale bar: 5 μm. B. Analysis of mRNA distribution after dd-GFP-TgUAP56 overexpression with 1 μM Shld1. i) Western blot to analyze induction of dd-GFP-TgUAP56. The protein was detected with anti-GFP. Aldolase was used as loading control. dd-GFP-TgUAP56 was detectable after 6 hours of incubation with 1 μM of Shld1. The numbers above the Western blot indicate the relative expression levels of dd-GFP-TgUAP56 at each indicated time point, normalized to the loading control aldolase using ImageJ software with the densitometry plugin (Version 1.6, National Institutes of Health, Bethesda, MD). ii) To check mRNA distribution, poly(A)+ mRNAs were detected by fluorescent in situ hybridization (FISH) using oligodT-Alexa594 as probe: in Red. Nuclear and apicoplast DNA staining with DAPI: in blue. dd-GFP-TgUAP56: in green. In the right: quantification of signals of immunofluorescence and DAPI in selected parasites, in yellow box. Scale bar: 10 μm. C. Analysis of mRNA distribution after knockout of uap56 by gene-swap strategy based on Di-Cre system in T. gondii. i) Endogenous uap56 gene is replaced with mcherry by Dicre after incubation with 50 nM of rapamycin. ii) uap56 knockout was analyzed in cKOuap56 strain western blot after incubation with 50 nM of rapamycin at different times. -, not induced; +, induced. Aldolase: Loading control. iii) mRNA distribution was analyzed in cKOuap56 strain after incubation with rapamycin at different times by fluorescent in situ hybridization (FISH) using oligodT-Alexa488 as probe, in green. Nuclear and apicoplast DNA was staining with DAPI: in blue. In the right: quantification of signals of immunofluorescence and DAPI in selected parasites. Scale bar: 10 μm. D. PCR analysis of mRNA splicing for selected genes. Total RNA was purified from DiCre strain and cKOuap56 strain both incubated with 50 nM of rapamycin, as indicated. -, not induced; +, induced. The total RNA was reverse transcribed and PCR amplified using primers that span an intron. PCR of gDNA was included as a reference to distinguish between properly spliced (S) and pre-spliced (PS) forms of each gene. In the top: Tubulin, used as loading control (Dalmasso et al., 2009). In the bottom: PCR analysis of mRNA splicing for selected genes: RNA polymerase II p8.2 subunit (TGME49_217560), RNA polymerase II p19 subunit (TGME49_271300), RNA polymerase II p23 subunit (TGME49_240590), imc1 (TGME49_231640), imc15 (TGME49_275670), imc5 (TGME49_224530), and transcription factor iid (TGME49_258680). gDNA: genomic DNA from non-induced parasites of cKOuap56 strain. Expected sizes for pre-mRNA (Pre-spliced) and mRNA (spliced) are shown for each selected gene. Figure 2 Establishment of a conditional Cas9 (ddCas9) A. Western blot showing ddCas9-FLAG overexpression. Parasites were induced for indicated times with 1μM of Shld1 prior protein extraction. RH-Δhxgprt strain was used as control (first and second lanes - wild type-wt) Aldolase: Loading control. B. i) Nuclear localization of Cas9 in RHddCas9 parasites after addition of 1 μM Shld1 for 24h. Nuclear and apicoplast DNA staining with DAPI: in blue. Scale bar: 10μm. ii) Co-localization map, showing in grey the areas where there was co-localization with an M2 of 0.8. Graph represents the areas where there was a signal for green (green line) and areas where there was signal for blue (blue line). Y axis: intensity level; X axis: distance in microns. C. Plaque assays for parental RHddCas9 and RHddCas9-gap40 gRNA strains. Both parasite strains were grown on human foreskin fibroblasts, in the presence or absence of 1 μM of Shld1, as indicated, for 108 hours. -, not induced; +, induced. Scale bar: 500 μm. D. Immunofluorescence assay of parental RHddCas9 and RHddCas9-gap40 sgRNA strains in the presence or absence of Shld1. Collapsing vacuoles with a significant reduction of GAP40 signal were only observed in induced parasites that expressed the specific sgRNA against gap40. Scale bar: 8μm. E. mRNA distribution was analyzed in RHddCas9, RHddCas9-gap40 gRNA and RHddCas9-uap56 gRNA strains after incubation for 4 hours with 1 μM Shld1 and further incubation for 48 hours in media. The analysis was performed by fluorescent in situ hybridization (FISH) using oligodT-Alexa594 as probe, in red. Nuclear and apicoplast DNA was staining with DAPI: in blue. Scale bar: 5 μm. F. mRNA distribution and TgUAP56 protein presence analysis in RHddCas9-uap56 gRNA strain after incubation for 4 hours with 1 μM Shld1 and further incubation for 48 hours in media. i) The analysis was performed by immunofluorescence assay, α-TgUAP56 in green, combined with fluorescent in situ hybridization (FISH) using oligodT-Alexa594 as probe, in red. mRNA export blocking was observed in absence of TgUAP56 in induced parasites that expressed the specific sgRNA against uap56. Nuclear and apicoplast DNA was staining with DAPI: in blue. Scale bar: 5μm. ii) Western blot to analyse TgUAP56 protein levels after 1 μM Shld1 incubation for 24 and 48 hours. The protein was detected with anti-TgUAP56. Aldolase was used as loading control. ddCas9-FLAG was detected using antibody α-Flag. -, not induced; +, induced. Figure 3 ddCas9 genetic screen for potential candidates related to mRNA export in T. gondii mRNA distribution was analyzed in RHddCas9, RHddCas9-candidate strains after incubation for 4 hours with 1 μM Shld1 and then 48 hours with fresh media. The analyses were performed by fluorescent in situ hybridization (FISH) using oligodT-Alexa594 as probe, in red. Nuclear and apicoplast DNA was stained with DAPI: in blue. Scale bar: 5 μm. Figure 4 Subcellular localization and phenotypic analysis after overexpression of T. gondii candidate proteins in T. gondii A. Plaque assays for overexpression strains. Both parasite strains were grown on human foreskin fibroblasts, in the presence or absence of 1 μM of Shield, as indicated, for 108 hours. -, not induced; +, induced. Scale bar: 500 μm. B–F) mRNA distribution in different times of candidates overexpression by incubation with 1 μM of Shld1. poly(A)+ mRNAs were detected by fluorescent in situ hybridization (FISH) using oligodT-Alexa594 as probe: in Red. Nuclear and apicoplast DNA staining with DAPI: in blue. dd-GFP-candidates: in green. Scale bar: 5 μm. Figure 5 Localization and functional analysis of TgRRM_1330. A. Analysis of mRNA distribution during dd-GFP- TgRRM_1330 overexpression after incubation with 1 μM Shld1 at different times To check mRNA distribution, poly(A)+ mRNAs were detected by fluorescent in situ hybridization (FISH) using oligodT-Alexa555 as probe: in Red. Nuclear and apicoplast DNA staining with DAPI: in blue. dd-GFP- TgRRM_1330: in green. Scale bar: 5 μm. B. dd-GFP-TgRRM_1330 protein was detected with anti-GFP and the overexpression levels were quantified by comparison with aldolase levels. dd-GFP-TgRRM_1330 was stabilized after 6 hours of incubation with 1 μM of Shld1. The numbers above the Western blot means the percentage of overexpression at each indicated time point, related to result after 6 hours, proportional to loading control. C. dd-GFPTgRRM_1330 strain growth assay. Parasites were grown on human foreskin fibroblasts in the presence of different concentration of Shld1. After 108 hours of incubation, the cells were fixed and stained with Giemsa. D. Colocalization analysis between TgUAP56 and dd-GFP- TgRRM_1330. i) Super-resolution microscopy of four tachyzoites nuclei. There is a clear co-stain with anti-TgUAP56 (in red) and the GFP signal of dd-GFP-TgRRM_1330 (in green) within the nucleus, stained in blue with DAPI. The fluorescence signals were analyzed and plotted, showing a co-localization of the fluorescences in the same areas within the nuclei highlighted in the white box. ii) Immunoelectron micrograph of a tachyzoite nucleus. Arrows indicate labelling of anti-TgUAP56 protein, and arrowheads indicate anti-GFP protein. iii) dd-GFP-TgRRM_1330 immunoprecipitation. dd-GFP-TgRRM_1330 was stabilized for 2 hours with 0,5 μM of Shld1. The membrane was incubated with anti-TgUAP56. I: Input. W1: First wash. W4: Fourth and last wash. E: Eluted. Table 1 mRNA export candidates in T. gondii based on sequence and phylogenetic analysis. S. cerevisiae Metazoans ID NCBI - Description References Length (aa) PFAM-Domains ToxoDB - Description ID Length (aa) PFAM - Domains Yra1p Aly/REF GI: 6320589 Nuclear polyadenylated RNA-binding protein; required for export of poly(A)+ mRNA from the nucleus. Is deposited onto mRNAs through its interaction partner Sub2/UAP56 and couple mRNA export with 3′ end processing via its interactions with Mex67p Lou et al (2001); Zhou (2000), Masuda et al (2005); Meinel et al (2013); Ma et al. (2013); Johnson et al. (2011) 226 RRM_Aly_REF RNA recognition motif-containing protein TGME49_291330 (TgRRM_1330) 228 RRM_1 Npl3 PF10_0217 (serine/arginine-rich splicing factor 4 (SRSF4)) In yeast: RS containing shuttling RNA-binding-protein recruited to the mRNAs co-transcriptionally early by RNA polymerase II and is required for pre-mRNA splicing. Phosphorylation is essential for efficient competent mRNP export Tuteja and Mehta, (2010 538 RRM1_RRM1 Splicing factor SF2 (SF2) TGME49_319530 (TgSF2_9530) 512 RRM_1/RRM_1 Gbp2 PF10_0068 (RNA-binding protein, putative) In yeast: Poly(A+) RNA-binding protein recruited to the mRNAs co-transcriptionally via THO complex involved in mRNA surveillance and nuclear mRNA quality control. Tuteja and Mehta, (2010) 246 RRM1_RRM1 RNA recognition motif-containing protein TGME49_262620 (TgRRM_2620) 293 RRM_1/RRM_1 U2AF35 GI: 68800128 RNA recognition motif in U2 small nuclear ribonucleoprotein auxiliary factor U2AF 35 kDa subunit, that directly binds to TAP, and this interaction is conserved across metazoan species. Wu et al (1999); Zolotukhin et al., (2002) 240 aa zf-CCCH/RRM_5/zf-CCCH U2 snRNP auxiliary factor, putative TGME49_236910 (TgU2_6910) 254 zf-CCCH/zf-CCCH/RRM_5 CRM1 Xpo1 GI: 398366207 Major karyopherin/Exportin involved in export of proteins, snRNAs, rRNAs, viral RNAs and a subset of endogenous mRNAs Hammell et al. (2002), Cullen (2003), Koyama e Matsuura (2010); Sun et al. (2013), Wickramasinghe and Laskey, 2015 1084 CRM1 _C/Xpo1/IBN_N Exportin 1, putative TGME49_249530 (TgCRM1) 1125 CRM1_C/Xpo1/IBN_N Ran GTPase GSP1 Ran GI: 6323324 Ran GTPase; GTP binding protein involved in the maintenance of nuclear organization, RNA processing and transport Cullen (2003), Wickramasinghe and Laskey, 2015 219 Ras GTP-binding nuclear protein ran/tc4 TGME49_248340 (TgRan) 229 Ras Abbreviated Summary mRNA export is well characterised in mammals but poorly understood in single-cell parasites and other divergent organisms. We have utilized sequence searching, phylogenetic analyses and reverse genetic tools to investigate this pathway in Toxoplasma gondii, a parasite that causes Toxoplasmosis in humans and is related to the malaria causing parasite. This study has revealed essential factors and point towards that this parasite may have undiscovered unique components for mRNA export. Author Contributions Experimental design: MS, EJR, MM and ARA; Generation of transgenic strains: MS, EJR, CK and NA; Conditional Cas9 system establishment: EJR and MS; Image acquisition, analysis and interpretation: MS, EJR and LL; Sequence and phylogenetic analysis: NMV; Splicing analysis: MS and PM; Manuscript writing: MS, EJR, NMV, GP, MM and ARA. Conflict of interest statement: None declared. 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PMC005xxxxxx/PMC5118109.txt
LICENSE: This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. 9304420 2335 Nucl Med Biol Nucl. Med. Biol. Nuclear medicine and biology 0969-8051 1872-9614 27694058 5118109 10.1016/j.nucmedbio.2016.08.017 NIHMS820311 Article Monooxorhenium(V) complexes with 222-N2S2 MAMA ligands for bifunctional chelator agents: Syntheses and preliminary in vivo evaluation Demoin Dustin Wayne ad Dame Ashley N. ad Minard William D. a Gallazzi Fabio b Seickman Gary L. d Rold Tammy L. cd Bernskoetter Nicole d Fassbender Michael E. e Hoffman Timothy J. acd Deakyne Carol A. a Jurisson Silvia S. a a Department of Chemistry, University of Missouri, Columbia, MO 65211, USA b Department of Structural Biology Core, University of Missouri, Columbia, MO 65211, USA c Department of Medicine, University of Missouri, Columbia, MO 65211, USA d Research Division, Harry S. Truman Memorial Veteran’s Hospital, Columbia, MO 65201, USA e Chemistry Division, Los Alamos National Laboratory, PO Box 1663, Los Alamos, NM 87545 USA Corresponding author at: Department of Chemistry, 601 South College Avenue, University of Missouri, Columbia, MO 65211; jurissons@missouri.edu; 573-882-2107 (phone); 573-882-2754 (fax) 5 10 2016 31 8 2016 12 2016 01 12 2017 43 12 802811 This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. Introduction Targeted radiotherapy using the bifunctional chelate approach with 186/188Re(V) is challenging because of the susceptibility of monooxorhenium(V)-based complexes to oxidize in vivo at high dilution. A monoamine-monoamide dithiol (MAMA)-based bifunctional chelating agent was evaluated with both rhenium and technetium to determine its utility for in vivo applications. Methods A 222-MAMA chelator, 222-MAMA(N-6-Ahx-OEt) bifunctional chelator, and 222- MAMA(N-6-Ahx-BBN(7-14)NH2) were synthesized, complexed with rhenium, radiolabeled with 99mTc and 186Re (carrier added and no carrier added), and evaluated in initial biological distribution studies. Results An IC50 value of 2.0 ± 0.7 nM for natReO-222-MAMA(N-6-Ahx-BBN(7-14)NH2) compared to [125I]-Tyr4-BBN(NH2) was determined through competitive cell binding assays with PC-3 tumor cells. In vivo evaluation of the no-carrier added 99mTc-222-N2S2(N-6-Ahx-BBN(7-14)NH2) complex showed little gastric uptake and blockable pancreatic uptake in normal mice. Conclusions The 186ReO-222-N2S2(N-6-Ahx-BBN(7-14)NH2) complex showed stability in biological media, which indicates that the 222-N2S2 chelator is appropriate for chelating 186/188Re in radiopharmaceuticals involving peptides. Additionally, the in vitro cell studies showed that the ReO-222-N2S2(N-6-Ahx-BBN(7-14)NH2) complex (macroscopically) bound to PC3-tumor cell surface receptors with high affinity. The 99mTc analog was stable in vivo and exhibited pancreatic uptake in mice that was blockable, indicating BB2r targeting. Rhenium-186 rhenium(V) MAMA ligands quantum chemical studies bombesin radiotherapy 1. Introduction Two medically useful rhenium isotopes (186Re and 188Re) are beta emitters with different half-lives, nuclear production routes [1–3], particle energies, and thus tissue ranges (Table 1). The nuclear properties [4] of these two Re radioisotopes, both available at no carrier added (nca) concentrations, makes them suitable for various radiotherapeutic applications (i.e., 186Re for antibody labeling and smaller tumors and 188Re for peptide labeling and larger tumors) for personalized tumor treatment. Rhenium is the third row transition-metal congener of technetium, which is widely used in 99mTc-based diagnostic agents for SPECT (single-photon emission computed tomography) imaging [5–7]. A bifunctional chelating agent conjugated to a targeting vector for in vivo localization that delivers Tc and Re to the tumor site could provide complementary diagnostic and therapeutic agents. A number of NxS4-x ligand systems have been reported for Re(V) [5,6,8,9], with the N2S2- based monoamine-monoamide dithiol (MAMA) chelators of particular interest since the amine allows for conjugation of a single targeting vector. Kung et al. compared the 222-MAMA ligands for chelating oxotechnetium(V) with the bis(aminoethanethiol) (BAT) ligands and showed that the 222-MAMA chelators were more stable over time [10]. The MAMA-based complexes were more hydrophilic than their BAT analogues based on shorter HPLC retention times and lower rat brain uptake [10]. Subsequently, N-alkylated 222-MAMA derivatives were complexed with monooxotechnetium(V) [and to a lesser extent with monooxorhenium(V)] and shown to be stable under biological conditions [11–18]. The 222-MAMA-based bifunctional chelating agents were evaluated for forming stable 186/188Re complexes for targeted peptide-based radiotherapy agents, using the seventh through fourteenth amino acids (BBN(7-14)NH2) of the bombesin peptide sequence as a potential bombesin receptor (BB2r) targeting vector [19]. The BBN(7-14)NH2 sequence coupled to a variety of bifunctional chelating agents has been shown to specifically target the BB2r both in vitro and in vivo [6,20–26]. The synthesis, characterization, and radiolabeling of a new 222-MAMA derivatized bifunctional chelate for complexing 186/188/natRe(V) are reported with initial stability studies and in vivo biodistributions. 2. Methods 2.1. General methods All chemicals, unless otherwise indicated, were commercially available and used without further purification. Technetium-99m pertechnetate was available from saline elution of a 99Mo/99mTc generator (Mallinckrodt Medical, St. Louis, MO). Rhenium-186 was obtained using acid dissolved enriched Al(185ReO4)3 targets (94.6%; Isotech) from 185Re(n,γ)186Re production reactions at the University of Missouri Research Reactor (MURR, Columbia, MO) with a specific activity of 3.6–6.4 GBq/mg (0.098–0.172 Ci/mg). No carrier added 186Re was produced at the Los Alamos National Laboratory Isotope Production Facility (LANL-IPF) using an encapsulated target of enriched 186WO3 Powder (99.9%; Isoflex USA) in a 40 MeV incident proton beam. The 186Re was recovered as previously reported [27,28] with a slight modification: the anion exchange column was eluted with 8 M HNO3 (2 x 50 mL) for ReO4− desorption. The nitric acid was removed by evaporation and the residue reconstituted in 0.1 M HCl. The specific activity was determined to be 790 ± 90 GBq/mg (21 ± 2 Ci/mg) [27,28]. PC-3 tumor cells were obtained from ATTC (Manassas, VA) and cultured by the MU Cell and Immunobiology Core (CIC). NMR studies were performed with a Bruker DRX 300 or 500 MHz Spectrometer (as noted). ESI-MS was performed using a Finnigan TSQ7000 triple-quadrupole mass spectrometer. HPLC analysis was performed with a Shimadzu HPLC system outfitted with both UV-vis (254 and 358 nm) and radioisotope detectors. HPLC columns included a Betabasic-18 column (Thermo Scientific, Waltham, MA, 150 mm × 4.6 mm, 5 μm), a Jupiter C-18 column (Phenomenex, Torrance, CA, 250 mm × 4.60 mm, 5 μm, 300 A pore size), and a Nova-Pac semi-prep C-18 column (Waters, Milford, MA, 300 mm × 19 mm, 6 μm, 60 Å). All HPLC mobile phases used acetonitrile (AcN) in water with 0.1% trifluoroacetic acid (TFA); the specific conditions (i.e., column, gradient, flow rate) are indicated for purifications and analyses. Sep-Pak C18 Plus Light cartridges were purchased from Waters (Milford, MA). Radio-TLC strips (Saturation pads, Analtech, Newark, DE) were counted using a Bioscan 200 Imaging Scanner (gas ionization detector), or by cutting the TLC strips and counting them in a NaI(Tl) well detector (Harshaw Chemical Company, Serial Number EX-53, with Ortec electronics and a Canberra high-voltage supply) or a Tri-Carb 2900TR Liquid Scintillation Analyzer (PerkinElmer, Waltham, MA). A Beckman Coulter HPLC system in series with an ion trap mass analyzer (a LCQ FLEET instrument, Thermo Fisher Scientific, with positive ion ionization) was used to obtain LC/ESI-MS results (Betabasic-18, 10–50% AcN over 30 min, 1 mL/min). MS analysis was performed using the XCalibur software (Thermo Fisher Scientific). A Thermo Nicolet AEM FT-IR instrument was used for IR analysis (KBr pellets). UV-Vis analysis was performed with an OceanOptics USB2000 USB-ISS-UV/VIS spectrometer. All elemental analyses were performed by Atlantic Microlabs, Inc (Norcross, GA). 2.2. Synthesis of compounds and complexes Compounds 1 and 2 (Fig. 1) were synthesized with trityl protecting groups following a preparation similar to Ono et al. and verified by NMR [17]. Ethyl 6-((2-oxo-2-((2-(tritylthio)ethyl)amino)ethyl)(2-(tritylthio)ethyl)amino)hexanoate (3) [trityl protected 222-MAMA(N-6-Ahx-OEt)] Method 1 In oven-dried glassware under an Ar (g) atmosphere, 2 (1.15 g, 1.7 mmol) was added in 2 mL of anhydrous dimethylformamide (DMF). Anhydrous DMF (13 mL), ethyl-6-bromohexanoate (0.4 mL, 2.2 mmol), and diisopropylethylamine (0.33 mL, 1.9 mmol) were added in series. The reaction mixture was stirred under Ar (g) at 90 °C for 3 h. The product mixture was dried in vacuo, dissolved in ethylacetate (EtOAc; 10 mL) and extracted with a saturated NaCl solution (10 mL). The organic layer was dried over anhydrous Na2SO4, gravity filtered, rotary evaporated to an oil and placed under vacuum overnight. The product was purified on a silica gel column (1 in. × 6 in.) conditioned with 15% EtOAc in hexanes and eluted with 15% EtOAc in hexanes (100 mL), 30 % EtOAc in hexanes (100 mL), and 50% EtOAc in hexanes (300 mL), sequentially. The product, collected in two brown-colored fractions (eluted during the 30% EtOAc fraction and later in the 50% EtOAc fraction), were individually collected and dried to yield oils, which contained 3 and residual DMF. The two product fractions were combined and subsequently heated to 90 °C under vacuum for 24 h to obtain 0.367 g (0.4 mmol, 26.3% yield) of 3. 1H-NMR (500 MHz, CDCl3, δ (ppm), letters correspond to Fig. 1): 1.16–1.36 (m, 7H, n, h, i), 1.53 (quintet, J = 7.6, 2H, j), 2.18–2.28 (m, 6H, f, g, k), 2.33–2.41 (m, 4H, a, e), 2.83 (s, 2H, d), 2.96–3.05 (m, 2H, b), 4.07–4.15 (m, 2H, m), 7.13–7.32 (m, 18H, q, s), 7.34–7.50 (m, 12H, r). 13C-NMR (500 MHz, CDCl3, δ (ppm), letters correspond to Fig. 1): 14.3 (n), 24.7 (j), 26.8 (h & i), 29.9 (f), 32.0 (a), 34.2 (k), 37.9 (b), 53.8 (g), 54.6 (e), 58.2 (d), 60.2 (m), 66.7 (o), 126.7 (s), 127.9 (q), 129.5 (r), 144.7 (p), 171.2 (c), 173.5 (l). ESI-MS (m/z): 821.10 (calc. 821.38 [C52H57N2O3S2+][M+H+]). Anal. Calcd (Found) for C52H56N2O3S2·2HCl: C, 69.86 (69.88); H, 6.54 (6.84); N, 3.13 (3.22); S, 7.17 (7.49). Method 2 To a scintillation vial equipped with a stir bar, 2 (1.01 g, 1.49 mmol) was dissolved in dry AcN (2 mL; dried over molecular sieves). Diisopropylethylamine (0.25 g, 1.93 mmol) in AcN (3 mL) was added, followed by slow addition of ethyl-6-bromohexanoate (0.43 g, 4.67 mmol) in 3 mL of AcN. The reaction mixture was placed in an oil bath and refluxed at 85 °C with under N2 gas, and allowed to react for 24 h. The reaction vessel was brought to room temperature before removal of solvent in vacuo. EtOAc (5 mL) was added to the residue, and undissolved particulates were removed by filtration. The volume was reduced by half and 0.5 mL of hexanes was added. The crude product was purified on a silica gel column (10 g, 1.3 cm diameter) that had been pre-conditioned with 15% EtOAc in hexanes. The column was eluted with 30% EtOAc in hexanes (100 mL) followed by 50% EtOAc in hexanes (200 ml). Fractions (5 mL) were collected and analyzed by TLC analysis (silica gel; 50% EtOAc in hexanes. Fractions showing a single species with Rf = 0.4 were combined, and dried under vacuum overnight to obtain 1.08 g (1.32 mmol, 88% yield) of 3. 6-((2-oxo-2-((2-(tritylthio)ethyl)amino)ethyl)(2-(tritylthio)ethyl)amino)hexanoic acid (4) [trityl protected 222-MAMA(N-6-Ahx-OH)] 3 (0.14 g, 0.17 mmol) was dissolved in dry tetrahydrofuran (THF; 3 mL) and transferred to the reaction flask. Ethanol (EtOH; 3 mL) and aqueous 3 M NaOH (2 mL) were added. The mixture was refluxed for 9 h. The solvent was removed by rotary evaporation and the product left under vacuum overnight. 4 was dissolved in CHCl3 and loaded onto a silica gel column (1 in. × 6 in.), eluted with CHCl3 (200 mL) and, subsequently, 20% methanol (MeOH) in CHCl3 (100 mL). The brown-colored fraction (obtained from the 20% MeOH eluent) contained 0.10 g (0.13 mmol, 76.5% yield) of 4. 1H-NMR (500 MHz, CDCl3, δ (ppm), letters correspond to Fig. 1): 1.18–1.27 (m, 2H, i), 1.32 (tt, J = 7.4, 7.4 Hz, 2H, h), 1.54 (q, J = 7.5 Hz, 2H, j), 2.20–2.29 (m, 6H, f, g, k), 2.32–2.42 (m, 4H, e, a), 2.83 (s, 2H, d), 3.00 (quartet, J = 6.3 Hz, 2H, b), 7.14–7.30 (m, 18H, o, q), 7.35–7.42 (m, 12H, p), 7.44 (t, J = 5.8 Hz, 1H, r). 13C-NMR (500 MHz, CDCl3, δ (ppm), letters correspond to Fig. 1): 24.5 (j), 26.7 (i), 26.7(h), 30.0 (f), 32.0 (a), 33.6 (k), 37.9 (b), 53.8 (e), 54.5 (g), 58.2 (d), 66.7 (m), 126.7 (q), 127.9 (o), 129.5 (p), 144.7 (n), 171.3 (c), 177.5 (l). LC-ESI-MS (m/z, 10–50 % AcN over 30 min, 1 mL/min, Rt = 34.4 min): 793.8 (calc. 793.35 [C50H53N2O3S2+]); ESI-MS (m/z): 791.38 (calc. 791.33 [C50H51N2O3S2-1][M-H-]). Anal. Calcd (Found) for C50H52N2O3S2·HCl·H2O: C, 70.85 (70.86); H, 6.54 (6.30); N, 3.31 (3.34); S, 7.57 (7.53). N1-((5S,8S)-11-((1H-imidazol-4-yl)methyl)-5-carbamoyl-24-(1H-indol-3-yl)-8-isobutyl-20-isopropyl-17-methyl-7,10,13,16,19,22-hexaoxo-2-thia-6,9,12,15,18,21-hexaazatetracosan-23-yl)-2-(6-((2-mercaptoethyl)(2-((2-mercaptoethyl)amino)-2-oxoethyl)amino)hexanamido)pentanediamide (5) [222-MAMA(N-6-Ahx-BBN(7-14)NH2)] The peptide was synthesized in a model 396 multiple peptide synthesizer (AAPPTEC, Louisville, KY) on a Sieber resin using standard, solid-phase, Fmoc protection strategy for linear elongation. Fmoc protected amino acids with protected side-chains (where appropriate) were used to synthesize the amino acid sequence -Gln-Trp-Ala-Val-Gly-His-Leu-Met-NH2 [BBN(7-14)]. Coupling was achieved by in situ activation with HBTU and DIPEA at every elongation step. 4 was added as the final amino acid using these same conditions. The product was cleaved and side chains deprotected with 85% trifluoroacetic acid (TFA) and non-reducing scavengers (phenol/water/triisopropylsilane, 5% each). The synthesis yielded 300 mg of impure 5 (85% pure), which was HPLC purified (20-40% AcN (0.1% TFA) in H2O (0.1% TFA) over 40 min) resulting in 80 mg of 5 in >98% purity. LC/ESI-MS (m/z, 10–50 % AcN over 30 min, 1 mL/min, Rt = 15.6 min): 1230.3 (calc. 1230.59 [C55H88N15O11S3+][M+H+]), 615.6 (calc. 615.80 [C55H89N15O11S32+][M+2H2+]). N-(2-mercaptoethyl)-2-((2-mercaptoethyl)amino)acetamide (6) [deprotected 222-MAMA] 2 (0.1 g, 0.1 mmol) was deprotected with 0.4 mL of a TFA solution (95% TFA:5% triethylsilane [TES]) at room temperature for 2 h with constant shaking. The solvent was evaporated under N2 (g), and the resulting solids were extracted with hexanes (6 x 10 mL) to yield an oil (0.03 g, 0.1 mmol). 1H-NMR (500 MHz, d6-DMSO, δ(ppm), letters correspond to Fig. 1): 2.56 (dt, J = 7.2, 7.1 Hz, 2H, a), 2.73 (dt, J = 6.5, 6.5 Hz, 2H, f), 2.78–2.88 (m, 1H, g), 3.11 (t, J = 7.5 Hz, 2H, e), 3.30 (dt, J = 6.3, 6.4 Hz, 2H, b), 3.76 (s, 2H, d), 8.61 (s, 1H, h). 13C-NMR (500 MHz, d6-DMSO, δ (ppm), letters correspond to Fig. 1): 19.5 (f), 23.3 (a), 42.1 (b), 47.4 (d), 49.4 (e), 165.1 (c). ReO(222-MAMA(N-6-Ahx-OEt)) [ReO-3] Method 1 3 (0.9277 g, 1.1 mmol) was deprotected in a TFA solution (95% TFA:5% TES), washed with hexanes (6 × 10 mL), dissolved in MeOH (18 mL), and pH adjusted to 4.5–5 with 1 M NH4OAc in MeOH using pH strips. ReOCl3(PPh3)2 (0.98 g, 1.2 mmol) was added as a solid and the reaction mixture refluxed at 80 °C for 3.5 h. The product mixture was rotary evaporated to dryness, and dissolved in EtOAc (20 mL) and water (20 mL). The organic layer was extracted with saturated NaCl solution (20 mL), filtered to remove green solids, dried over anhydrous sodium sulfate, and taken to dryness in vacuo. The residue dissolved in CH2Cl2 was purified on a silica gel column (1 in. × 6 in.), eluted with 100% CH2Cl2 (250 mL), 1% MeOH in CH2Cl2 (200 mL), 2% MeOH in CH2Cl2 (300 mL), 4% MeOH in CH2Cl2 (200 mL), 7% MeOH in CH2Cl2 (200 mL), 10% MeOH in CH2Cl2 (200 mL), and 15% MeOH in CH2Cl2 (100 mL), sequentially. Colored bands were collected as separate fractions (i.e., a brown band, a red band, and a second brown band). Each fraction was rotary evaporated to dryness. The first (0.3735 g impure product) and second (0.0680 g impure product) brown bands were each HPLC purified (Betabasic-18, 10–40% AcN over 10 min, followed by 40-43.25% AcN over 13 min, and followed by 43.25–50% AcN over 2 min, 1 mL/min) in portions to collect the HPLC peaks at 18.5 min and 19.2 min together. The collected peaks were rotary evaporated to dryness, dissolved in CHCl3, dried over anhydrous Na2SO4, and rotary evaporated to dryness. Approximately 25% yield (0.15 g, 0.28 mmol) of solid ReO-3 was obtained. IR (KBr Pellet): 1653.0 cm−1 (C=O); 969.90 cm−1 (Re=O). 1H-NMR (500 MHz, CDCl3, δ (ppm), letters correspond to Fig. 1): 1.27 (t, J = 7.0 Hz, 3H, n), 1.38-1.48 (quint, J = 7.5 Hz, 2H, i), 1.64 (dd, J = 4.5, 12.8 Hz, 1H, e), 1.72 (quint, J = 7.6 Hz, 2H, j), 1.77–1.92 (m, 2H, h), 2.36 (t, J = 7.3 Hz, 2H, k), 2.90 (dd, J = 4.5, 13.5 Hz, 1H, f), 3.10–3.32 (m, 3H, a, b, e), 3.38 (dt, J = 3.2, 13.3 Hz, 1H, f), 3.53 (td, J = 3.7, 12.9 Hz, 1H, g), 3.95 (dt, J = 5.9, 12.8 Hz, 1H, g), 4.10 (dt, J = 3.3, 13.5 Hz, a), 4.15 (q, J = 7.2 Hz, 2H, m), 4.19 (d, J = 16.5 Hz, 1H, d), 4.54 (dd, J = 5.7, 11.8 Hz, 1H, b), 4.70 (d, J = 16.5 Hz, 1H, d). 13C-NMR (500 MHz, CDCl3, δ (ppm), letters correspond to Fig. 1): 14.2 (n), 23.5 (h), 24.4 (j), 26.3 (i), 33.8 (k), 39.1 (f), 47.7 (a), 59.6 (b), 60.7 (m), 63.6 (g), 64.2 (e), 67.0 (d), 173.5 (l), 188.1 (c). UV-Vis (ethyl acetate): 358 nm. LC/ESI-MS (m/z; Betabasic-18, 10-50% AcN over 30 min, 1 mL/min; Rt = 30.1 min): 537.1 (calc. 537.09, [C14H26N2O4ReS2+][M+H+]). Anal. Calcd (Found) for C14H25N2O4ReS2·0.36CH2Cl2: C, 30.46 (30.82); H, 4.58 (4.42); N, 4.95 (4.88); S, 11.32 (10.98). Method 2 Ammonium perrhenate (0.044 g, 0.16 mmol) and sodium citrate dihydrate (0.060 g, 0.20 mmol) were dissolved in 5 mL of DI water. Stannous tartrate (0.10 g, 0.37 mmol) was added and the reaction mixture was stirred at room temperature for 10 min to yield a blue solution. In a separate vial, 3 (0.050 g, 0.061 mmol) was deprotected in a TFA solution (95% TFA:5% TES), washed with hexanes (6 × 10 mL), and rotary evaporated to dryness to yield 6. The rhenium-citrate solution was added to the vial containing 6 and the reaction was refluxed at 85 °C for 4 h. Sodium phosphate (pH 5) was added and the reaction was refluxed for another 4 hr. The reaction mixture was cooled to room temperature, extracted with EtOAc (2 × 5 mL), the organic extracts were combined, dried over anhydrous Na2SO4 and rotary evaporated to dryness. Approximately 60% yield (0.2 g, 0.37 mmol) of solid ReO-3 was obtained. HPLC: (Betabasic-18, 10–50 % AcN over 30 min, 1 mL/min) Rt = 30.2 min. LC/ESI-MS (m/z; Betabasic-18, 10–50% AcN over 30 min, 1 mL/min; Rt = 29.4 min): 537.3 (calc. 537.09, [C14H26N2O4ReS2+][M+H+]). ReO(222-MAMA(N-6-Ahx-BBN(7-14)NH2)) [ReO-5] Method 1 5 (14.1 mg, 11.4 μmol) and ReOCl3(PPh3)2 (12.5 mg, 15.0 μmol) were combined in a 1.5 mL snap cap centrifuge tube, followed by MeOH (400 μL) and 1 M NH4OAc in MeOH (100 μL). The centrifuge tube was capped and the reaction mixture was heated at 80 °C for 2 h with stirring. The product mixture was centrifuged and the supernatant removed (~ 300 μL). A portion of the sample (50 μL) was removed for LC-ESI-MS. The solids were washed with 200 μL of MeOH, centrifuged, and the supernatant removed four times. The combined supernatants were rotary evaporated to yield 20.7 mg of impure product. The residue was dissolved in 1 mL of MeOH and HPLC purified (Nova-Pac semi-prep, 10–50% AcN over 60 min, 10 mL/min). The peaks from 47 to 50 min (38.5-40% AcN in water with 0.1% TFA) were collected. The product was further HPLC purified (Betabasic-18, 37–50 % AcN over 20 min, 1 mL/min; collected the 5.3 min peak) and the solvents removed in vacuo to obtain 2.0 mg of pure ReO-5 (12 % isolated yield). LC-ESI-MS (m/z; Betabasic-18, 10–50 % AcN over 30 min, 1 mL/min; Rt = 25.5 min): 1430.4 (calc. 1430.52 [C55H85N15O12ReS3+][M+H+]); 1452.5 (calc. 1452.5 [C55H84N15O12ReS3Na+]); 715.8 (calc. 715.8 [C55H86N15O12ReS32+][M+2H2+]). Method 2 Ammounium perrhenate (2.69 mg, 10.04 μmol), sodium citrate dihydrate (5.91 mg, 20.1 μmol) and tin(II) tartrate (8.0 mg, 30.0 μmol) were added to 200 μL of DI water and sonicated for 15 min, or until the light blue color of Re-citrate had formed. In a separate vial, 5 (9.27 mg, 0.648 μmol), the Re-citrate solution, and 100 μL AcN were combined in a 1.5 mL snap cap centrifuge tube, and heated at 70°C for 1 h. The reaction mixture was centrifuged and the supernatant collected. The solids were washed with 50:50 AcN:H2O (500 μL), centrifuged, and the second supernatant combined with the first. The combined supernatants were filtered through a 0.45 μM filter, purified by HPLC (Betabasic-18, 10–50% AcN over 30 min at 1 mL/min), and the 25 min product peak was collected. The product was rotary evaporated to dryness to yield ReO-5 (10 mg; 90%). LC-ESI-MS (m/z; Betabasic-18, 10–50 % AcN over 30 min, 1 mL/min; Rt = 25.4 min): 1430.4 (calc. 1430.52 [C55H85N15O12ReS3+][M+H+]); 1452.5 (calc. 1452.5 [C55H84N15O12ReS3Na+]). 99mTcO(222-MAMA(N-6-Ahx-OEt)) [99mTcO-3] A GAS solution (56.4 mM sodium glucoheptonate, 0.25 M HCl, 3.7 mM SnCl2 solution) was prepared. A mixture of 3 in EtOH (0.006 M, 0.3 mL), generator eluent (0.3 mL; 300 MBq (10 mCi)), and GAS (0.3 mL) was vortexed and allowed to react at 70 °C for 40 min. Phosphate buffer (0.9 mL of a 20 mM solution, pH 8–9) was added to the reaction mixture, which was then vortexed, and allowed to react at 70 °C for 30 min. The EtOH was removed from the reaction mixture under a stream of N2 and the resultant mixture was extracted with EtOAc (3 × 2.0 mL). The organic layer was analyzed by radio-HPLC (Betabasic-18, 10–50% AcN over 30 min, 1 mL/min; Rt = 30.4 min). Radiochemical purity: 82 ± 7%. 99mTcO(222-MAMA(N-6-Ahx-OH)) [99mTcO-4] The 99mTcO-4 was prepared using the same procedure described for 99mTcO-3, except with 0.3 mL of an EtOAc solution of 4 (4.97 mg in 0.32 mL EtOAc), with 23.2% isolated radiochemical yield. The organic layer was analyzed by radio-HPLC (Betabasic-18, 10-50% AcN over 30 min, 1 mL/min; Rt = 20.2 min). 99mTcO(222-MAMA(N-6-Ahx-BBN(7-14)NH2)) [99mTcO-5] A GAS solution (56.4 mM sodium glucoheptonate, 0.25 M HCl, 3.7 mM SnCl2 solution) was prepared. A mixture of 5 in a 50:50 EtOH:H2O solution (0.81 mM, 0.1 mL), 0.3 mL of generator [99mTc]-TcO41- eluent (~0.91 GBq (25 mCi)), and 0.3 mL of the GAS solution was vortexed, reacted in a 70 °C water bath for 40 min. Approximately, 0.3 mL of 20 mM phosphate buffer was added, and the resulting solution was pH 2. The product mixture was purified via a Waters Sep-Pak C18 Plus Light cartridge, which had been pretreated with 10 mL of EtOH followed by 10 ml of H2O. Three fractions were collected, the load volume, a 1 ml H2O wash, and a 1 ml EtOH elution. The EtOH fraction, contained ~0.21 GBq (5.7 mCi; 65.1% of the activity loaded). An aliquot of the concentrated 99mTcO-5 sample (7-8 μCi) was added to a sterile saline and checked for purity (Betabasic-18, 10–50% AcN over 30 min, 1 mL/min, Rt = 21.6 and 24.3 min in a 1:4 ratio). Radiochemical yield: 53 ± 6%, pre-purification; radiochemical purity: 88 ± 3%, post purification Initial cysteine challenge experiment The concentrated 99mTcO-5 product (50 μL, ~ 30 MBq (0.8 mCi) per vial) was added to approximately 450 μL of 1.1 mM cysteine in phosphate buffered saline (PBS) and incubated in a 37 °C water bath. The challenge experiment was performed twice (n = 3 each time), as was the experiment with pertechnetate blanks (using 99mTcO41− generator eluent instead of the 99mTcO-5 solution). RadioTLC analysis was accomplished using saturation pads that were developed in saline and 50% AcN in water. Pertechnetate moved with the solvent front in both cases, while 99mTcO-5 remained at the origin in saline and moved with the solvent front in 50% AcN in water. The strips were cut in half and counted using a NaI(Tl) well detector at 0, 1, 4, and 24 h for both 99mTcO41− and 99mTcO-5. Carrier Added 186ReO(222-MAMA(N-6-Ahx-OEt)) [ca 186ReO-3] A GA10S solution (55 mg sodium glucoheptonate, 50 μL HCl, 35 mg SnCl2·2H2O, and 3.5 mL H2O) was prepared. A mixture of 3 in EtOAc (4.5 mM, 0.3 mL), 10 μL of a [186Re]-ReO41− solution (8.25 MBq (223 μCi) of 186Re; 6.6 GBq/mg Re (0.179 Ci/mg)), and 0.3 mL of GA10S were combined, vortexed, and reacted in a 70 °C water bath for 40 min. Phosphate buffer (0.3 mL of a 20 mM solution, pH 8-9) was added, the solution was vortexed, and the reaction was continued in a 70 °C water bath for 30 min. The product mixture was extracted with EtOAc (2 × 2 mL) and the layers were counted using the dose calibrator (64.6% extracted yield). The first EtOAc collection vial contained 1.65 mg of gentisic acid (2,5-dihydroxybenzoic acid) to prevent radiolysis of the complex. Carrier Added 186ReO(222-MAMA(N-6-Ahx-BBN(7-14)NH2)) [ca 186ReO-5] 5 (0.8 mg, 0.7 μmol) in 0.3 mL of EtOH and 0.15 mL of a carrier added [186Re]-Al(ReO4)3 solution in water (32.9 MBq (889 μCi), 3.6 GBq/mg (0.098 Ci/mg), 0.0091 mg, 0.048 μmol) were combined with0.15 mL of deionized water and 0.3 mL of freshly prepared GA10S. The reaction mixture was vortexed, reacted at 75–80 °C in a dry bath for 40 min, and pH adjusted with pH 8–9 phosphate buffer (0.3 mL of a 20 mM phosphate buffer) to approximately 6.5. The product mixture was purified via a pretreated C-18 column (BondElut, Agilent Technologies, 1 in. × 2 in.) eluted with 15 mL of 50:50 AcN in H2O. Three fractions were collected with volumes of 4 mL, 6 mL, and 5 mL, respectively. The 6 mL fraction (45% isolated radiochemical yield) was collected with gentisic acid (8 mg), concentrated in a 70 °C water bath with a stream of N2 (g), and analyzed by radioTLC (0 and 1 h). No Carrier Added 186ReO(222-MAMA(N-6-Ahx-BBN(7-14)NH2)) [nca 186ReO-5] 5 (0.2 mg, 0.1 μmol) in 100 μL of absolute ethanol, 7.4 MBq (0.2 mCi) of nca 186ReO41- and 0.1 mL of GAS solution (56.4 mM sodium glucoheptonate, 0.25 M HCl, 3.7 mM SnCl2 solution) were combined, vortexed and heated in a sand bath at 80°C for 1 h. After removing from heat, 0.1 mL of 20 mM phosphate buffer was added. The reaction mixture was purified on a C-18 column (BondElut, Agilent Technologies, 0.5 in. × 0.5 in.) that had been pretreated with 5 mL of 50:50 AcN:H2O. The reaction mixture was loaded, washed with 3 mL of H2O, and eluted with 5 mL of 50:50 AcN:H2O. HPLC (Jupiter C-18 column, at 25 °C with a gradient of 10–70% AcN with 0.1% TFA in water with 0.1% TFA over 15 min) retention time: 13.1 min, analogous to the macroscopic ReO-5 standard, indicated formation of nca 186ReO-5. Initial stability studies in 0.88 mM cysteine The ca 186ReO-5 was prepared as described above, evaporated to near dryness and reconstituted in EtOH. An aliquot of the ethanolic solution (40 μL) was added to each of three tubes containing 160 μL of 1.1 mM cysteine, which were placed in a 37 °C water bath. Samples were analyzed by HPLC (Betabasic-18, 10–30% AcN over 15 min, followed by 30–50% AcN over 15 min, 1 mL/min) at 0, 1 and 17.4 h. The 17.4 h sample was also analyzed by TLC (paper chromatography, saline and 50% AcN in water eluents) and LSC. A sample prepared without cysteine was used as the standard for comparison. In vitro cell binding studies with ReO-5 and PC-3 tumor cells The protocol used was previously reported [24]. Specifically, [125I]-Tyr4-BBN(NH2) (PerkinElmer, Waltham, MA) was used as the competitor; cell media [500 mL RPMI 1640 cell media (Invitrogen, Carlsbad, CA) was supplemented with approximately 30 μM bovine serum albumin (BSA, 1 g, 15 μmol) and 20.6 mM 2-[4-(2-hydroxyethyl)piperazin-1-yl]ethanesulfonic acid (HEPES, 2.46 g, 10.3 mmol), filtered through a 0.22 μm sterile filter, and pH adjusted to 7.4] was prepared for the study. Approximately 30,000 PC-3 cells were incubated at 37 °C, 95% humidity, and 5% CO2 for 45 min, with approximately 30,000 cpm [125I]-Tyr4-BBN(NH2) and varying concentrations of ReO- 5 (prepared by Method 1) in the modified cell growth media. The cells were washed with cold modified media to remove unbound activity. An LTi Multi-Wiper gamma counter (LTI Laboratory Technologies; Elburn, IL) was used to count the activity bound to the cells. The entire process was performed three times in duplicate. The IC50 value was calculated using GraFit (Erithacus Software, West Sussex, UK). Pharmacokinetic studies in CF-1 mice All animal experiments were conducted in accordance with protocols approved by the Harry S. Truman Memorial Veteran’s Administration Hospital Subcommittee for Animal Studies. Normal mice (CF-1; 8 weeks old; Charles Rivers Laboratories; Wilmington, MA) were injected via the tail vein with approximately 0.37 MBq (10 μCi) of the radiolabeled material in approximately 100 μL of sterile PBS. The mice were sacrificed at 1 h (eight mice, four with 99mTcO41− and four with 99mTcO-5) post injection. The organs and tissues were isolated, weighed, counted using a NaI(Tl) well counter, and the percent injected dose (% ID) and percent injected dose per gram (% ID/g) of each were calculated. The entire blood mass was estimated to be 6.5% of the total body weight [26]. All urinary bladder contents excreted from the time of injection to the time of sacrifice were collected, counted, and reported as urine (% ID). 2.3. Computational Methods All calculations were performed using the Guassian09 program package [29,30]. ReO-2 and ReO-222-MAMA(N-methyl) were fully optimized in the gas and solution phases (SMD chloroform [31]) using the PBE0/6-31G**,LANL2TZ method and basis set as validated in our previous work [32]. (In this notation, the first basis set (6-31G**) was used for the non-metal atoms; the second basis set (LANL2TZ) was used for the metal atom.) All equilibrium structures were verified as minima (no imaginary frequencies). The NMR calculations discussed herein were performed using the GIAO method [29] on the lowest-energy PBE0/6-31G**,LANL2TZ gas- or solution-phase equilibrium structure. The calculated NMR shifts are referenced to the 13C- and 1H-NMR shifts for tetramethylsilane computed at the same level and in the same phase. 3. Results and Discussion The 222-MAMA ligand conjugated to BBN(7–14)NH2 via a six carbon spacer was investigated as a potential bifunctional chelate for 186/188Re(V), the most readily accessible oxidation state of Re from the available 186/188ReO41− [6]. Although the 222-MAMA ligands have been evaluated with 99mTc, none conjugated to a peptide for chelating 186/188Re have been reported. The overall scheme for preparing the oxorhenium(V) or oxotechnetium(V) complexes with the various 222-MAMA ligands is shown in Fig.. 3.1. Ligand and bifunctional chelator synthesis 2 was coupled to BBN(7–14)NH2 through a 6-carbon linker, which was complexed with rhenium for in vitro and technetium for in vivo studies. The target 222-MAMA(N-6-Ahx-BBN(7–14)NH2) (5) was prepared in three steps as shown in Schemes 1–3 using TFA in the final step to cleave 5 from the resin bead [10,33]. The trityl groups for the ligands (2 and 3) were removed using TFA and TES prior to reacting with ReOCl3(PPh3)2 (Method 1) or rhenium-citrate (Method 2), or in situ with 99mTc or 186Re on the radiotracer scale in the presence of Sn2+ and low pH conditions. The bifunctional chelator (4), synthesized from 3, was conjugated to the BBN(7–14) peptide via traditional solid-phase peptide synthesis utilizing the carboxylic acid derivatized product as the final amino acid-like reactant. 5 was cleaved from the Sieber resin bead. The crude product was 85% pure, and further purified by semi-preparative HPLC to obtain pure 5 (>98% pure). 3.2. Rhenium Complexes The oxorhenium(V) 222-MAMA complexes with 3 and 5 were synthesized from either ReOCl3(PPh3)2 or ReO(citrate)21−, and exhibit absorbance around 358 nm (λmax). The 1H-NMR spectra exhibit complex splitting patterns indicating that the backbone protons became unique on coordination to the monooxorhenium(V) core. All chemical shifts are observed downfield on complexation with the exception of the methylene protons on the carbon alpha to the amine (e in the free ligands and the complexes, Fig. 1), with one of the protons shifted upfield and the other downfield, and identified via 2-D NMR experiments. Gas-phase NMR computations of the syn and anti isomers of ReO-222-MAMA(N-methyl) at the PBE0/6-31G**,LANL2TZ level using the GIAO method with chloroform solvent effects (SMD method) were used to validate the assignment of the upfield shifted proton. The assignment of protons in ReO-3 is consistent with the 1H-NMR results published by Katzenellenbogen and co-workers for syn-ReO-222-MAMA(N-benzyl) [11] and Jones and coworkers for the ReO-222-MAMA(N-β-Ala-OCH2CH3) complex [12]. The dramatic splitting of the protons on carbon e [2.33–2.41 ppm in 3 to 1.64 and 3.10–3.32 ppm in ReO-3] is due to the proximity to the Re≡O bond. The quantum-mechanical NMR computations indicate that the complex isolated from our synthesis is the syn isomer. The 1.24 ppm difference in chemical shifts between the e protons determined computationally for the syn isomer is similar to the 1.6 ppm shift difference observed for ReO-3 experimentally. Additionally, the downfield shift of peak g (3) from 2.18–2.28 multiplet to 3.53 ppm triplet of doublets and 3.95 ppm triplet of doublets indicates that the syn isomer was isolated [12,13]. The e proton shifts from our quantum-mechanical NMR computations for the anti isomer show a difference of 0.5–0.7 ppm. According to our calculations, the syn and anti isomers are equally thermodynamically favorable, but the transition between the two requires inversion of the rhenium center (through an associative mechanism using water) or deprotonation (basic conditions) of the amine. All of the 13C-NMR carbon signals are observed downfield on complexation to the monooxorhenium(V) center. Again, the 13C-NMR peak shifts closely match those reported for ReO-222-MAMA(N-β-Ala-OCH2CH3) [12]. All Re complexes were characterized by reversed phase HPLC, as standards for the 99mTc and nca 186Re analogues prepared at the radiotracer level using several methods. Table 2 lists the retention times of the complexes by the two most commonly used methods. 3.3. Radiolabeling of 3 The radiolabeling of 3 was optimized using 99mTcO41− under a variety of reaction conditions (i.e., deprotected ligand or protected ligand, biphasic or aqueous reaction mixtures, reaction pH (1–9), reaction time (20–40 min), reaction temperature (30–70 °C), and ligand concentration (0.0025–6.7 mM in the total reaction mixture). These studies were monitored by EtOAc extraction (following the extraction method used by Oya et al. [10]). The optimal radiolabeling yield was observed with the protected ligand dissolved in EtOH (0.006 M, 0.3 mL), a 40 min reaction time at 70 °C with pH of ~1 (from the GAS solution), a pH adjustment with 20 mM pH 8–9 phosphate buffer, a 30 min heating at 70 °C, and an EtOAc extraction. A radiochemical yield of 85±4% was observed. HPLC analysis of the product mixture (Fig. 3) indicates that the product from the 99mTc labeling reaction with 3 (222-MAMA(N-hexanoate)) (Rt = 30.4 min) is analogous to the non-radioactive ReO-3 HPLC standard (Rt = 30.2 min). The 186ReO-3 complex, using ca 186Re, was prepared similarly to the 99mTcO-3 complex (by Method 1), utilizing a GAS solution with ten times the [Sn2+] (GA10S) and gave an extracted yield >60%. The increased Sn2+ concentration was required because rhenium is more difficult to reduce than technetium [34] and the [186Re]-ReO41− solution was carrier added. EtOAc extractions of [186Re]-ReO41− from saline contained 6.24% of the radioactivity. The EtOAc layer from the ca 186ReO-3 labeling-reaction product mixture extraction contained approximately 5 % 186ReO2 (from TLC analysis). The amount of carrier added 186ReO-3 produced was insufficient for HPLC analysis. 3.4. Radiolabeling of 5 The 99mTc labeled 222-MAMA(N-6-Ahx-BBN(7–14)NH2) complex, 99mTcO-5, was prepared as described above with 53±6% yield. The 99mTcO-5 was purified by Sep-Pak to remove 99mTcO41−, 99mTcO2, and excess 5. Unreacted ligand 5 was still present according to the HPLC analysis; however, 99mTcO-5 was not further purified. Approximately 30% of the unlabeled 5 (average 0.03 mg) remained in solution following Sep-Pak purification. Radio-HPLC analysis of the purified 99mTcO-5 product mixture showed 88 ± 3% purity in the combined 21.6 and 24.3 min peaks, with the remainder present as pertechnetate. When 99mTcO-5 was purified by Sep-Pak, two species were observed at 21.6 min and 24.3 min, presumably the syn and anti isomers. This isomerization was confirmed by collecting each individual product (peak) separately, reducing the volume, and reinjecting a sample (Fig. 4). The species at 21.6 min showed the growth of a peak at 24.3 min, which over time equilibrated to a 1:2 ratio favoring the later eluting species. The 24.3 min species changed very little over time, with <5% in-growth of the 21.6 min species. To verify this isomerization reaction, an aliquot of ReO-5 was dissolved in EtOH and analyzed by HPLC over time. Two species were observed at 22.1 and 24.8 min, with the 24.78 min species dominating (89%). In AcN only the later eluting species is observed. The 99mTcO-5 was relatively stable in sterile saline (without added gentisic acid) dropping from ≥90% initially to ≥75% remaining at 6 h, as confirmed by HPLC. The ca 186ReO-5 complex was prepared similarly to ca 186ReO-3 and isolated by C18 column chromatography, and collected into a vial containing gentisic acid. The isolated fraction (0.988 mCi/mL) contained the majority of the desired product (approximately 66% of the total radioactivity). The isolated ca 186ReO-5 co-eluted with the ReO-5 standard at 10.1 min (Jupiter C-18, 30–60% AcN in water without TFA over 15 min) or 20.5 min (Betabasic, 10–30% AcN in water with 0.1% TFA over 15 min and 30–50% AcN in water with 0.1% TFA over 5 min) and was unstable in the absence of gentisic acid. Previous results have shown that complexes containing beta emitters are less prone to radiolysis with the addition of a small amount of gentisic acid [35–38]. To assess the stability of ca 186ReO-5 in biological media, the complex was incubated with 0.88 mM cysteine at 37 °C in PBS. HPLC analysis showed only 186ReO-5 until 17.4 h, at which time TLC analysis indicated about 10–12% 186ReO41− and at most 1% 186ReO2 had formed. Thus, after 17.4 h approximately 86–89% of the original 186ReO-5 complex remained intact. This amount is approximately the same as the amount of the 99mTcO-5 complex intact after 1 h. The difference in stability could be due to the addition of gentisic acid in the purified ca 186ReO-5 sample or the higher concentration of the ca 186ReO-5 synthesis. These results are consistent with the stability of 186ReO-MAMA(N-bisphosphonate) derivatives reported by Ogawa et al. [39]. The nca 186ReO-5 was synthesized similarly to 99mTcO-5 and was analyzed by HPLC (Jupiter C-18 column, at 25°C with a gradient of 10–70% AcN in water with 0.1% TFA over 15 min) (Fig. 5). Initially, only one peak at 13.1 min was observed, which over time separated into two peaks (likely the syn and anti isomers) observed at 12.5 and 13.5 min. These results are consistent with those observed for 99mTcO-5 and indicate formation of the desired nca 186ReO-5 product. Two isomers are observed for ReO-5 only when EtOH is present. 3.5. In vitro Stability Studies Initial stability studies of HPLC purified 99mTcO-5 complex (without gentisic acid) in 1 mM cysteine at 37 oC showed that approximately 90% remained intact at 1 h and 48% at 24 h (Fig. ). Oya et al. reported that 70% of the 99mTcO-2 complex was intact after incubation in rat serum at 37 °C for 30 min [10]; Yamamura et al. reported that 87.1% of 99mTcO-4 remained intact after 1 h in 10 μM cysteine in 0.05 M phosphate buffer (pH 7.0) at 37 °C [40]. 3.5. In vitro competitive cell binding studies In vitro competitive cell binding studies in PC-3 prostate cancer cells, known to express GRP (BB2r) receptors, of ReO-5 (prepared by Method 1) against [125I]-Tyr4-BBN(NH2) gave a calculated IC50 value of 2.0 ± 0.7 nM (n = 6). This value is similar to previous results with other metalated and non-metalated BB2r targeting compounds [21,22]. Additionally, this value is nearly identical to that reported for In-DOTA-5-Ava-BBN(7–14)NH2 (1.7 ± 0.4 nM) [22] and is similar to the value reported for ReO-N3S-5-Ava-BBN(7–14)NH2 (1.0 ± 0.2 nM) [20]. 3.6. In vivo biodistribution studies Biodistribution studies with the 99mTcO-5 complex (prepared by Method 2, >95% pure) were performed in normal CF-1 mice, with four mice injected with TcO-5 (0.26–0.40 MBq; 7–8 μCi) and four mice injected with BBN[1–14] as a blocking agent 5 min prior to injection of 99mTcO-5 (0.26–0.40 MBq; 7–8 μCi). The biodistribution data obtained from these studies is tabulated in Table 3 and shown graphically in Figs. 7 and 8. Approximately 2 % ID/g uptake was observed in the pancreas; this lower pancreatic uptake may be due to the presence of unlabeled 5 competing for receptor sites. Thus, HPLC purification may be necessary to increase the specific activity of the tracer, which may improve tumoral uptake in future in vivo studies. The pancreatic uptake does suggest BB2r targeting because the uptake was blocked by injection of BBN[1–14] prior to injection of 99mTcO-5. Additionally, the complex is very hydrophobic, as seen with its long HPLC retention time and its high liver and intestinal uptake. Conclusions and future directions The 222-MAMA-based chelators were synthesized for potential use in radiopharmaceuticals that incorporate 186/188Re. The 222-MAMA chelator was conjugated to BBN(7–14)NH2 and analyzed via 99mTc, non-radioactive Re, and carrier-added and no carrier added 186Re studies. Cell surface receptor binding studies with the ReO-5 complex and in vivo studies with 99mTcO-5 indicate BB2r targeting by these constructs. Thus, these studies indicate that 222-MAMA(N-6-Ahx-BBN(7–14)NH2) chelates oxorhenium(V) and oxotechnetium(V) for delivery in vivo to BB2r-positive tissues. The bifunctional chelator (3) may be useful for conjugation to other biological targeting vectors and may have utility for delivering therapeutic doses of 186/188Re to tumor tissues using peptides and antibodies. The availability of nca 186Re gives impetus to develop 99mTc/186Re “matched pair” agents for imaging and treating cancer. Supplementary Material supplement Dr. Susan Lever provided helpful suggestions with the organic chemistry work. Drs. Tim Glass, Michael Harmata, and Vikram Gaddam were instrumental in obtaining 3 and 4. Ma-Guadalupe Ruvalcaba Andrade helped with corroborating the synthesis of these compounds. The authors acknowledge the University of Missouri Bioinformatics Consortium for the use of their High Performance Computing resources, University of Missouri Mass Spectroscopy Facility, National Science Foundation grant NSF-CHE-89-08304 for the use of the NMR facility, and Dr. Wei Wycoff for assistance with the NMR. Research was supported by the National Institute of Biomedical Imaging and Bioengineering Training Grant No. NIBIB 5 T32 EB004822 (DWD). The research was also supported in part by the U.S. Department of Energy, Office of Basic Energy Sciences, Heavy Element Chemistry program under grant No. DE-FG02-09ER16097 and Projects for Interrogations of Biological Systems No. DE-SC0002040 as well as VA Merit Award Number 1I01BX001699 and a Research Career Scientist Award (TJH) from the Biomedical Laboratory Research and Development Service of the U.S. Department of Veterans Affairs. Figure 1 1–6, and ReO-3 with lettering scheme used for 1H- and 13C-NMR. Figure 2 Overall schematic for rhenium and technetium complex formation (R is H, (CH2)5COOEt, (CH2)5COOH, or (CH2)5CO-QWAVGHLM-NH2). Figure 3 HPLC chromatograms (Betabasic, 10–50% AcN over 30 min, 1 mL/min) of A) 99mTcO-3 (radio-HPLC), and B) ReO-3 (UV-vis, 358 nm). The 21.9 min peak is presumably 99mTcO-4 (from ester hydrolysis during ligand deprotection). Figure 4 HPLC chromatograms (Betabasic, 10–50% AcN over 30 min, 1 mL/min) of A) 99mTcO-5, B) isolated 21.6 min peak re-injected (shows in-growth of 24.3 min species), and C) isolated 24.3 min peak (shows very little in-growth of 21.3 min species). Figure 5 HPLC chromatograms (Jupiter C-18, 10–70% AcN over 15 min, 1 mL/min) of A) ReO-5 and B) nca 186ReO-5. Figure 6 99mTcO-5 stability over 24 h in 1 mM cysteine at 37 °C. Fig. 7 Biodistributions in percent injected dose (%ID) for 99mTcO-5 (at 1 h) and 99mTcO-5 (at 1 h) with blocking agent administered 5 min prior. Fig. 8 Biodistributions in percent injected dose per gram (%ID/g) for 99mTcO-5 (at 1 h) and 99mTcO-5 (at 1 h) with blocking agent administered 5 min prior. Scheme 1 Two-step preparation of target trityl-protected MAMA ligands.13 Scheme 2 Attaching linking group to chelator and subsequent saponification to obtain the bifunctional chelator. Scheme 3 Solid-phase peptide synthesis (SPPS) and cleavage to give the bifunctional chelator conjugated to the targeting peptide. Table 1 Nuclear properties of 186/188Re [4]. Nuclide t1/2 Eβ− max γ decay energy (% abundance) Rangeβ− max (H2O) Production routes [1–3] 186Re 3.7 d 1.1 MeV 137 keV (8%) 4.8 mm 185Re(n,γ)186Re 186W(p,n)186Re 186W(d,2n)186Re 188Re 17 h 2.1 MeV 155 keV (15%) 10.4 mm 186W(2n,γ)188W → β − + 188Re + ν̄ 187Re(n,γ)188Re Table 2 HPLC retention times of compounds. Compound Betabasic-18, 10–50% AcN with 0.1% TFA over 30 min, 1 mL/min Jupitor-18, 10–70% AcN with0.1% TFA over 15 min, 1 mL/min ReO-3 (method 1) ReO-3 (method 2) 30.1 min 30.2 min 99mTcO-3 30.4 min 99mTcO-4 20.2 min 5 15.6 min ReO-5 (method 1) ReO-5 (method 2) 25.5 min 25.4 min 13.2 min 99mTcO-5 (method 2) 24.3 min nca 186ReO-5 13.1 min Table 3 Biodistribution in CF-1 normal mice for 99mTcO-5 and blocking study at 1 h post injection. %ID (n=4) %ID/g (n=4) 99mTcO-5 Blocked 99mTcO-5 Blocked Heart 0.02±0.02 0.05±0.07 0.11±0.16 0.40±0.51 Lung 0.13±0.16 0.15±0.07 0.55±0.69 0.80±0.41 Liver 20.61±4.47 12.47±4.27 10.38±1.88 6.51±1.98 Kidneys 2.00±0.23 1.60±0.39 4.24±0.60 3.57±89 Spleen 0.15±0.20 0.13±0.15 1.07±1.48 0.86±1.10 Stomach 1.64±0.71 1.44±0.33 3.60±2.15 1.87±0.29 S. Intestine 27.40±9.51 59.19±3.14 15.46±6.08 29.72±2.22 L. Intestine 23.20±10.47 0.39±0.05 18.04±8.25 0.37±0.11 Muscle 0.02±0.03 0.10±0.08 0.06±0.12 0.54±0.40 Bone 0.02±0.04 0.11±0.15 0.32±0.64 1.52±2.17 Brain 0.01±0.02 0.03±0.03 0.02±0.04 0.06±0.06 Pancreas 0.72±0.03 0.09±0.06 2.03±0.42 0.24±0.17 Bladder 2.46±1.12 1.40±0.16 0.05±0.02 0.3±0.06 Blood 0.83±0.23 1.09±2.80 0.38±0.09 0.49±0.52 Carcass 5.50±0.53 4.57±0.49 0.24±0.04 0.21±0.03 Urine - - 12.95±8.19 18.34±2.22 Cage Paper - - 4.76±9.25 0.23±0.42 Supporting Information Supporting information is available. This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final citable form. 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PMC005xxxxxx/PMC5118111.txt
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It may also be used consistent with the principles of fair use under the copyright law. 7605074 6087 Neuroscience Neuroscience Neuroscience 0306-4522 1873-7544 27693474 5118111 10.1016/j.neuroscience.2016.09.038 NIHMS822629 Article Direct Projections from Hypothalamic Orexin Neurons to Brainstem Cardiac Vagal Neurons Dergacheva Olga * Yamanaka Akihiro ** Schwartz Alan R. *** Polotsky Vsevolod Y. *** Mendelowitz David * * Department of Pharmacology and Physiology, The George Washington University, 2300 Eye Street, NW, Washington, DC, 20037, USA ** Research Institute of Environmental Medicine, Nagoya University, Nagoya 464-8601, Japan *** Johns Hopkins University School of Medicine, Baltimore, MD 21224, USA Corresponding author's address: Olga Dergacheva, Department of Pharmacology and Physiology, The George Washington University, 2300 Eye Street, NW, Washington, DC, 20037, olgad@gwu.edu, phone: 202-994-5029, fax: 202-994-2870. 15 10 2016 28 9 2016 17 12 2016 17 12 2017 339 4753 This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. Orexin neurons are known to augment the sympathetic control of cardiovascular function, however the role of orexin neurons in parasympathetic cardiac regulation remains unclear. To test the hypothesis that orexin neurons contribute to parasympathetic control we selectively expressed channelrhodopsin-2 (ChR2) in orexin neurons in orexin-Cre transgenic rats and examined postsynaptic currents in cardiac vagal neurons (CVNs) in the dorsal motor nucleus of the vagus (DMV). Simultaneous photostimulation and recording in ChR2-expressing orexin neurons in the lateral hypothalamus resulted in reliable action potential firing as well as large whole-cell currents suggesting a strong expression of ChR2 and reliable optogenetic excitation. Photostimulation of ChR2-expressing fibers in the DMV elicited short-latency (ranging from 3.2 ms to 8.5 ms) postsynaptic currents in 16 out of 44 CVNs tested. These responses were heterogeneous and included excitatory glutamatergic (63%) and inhibitory GABAergic (37%) postsynaptic currents. The results from this study suggest different sub-population of orexin neurons may exert diverse influences on brainstem CVNs and therefore may play distinct functional roles in parasympathetic control of the heart. Optogenetic neurons orexin brainstem cardiac parasympathetic Preganglionic cardiac vagal neurons (CVNs) in the dorsal motor nucleus of the vagus (DMV) project directly to the cardiac ganglia and play a substantial role in the cardiac regulation (Sullivan and Connors, 1981, Ciriello and Calaresu, 1982, Cheng et al., 1999). Electrical stimulation of the cardiac branches of the vagus nerve antidromically activates neurons in the DMV and electrical stimulation of the DMV reduces heart rate and myocardial contractility (Calaresu and Pearce, 1965, Nosaka et al., 1979, Ciriello and Calaresu, 1982). Increasing the activity CVNs in the DMV protects the heart from ischemia/reperfusion injury independent of changes in heart rate (Mastitskaya et al., 2012). The activity of CVNs in the DMV are strongly influenced by neurotransmission from other neurons in the brainstem, as well as pathways from the locus coeruleus and oxytocin neurons in the hypothalamus (DePuy et al., 2013, Dergacheva et al., 2014, Pinol et al., 2014, Wang et al., 2014). The results from immunohistochemical studies indicate orexin neurons could be another important source of innervation to neurons in the DMV (Peyron et al., 1998, Date et al., 1999). However, the DMV is a heterogeneous nucleus and it is unknown whether there are direct connections between orexin neurons and the selective population of CVNs in the DMV that play a major role in controlling heart rate and cardiac function. Compelling evidence indicates orexin neurons and receptors play an important role in the regulation of cardiovascular function (Peyron et al., 1998, Ciriello and de Oliveira, 2003, Ciriello et al., 2003, Dergacheva et al., 2005, Carrive, 2013, Dergacheva et al., 2013). Orexin is well known to exert sympathoexcitatory effects such as increases in heart rate, blood pressure and sympathetic nerve activity (Samson et al., 1999, Shirasaka et al., 1999, Chen et al., 2000, Antunes et al., 2001, Matsumura et al., 2001). However, little is known about the role of orexin neurons in parasympathetic control of the heart and the few studies that have examined this issues are conflicting. For example, microinjection of orexin-A into the rostral ventral medulla produces tachycardia mediated in part by inhibition of parasympathetic activity to the heart (Ciriello et al., 2003), whereas microinjection of orexin-A into the nucleus ambiguus elicits bradycardia mediated by excitation of parasympathetic activity to the heart (Ciriello and de Oliveira, 2003). Thus, this study was undertaken to identify and characterize the synaptic pathway from orexin neurons to CVNs in the DMV. To accomplish this goal, we utilized a transgenic strain of orexin-Cre rats that allows us to photoexcite channelrhodopsin-2 (ChR2) in orexin fibers in the brainstem DMV while recording synaptic events in fluorescently identified CVNs in the DMV in an in-vitro slice preparation. EXPERIMENTAL PROCEDURES Animals Orexin-EGFP-2A-Cre rats (both males and females) were used in this study. The generation of these transgenic animals in which Cre recombinase and green fluorescent protein are exclusively expressed in hypothalamic orexin neurons has been described previously (Dergacheva et al., 2016). Rats were housed in the George Washington University animal care facility. All animal surgeries and experiments were approved by the George Washington University Institutional Animal Care and Use Committee. We made all efforts to minimize number of rats used in this study and reduce animal discomfort. Cardiac neuron labeling and viral injections into the lateral hypothalamus Parasympathetic CVNs were labeled as described previously (Dergacheva et al., 2013, Dergacheva, 2015). At postnatal days 4–5 orexin-Cre rats were anesthetized with hypothermia, the heart was exposed and 0.05 ml of 1–5% rhodamine (XRITC; Molecular Probes, Eugene, OR) was injected into the pericardial sac. The previous study showed the specificity of the cardiac vagal labeling (Bouairi et al., 2004). ChR2 fused to enhanced yellow fluorescent protein (EYFP) was targeted to the plasma membrane of orexin neurons and axons as shown in Fig. 1. Adeno-associated viral vector with “FLEX-switch” ChR2 construct (AAV1-ChR2-EYFP, Penn Vector Core, Philadelphia, PA, catalog number AV-1-20298P) was injected into the lateral hypothalamus of orexin-Cre rats using a stereotactic apparatus with a neonatal adapter (Stoelting, Wood Dale, IL). A pulled calibrated pipette (VWR, Radnor, PA) containing viral vector was positioned at the following coordinates: 1.7-1.9 mm posterior and 0.4 mm lateral relative to bregma. The viral vector (60 nL) was slowly injected 5.2 mm lower the dorsal surface of the brain. The pipette was left in the lateral hypothalamus for 5 minutes after injection, then slowly retracted. To reduce pain and discomfort caused by the surgery, buprenorphine was administered after surgery, and animals were carefully monitored until ambulatory. Slice Preparation and Electrophysiology Animals (21-24 days old) were anesthetized with isoflurane and sacrifice by transcardial perfusion of glycerol-based artificial cerebrospinal fluid (aCSF, 4°C) that contained (in mM): 252 glycerol, 1.6 KCl, 1.2 NaH2PO4, 1.2 MgCl, 2.4 CaCl2, 26 NaHCO3, and 11 glucose. Coronal slices of the brainstem (300-μm) were obtained with a vibratome. In another set of experiments 300-μm-thick coronal slices of the hypothalamus that included orexin neurons were made using a vibratome. The slices were then allowed to recover for 15 min in a solution containing (in mM): 110 N-methyl-d-glucamine (NMDG), 2.5 KCl, 1.2 NaH2PO4, 25 NaHCO3, 25 glucose, 110 HCl, 0.5 CaCl2, and 10 mM MgSO4 equilibrated with 95% O2-5% CO2 (pH 7.4, at 34°C). For performing electrophysiological experiments, the slices were transferred to a recording chamber containing (in mM) 125 NaCl, 3 KCl, 2 CaCl2, 26 NaHCO3, 5 glucose, 5 HEPES and equilibrated with 95% O2-5% CO2 (pH 7.4, at 25°C). CVNs in the DMV and orexin neurons in the lateral hypothalamus were identified by the presence of the retrograde tracer and EYFP-expression, respectfully. Infrared-sensitive video detection cameras and differential interference contrast optics were then used to image these identified CVNs and orexin cells. We patched CVNs with patch pipettes (2.5–3.5 MΩ) filled with a solution consisting of (in mM) 150 KCl, 2 MgCl2, 2 EGTA, 10 HEPES, and 2 Mg-ATP, pH 7.3. In experiments that examined activity in orexin cells, the patch pipettes were filled with a solution consisting of 135 mM K-gluconic acid, 10 mM HEPES, 10 mM EGTA, 1 mM CaCl2, and 1 mM MgCl2, pH 7.3. We performed voltage clamp whole-cell recordings at a holding potential of −80 mV. Firing activity of orexin neurons was examined in current-clamp whole-cell configuration. All recordings were made with an Axopatch 200 B and pClamp 8 software (Axon Instruments, Union City, CA). Drugs used in this electrophysiological study were purchased from Sigma-Aldrich Chemical Co (St. Louis, MO). For selective photostimulation of ChR2 expressing fibers surrounding CVNs we used a CrystaLaser (473-nm blue light, Reno, NV, USA) which was attached to the microscope using a dual housing adapter (Nikon). A series of 60 consecutive single stimulations (3 ms, at a frequency of 1 Hz) were applied to each neuron. Laser light intensity was kept at an output of 10 mW across all experiments. Immunohistochemistry and Imaging Study We utilized immunostaining to determine the specificity of ChR2-EYFP expression in orexin neurons in the lateral hypothalamus. Three weeks after AAV1-ChR2-EYFP viral injections into the lateral hypothalamus, hypothalamic slices (100 μm) were prepared and soaked 3 hours in 10% formalin and were then processed for orexin immunoreactivity. Rabbit anti-orexin-A was used as a primary antibody (1: 15,000 dilution, overnight incubation, Phoenix Pharmaceuticals, Inc., Burlingame, CA) and anti-rabbit Alexa Fluor 633 was used as a secondary antibody (1:200, 4 hours, Life Technologies, Carlsbad, CA). For analysis of co-localization of orexin immunoreactivity and ChR2-EYFP-expression the Zeiss 710 confocal imaging system was used. Orexin immunoreactivity was found in 83±3% of ChR2-EYFP neurons whereas 68±3% of orexin-containing neurons expressed ChR2-EYFP, (n=4 rats, see Fig. 1). Data Analysis and Statistics Postsynaptic currents were measured with pClamp 8 software (Molecular Devices, Sunnyvale, CA). The time between the onset of the optogenetic stimulation and the onset of synaptic current evoked by the stimulation was determined as a synaptic latency of the responses. The mean value for each neuron was created by averaging responses to 60 consecutive photostimulations. A summary of results for each population was created by averaging the mean value from each neuron in the population. The results were statistically compared using GraphPad Prism 5 software and using Student's paired T-test. The data is presented as mean ± SE with significant difference set at p < 0.05. RESULTS Selective photostimulation of orexin neurons Optogenetic photostimulation (3 ms, 1 Hz) of orexin neurons fluorescently identified by ChR2-EYFP expression in the lateral hypothalamus generated large inward current (in voltage clamp configuration, 521±1842 pA, n=8, Fig. 2, B,) and reliable action potentials with each photostimulation (n=8 cells, Fig. 2, A). This robust excitation upon photoactivation indicates there is a strong expression of ChR2-EYFP (Schoenenberger et al., 2011). No electrophysiological responses in orexin neurons in the lateral hypothalamus were observed in orexin-Cre rats that did not receive AAV1-ChR2-EYFP viral injections (n=5 cells, Fig. 2, C and D), indicating that the responses were not due to non-specific cellular activation by light pulses. Direct projections from orexin-containing neurons to CVNs in the DMV To identify and characterize functional projection from orexin neurons to CVNs in the DMV optogenetic stimulation of ChR2-containing fibers from orexin neurons was combined with patch-clamp recordings from CVNs. Although brainstem slices that contained CVNs in the DMV did not include the cell bodies of ChR2-EYFP-expressing orexin neurons it has been previously shown that light-triggered transmitter release from ChR2-EYFP-expressing fibers occurs in the absence of the ChR2-EYFP-expressing cell bodies (Pinol et al., 2012, Schone et al., 2012, Dergacheva et al., 2014). Photostimulation of ChR2-EYFP fibers with brief light pulses (3 ms) generated fast post-synaptic responses in 16 out of 44 CVNs tested (36%). A majority of responses (63%, n=10 neurons) were blocked by application of CNQX (50 μM, from 14.9±1.6 pA to 2.9±0.4 pA, p< 0.001, Student's paired t-test, Fig. 3) indicating these excitatory postsynaptic currents (EPSCs) were mediated via glutamatergic AMPA receptor activation. The latency of excitatory currents was 5.5±0.5 ms (ranging from 3.2 ms to 8.5 ms) while the decay time constant was 4.9±1.0 ms (ranging from 2.8 ms to 11 ms, n=10, see Fig. 3). GABAergic inhibitory postsynaptic currents (IPSCs) were detected in 6 out of 16 CVNs (37%) as these responses were not abolished by CNQX, but were successfully blocked by application of gabazine at a concentration of 25 μM (pick amplitude diminished from 36.8±7.9 pA to 3.3±0.9 pA, p< 0.005, Student's paired t-test). The latency of these GABAergic IPSCs was 4.9±0.4 ms (ranging from 4.3 ms to 6.8 ms) and the decay time constant was 15.3±4.2 ms (ranging from 7.6 ms to 35.2 ms, n=6, see Fig. 4). In addition to establishing functional connectivity between orexin neurons and the DMV, we examined whether orexin neurons project to another important region of cardiac parasympathetic control – CVNs in the nucleus ambiguus. Although ChR2-EYFP fibers from orexin neurons were detectable within the nucleus ambiguus no direct electrophysiological responses were found in CVNs upon optogenetic stimulation of orexin fibers (n=17 cells). DISCUSSION To the best of our knowledge, this is the first report identifying and characterizing neurotransmission from orexin neurons to CVNs in the DMV. There are 2 major findings in this study. 1) Optogenetic stimulation of ChR2-EYFP-expressing orexin neurons in the lateral hypothalamus results in reliable excitation of these orexin neurons, observed both by action potential firing and large inward currents. 2) Optogenetic stimulation of ChR2-EYFP-expressing orexin fibers in the DMV evokes short-latency postsynaptic responses in 35% of CVNs tested in the DMV. Of the CVNs that responded to photostimulation of orexin fibers 63% received glutamatergic and 37% received GABAergic neurotransmission. Orexin has previously been shown to contribute substantially to central cardiovascular and respiratory regulation (Peyron et al., 1998, Ciriello and de Oliveira, 2003, Ciriello et al., 2003, Dergacheva et al., 2005, Iigaya et al., 2012, Carrive, 2013, Dergacheva et al., 2013). Intraventricular administration of orexin elicits tachycardia, hypertension and hyperventilation (Samson et al., 1999, Shirasaka et al., 1999, Chen et al., 2000, Matsumura et al., 2001, Zhang et al., 2005), while orexin knock-out animals have reduced blood pressure and diminished cardiovascular response to bicuculline injections in the hypothalamus (Kayaba et al., 2003). These data point to a sympathoexcitatory role of orexin, however microinjection of orexin into various regions of the central autonomic network has been shown to produce unexpected and differential effects. For instance, pressor and tachycardiac effects have been demonstrated after injections of orexin into medullary raphe area (Luong and Carrive, 2012), rostral ventrolateral medulla (Chen et al., 2000, Machado et al., 2002, Huang et al., 2010) and commissural nucleus of the solitary tract(Smith et al., 2002). However, in contrast, orexin administrated into caudal dorsolateral and medial subnuclei of the solitary tract elicits depressor and bradycardia responses (de Oliveira et al., 2003). Microinjection of orexin into the nucleus ambiguus, an area also involved in parasympathetic regulation of heart rate, results in a dose-related decrease in heart rate and activated arterial baroreflex (Ciriello and de Oliveira, 2003). The results from these previous studies, therefore, strongly point to involvement of orexin in the cardiovascular regulation, however these results suggest orexin may play complex differential (or even opposite) roles in different regions of the brain. One important target of orexin neurons are the CVNs in the DMV. The DMV is innervated by orexin-containing fibers (Peyron et al., 1998, Date et al., 1999) and superfusion of orexin depolarizes neurons in this nucleus (Hwang et al., 2001). However, the pathways and mechanisms underlying cardiac effects of orexin in CVNs in the DMV have not been previously established. The results from this study indicate that ChR2-EYFP expression in orexin neurons is sufficient for optogenetic stimulations of both soma of orexin neurons and their distal axons surrounding CVNs in the DMV. Photostimulation of each orexin neurons results in reliable action potential firing and large inward currents. Optogenetic stimulation of orexin neuron fibers in the brainstem evokes short-latency responses in CVNs in the DMV indicating a monosynaptic connection (Petreanu et al., 2007). These responses include both glutamatergic and GABAergic postsynaptic currents. A majority of the responses (63%) are mediated by glutamate release and postsynaptic AMPA receptor activation as these responses are completely blocked by application of the AMPA receptor antagonist CNQX (50 μM). These results provide an evidence that orexin neurons monosynaptically excite, via glutamatergic neurotransmission, CVNs in the DMV. Similar data have been reported that optogenetic stimulation of ChR2-containing fibers from orexin neurons elicits glutamatergic postsynaptic currents in histaminergic tuberomammillary neurons (Schone et al., 2012). In addition, our data support previous work from immunohistochemical studies indicating that orexin neurons use glutamate as their main neurotransmitter (Torrealba et al., 2003, Henny et al., 2010, Carrive, 2013). A minority (37%) of the responses include GABAergic currents as these responses are not abolished by CNQX, but blocked by application of gabazine (25 μM). In accordance with these data, GABA-like immunoreactivity has been found in 10-25% of orexin neurons (Apergis-Schoute et al., 2015). Thus, our data suggest there are different subpopulations of orexin neurons including those that differentially release glutamate and GABA, with excitatory and inhibitory inputs, respectively, to CVNs in the DMV. These subpopulations of orexin-containing cells could be differently influenced by various environmental stimuli and/or internal factors and may therefore play differential roles in parasympathetic control of cardiovascular function. Since the majority of the inputs from orexin neurons to CVNs are excitatory it is likely that activation of orexin cells would increase the activity of parasympathetic CVNs in the DMV and decrease heart rate. Orexin neuron inactivation, in turn, may lead to diminished cardioprotective parasympathetic activity from CVNs to the heart. Supporting this hypothesis, individuals with narcolepsy, the disease characterized by orexin neurons deficiency, have increased heart rate during wakefulness (Grimaldi et al., 2012, Sorensen et al., 2013). Similar, tachycardia has been reported in orexin-deficient mice (Bastianini et al., 2011, Silvani et al., 2014). In conclusion, this report is the first demonstration of heterogeneous projections from orexin neurons to CVNs in the DMV. This study elucidates the network mechanisms by which orexin neurons contribute to parasympathetic regulation of cardiovascular function. Further work is needed to understand the differences between subpopulations of orexin neurons and their pathways to CVNs and how they may serve disparate roles in cardiovascular regulation and cardiovascular abnormalities associated with narcolepsy. Acknowledgements Supported by NIH grant HL 72006 (D.M.) ABBREVIATIONS aCSF Artificial cerebrospinal fluid CVNs cardiac vagal neurons ChR2 channelrhodopsin-2 DMV dorsal motor nucleus of the vagus EYFP enhanced green fluorescent protein EPSCs excitatory postsynaptic currents IPSCs inhibitory postsynaptic currents NMDG 110 N-methyl-d-glucamine Figure 1 Localization of orexin-A immunoreactivity (red, left panel) with ChR2-EYFP (green, middle panel) driven by orexin-Cre selective expression in the lateral hypothalamus. Co-localization is shown in the right panel. Representative example of n=4 animals. Scale bar, 100 μm. Figure 2 Optogenetic stimulation of orexin cell bodies in the lateral hypothalamus evoked reliable action potentials (A) as well as large inward whole-cell currents (B) in all orexin neurons tested (n=8) in rats that received AAV1-ChR2-EYFP viral injections. In contrast, neither light-triggered action potential firing (C) nor large inward currents (D) were observed in animals that did not receive AAV1-ChR2-EYFP viral injections (n=5 orexin neurons). Black circles represent light pulses (3 ms, 1 Hz). Figure 3 Glutamatergic EPSCs in CVNs. Representative example of optogenetically-evoked glutamatergic postsynaptic current in an individual CVN shown in A, left. Abolishment of this this synaptic response by application of CNQX (50 μM) is demonstrated in A, right. Properties of glutamatergic synaptic events in CVNs are illustrated in B. Black circles represent average from 60 sweeps in individual CVNs (3 ms stimulation at 1 Hz) while horizontal bars are population means ± SEM. Amplitude, latency and decay time constant of the glutamatergic responses are shown from left to right. Figure 4 GABAergic IPSCs in CVNs. Representative example of optogenetically-evoked GABAergic postsynaptic current in an individual CVN shown in A, left. Abolishment of this this current by application of gabazine (25 μM) is demonstrated in A, right. Properties of GABAergic responses in CVNs are illustrated in B. Black circles represent average from 60 sweeps in individual CVNs (3 ms stimulation at 1 Hz) while horizontal bars are population means ± SEM. Amplitude, latency and decay time constant of the GABAergic responses are shown from left to right. Highlights ● Photoactivation of orexin neurons by channelrhodopsin-2 expression ● Orexin neurons monosynaptically project to brainstem cardiac vagal neurons ● Orexin cells release GABA and glutamate to modulate cardiac vagal neuron activity This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final citable form. 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PMC005xxxxxx/PMC5118115.txt
LICENSE: This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. 9214478 2614 Mol Ecol Mol. Ecol. Molecular ecology 0962-1083 1365-294X 27696597 5118115 10.1111/mec.13872 NIHMS820626 Article The fungal cultivar of leaf-cutter ants produces specific enzymes in response to different plant substrates Khadempour Lily 123 Burnum-Johnson Kristin E. 4 Baker Erin S. 4 Nicora Carrie D. 4 Webb-Robertson Bobbie-Jo M. 4 White Richard A. III 4 Monroe Matthew E. 4 Huang Eric L. 4 Smith Richard D. 4 Currie Cameron R. 13* 1 Department of Bacteriology, University of Wisconsin-Madison, Madison, WI, USA, 53706 2 Department of Zoology, University of Wisconsin-Madison, Madison, WI, USA, 53706 3 Department of Energy Great Lakes Bioenergy Research Center, University of Wisconsin-Madison, Madison, WI, USA, 53706 4 Biological Sciences Division, Pacific Northwest National Laboratory, Richland, WA, USA, 99352 * Corresponding author: CR Currie, Department of Bacteriology, University of Wisconsin-Madison, 6155 Microbial Sciences Building, 1550 Linden Drive, Madison, WI 53706, USA Fax: (608) 262-9865 currie@bact.wisc.edu 9 10 2016 26 10 2016 11 2016 01 11 2017 25 22 57955805 This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. Herbivores use symbiotic microbes to help derive energy and nutrients from plant material. Leaf-cutter ants are a paradigmatic example, cultivating their mutualistic fungus Leucoagaricus gongylophorus on plant biomass that workers forage from a diverse collection of plant species. Here, we investigate the metabolic flexibility of the ants’ fungal cultivar for utilizing different plant biomass. Using feeding experiments and a novel approach in metaproteomics, we examine the enzymatic response of L. gongylophorus to leaves, flowers, oats, or a mixture of all three. Across all treatments, our analysis identified and quantified 1,766 different fungal proteins, including 161 putative biomass-degrading enzymes. We found significant differences in the protein profiles in the fungus gardens of sub-colonies fed different plant substrates. When provided with leaves or flowers, which contain the majority of their energy as recalcitrant plant polymers, the fungus gardens produced more proteins predicted to break down cellulose: endoglucanase, exoglucanase, and β-glucosidase. Further, the complete metaproteomes for the leaves and flowers treatments were very similar, while the mixed substrate treatment closely resembled the treatment with oats alone. This indicates that when provided a mixture of plant substrates, fungus gardens preferentially break down the simpler, more digestible substrates. This flexible, substrate-specific enzymatic response of the fungal cultivar allows leaf-cutter ants to derive energy from a wide range of substrates, which likely contributes to their ability to be dominant generalist herbivores. Introduction Herbivores are the most abundant and diverse animals on earth (Ricklefs & Miller 2000). Their success is shaped, at least in part, by different animal lineages evolving to specialize on different plant species and plant parts, each of which provide different barriers for herbivores to access stored carbon and other nutrients (Hansen & Moran 2013). Arguably, the most important strategy herbivores use to contend with these barriers to consumption is establishing symbiotic associations with microbes that broaden their physiological capacity (Dowd 1991). The microbial mediation of herbivory has been studied at length in substrate-specialized herbivore systems. Microbial symbionts, which include bacteria, fungi and other microorganisms, mediate herbivory in three main ways: helping their hosts overcome recalcitrant plant material, supplementing nutrient-poor diets, and reducing the impact of plant defense compounds (Hansen & Moran 2013). For example, termites break down the highly recalcitrant biomass in wood through their association with both eukaryotic and bacterial symbionts (Tartar et al. 2009). The plant sap feeding aphids house intracellular Buchnera aphidicola that compensate for the absence of essential amino acids in their diet (Hansen & Moran 2011). Finally, when attacking trees the mountain pine beetle vectors fungi and bacteria, which break down terpenes that would otherwise be toxic to the developing larvae that specialize on tree phloem as a food source (Wang et al. 2012; Boone et al. 2013). Unlike most herbivores, leaf-cutter ants are polyphagous, meaning that they occupy a generalist herbivore niche. These dominant herbivores belong to two genera, Acromyrmex and Atta, and forage on 2–17% of all the foliar biomass in some ecosystems in the Neotropics (Herz et al. 2007; Costa et al. 2008). Their success as herbivores can be attributed to their obligate mutualism with a fungus, Leucoagaricus gongylophorus, which they cultivate for food: they provide the fungus with leaf material and, in turn, the fungus provides specialized hyphal swellings called gongylidia, which the ants feed on (Holldobler & Wilson 1990; Mayhé-Nunes & Jaffe 1998; Holldobler & Wilson 2008). The types of plant material that a colony consumes depends on the ant species, the location, and the season in which the colony is observed (De Vasconcelos 1990; Wirth 2003). In general, they tend toward young leaves with soft cuticles, less-toxic plant defense compounds, fewer trichomes, fewer endophytes and higher nutritional value (Howard 1987; 1988; Van Bael et al. 2011). Within these constraints, leaf-cutter ants incorporate many different types of plants into their fungus gardens and have been observed foraging at least 20 different species of plants over three days (Wirth et al. 1997). Ants also incorporate a variety of plant parts into their gardens such as leaves, flowers, seeds, and fruit parts in the wild, and oats and parboiled rice in laboratory settings (Wirth et al. 1997; Kooij et al. 2011). Leaf-cutter ants tend to their mutualistic fungus in gardens, which can be viewed as an ‘external gut’. These gardens contain both the fungus itself and a low diversity community of bacteria. Through enzymatic, metagenomic and metaproteomic analyses, the microbial communities in the fungus gardens of leaf-cutter ants Atta sexdens and Atta cephalotes have been explored. Many fungal amylases (Silva et al. 2006b), pectinases (Silva et al. 2006a), carbohydrate-active enzymes (CAZy), fungal oxidative lignin enzymes (FOLy), and secreted proteases have been identified (Aylward et al. 2012; 2013a), demonstrating that the fungus in this system is primarily responsible for the breakdown of plant biomass. The bacterial community in the fungus gardens was identified using isolation, metagenomics and 16S sequencing (Suen et al. 2010; Aylward et al. 2012). While the bacterial community has the genetic capacity for biomass degradation (Suen et al. 2010), there is not yet evidence that this is actually occurring in the gardens. In this study, we explore microbial mediation in a generalist herbivore by combining feeding experiments with metaproteomic analyses. Specifically, we fed sub-colonies of leaf-cutter ants leaves, flowers, oats or a mixture of all three. Using a novel multidimensional platform, coupling liquid chromatography, ion mobility spectrometry and mass spectrometry (LC-IMS-MS), we determined the metaproteomic response of fungus gardens on the different diets. Our working hypothesis is that the fungal cultivar L. gongylophorus responds to different plant substrates integrated into the garden by worker ants by producing specific proteins that have the capacity to break down the substrate provided. Methods Experimental design Atta cephalotes fungus gardens were excised from colonies excavated in the secondary tropical moist forest surrounding the Smithsonian Tropical Research Institute (STRI) Gamboa research station in Panama between Dec. 27, 2012 and Jan 10, 2013. Five mature colonies were excavated. Since lab-reared sub-colonies without queens are unstable, five fungus chambers were excised from each colony to ensure that we would have sufficient numbers of replicates for proteomics. These fungus chambers were split into four sub-colonies each and were contained within a plastic container (10×10×8 cm) that was kept in a larger plastic container (14×19×9 cm). Care was taken to minimize disturbance to the fungus gardens and to ensure that a relatively even number of workers were distributed to each sub-colony. Each sub-colony was randomly assigned to one of four feeding treatments, and received different plant biomass to use as substrate for cultivating their fungal mutualist. The four feeding treatments were Lagerstroemia speciosa L. leaves, Hibiscus rosa-sinensis flowers, Quaker instant oatmeal, or a mixture of all three (Figure 1). The substrates that were selected were all readily available and were readily incorporated into the gardens by the ants, but they varied in terms of their energy availability. Leaves are the most recalcitrant substrate of the three. The flowers are similar to leaves in terms of cell wall structures but are more easily digestible (Amaglo et al. 2010). The oats are highly processed and have the most accessible energy in the form of sugars and starches (Cuddeford 1995; Welch 1995). The flowers and leaves were collected daily from plants in the immediate vicinity in Gamboa. The sub-colonies were fed ad libitum, typically every one or two days, depending on how quickly the ants would incorporate new substrate. The colonies were maintained at ambient temperature and humidity. After 15 days, the entire fungus garden from each sub-colony was frozen in PBS buffer at −20°C in a 50 mL conical tube, in preparation for further processing. One of the five colonies was excluded from metaproteomic analysis because it did not have surviving sub-colonies from all treatments but it was included it in the survivorship analysis. From the surviving sub-colonies we selected 16 samples for metaproteomics (four treatments and four colony replicates each). The sub-colonies that were selected for metaproteomics were all active and still incorporating new material into their gardens at the end of the 15 days of the experiment. Mass spectrometry instrumentation Analysis of the trypsin-digested peptide mixtures (Supplemental Methods) from the gardens was performed on both a Thermo Fisher Scientific LTQ Orbitrap mass spectrometer (MS) (San Jose, CA, USA) operated in tandem MS (MS/MS) mode and an in-house built ion-mobility MS (IMS-MS) instrument that couples a 1-m ion mobility drift cell (Baker et al. 2007; 2010) with an Agilent 6224 time-of-flight (TOF) MS that was upgraded to have a 1.5 m flight tube for resolution around 25,000. The same fully automated in-house built 2-column HPLC system (Livesay et al. 2008) equipped with in-house packed capillary columns was used for both instruments with mobile phase A consisting of 0.1% formic acid in water and B comprised of 0.1% formic acid in acetonitrile. A 100 min LC separation was performed on the Velos MS (using 60-cm long columns having an o.d. of 360 µm, i.d. of 75 µm, and 3 µm C18 packing material) while only a 60 min gradient with shorter columns (30-cm long columns with the same dimensions and packing) that was used with the IMS-MS since the additional IMS separation helps address detector suppression and also faster LC analyses. Both gradients were linear with mobile phase B increasing from 0 to 60% until the final 2 min of the run when B was purged at 95%. 5 µL of each sample was injected for both analyses and the HPLC was operated under a constant flow rate of 0.4 µL/min for the 100 min gradient and 1 µL/min for the 60 min gradient. The Velos MS data was collected from 400–2000 m/z at a resolution of 60,000 (automatic gain control (AGC) target: 1×106) followed by data dependent ion trap MS/MS spectra (AGC target: 1×104) of the twelve most abundant ions using a collision energy setting of 35%. A dynamic exclusion time of 60 s was used to discriminate against previously analyzed ions. IMS-TOF MS data was collected from 100–3200 m/z. Metaproteomic data processing and statistical analysis Identification and quantification of the detected peptide peaks were performed using the accurate mass and time (AMT) tag approach (Zimmer et al. 2006; Burnum et al. 2012). Peptide database generation utilized Velos tandem MS/MS data (Kim et al. 2008; Piehowski et al. 2013) from pooled fractionated samples (Supplemental Methods). Due to the greater sensitivity and dynamic range of measurements (Burnum et al. 2012) relative quantitation of the peptide peaks utilized the LC-IMS-MS data. Multiple in-house developed (Monroe et al. 2007; Jaitly et al. 2009) informatics tools were used to process the LC-IMS-MS data and correlate the resulting LC-IMS-MS features to the AMT tag database containing LC elution times, IMS drift times, and accurate mass information for each assigned peptide. Our in-house ion mobility mass spectrometry platform has previously provided novel insight into complex biological systems (Burnum et al. 2012; Baker et al. 2014; Cha et al. 2015; Baker et al. 2015; Kyle et al. 2016). Data filtering was performed to remove peptides with inadequate data for statistics and samples that are extreme outliers (Webb-Robertson et al. 2010; Matzke et al. 2011). This resulted in 6,676 peptides and 1,766 proteins across the sixteen samples (four feeding treatments and four biological replicates for each treatment). Normalization approaches were evaluated using a statistical procedure for the analyses of peptide abundance normalization strategies (SPANS) and normalization factors were generated as the mean of the datasets that were observed consistently across technical replicates (Webb-Robertson et al. 2011). Peptide statistics were performed by comparing all treatment groups to one another using Analysis of Variance (ANOVA) with a post-hoc Tukey test to define peptide signatures. A BP-Quant quantification (Webb-Robertson et al. 2014) approach was used to estimate abundance at the protein level. Proteins were also evaluated with a Tukey test and deemed significant at a p-value<0.05. Only fungal proteins identified by ≥ 2 peptides are discussed (see Supplemental Table 1 for the full list of all detected proteins). Non-metric multidimensional scaling (NMDS) was conducted on these data with Bray-Curtis dissimilarity, using the vegan package in the R statistical programming environment (Oksanen et al. 2013; R Core Team 2013). To determine if the fungus gardens from different treatments had significantly different protein profiles, function adonis was used to run a Permutational Multivariate Analysis of Variance Using Distance Matrices (PERMANOVA). Results Fungal proteomics With our metaproteomic analysis of the fungus gardens, we identified and quantified 1,766 different fungal proteins, including 161 putative biomass-degrading enzymes (Supplemental Table 1). NMDS analysis of the global proteome profiles across treatments and replicates revealed grouping according to treatment (Figure 2A). These differences according to treatment were significant (PERMANOVA p<0.001). Fungus garden proteomic profiles in both the leaves and flowers treatments showed low variability within-group and between-group, while the oats and mixed treatments had greater within-group variability and overlapped with each other. These groupings are evident when individual proteins are compared between treatments. To analyze the differential abundance of individual proteins, we conducted pair-wise comparisons of each protein in the four treatments. Numerous proteins with significantly different abundances were identified between the treatments (Supplemental Table 1). When individual protein differences are observed globally using heat maps, we can again see grouping according to treatment (Figures 3 and 4): the oats sub-colonies were most similar to the mixed sub-colonies, while the leaves sub-colonies were similar to the flowers. The significant changes for each protein pairwise comparison were identified by at least 2 peptides with: oats/mixed having 52 significantly changing proteins, leaves/flowers - 31, leaves/oats - 286, flowers/oats - 259, leaves/mixed - 135, and flowers/mixed - 125 (Supplemental Table 1). All biomass-degrading enzymes observed to be significantly different (p<0.05) between treatments are listed in Table 1, where individual proteins are compared between the mixed and other treatments. We compared to the mixed treatment since it most closely resembles the ants’ natural tendency to incorporate a mixture of substrates into their fungus gardens. In general, the leaves and flowers treatments had similar results with much higher abundances of CAZys, proteases and enzymes necessary for the breakdown of cellulose: endoglucanases (GH5 and GH6), exoglucanase (GH6), and β-glucosidases (GH3 and GH31), compared with the other two treatments. However, the oats treatment was very similar to the mixed treatment with a lower abundance of these proteins and proteases (Table 1, Figure 4). Bacterial proteomics We detected only 44 unique bacterial peptides and from these data we determined, through similar pairwise comparisons between treatments, that there were three bacterial proteins that differed significantly between treatments. Each of these proteins was identified with only a single peptide. These proteins were identified based on genomes of bacterial symbionts of leaf-cutter ants (Enterobacter strain FGI 35, Serratia strain FGI 94 (Aylward et al. 2013c), Enterobacteriaceae strain FGI 57 (Aylward et al. 2013b), Pseudomonas strain FGI 182, Klebsiella variicola strain AT-22 and Pantoea strain AT-9b (Aylward et al. 2014)). Malate dehydrogenase, which mapped equally to Cronobacter, Pantoea, Serratia, Enterobacter, and Klebsiella genomes, was more abundant in the leaf treatment. Periplasmic trehalase, which mapped to the Enterobacter genome, was more abundant in the flower treatments. ATP synthase subunit β, which mapped to all six bacterial genomes, was the least abundant in the leaf treatments. Overall, the global bacterial protein profiles did not differ between treatments (Supplemental Table 2, Figure 2B). Sub-colony Survivorship The fungus garden of some sub-colonies did not remain healthy throughout the experimental period, but instead dried out, were discarded by workers, or were overgrown by a pathogen. This was especially common for sub-colonies created from the gardens excised from the last two parent colonies. A sub-colony was considered failed when all the ants were dead or when the fungus garden was overtaken by a pathogen. Overall, sub-colonies fed exclusively on oats had significantly lower survivorship than the other colonies (Figure 5). Discussion The breakdown of plant biomass by L. gongylophorus is central to the success of leaf-cutter ant colonies and the function of this ant-fungus mutualism. Nevertheless, our understanding of the process of digesting leaves and other plant substrates within the fungus garden is limited. Specifically, the ability of L. gongylophorus to digest cellulose and other recalcitrant material has been debated. Some have argued that it does not effectively break down cellulose and instead relies on other plant components such as pectin for energy (De Siqueira et al. 1998; Silva et al. 2006a; Moller et al. 2011). In contrast to this, sugar composition analysis and microscopy shows a significant decrease in cellulose within fungus gardens and genomics and metaproteomics show a significant capacity of L. gongylophorus to degrade it (Suen et al. 2010; Nagamoto et al. 2011; Aylward et al. 2012; Grell et al. 2013; Aylward et al. 2013a). Our results here provide further support for the role of the fungus in recalcitrant biomass degradation. Specifically, our metaproteomic analysis detected 100 CAZys produced by L. gongylophorus, including 53 glycoside hydrolases (GH), 6 carbohydrate esterases (CE), 8 carbohydrate binding molecules (CBM), 4 polysaccharide lyases (PL), and 30 auxiliary activities enzymes (AA) (Figure 4, Supplementary Table 1). This suite of enzymes includes all the components necessary for the breakdown of cellulose (endoglucanases GH5, GH12 and GH6, exoglucanase GH6 and β-glucosidase GH31). Although our combination of proteomics and feeding experiments provide further evidence for the ability of L. gongylophorus to deconstruct cellulose, our findings indicate that this enzymatic response is context-dependent. Specifically, we found metabolic flexibility in the ants’ fungal cultivar to preferentially digest various substrates; instead of consuming recalcitrant materials, the fungus digests the more readily accessible carbon sources when available. This is most clearly observed when comparing the mixed and oat treatment metaproteomes. In the mixed treatment the fungus does not produce an abundance of biomass-degrading enzymes, despite the presence of recalcitrant biomass. It instead has a metaproteome that is more similar to that of the oat treatment, suggesting that when given a mixture of substrates, the fungus derives its energy from the oats. The flexible, substrate-specific response of the fungus is important in a system where the ants cut a large diversity of substrates, which vary between seasons and environments. For example, in the dry season substrates that are rich in easily accessible nutrients may be more limited, such that the fungal cultivar needs to respond to and to derive energy from more recalcitrant sources. In contrast, in the wet season when substrates such as fruits and young leaves are more readily available, the fungal cultivar would benefit from reducing the energy expended on digesting recalcitrant material when easily accessible sugars are available. Evidence supporting the substrate-specific response in the leaf-cutter ant fungus garden has been previously reported elsewhere. Kooij et al. (2011) manipulated the substrate for A. cephalotes fungus gardens and using Azurine-Crosslinked (AZCL) assays measured changes in specific enzymes of interest, observing an overall shift in enzyme activity between substrates. AZCL is a high throughput method used to detect enzyme activity, while metaproteomics provides accurate detection and quantification of the specific proteins present. Thus, our approach represents a more thorough enzymatic response of the fungus garden, as follows. First, AZCL is conducted with a limited suite of substrates and only shows activity of enzymes to those substrates. This excludes any non-enzymatic proteins and any enzymes that did not have the appropriate substrate to respond to. Second, AZCL does not allow us to characterize specific proteins, whereas metaproteomics does.. Other systems where microbes are responsible for biomass breakdown also show substrate-specificity through fluctuations in the community structure of multiple microbes (Thoetkiattikul et al. 2013; Miyata et al. 2014). Here, a single vertically transmitted cultivar, with little variability between isolates (Silva-Pinhati et al. 2004) is responsible for the flexible, substrate-specific response of the system. The leaf-cutter ant system, which is optimized for the extraction of energy from plant material then fine-tunes the enzymatic response of the fungal cultivar. Previous work has shown that the lignocellulases and laccases from gongylidia are transferred by the ants from the middle of the garden and defecated on the top, serving as a pretreatment step for beginning rapid biomass degradation and detoxification (Cherrett et al. 1989; Moller et al. 2011; De Fine Licht et al. 2013; Aylward et al. 2015). Recent work has identified the presence of an apparent consistent bacterial community in the fungus garden (Pinto-Tomás et al. 2009; Suen et al. 2010; Aylward et al. 2012). Although certain functional roles of the bacteria have been elucidated, such as nitrogen fixation (Pinto-Tomás et al. 2009) and the apparent capacity to provide vitamins (Aylward et al. 2012), our insights regarding the bacteria remain limited. Here, we did not observe a notable change in bacterial proteins, other than the three which are all part of central carbon metabolism and unlikely to play a direct role in substrate breakdown or detoxification (Bergmeyer & Gawehn 1974; Boos et al. 1987). Only 1% of the unique peptides that were detected in these analyses were identified as bacterial. This is likely due to a considerable difference in the amount of fungal and bacterial biomass in the fungus gardens. It could also indicate that bacteria play a more limited role in the fungus gardens. Interestingly, despite our finding that L. gongylophorus preferentially uses the simplest energy source (i.e., oats) when provided with a mixture of substrates, sub-colony survivorship dramatically decreased when this was the only substrate provided. This correlation between decreased health and feeding exclusively on a simple, energy rich diet has been observed in other animals. Cows that are fed a grain-rich diet gain weight quickly but suffer frequently from ruminal acidosis, which negatively impacts both production and animal welfare (Krause & Oetzel 2006). Ruminal acidosis results from different rates of fermentation in the standard grassy diet and has effects on the microbial community composition in the rumen (Steele et al. 2011; Hook et al. 2011). Humans also show a correlation between diet, the gut microbiome, and health (De Filippo et al. 2010; Martínez et al. 2013). While this experiment suggests that the fungus gardens of oat-fed sub-colonies are apparently less stable, colony health was not the focus of our study. However, we hypothesize that an exclusive diet of oats lacks required micronutrients that the ants, fungus or bacteria obtain from fresh plant material. While there have been thorough investigations into plant characteristics that are deterrents to leaf-cutter ant foraging and how this limits the diversity of plants they consume, no work has been done investigating whether a more diverse diet leads to higher fitness for leaf-cutter ants. Testing this hypothesis in future studies would help us to determine what minimum requirements exist for leaf-cutter ant forage and whether this is achieved more effectively with a diverse diet. The mutualism between leaf-cutter ants and their fungal cultivar has been described as an “unholy alliance” (Cherrett et al. 1989), where the tasks of mechanical and enzymatic breakdown of plant material are partitioned to the ants and fungal cultivar, respectively. Through this alliance, leaf-cutter ants are capable of utilizing a wide diversity of plant material, unlike most other herbivores. Polyphagy in this system necessitates metabolic flexibility on the part of the fungus, and is a key factor in making leaf-cutter ants dominant herbivores. In this study, we dissect this unholy alliance at a previously unattainable depth, demonstrating that the cultivar does indeed have a flexible, specific response to different plant substrates. Our study provides an important step in building toward understanding the microbial mediation of a generalist herbivore system. Supplementary Material Supp Methods Supp Table S1 Supp Table S2 This work was funded in part by the Department of Energy Great Lakes Bioenergy Research Center (DOE Office of Science BER DE-FC02-07ER64494) with support for LK and CRC. Proteomics measurements were supported by the DOE, Office of Biological and Environmental Research, Genomic Science Program under the Pacific Northwest National Laboratory (PNNL) Pan-omics Program, and were performed in the Environmental Molecular Science Laboratory, a U.S. DOE national scientific user facility at PNNL in Richland, WA. Battelle operates PNNL for the DOE under contract DE-AC05-76RLO01830. This work was supported in part by grants NIEHS/NIH (R01ES022190) to ESB, HHS NCI/NIH (U01CA184783-01) to BJWR. Figure 1 Leaf cutter ants carrying various substrates (A) a leaf, (B) a flower and (C) an oat. Ants tending to their fungus garden with newly incorporated leaf material (D) (photographs by Don Parsons). Figure 2 NMDS plot of (A) fungal and (B) bacterial whole-community metaproteomics. While the fungal results were significantly different between treatment groups, the bacterial metaproteomes were not possible to differentiate statistically. Figure 3 A heat map of the complete metaproteome. Columns represent each treatment and rows represent each protein. A clear division is visible between the two left columns (leaves and flowers) and the two right columns (oats and mixed). Figure 4 Heat map of higher or lower abundance of biomass degrading enzymes. A clear division can be seen between leaves and flowers on the left and oats and mixed on the right. GH – glycoside hydrolases, CE – carbohydrate esterases, CBM – carbohydrate binding molecules, PL – polysaccharide lyases, AA – auxiliary activities. Proteins in red text were significantly different between at least two treatments. Figure 5 Sub-colony survival by treatment. Sub-colonies that were fed oats survived significantly (*) less than the other sub-colonies, over the course of the experiment (ANOVA p<0.05). Table 1 Fungal biomass-degrading enzymes that differ significantly from the mixed treatment LAG Protein Family Annotation Leaves Flowers Oats CAZy 1450 CE8 Pectin methylesterase − 925 CBM57, CE15 Found attached to glycosidases − 1065 GH31 α-glucosidase, and others − 2832 GH6 Endoglucanase, exoglucanase, cellobiohydrolase + 1778 CBM32 Binding to galactose, lactose, polygalacturonic acid, LacNAc + − 4224 GH10 Xylan targeting + 3545 GH5 Endo-β-1,4-glucanase / cellulase and many others + 3581 CE5 Acetyl xylan esterase, cutinase + + 3843 GH10 Xylan targeting + + 830 GH105 Unsaturated rhamnogalacturonyl hydrolase; d- 4,5-unsaturated β-glucuronyl hydrolase + + 420 GH18 Lysozyme, chitinase, many others + + 5098 GH3 β-glucosidase, and others + + 811 GH3 β-glucosidase, and others + + 1724 GH31 α-glucosidase, and others + + 1811 GH92 Mannose targeting − − 11012 AA5 Glyoxal oxidase − 3543 AA5 Glyoxal oxidase − 1590 AA3 Glucose oxidase − − 3638 AA3 Alcohol oxidase 1 + + 2639 AA1 Laccase-1 + + 3464 AA1 Laccase-4 + + 5297 AA1 Laccase-2 + 2404 AA1 Laccase-1 + 5522 AA1 Laccase-2 + 3730 AA2 Chloroperoxidase + 5105 AA2 Chloroperoxidase − − 3594 AA3 Dihydrolipoyl dehydrogenase, mitochondrial + Proteases 3716 M36 Endopeptidase − 971 C44 Self-processing precursor of Amidophosphoribosyltransferase − 2519 M67A Isopeptidases that releases ubiquitin from ubiquitinated proteins + 3036 C01B Endopeptidases or exopeptidases + 3725 M28E Aminopeptidase − 439 A01A Pepsin A + + 100 M03A Thimet oligopeptidase + + 748 M13 Metalloendopeptidase + + 1996 M41 ATP-dependent metalloendopeptidase + + 15046 M67A Isopeptidases that release ubiquitin from ubiquitinated proteins − − 3735 S08A Subtilisin Carlsberg + + 2389 S08A Subtilisin Carlsberg + 3512 S08A Subtilisin Carlsberg + − 5096 S08A Subtilisin Carlsberg + − 2939 S10 Carboxypeptidase Y + + 4473 S10 Carboxypeptidase Y − 2743 S10 Carboxypeptidase Y − − − 924 S26B Signalase 21 kDa component + + + 2527 S53 Sedolisin + + A significant increase in abundance compared to the mixed treatment is indicated by + and a significant decrease is indicated by −. Data accessibility All of the metaproteomic data from this study is available in the Supplemental Materials (Supplemental tables 1 and 2). 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PMC005xxxxxx/PMC5118126.txt
LICENSE: This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. 9214478 2614 Mol Ecol Mol. Ecol. Molecular ecology 0962-1083 1365-294X 27718295 5118126 10.1111/mec.13877 NIHMS822311 Article Mosquitoes host communities of bacteria that are essential for development but vary greatly between local habitats Coon Kerri L. Brown Mark R. Strand Michael R. Department of Entomology, The University of Georgia, Athens, GA, 30602, USA Corresponding author: Michael R. Strand, Department of Entomology, University of Georgia, 120 Cedar Street, 420 Biological Sciences, Athens, GA 30602, USA, Fax: 706-542-2279, mrstrand@uga.edu 13 10 2016 31 10 2016 11 2016 01 11 2017 25 22 58065826 This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. Mosquitoes are insects of interest because several species vector disease-causing pathogens to humans and other vertebrates. We previously reported that mosquitoes from long-term laboratory cultures require living bacteria in their gut to develop, but development does not depend on particular species of bacteria. Here, we focused on three distinct but interrelated areas of study to better understand the role of bacteria in mosquito development by studying field and laboratory populations of Aedes aegypti, Aedes albopictus, and Culex quinquefasciatus from the Southeastern United States. Sequence analysis of bacterial 16S rRNA gene amplicons showed that bacteria community composition differed substantially in larvae from different collection sites, whereas larvae from the same site shared similarities. Although previously unknown to be infected by Wolbachia, results also indicated that Ae. aegypti from one field site hosted a dual infection. Regardless of collection site or factors like Wolbachia infection, however, each mosquito species required living bacteria in their digestive tract to develop. Results also identified several concerns in using antibiotics to eliminate the bacterial community in larvae in order to study its developmental consequences. Altogether, our results indicate that several mosquito species require living bacteria for development. We also hypothesize these species do not rely on particular bacteria because larvae do not reliably encounter the same bacteria in the aquatic habitats they colonize. microbiota insect Wolbachia development Introduction Most multicellular animals host communities of microbes in their digestive tract. One important area of study is to understand how animals acquire these microbes and the factors that influence their composition. This is because several studies show that the gut microbiota and its composition have wide-ranging effects on the physiology of different vertebrates and invertebrates (Buchon et al. 2013; Lee & Brey 2013; Sommer & Backhed 2013; Blaser 2016; Goodrich et al. 2016). Among insects, some groups including termites (Blattodea), bees and ants (Hymenoptera), and select Heteroptera have specialized gut microbiota that are maintained by direct transfer between individuals (Fukatsu & Hosokawa 2002; Ohkuma & Brune 2011; Anderson et al. 2012; Martinson et al. 2012). Others including certain moths (Lepidoptera) and fruit flies (Diptera: Drosophilidae) acquire most if not all of their gut microbiota each generation from the environment (Robinson et al. 2010; Chandler et al. 2011; Tang et al. 2012). In the case of mosquitoes (Diptera: Culicidae), all species are aquatic as larvae, feeding on detritus, microorganisms and small invertebrates, while adults are terrestrial with both sexes usually feeding on nectar (Merritt et al. 1992; Clements 1992). Adult females of most species also must feed on vertebrate blood to produce eggs, which underlies why many mosquitoes are important disease vectors (Clements 1992). Deep sequencing of bacterial 16S rRNA gene amplicons from select species shows that larvae contain a subset of the operational taxonomic units (OTUs) in their aquatic environment, while some but not all of the OTUs in larvae are also in adults (Wang et al. 2011; Boissiere et al. 2012; Coon et al. 2014; Gimonneau et al. 2014). Controlled experiments further indicate that mosquito larvae contain no bacteria if they hatch from surface sterilized eggs and are maintained in a sterile environment, while also showing that most OTUs in adults overlap with those in larvae (Coon et al. 2014). Altogether, these data support that mosquito larvae acquire their gut microbiota from the water in which they feed and that some community members in larvae persist in adults. Variability in the microbiota of mosquitoes has been detected within and between species from different geographic locations (Boissiere et al. 2012; Osei-Poku et al. 2012; Gimonneau et al, 2014; Duguma et al. 2015; Buck et al. 2016; Muturi et al. 2016). In contrast, less is known about community composition on finer geographic scales, which is relevant to many vector species that develop as larvae in small volume containers, which are often located in close proximity to one another in urban habitats. The issue of variability in bacterial community composition is also functionally important from the perspective of mosquito development. Most mosquitoes molt through four instars before metamorphosis into adults when fed a nutritionally complete diet under conventional (non-sterile) rearing conditions (Clements 1992). However, our own recent studies of three species (Aedes aegypti, Aedes (=Georgecraigius) atropalpus, and Anopheles gambiae) from long-term laboratory cultures show that axenic larvae with no bacteria die as first instars when fed a nutritionally complete diet (Coon et al. 2014). Axenic larvae of each species also die as first instars if fed dead bacteria plus diet or diet preconditioned by living bacteria before feeding. Re-colonization with a mixed community of bacteria from conventional cultures, however, rescues development. Experiments with Ae. aegypti further show that several members of the laboratory bacterial community including an Acinetobacter, Aeromonas, Aquitalea, and Chryseobacterium or the non-community member Escherichia coli individually colonize the gut, which produces monoassociated, gnotobiotic larvae that develop normally (Coon et al. 2014). Resulting adults also show no morphological defects or reductions in fitness as measured by development time, size and fecundity (Coon et al. 2014; 2016). Thus, each of the species studied by Coon et al. (2014) required living bacteria for development, yet development did not depend on a particular species or community assemblage because several different bacteria rescued development of gnotobiotic larvae. In contrast, a study that used antibiotics to eliminate the gut microbiota from Anopheles mosquitoes reported delays in growth but larvae nonetheless survived and developed into adults (Chouaia et al. 2012). Older studies also report variable effects on mosquito development after perturbing the microbial communities in larval habitats (Hinman 1930; Rozeboom 1935; Ferguson & Micks 1961; Jones & DeLong 1961; Chao et al. 1963). Thus, unlike our own results, some studies in the literature suggest living bacteria in the gut are not required for mosquito larvae to develop. One explanation for these differing conclusions is that mosquitoes vary in their requirement for bacteria as a function of species or rearing conditions that could also affect the communities of bacteria that are naturally present. Another factor of potential importance is that vertically transmitted intracellular bacteria like Wolbachia infect some mosquitoes, and can affect fitness both positively and negatively (Brownlie et al. 2009; Ross et al. 2016). However, since Coon et al. (2014) examined laboratory populations of mosquitoes that were not infected by Wolbachia or other intracellular bacterial symbionts, this study could not assess whether Wolbachia potentially affect the importance of gut bacteria for development. The third possibility is that surface sterilization of eggs and antibiotic treatment do not equivalently eliminate bacteria from mosquitoes, which underlies why these two approaches have led to differing conclusions about the functional role of the gut microbiota in larvae. The overall goal of this study, therefore, was to determine if any of the factors discussed above affect whether mosquito larvae require living bacteria in their digestive tract for development. To meet this goal, we studied field and laboratory populations of Aedes aegypti, Aedes albopictus, and Culex quinquefasciatus from the Southeastern United States (US). Each of these species has a worldwide distribution in subtropical and tropical regions (Rey et al. 2006; Leonel et al. 2015). Ae. aegypti and C. quinquefasciatus were introduced into North America from Africa centuries ago, while Ae. albopictus was introduced from Asia in the 1980s (Huang et al. 2011; Bargielowshi & Lounibos 2014). Ae. albopictus has also altered the range of Ae. aegypti, which along the east coast of the US is infrequently collected outside of Florida (Bargielowshi & Lounibos 2014; Hahn et al. 2016). In the first part of our study, we used 16S rRNA gene analysis to characterize bacterial diversity in larvae from field versus laboratory cultures. We also examined larvae from different field sites to assess the variability of bacterial community composition between breeding sites that were in close proximity to one another. Second, we assessed whether larvae from each species differed in their requirement for living bacteria as a function of being from the lab or field, the composition of the bacterial community where larvae were collected from, or Wolbachia infection. Third, we compared the efficacy of surface sterilizing eggs and antibiotic treatment in eliminating bacteria from larvae and their effects on development. Results showed that bacterial diversity in larvae differed substantially between collection sites. However, each species required living bacteria in their digestive tract for development regardless of where they came from or whether they were infected with Wolbachia. Antibiotic treatment in contrast did not fully eliminate bacteria, which results in larvae that develop. High concentrations of some antibiotics also adversely affected larvae independent of their impact on bacteria. Materials and methods Field collections and laboratory cultures We assessed bacterial diversity in Ae. aegypti, Ae. albopictus and C. quinquefasciatus by collecting samples from six field sites and laboratory cultures. One field site was located in Athens, GA and contained Ae. albopictus and C. quinquefasciatus (Fig. 1). Five others were located in Jacksonville, FL USA with one containing both Ae. aegypti and C. quinquefasciatus, three containing only Ae. aegypti, and one containing only C. quinquefasciatus (Fig. 1). Each site was a small container habitat that was sampled 2 or 3 times over the breeding season by collecting: (1) 50 ml of water in a sterile Falcon tube (BD Diagnostics) that was transferred to ice, and (2) mosquito larvae in 300 ml of water that were placed in a 500 ml container. Samples were taken to the laboratory where larvae were counted in a laminar hood and identified to species using defined morphological characters (Breeland & Loyless 1989). Water samples were centrifuged at 5,000 x g for 30 min at 4° C and the resulting pellet was stored at −20° C until DNA isolation. Almost all larvae (>98%) collected from the field sites we sampled were Ae. aegypti, Ae. albopictus, or C. quinquefasciatus. As previously noted, results from prior studies showed that laboratory cultures of three species (Ae. aegypti, Ae. atropalpus, An. gambiae) contained no Wolbachia, and eggs that hatched from surface sterilized eggs contained no bacteria as measured using culture and PCR-based assays (Coon et al. 2014). This latter result indicated that all of the OTUs identified by deep sequencing in laboratory-reared Ae. aegypti were acquired from the environment through larval feeding, while also suggesting most if not all of the OTUs in conventionally reared larvae were gut community members (Coon et al. 2014). Prior studies also showed that the small size of mosquito larvae and corresponding small number of bacteria that are present (~103–4) (Coon et al. 2016) often do not yield sufficient DNA template for library construction. Thus for this study, pooled samples were prepared by collecting 15 larvae (fourth instars) per species, site and collection date. Each pool was then rinsed in 70% EtOH, dried, and stored at −20° C until use for DNA isolation. The remaining larvae were kept in their habitat water until pupation. Pupae were then surface sterilized and allowed to emerge in sterile cages (Coon et al. 2014). Three adult female Ae. aegypti from site 1 in Jacksonville, FL were rinsed in 70% EtOH, dried and stored at −20° C for DNA isolation. Ribosomal internal transcribed spacer region 1 (ITS1) from these adults was PCR amplified using ITS1A and ITS1B primers (Beebe et al. 2000) followed by comparison to the known ITS1 sequence for Ae. aegypti (Wesson et al. 1992). Other adults were maintained at 27° C and a 16 h light: 8 h dark photoperiod and fed 10% sterile sucrose in water. Day 3 females were blood fed on a surface-sterilized rat and then allowed to oviposit onto moist filter paper. Eggs were collected within 24 h of being laid and either stored in humidified containers (Ae. aegypti, Ae. albopictus) or immediately surface-sterilized and hatched (C. quinquefasciatus) for use in developmental assays. Laboratory cultures for each species were maintained in an insectary that was 2 km from the Athens, GA field site. The Ae. aegypti culture was established in 1974 from offspring collected in Athens, GA (UGAL strain) (Foster & Lea 1975). The Ae. albopictus and C. quinquefasciatus cultures were obtained in 2012 from the Centers for Disease Control (Atlanta, GA, USA) from offspring collected in Johannesburg, South Africa and Keyport, NJ, USA respectively (Cornel et al. 2003; Marcombe et al. 2014). Larvae were maintained in covered rearing pans containing distilled water and fed a nutritionally complete, standard diet of ground rat chow (Purina): lactalbumin: brewers yeast (1:1:1). Pupae were transferred to cages for adult emergence, while females were blood fed as described above to produce eggs. Water and larvae from the laboratory were collected for DNA isolation as described above. Bacterial 16S rRNA library construction and sequencing DNA was isolated from samples using the Gentra Puregene Yeast/Bacteria Kit (Qiagen). All samples were processed at the same time to eliminate potential batch contamination effects. Since our primary goal was to assess bacterial diversity within and between sites, bacterial 16S rRNA gene V3–V4 variable regions were PCR-amplified using the universal primers 341F and 785R (Faircloth & Glenn 2012; Klindworth et al. 2013) containing multiplex identifier sequences (Table S1). PCR amplifications were performed in triplicate 20 ul reactions containing 10 ng of template DNA, 0.4 U of iProof High-Fidelity polymerase (Bio-Rad), 1X polymerization buffer, 200 μM dNTPs and 0.2 μM of each primer. Reactions using template from blank DNA extractions served as a negative control. Reaction conditions were: initial denaturation cycle of 98° C for 30 s, followed by 25 cycles at 98° C for 10 s, 55° C for 15 s and 72° C for 15 s, and a final extension step at 72° C for 5 min. Products were visualized on 1.2% agarose gels, pooled, purified with the MinElute PCR purification kit (Qiagen), and eluted in 11 μl of EB buffer. Pooled amplicons served as template for a second round of PCR to attach Nextera indices and adapters (Faircloth & Glenn 2012). Products were again visualized on agarose gels and repurified before quantification using a Qubit dsDNA HS assay and fluorometer (Invitrogen). Three libraries were constructed and sequenced per sample (i.e. three technical replicates) using different barcode sequence combinations to prevent PCR bias. For each replicate PCR, negative controls produced no amplicon indicating no contamination of reagents. Altogether, 6 field sites sampled multiple times and 3 laboratory cultures resulted in 36 samples. Three technical replicates per sample thus resulted in 108 sequencing libraries. Barcoded products were combined in equimolar amounts with libraries repurified using a SPRI plate and Sera-Mag Speed-beads prior to paired-end sequencing (2 x 300 bp) on half of an Illumina MiSeq lane by the University of Georgia Genomics Facility. Triplicate libraries from three adult Ae. aegypti females that emerged from larvae collected at site 1 in Jacksonville, FL on 7/21/2014 were also paired-end sequenced. Amplicon data analyses Sequenced reads were trimmed at any site of two sequential bases receiving a quality score <Q30 and paired-end reads were merged using PEAR (Zhang et al. 2014). Read filtering criteria included: no ambiguous base calls or barcode/primer errors, all bases must have a PHRED equivalent score of 30 or higher (per base error rate of 0.1%), and reads must be between 440 and 484 bp in length. Quality-filtered reads were demultiplexed using an in-house Perl script and assigned to operational taxonomic units (OTUs) at a 97% identity threshold using the Quantitative Insights Into Microbial Ecology (QIIME) version 1.7.0 (Caporoso et al. 2010b) USEARCH 6.1 wrapper (Edgar 2010). Chimeric sequences were identified and removed using UCHIME (Edgar et al. 2011). Taxonomic classification was assigned against the latest Greengenes database (http://greengenes.lbl.gov/cgi-bin/nph-index.cgi) using the QIIME-based RDP Bayesian classifier with a 0.80 confidence threshold. OTUs making up less than 0.005% of sequence libraries were filtered out of our analysis (Bokulich et al. 2013). Sequence alignment was performed by PyNAST (Caporoso et al. 2010a), and phylogenetic tree construction was performed using FastTree (Price et al. 2009). For each sample, we first compared calculated indices for species richness and diversity (Chao1, Shannon’s H) within each technical replicate library to assess whether between replicate variation could affect alpha diversity estimates. One-way ANOVA detected no significant differences between replicated libraries for each measure (P > 0.05) (Table S2). We also compared beta diversity using the unweighted UniFrac distance and Bray-Curtis index of dissimilarity between pairs of samples within a given replicate. One-way ANOVA again detected no differences between technical replicates for any sample or either metric (P > 0.05) (Table S2). We therefore combined the three technical replicate libraries for each sample for diversity analyses, which were conducted on data rarefied to 38,735 sequences per sample. Separate analyses of variance (ANOVAs) were performed using R (http://www.r-project.org/) to compare alpha diversity (species richness, Chao1, and Shannon’s H diversity indices) between sites and mosquito species. We performed a principal coordinates analysis (PCoA) on Bray-Curtis distances using QIIME (Lozupone et al. 2007). A multivariate analysis of variance (MANOVA) was run on the first three PCoA vectors across all larval libraries to determine whether site, mosquito species, or collection date were significantly associated. We then performed univariate ANOVAs on significant MANOVA factors to examine which axis or axes drove the differences visible in the PCoA plots. Separate MANOVAs followed by univariate ANOVAs were also run using only the larval libraries for the sites in Jacksonville, FL or the two sites that contained more than one mosquito species. We assessed whether unweighted UniFrac distances were smaller for larval libraries of species within versus between sites using Monte Carlo t-tests (9,999 simulations). The same approach was used to assess whether UniFrac distances were smaller between water and larval libraries from a given site at late versus early sampling dates. We tested for differences in taxon abundance across sample groups using the QIIME script otu_category_significance.py. All MANOVAs and ANOVAs were run in R (http://www.r-project.org/) and analysed with Pillai’s Trace as the test statistic (Sullam et al. 2012). We used oligotyping of 16S ribosomal RNA gene amplicons to further investigate bacterial diversity within the six dominant phyla detected by OTU clustering. This was performed separately at the phylum level for five taxa (Actinobacteria, Bacteroidetes, Firmicutes, Cyanobacteria, Verrucomicrobia) while for Proteobacteria each class (Alphaproteobacteria, Betaproteobacteria, Gammaproteobacteria, and Deltaproteobacteria) was analyzed separately. Taxonomic assignments were made using quality filtered reads against the latest Greengenes database using the RDP classifier with a 0.80 confidence threshold. Sequences corresponding to each phylum or class were extracted using an in-house python script and an o-pad-with-gaps script to eliminate any length variation between reads. Oligotyping, which uses Shannon (1948) entropy to detect the amount of diversity at each nucleotide position, was conducted as outlined by Eren et al. (2013). Entropy values for nucleotide positions ranged from 0 to 2 with values ≥ 1.0 indicating greater bacterial diversity. Oligotypes were generated using the first position with the highest entropy value followed by further decomposition using user-defined nucleotide selection. Between 25 and 85 positions were chosen for each of the 9 datasets until no peaks were left unresolved. Peaks ≤ 0.2 were considered background noise. The value for parameter ‘s’ (the minimum number of samples in which an oligotype is present) was set to 2 to correct for technical errors due to sequencing, parameter ‘A’ was set to 0.0005% (the minimum total abundance of an oligotype in all samples) of the total reads for each data set to match the parameter set for OTU clustering, and parameter ‘M’ (the minimum count of the most abundant unique sequence in an oligotype) was set to 137 which corresponded to the average number of reads per sample divided by 1000 (Eren et al. 2013). Oligotype representative sequences (i.e. the most abundant sequence within an oligotype) were classified using the RDP classifier with a 0.8 confidence threshold. For determining percent alignment scores, the sequences corresponding to individual oligotypes were extracted from the OLIGO-REPRESENTATIVES directory and aligned using MAFFT (Katoh et al. 2005). Multilocus sequence typing (MLST) of Wolbachia from Ae. aegypti Wolbachia from Ae. aegypti was genotyped by multilocus sequence typing (MLST) of five housekeeping genes (gatB, coxA, hcpA, fbpA and ftsZ) (Baldo et al. 2006). Each gene was amplified using primer sets and reaction conditions for double AB-infected individuals as outlined by the Wolbachia MLST website (http://pubmlst.org/wolbachia/info/amp_seq_double.shtml). PCR products were visualized on 1% agarose gels using ethidium bromide followed by purification (PCR Purification Kit, Qiagen) and bidirectional sequencing (Eurofins MWG Operon). Sequences were concatenated, aligned and trimmed followed by analysis against the Wolbachia MLST database (http://pubmlst.org/wolbachia/). PhyML version 3.0 with the SPR search option was used for phylogeny construction, while branch support was estimated by bootstrapping the dataset 1,000 times (Guindon et al. 2010). Development Assays First instars with no gut bacteria were produced from surface sterilized eggs as previously described (Coon et al. 2014; Supplementary Methods). The status of larvae was confirmed using culture and PCR assays (Supplementary Methods). Standard mosquito larval rearing diet was sterilized by cobalt 60 gamma irradiation with sterility of diet confirmed by culture-based assays (Supplementary Methods). Water for sterile rearing cultures was autoclaved. Ten first instars were placed into 25 cm2 cell culture flasks (Corning) containing 20 ml of sterile water and sterilized standard diet (2 mg). Some flasks were maintained this way while to others we added 100 μl of water from laboratory trays containing conventionally reared larvae, 100 μl of water from site 1 in Jacksonville, FL, or 2 μl of an overnight E. coli (K12 MG1655 strain) culture. Note that inoculating cultures with water from conventional laboratory cultures or field site 1 provided the community of bacteria that was present. Each of the above treatments was replicated a minimum of three times with the proportion of first instars that developed into adults and total development time (days) determined by inspecting cultures daily. Survival data were analysed by Fisher’s Exact tests followed by post-hoc Bonferroni-corrected pairwise tests to compare treatments. Development times were tested for normality and equality of variances before analysis by one-way ANOVA and post-hoc Tukey-Kramer Honest Significant Difference (HSD) tests using R. Antibiotic assays We previously isolated, identified and cultured several members of the bacterial community in UGAL Ae. aegypti (Coon et al. 2014). Several members of the community in Ae. albopictus fourth instars collected at the Athens, GA field site were isolated in the current study by the same methods (Table S3). Five community members from UGAL Ae. aegypti (Aquitalea, Aeromonas, Chryseobacterium, Comamonas, and Sphingobacterium spp.) and two from field collected Ae. albopictus (Bacillus and Aeromonas spp.) were then used to assess their antibiotic susceptibility by standardized dilution (Wiegand et al. 2008). In brief, single colonies from overnight culture plates were suspended to 5 x 105 CFU/ml in Luria Bertani (LB) broth containing serially diluted ampicillin (Sigma), kanamycin (Roche), streptomycin (Sigma), chloramphenicol (Sigma), penicillin (Sigma), tetracycline (Sigma), or gentamicin (Gibco) (200 μg - 2 ng/ml). Suspensions were incubated at 28° C for 18 h. The minimal inhibitory concentration (MIC) was recorded as the lowest amount of antibiotic where no visual growth of bacteria was detected. We then placed newly hatched first instars (N=12) from the conventionally reared UGAL Ae. aegypti culture into 1 ml of distilled water in a culture plate containing non-sterilized standard diet (300 μg) and the same dilution series of antibiotics. From 2–6 wells and a total of 24–72 larvae per antibiotic dose were bioassayed. The number of larvae that died or molted to the second instar after 2 or 5 days was then recorded with 2 day molting data further analyzed by Fisher’s Exact tests. In other replicates we selected 6 larvae at 2 days post-hatching in cultures that contained either 200 μg/ml of ampicillin, kanamycin streptomycin, chloramphenicol and penicillin or 20 μg/ml of tetracycline or gentamicin. Larvae cultured for the same period with no antibiotic served as a positive control while axenic larvae served as a negative control. Larvae were then individually homogenized in Luria broth (LB) followed by serial dilution on LB plates which were incubated at 27° C for 72 h. The number of living bacteria per individual that could be cultured were then determined by colony count assay (Coon et al. 2016). Lastly, axenic first instars were produced and cultured in different concentrations of the same antibiotics followed by determination of the proportion of larvae that died after 5 days. Axenic larvae cultured with no antibiotics served as the positive control with mortality data across all treatments analyzed by Fisher’s Exact tests. 3. Results Clustering analyses of amplicon data identify variable bacterial communities Multiplex sequencing of 16S rRNA gene amplicons for all field and laboratory samples generated a total of 8.3 million reads of which 5.8 million were retained after quality filtering. Reads per sample ranged from 38,735 to 191,711, and grouped by percentage similarity into 1,253 operational taxonomic units (OTUs) at a cut-off threshold of 97% (Fig. 1, Table S4). However, 68 OTUs accounted for more than 50% of the total quality filtered reads. Rarefaction curves saturated or near saturated at 3,000 sequences, which indicated that most bacteria in each sample were captured (Fig. S1). Sample complexity varied with OTUs ranging from 211 to 628 for water and 85 to 556 for larvae. Bacterial species diversity differed by site as measured by richness (F6,29 = 10.63, P < 0.0001), Chao1 (F6,29 = 9.672, P < 0.0001), and Shannon’s H indices (F6,29 = 3.68, P < 0.01) (Fig. 1). The highest richness values were from sites in Jacksonville, FL, while the lowest were from laboratory cultures (Fig. 1). Richness was higher in water than larvae at most sites while alpha diversity in water and larvae at each site significantly correlated (r =0.72, P=0.0004). Twenty nine bacterial phyla were identified across all samples but 6 accounted for 81% of the OTU groups at the 97% cut-off threshold: Proteobacteria (49%), Actinobacteria (11%), Bacteroidetes (12%), Firmicutes (5%), Cyanobacteria (2%), and Verrucomicrobia (2%). Classification into orders showed that larvae contained the same taxa present in the water they were collected from but relative abundance differed. To visualize these trends we merged sample times for each collection site to produce the bar graphs shown in Fig. 2. This showed that laboratory reared Ae. aegypti, Ae. albopictus, and C. quinquefasciatus contained a greater proportion of Actinomycetales than field collected larvae (P=0.0003, after FDR-correction for multiple comparisons), while Ae. albopictus and C. quinquefasciatus from the Athens, GA field site contained a higher proportion of Burkholderiales than larvae from other sites (P=0.005) (Fig. 2). Considerable heterogeneity at the ordinal level was also observed between the field sites in Jacksonville, FL, which was striking given the proximity of most sites to one another (Fig. 1). PCoA analysis using the Bray-Curtis dissimilarity index showed clustering by collection site, mosquito species, and sampling date (Fig. 3). A MANOVA across all larval libraries indicated that differences along the PCoA axes were significant for site but not species or collection date (Table 1A). Separate MANOVAs for only the larval libraries from Jacksonville, FL (Table 1B) or the three sites that contained more than one mosquito species (site 1 in Jacksonville, the field site in Athens, GA, and the laboratory) (Table 1C) likewise indicated the bacterial communities in larvae differed by site but not collection date or species. We next calculated the unweighted UniFrac distances between samples. Pairwise analysis of all larval sequencing libraries using Monte Carlo resampling indicated that UniFrac distances differed between the same species from different sites (P≤0.002), whereas no significant differences were detected between mosquito species from the same site (P>0.05) (Fig. 4). Comparing UniFrac distances between the larval and aquatic samples from each field site also showed that distances were significantly larger at the early versus late sampling date (P≤0.03). Overall, these results indicated that the bacterial communities in water and mosquito larvae strongly differed between sites, while also suggesting that the larval and water communities within each site were more dissimilar to one another at the early collection dates than at the late collection dates. A final feature of note was detection of low abundance reads corresponding to Wolbachia in some but not all larval samples. Two Wolbachia OTUs were detected in all field and laboratory samples for Ae. albopictus while one Wolbachia OTU was detected in all field and laboratory samples for C. quinquefasciatus. No Wolbachia were detected in the Ae. aegypti laboratory culture (UGAL), which we previously reported (Coon et al. 2014), or in Ae. aegypti larvae from sites 2–4 in Jacksonville, FL. However, two Wolbachia OTUs were detected in Ae. aegypti larvae from site 1 in Jacksonville, FL. Mean prevalence of Wolbachia across larval samples for all species was 0.35%. Detection of Wolbachia in Ae. albopictus and C. quinquefasciatus was expected since both are known to harbor natural infections in North America (Kittayapong et al. 2002; Zouache et al. 2009; Almeida et al. 2011; Atyame et al. 2011; Minard et al. 2014). This was not expected though for Ae. aegypti because no natural infection of this species by Wolbachia has been reported anywhere in the world (Ross et al. 2016). We therefore reared and analyzed Ae. aegypti adults from larvae collected at Jacksonville site 1 on 7/21/2014 to assess whether they too were Wolbachia infected. Sequencing ITS1 domains from three adult females confirmed each was correctly identified to species. Sequencing of 16S rRNA gene amplicons from triplicate libraries produced from the same females also showed that the abundance of Wolbachia reads was much higher than in larvae but grouped into the same two OTUs (Fig. S2). MLST genotyping indicated one of these strains belonged to supergroup A and was related to a strain in Ae. albopictus, while the second was a supergroup B member present in a number of other insects including Ae. albopictus that were collected in Thailand (Fig. S3). Non-Wolbachia reads in these adults grouped into 27–43 OTUs that were either identical or belonged to the same genera detected in larvae but whose relative abundance differed (Fig. S2). For example Rhodocyclales that were abundant in larvae were reduced while Rhodospirillales and Burkholderiales (adults 1 and 2), or Burkholderiales and Pseudomonadales (adult 3) were elevated (Fig. S2). Oligotyping identifies additional bacterial diversity Oligotyping provides a computational method for identifying subpopulations (oligotypes) within OTUs. We therefore generated oligotyping datasets for the six most abundant bacterial phyla we identified (Proteobacteria, Actinobacteria, Bacteroidetes, Firmicutes, Cyanobacteria, and Verrucomicrobia), which as noted above accounted for 81% of the OTU groups we identified across all samples. A total of 2.6 million quality-filtered reads were used, which ranged from 3,301 to 164,841 per sample, and grouped into 4,321 unique oligotypes (Table S5). Sequence identities within an oligotype ranged from 99.5% to 100%, while relative abundance of individual oligotypes ranged from 0.006% to 0.3%. We used oligotyping to further assess bacterial diversity by focusing on two locations: Jacksonville field site 1, which on 7/21/2014 contained Ae. aegypti and C. quinquefasciatus larvae, and our laboratory culture of Ae. aegypti which was sampled on a single date. We first determined the total number of oligotypes for each of the bacterial phyla or classes (Proteobacteria) that contained >5% of the OTU groups in Ae. aegypti larvae from these collections. For Jacksonville field site 1, these taxa were Actinobacteria, Bacteroidetes, and four classes of Proteobacteria, while for the laboratory culture they were Actinobacteria, Bacteroidetes, Firmicutes, Betaproteobacteria and Verrucomicrobia (Fig. 5A). We then plotted the proportion of these oligotypes that were present in water from the same site. A majority of the oligotypes detected in Ae. aegypti larvae from field site 1 were detected in the water for some taxa (Bacteroidetes) but not others (Deltaproteobacteria) (Fig. 5A). In contrast, almost all oligotypes in Ae. aegypti larvae from the laboratory culture were detected in the water habitat (Fig. 5A). We next selected the most abundant OTU for each of the taxa shown in Fig. 5A, and determined the number of oligotypes for each in Ae. aegypti larvae. The taxonomic assignments for these OTUs are summarized in Table S6, which also presents the sequences for the two most abundant oligotypes, and the full-length sequences for the corresponding 16s rRNA gene amplicons. We also separately examined the number and identity of the oligotypes for each of the OTUs in the three technical sequencing replicates for these samples. This showed that the number and identity of the oligotypes for each OTU per replicate were identical. Comparison of these OTUs and oligotypes to the C. quinquefasciatus larvae that were also present at Jacksonville field site 1 on 7/21/2014 showed almost complete overlap, whereas only partial overlap was detected in the water (Fig. 5B). Comparison to Ae. aegypti larvae collected from site 1 on 9/15/2014 also showed that some OTUs and corresponding oligotypes near fully overlapped (Leucobacter, Dysgonomonas), while others (C39, Desulfovibrio cuneatus) were absent although some oligotypes were detected in the water (Fig. 5B). In contrast, almost no overlap in oligotypes was detected in Ae. aegypti larvae collected from Jacksonville field sites 3 and 4 on 7/21/2014 or the laboratory, because either these OTUs were absent or very rare (Fig. 5B). The same exercise with the most abundant OTUs in Ae. aegypti larvae from the laboratory showed near complete overlap with the oligotypes detected in the water (Fig. 5C). In contrast, little overlap was detected with Ae. aegypti larvae from different Jacksonville field sites (Fig. 5C). The one exception to these trends was the unclassified Microbacteriaceae where a number of oligotypes overlapped with Ae. aegypti larvae from Jacksonville field site 1. However, this OTU was also very rare in site 1 larvae with almost all of the overlapping oligotypes detected as single sequences (singletons). For most of the OTUs discussed above, the two most abundant oligotypes differed from each other by only 1 nucleotide with corresponding full-length amplicons exhibiting ≥99% identity (Table S6). Exceptions were the unnamed genus C39 (Betaproteobacteria) detected in Ae. aegypti larvae from Jacksonville field site 1 where the two most abundant oligotypes derived from full-length amplicons that differed by 29 nucleotides over 463 nt (92% sequence identity) and the Chryseobacterium (Bacteroidetes) in Ae. aegypti larvae from the laboratory where the two most abundant oligotypes derived from full-length amplicons that differed by 96 nucleotides over the 453 nt (79% sequence identity). The strongest matches identified after BlastN searches in most cases exhibited ~99% sequence identity with known bacteria (Table S6). Most matches were to uncultured bacterial clones identified from different parts of the world in freshwater, rainwater, or soil (Table S6). Notably though, oligotype 1 for C39 shared 99% sequence identity with an uncultured bacterium identified in the larval gut of Anopheles stephensi while oligotype 1 for the Chryseobacterium in laboratory Ae. aegypti larvae shared 99% sequence identity with an uncultured clone from a cranefly, Tipula abdominalis, which resides in the sister family (Tupulidae) of the Culicidae (Table S6). Mosquitoes from the field and laboratory both require gut bacteria for development The preceding results indicated the microbiota in Ae. aegypti, Ae. albopictus, and C. quinquefasciatus larvae differ between local field sites and collection dates as well as between field sites and the laboratory. We therefore asked whether these differences affected the requirement of mosquitoes from the field and laboratory for gut bacteria to develop. Examining progeny from every field site for these experiments was not technically feasible because of the effort involved in rearing field-collected mosquitoes, producing eggs, and generating progeny with no gut bacteria. We therefore focused these experiments on comparing the laboratory population of Ae. albopictus to Ae. albopictus from the field site in Athens GA, and Ae. aegypti plus C. quinquefasciatus from the laboratory to the same species collected at Jacksonville field site 1. These choices were justified because each of these populations differed in terms of deriving from sites with distinctly different bacterial communities, having different culture histories, and in the case of Ae. aegypti also differing in regard to Wolbachia infection. We first verified that previously developed methods for surface sterilizing eggs (Coon et al. 2014) produced larvae with no gut bacteria. For each species, culture-based assays showed that numerous bacterial colonies grew when homogenates of first instars from non-sterilized eggs were plated on LB or BHI plates. PCR assays also generated amplicons using universal 16S rRNA bacterial gene primers and DNA templates from non-sterilized eggs. In contrast, no bacteria grew when homogenates of first instars from surface sterilized eggs were placed on culture plates. No bacterial amplicons were detected using universal primers and templates from laboratory (UGAL) Ae. aegypti first instars that hatched from surface sterilized eggs but weak amplicons were detected in the other samples that we assumed were due to Wolbachia. This interpretation was supported using primers for the Wolbachia wsp gene, which generated amplicons from each sample except UGAL Ae. aegypti. Thus, surface sterilization of eggs produced axenic larvae with no detectable bacteria in the case of UGAL Ae. aegypti, whereas larvae for all other samples likely had no gut bacteria but, as expected, remained infected with Wolbachia, which are vertically transmitted and intracellular. We then placed larvae from surface sterilized eggs in sterile water plus sterile food. All ultimately died as first instars after hatching (Fig. 6). Larvae in this condition usually died 6–9 days after hatching but some lived up to 14 days as first instars that never molted before finally dying. In contrast, a majority of larvae from each collection site and species developed into adults if inoculated with water from laboratory trays containing conventionally reared (non-sterile) Ae. aegypti larvae or water from field site 1 in Jacksonville, FL (Fig. 6). A majority of larvae from surface sterilized eggs also developed into adults if inoculated with only E. coli, which was absent from all field and laboratory samples we analyzed (Fig. 6). Antibiotics do not fully eliminate bacteria from conventionally reared Ae. aegypti larvae and adversely affect axenic larvae that contain no bacteria The preceding results indicated that Ae. aegypti, Ae. albopictus and C. quinquefasciatus require gut bacteria for development regardless of origin, prior rearing history, or Wolbachia infection. These results were also near identical to our previous results that examined only long-term laboratory cultures of Ae. aegypti, Ae. atropalpus and An. gambiae that were not Wolbachia infected (Coon et al. 2014). However, they clearly differed from results showing that mosquito larvae treated with antibiotics only exhibit delays in development (Chouaia et al. 2012). We thus assessed whether antibiotic treatment results in developmental delays because bacteria that colonize mosquitoes are not fully eliminated. As with our developmental assays, it was not logistically feasible to examine the antibiotic susceptibility of every OTU we identified across the species and breeding sites we sampled. We therefore selected 7 abundant community members that we isolated from UGAL Ae. aegypti and field collected Ae. albopictus. Like E. coli, each individually colonizes Ae. aegypti and Ae. albopictus from surface sterilized eggs to produce gnotobiotic larvae that develop normally into adults. We first tested the susceptibility of these bacteria to several different antibiotics over a concentration range used in other studies to eliminate bacteria from the mosquito digestive tract (Dong et al. 2009; Chouaia et al. 2012; Ramirez et al. 2012; Minard et al. 2013). The purpose of this was to assess the sensitivity of each bacterium to these antibiotics in the absence of any confounding effects from being in a mosquito. Results showed that these bacteria exhibited highly variable sensitivities with the minimal inhibitory concentration (MIC) for ampicillin exceeding 200 μg/ml for each species while MICs for kanamycin, streptomycin, and penicillin exceeded 200 μg/ml for most (Table S7). Average MICs were lower for tetracycline, chloramphenicol, and gentamicin but were ≥ 200 μg/ml for a Chryseobacterium sp. isolated from UGAL Ae. aegypti (Table S7). Thus, in vitro each bacterium showed differential sensitivity to the antibiotics we tested and in some cases were largely unaffected at high doses. Given these findings, we next assessed the effects of each antibiotic on larvae across the same range of concentrations. Given the highly variable microbial communities we identified across species and populations but the inability of each to develop without gut bacteria, we selected conventionally reared (non-sterile) UGAL Ae. aegypti for these assays, which was also the source of most bacterial isolates for the preceding MIC assays. Results indicated these larvae molted to the second instar in two days in the absence of antibiotics and across all concentrations of ampicillin (Fig. 7A). The other antibiotics had dose-dependent effects on mortality, timing of molting, or both (Fig. 7A). Chloramphenicol and penicillin had no mortality effects but all larvae molted to the second instar within 5 days. All or a large proportion of larvae treated with 200 μg/ml of kanamycin, streptomycin or tetracycline or ≥ 20 μg/ml of gentamicin died within 5 days, but all surviving larvae molted within 5 days (Fig. 7A). Larvae treated with lower concentrations of these antibiotics exhibited no mortality and molted within 2 days (Fig. 7A). To quantify bacterial clearance, individual larvae from cultures containing the highest concentration of each antibiotic that did not cause larvae to die were homogenized at 2 days post-hatching and cultured on LB plates. Results showed that each antibiotic except ampicillin significantly reduced the number of culturable bacteria when compared to conventional larvae that were cultured with no antibiotic (Fig. 7B). However, all antibiotic treated larvae still contained viable bacteria, whereas axenic larvae produced from surface sterilized eggs contained, as expected, no culturable bacteria (Fig. 7B). We therefore assessed whether the mortality tetracycline and gentamicin caused in conventional larvae when used at 200 μg/ml also occurred in axenic larvae. Dose-response assays showed that these antibiotics as well as kanamycin and streptomycin dose-dependently increased the mortality of axenic larvae when compared to axenic control larvae that were cultured in the absence of antibiotics (Fig. 7C). Altogether, these results indicated that several antibiotics failed to fully eliminate bacteria from UGAL Ae. aegypti while also showing that antibiotic treatment adversely affects first instars when used at high concentrations regardless of whether or not they contained culturable bacteria. Discussion Our previous results (Coon et al. 2014; 2016) indicated that laboratory populations of three mosquito species required living bacteria to develop into adults, but development did not depend on a particular bacterial species or community assemblage. In this study, we generated additional information in three areas of study to better understand the functional role of bacteria in mosquito development. This included the characterization of bacterial community diversity within and between three species from breeding sites in the field and laboratory. This information was essential in order to know whether or not species or larvae from different locations host similar or different bacterial communities of potential importance in development. With this knowledge in hand, we then could assess whether: 1) larvae differ in their requirement for living bacteria to develop as a function of species, rearing history, overall bacterial community composition, or Wolbachia infection that has previously been suggested to nutritionally benefit mosquitoes during periods of stress (Brownlie et al. 2009). These data also fully positioned us to assess whether the approach of producing axenic larvae by surface sterilizing eggs versus treating larvae with antibiotics yield similar or different outcomes. Our analyses of bacterial community diversity indicate that Ae. aegypti, Ae. albopictus and C. quinquefasciatus larvae primarily contain a subset of the OTUs in the water they were collected from, which supports that larvae are colonized by a subset of the bacteria they ingest during feeding. Since our data derive from pooled samples of whole larvae, we cannot conclude that the OTUs we identified are all restricted to the gut. However, prior results as well as data in this study showing that axenic larvae contain no bacteria unless infected by Wolbachia strongly support that larvae acquired the bacteria we identified from the environment by feeding which in turn also suggests most of the OTUs we identified are present in the digestive tract. However, it is also possible some bacteria present in the gut over time colonize other tissues given findings in the literature that identify some species of bacteria present in the gut that also colonize other organs (see Chouaia et al. 2012; Gimonneau et al. 2014). We recognize that additional sampling could further improve upon our bacterial diversity studies. However, our data set was sufficiently robust to compare within-site versus between-site beta diversity, which strongly supported that community composition varied greatly between sites, while strong similarities were found between larvae of different species that were developing in the same site. That no species effect was detected in sites containing two species of mosquitoes supports that a similar subset of bacteria colonized larvae of each. That identical oligotypes were recovered from water and larvae within but not between sites is additional strong evidence for between site variability for the bacterial communities in water and larvae. Interestingly, our within site comparisons between different sampling dates also indicate that the bacterial communities in larvae and their aquatic habitats become more similar over the breeding season. At this time, we are uncertain what accounts for this. Certainly bacteria from diverse sources could colonize the sites we sampled. However, it is also possible that mosquitoes modify their aquatic habitat through cyclic transmission, which has been proposed for other aquatic organisms (McFall-Ngai 1998; Sullam et al. 2012). This could occur through larvae feeding and excreting bacteria that are selected for in their own digestive tract. We also previously showed that some abundant members of the larval and adult gut communities in laboratory-reared Ae. aegypti are present on the surface of eggs females lay (Coon et al. 2014). Thus, adult mosquitoes may transmit some gut community members to habitats where they oviposit, which over time could affect the microbial community in the water where larvae develop. The ability of mosquitoes to alter the composition of bacterial communities in larval habitats would be strongest in small volume containers like those we sampled. Comparison of sites persistently colonized by mosquito larvae to neighboring sites where no mosquitoes can colonize would be one approach to assessing whether mosquitoes significantly alter the bacterial communities in small aquatic habitats. Our community diversity data share some parallels with studies of terrestrial insects including Drosophila and certain Lepidoptera, which show that the food larvae consume overrides the effect of species in defining the composition of the gut microbiota (Chandler et al. 2011; Wong et al. 2011; Priya et al. 2012). However, it has also been noted that the complex relationships between bacteria and their environments may require finer scale information about microbial diversity than can be provided by the classification of OTUs or clustering approaches (Eren et al. 2013). Our use of oligotyping allowed us to address this concern and assess whether concealed diversity within identified OTUs reveals additional patterns. We generated oligotyping data sets for the six most abundant bacterial phyla detected across our entire sequencing dataset. However, we focused on Jacksonville field site 1, which contained both Ae. aegypti and C. quinquefasciatus larvae, and our Ae. aegypti laboratory culture to assess whether oligotyping revealed similar or different trends to our clustering analyses. In terms of colonization, almost all oligotypes in laboratory reared Ae. aegypti were present in the water they were collected from. This was also true for some bacterial taxa in Ae. aegypti from field site 1 but for others like Deltaproteobacteria most of the oligotypes detected in larvae were not detected in the water they came from. More interesting though were our results that focused on the most abundant OTUs for each oligotyped phylum or class in Ae. aegypti larvae from Jacksonville field site 1. These data showed that each OTU consisted of several oligotypes but nearly all oligotypes detected in Ae. aegypti larvae were also present in C. quinquefasciatus larvae from the same site and date. This provided strong evidence that the same subset of bacteria in the local habitat colonized both species. In contrast, almost none of these OTUs or oligotypes were detected in Ae. aegypti larvae collected on the same date from other sites in Jacksonville or the laboratory, which underscores the high variation that existed between the sites we sampled. As previously noted, the presence of Wolbachia in Ae. albopictus and C. quinquefasciatus was expected but identification of A and B group Wolbachia in Ae. aegypti from Jacksonville site 1 was not becaue no natural infections of this species have previously been reported (Ross et al. 2016). We thus were very careful to document these mosquitoes were correctly identified and that we genotyped the Wolbachia strains. We sequenced only a small number of adults from this site because we did not anticipate encountering any Wolbachia in Ae. aegypti, and characterizing these bacteria was not an original goal of the study. As a result we had only a small number of frozen adults from this site that could be used for sequence analysis when we learned from the larval data set that Wolbachia reads were present. Nonetheless the data we generated confirmed each adult contained the same Wolbachia OTUs detected in larvae. At this time, we need to be very cautious about these results and their possible implications because our data also clearly indicate that Ae. aegypti at most of the sites we sampled contained no Wolbachia. That both the A and B group members detected in Ae. aegypti from Jacksonville, FL field site 1 are related but not identical to Wolbachia that have been identified from Ae. albopictus suggests the possibility of past lateral transfer, which would also be consistent with Ae. aegypti and Ae. albopictus sharing partially overlapping ranges in several parts of the world including the Southeastern US. The presence of a natural Wolbachia infection in Ae. aegypti also has applied implications given the use of introduced Wolbachia in Ae. aegypti for use in population replacement to alter vector competency (reviewed in Minard, 2013). While Wolbachia abundance in larval stage mosquitoes has not previously been reported, our finding that titers are very low relative to adults is similar to a recent study, which noted that D. melanogaster larvae also contain a low abundance infection relative to adult females (Stevanovic et al. 2015). On the other hand, the high abundance of Wolbachia in adult female mosquitoes has been reported in other studies and has also been noted to hinder characterization of gut microbiota diversity in pyrosequencing data sets (Minard et al. 2014; Muturi et al. 2016). Our Illumina data in contrast provided sufficient coverage to discern that adults contained a subset of the OTUs detected in larvae, which circumstantially supports results from previous laboratory experiments that adults acquire a subset of the gut community in larvae by transstadial transmission (Coon et al. 2014). Collectively, our bacterial diversity and Wolbachia data positioned us to address the second goal of this study by assessing whether larvae differed in their developmental requirement for gut bacteria as a function of species, origin (laboratory versus field), or Wolbachia infection status. Results showed they did not with all larvae failing to develop when gut bacteria were absent but a high proportion of larvae developing into adults when recolonized with a mixed community of bacteria in water from the field or lab, or E. coli, which was absent across all samples and collection sites. In contrast, the third goal of our study revealed two important outcomes in regard to antibiotics. First, while antibiotics are commonly used to eliminate resident microbiota from insects including mosquitoes, our results indicate they do not fully eliminate the microbiota from Ae. aegypti larvae, which is one reason why antibiotic therapy does not prevent larvae from developing. A recent study similarly revealed that antibiotic treatment also does not fully eliminate the microbiota from adult Anopheles mosquitoes (Hughes et al. 2014). Second, some of the antibiotics we tested adversely affected the survival of Ae. aegypti which contained no bacteria. While no published work has previously noted antibiotic sensitivity in mosquito larvae, some antibiotics including tetracyclines are known to adversely affect other eukaryotes including insects independent of their effects on the microbiota (Ridley et al. 2013; Moullan et al. 2015). We thus conclude that surface sterilization of eggs is much more effective for producing mosquito larvae with no gut bacteria and that antibiotic therapy has several major shortcomings for studying the function of bacteria in mosquito development. We have now examined a total of five mosquito species from field and laboratory populations that each exhibit a requirement for living bacteria in their gut to develop, but also show no evidence that development depends on a particular species or community assemblage. While several studies have noted variable communities of bacteria in mosquitoes from different geographic locations, this study shows that bacteria are consistently present in mosquito larvae but community composition is also highly variable between sites on a fine geographic scale. Together, these data suggest the hypothesis that the mosquito species we have studied to date rely on bacteria for development quite generally because of the high unpredictability in the community of bacteria between sites. This lack of specialization could also reflect that most of the mosquitoes we have studied have been introduced into habitats outside of their native range. More specialized mosquito species or these species in their native habitat in contrast may exhibit more specific associations with bacteria. The obvious question going forward is what do living bacteria provide that mosquito larvae require? This issue is also very interesting from the perspective of the model organism literature where Drosophila and mice show roles for gut bacteria in maturation of the immune and digestive systems but also indicate bacteria are not required for development into adults because axenic cultures of both can be maintained for generations if fed a nutritionally complete diet (Buchon et al. 2013; Lee & Brey 2013; Sommer & Backhed 2013; Blaser 2016; Goodrich et al. 2016). One option is that many bacteria share conserved metabolic features that facilitate breakdown of factors in the larval diet or could produce nutrients that supplement the mosquito diet. Several studies have experimentally demonstrated or provide circumstantial support for gut bacteria having digestive or nutritional functions in some insects (summarized by Engel & Moran, 2013). However, most of these examples focus on species that feed on specialized diets with nutrient constraints, whereas laboratory reared mosquitoes consume nutritionally rich and complete diets. Alternatively, several different types of bacteria could potentially affect physiochemical parameters such as pH or redox state that alter the gut environment in ways that mosquito larvae depend upon to grow and molt. A third option is that most bacteria share cell wall components and/or generate conserved metabolites that could function as signaling molecules. The former are well known pattern recognition factors that the insect immune system recognizes, which could activate different signaling pathways in the gut that are essential for development. Contact-dependent interactions between bacteria and the gut epithelium or diffusible bacterial metabolites that gut cells perceive have also been identified to mediate gut homeostasis or systemic growth of mice and Drosophila (Shin et al. 2011; Storelli et al. 2011; Nicholson et al. 2012). Understanding the mechanism(s) underlying why mosquitoes require living bacteria is of translational significance, because the processes involved may be amenable to disruption, which could be used as a tool for controlling species that transmit human disease. Supplementary Material Supp Fig S1 Supp Fig S2 Supp Fig S3 Supp MethodsS1 Supp Table S1 Supp Table S2 Supp Table S3 Supp Table S4 Supp Table S5 Supp Table S6 Supp Table S7 We thank K. J. Vogel and G. R. Burke for suggestions during the study, J. A. Russell who provided considerable feedback after initial submission of the paper including the suggestion for oligotyping, and comments from an impressive number of anonymous reviewers. We thank J. Wright with the US Navy Entomology Center of Excellence for assistance in identifying larval habitats in Jacksonville, FL. J. Brandt assisted with field collections, M. Brandt provided technical support, and S.R. Robertson and A. Elliot assisted with rearing. This work was supported by the National Science Foundation (Graduate Research Fellowship 038550-04 (KLC)), University of Georgia Graduate School (KLC), Sigma Xi (KLC), and National Institutes of Health R01AI106892 and T32GM007103 (MRS). Fig. 1 Collection sites and sequencing statistics for the 16S rRNA libraries prepared from water and mosquito larvae. The upper portion of the figure shows the locations of the collection sites in Georgia and Florida. The lower portion of the figure summarizes the sites, sampling dates, and mosquito species that were collected. For each collection site, latitude and longitude coordinates are indicated along with a general description of the habitats, which were all containers of variable size. Numbers in parentheses in the column named Mosquito species indicate the approximate number of larvae that were present per 300 ml of water. This provides a sense of larval density between sites and collection dates. Number of reads for each library after quality filtering, number of OTUs, and indices for species richness and diversity (Chao 1, Shannon’s H) are also presented. Fig. 2 Bacteria at the levels of phylum and order in water and mosquito larvae from each collection site. Water and larval (fourth instar) libraries for each collection date were pooled for the bar graphs presented. Each bar presents the proportion of sequencing reads assigned to a given bacterial order. Only categories >2% are presented. Fig. 3 Principal coordinates analysis based on pairwise Bray-Curtis distances. Symbols are coloured by collection site (laboratory: green, Athens, GA: red, Jacksonville, FL: orange (site 1), dark blue (site 2), light blue (site 3), yellow (site 4), purple (site 5). The legends in the upper right of each plot designate sample type (water or species of larva) by symbol shape. Water and larval samples for each collection date are presented but are not given unique identifiers because date was not statistically significant (see Table 1). Fig. 4 Within and between-site variation in the bacteria in mosquito larvae. Within-site variation was determined by average unweighted UniFrac distances between different mosquito species from the same site, while between-site variation was determined by distances between the same mosquito species collected from different sites. Mean values ± 95% confidence intervals are shown. **, P < 0.01; ***, P < 0.0001 (Student’s t-test with 10,000 Monte Carlo permutations). Fig. 5 Oligotype analyses. (A) Oligotype overlap between Aedes aegypti larvae and water collected from site 1 in Jacksonville, FL (7/21/2014) or the laboratory. Bars indicate the proportion of oligotypes present in larvae that were also present in water. Numbers above the bars indicate the total number of oligotypes present in larvae. (B) Oligotype distribution between larvae collected from site 1, 3 or 4 in Jacksonville FL (7/21/2014) and the laboratory. The column on the left indicates the number of oligotypes present in Ae. aegypti larvae from site 1 whose taxonomic assignment matched the dominant OTU corresponding to a given phylum (or class). Subsequent bars indicate the proportion of these oligotypes present in either Culex quinquefasciatus larvae or water collected from the same site, or Ae. aegypti larvae collected from other sites on the same collection date. Bars on the far right indicate the proportion of these oligotypes present in Ae. aegypti larvae in the laboratory. The lower panel displays the proportion of oligotypes present in Ae. aegypti larvae from site 1 that were present in either Ae. aegypti larvae or water collected from the same site on 9/15/2014. Bars in (C) present oligotype overlap between Ae. aegypti larvae collected from the laboratory and the same field sites. The column on the left indicates the number of oligotypes present in Ae. aegypti larvae from the laboratory corresponding to the dominant taxa identified by OTU clustering. Subsequent bars indicate the proportion of these oligotypes present in either water collected from the same site, or Ae. aegypti larvae collected from site 1, 3 or 4 in Jacksonville, FL (7/21/2014). Only phyla (or classes) that accounted for >5% of the total number of reads are included in the figure. Fig. 6 Survival to adulthood and development time of Ae. aegypti, Ae. albopictus, and C. quinquefasciatus larvae that hatched from eggs laid by adult, mated females reared from field-collected larvae or larvae from laboratory cultures. Field derived Ae. aegypti and C. quinquefasciatus came from site 1 in Jacksonville, FL, while Ae. albopictus came from the field site in Athens, GA. All laboratory-reared females came from our long-term laboratory cultures (see Methods). All eggs were surface sterilized and the first instars that hatched were confirmed to contain no gut bacteria. The bars in the upper graph show the proportion of larvae that developed into adults when fed sterilized diet in sterile water, sterile water inoculated with 100 μl of non-sterile laboratory water, sterile water inoculated with 100 μl of non-sterile field water, and sterile water inoculated with Escherichia coli. Fisher’s Exact tests were conducted separately for each species with post-hoc Bonferroni-corrected pairwise tests to compare treatments (NS, treatments not significantly different; ***, sterile water only treatment significantly differs from the lab culture water, field water, and E. coli treatments (P < 0.0001). The bars of the lower graph show the development time from egg hatching until adult emergence for larvae reared in water inoculated with lab culture water, field water and E. coli. Development time for larvae cultured in sterile water only is not shown in the lower graph because no individuals survived beyond the first instar. Columns indicate mean values with 95% confidence intervals. ANOVA and post-hoc comparison tests were used to compare development times separately for each species (*** laboratory derived Ae. aegypti and Ae. albopictus reared in cultures inoculated with field water developed faster than larvae in cultures inoculated with laboratory water or E. coli (P < 0.05). Figure 7 Effect of antibiotics on UGAL strain Ae. aegypti larvae and associated bacteria. (A) Mortality and molting of conventionally reared (non-sterile) first instars treated with different antibiotics that were added to cultures. Columns from left to right indicate: antibiotic type, dose, total number of larvae treated per dose, the number of larvae that died within 5 days (d), the number of larvae that molted after 2 d, and the number of larvae that molted after 5 days. Asterisks (*) in the column labeled Molting after 2 d indicate the treatment significantly differed from the negative control which was larvae treated with no antibiotic (0 μg/ml) (P < 0.05; Fisher’s Exact Test, pairwise comparison against control). (B) Bacterial loads in 2 day old larvae collected from treatment dishes as described in (A). Non-sterile first instars reared conventionally without antibiotics served as the positive control. First instars from surface-sterilized eggs reared under sterile conditions (Axenic) served as the negative control. In most cases, a total of 6 larvae were sampled from the highest dose for each antibiotic treatment (200 μg/ml). In the case of tetracycline and gentamicin, larvae were sampled from the 20 μg/ml treatment due to 100% mortality at 200 μg/ml (see A). Bars show mean bacterial load per larva with 95% confidence intervals as determined by colony forming units (CFUs). An asterisk (*) above a bar indicates the treatment significantly differed from the positive control (*, P < 0.05; ***, P < 0.0001; Dunnett’s test). (C) Mortality of axenic first instars reared in the presence of antibiotic. Antibiotic treatment and corresponding dose are indicated below each bar. Axenic first instars reared under sterile conditions without antibiotic treatment served as the control. A total of 24 larvae were assayed per treatment. Numbers above the bars indicate the number of larvae that died within 5 d while an asterisk (*) following this number indicates significantly more larvae died relative to the control (P < 0.05; Fisher’s Exact Test, pairwise comparison against control). Table 1 Effects of collection site, species, and collection date on larval bacterial communities in mosquitoes (A) Multivariate analysis of all larval libraries Source of variation Pillai’s trace Hypothesis df Error df F P Site 2.882 18 24 32.630 <0.0001* Species 0.705 6 14 1.269 0.332 Sampling date 0.560 9 24 0.612 0.775 Univariate analysis of site (all larval libraries) Type III SS df F P Site  PCoA1 1.160 6 29.905 <0.0001*  PCoA2 1.097 6 28.223 <0.0001*  PCoA3 0.729 6 60.672 <0.0001* (B) Multivariate analysis of larval libraries from only Jacksonville, FL Source of variation Pillai’s trace Hypothesis df Error df F P Site 2.624 12 15 8.718 <0.0001* Species 0.786 3 3 3.673 0.157 Sampling date 1.043 6 8 1.453 0.305 Univariate analysis of site (Jacksonville, FL) Type III SS df F P Site  PCoA1 0.409 4 10.417 <0.01*  PCoA2 0.189 4 4.752 <0.05*  PCoA3 0.461 4 48.283 <0.0001* (C) Multivariate analysis of larval libraries from only multi-species sites Source of variation Pillai’s trace Hypothesis df Error df F P Site 1.926 6 6 26.036 <0.001* Species 0.804 6 6 0.672 0.679 Sampling date 0.847 9 12 0.525 0.831 Univariate analysis of site (multi-species) Type III SS df F P Site  PCoA1 0.968 2 56.247 <0.0001*  PCoA2 0.718 2 44.357 <0.0001*  PCoA3 0.0535 2 10.745 <0.01* P-values from MANOVA (multivariate) and ANOVA (univariate) analyses are based on Bray-Curtis distances (*significant at the ≤ 0.05 level). Data accessibility Sanger-sequenced 16S reads for bacterial isolates used for MIC determination are available under GenBank accession no. KJ192338-KJ192343 and KX260132-KX260135. Sanger-sequenced reads used for MLST of Wolbachia are available under GenBank accession no. [awaiting accession no. assignment]. Raw Illumina reads were deposited in the NCBI Sequence Read Archive (http://www.ncbi.nlm.nih.gov/sra) under project ID PRJNA342829. Input files for the QIIME and oligotyping pipelines as well as raw data files and R code for statistical analyses have been deposited in the Dryad digital repository under accession number doi:10.5061/dryad.qs43p. 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PMC005xxxxxx/PMC5118135.txt
LICENSE: This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. 0132144 7838 Transplantation Transplantation Transplantation 0041-1337 1534-6080 27495762 5118135 10.1097/TP.0000000000001406 NIHMS800569 Article Graft versus Host Disease After Liver Transplantation in Adults: A Case series, Review of Literature, and an Approach to Management Murali Arvind Rangarajan MD *Division of Gastroenterology & Hepatology, University of Iowa Hospitals and Clinics, Iowa City, Iowa, USA arvind-murali@uiowa.edu Chandra Subhash MD *Division of Gastroenterology & Hepatology, University of Iowa Hospitals and Clinics, Iowa City, Iowa, USA subhash-chandra@uiowa.edu Stewart Zoe MD, PhD Department of Surgery, Division of Transplantation & Hepatobiliary Surgery, University of Iowa Hospitals and Clinics, Iowa City, Iowa, USA zoe-stewart@uiowa.edu Blazar Bruce R MD Division of Blood and Bone Marrow Transplantation, University of Minnesota, Minneapolis, Minnesota, USA blaza001@umn.edu Farooq Umar MD Division of Hematology and Oncology, Bone Marrow Transplant, University of Iowa Hospitals and Clinics, Iowa City, Iowa, USA umar-farooq@uiowa.edu Ince M Nedim MD Division of Gastroenterology & Hepatology, University of Iowa Hospitals and Clinics, Iowa City, Iowa, USA m-nedim-ince@uiowa.edu Dunkelberg Jeffrey MD, PhD Department of Gastroenterology & Hepatology, University of Iowa Hospitals and Clinics, Iowa City, Iowa, USA jeffrey-dunkelberg@uiowa.edu Corresponding author Dr. Jeffrey Dunkelberg, MD, PhD, Clinical Professor, Division of Gastroenterology and Hepatology, Department of Internal Medicine, University of Iowa Hospitals and Clinics, Iowa city, Iowa, USA 52246, jeffrey-dunkelberg@uiowa.edu, Telephone number: 3193562132 * Murali AR and Chandra S have contributed equally and are both first authors. 17 7 2016 12 2016 01 12 2017 100 12 26612670 This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. Background Graft-versus-host-disease (GVHD) after liver transplantation (LT) is a deadly complication with very limited data on risk factors, diagnosis and management. We report a case series and a comprehensive review of the literature. Methods Data was systematically extracted from reports of GVHD after LT, and from the United Network for Organ Sharing (UNOS) database. Group comparisons were performed. Results 156 adult patients with GVHD after LT have been reported. Median time to GVHD onset was 28 days. Clinical features were skin rash (92%), pancytopenia (78%) and diarrhea (65%). 6-month mortality with GVHD after LT was 73%. Sepsis was the most common cause of death (60%). Enterobacter bacteremia, invasive aspergillosis and disseminated Candida infections were frequently reported. Recipient age over 50-years is a risk factor for GVHD after LT. Hepatocellular carcinoma (HCC) was over-represented, while chronic hepatitis C was under-represented, in reported United States GVHD cases relative to all UNOS database LT cases. Mortality rate with treatment of GVHD after LT was 84% with high-dose steroids alone, 75–100% with regimens using dose increases of calcineurin inhibitors (CNI), and 55% with IL-2 antagonists. Mortality was 25% in small case series using the CD2-blocker alefacept or tumor necrosis factor-α (TNF-α) antagonists. Conclusions Age over 50-years and HCC appear to be risk factors for GVHD. Hepatitis C may be protective. High-dose steroids and CNI are ineffective in the treatment of GVHD after LT. CD2-blockers and TNF-α antagonists appear promising. We propose a diagnostic algorithm to assist clinicians in managing adults with GVHD after LT. INTRODUCTION Graft-versus-host-disease (GVHD) is an infrequent complication after liver transplantation (LT), with an incidence of 0.5–2% 1–3. GVHD occurs as a result of donor immunocompetent cells recognizing recipient antigens as foreign and mounting an immune response. Grafts containing more immunocompetent donor lymphocytes, such as hematopoietic stem cell, bone marrow or peripheral blood stem cell transplantations, are associated with a high incidence of GVHD. Among solid organ transplants, intestinal transplantation has the highest incidence of GVHD, followed by LT; with lower rates of GVHD after kidney, heart or pancreas transplantation. The mortality rate for GVHD after LT has been reported to be up to 85%.1 In this article, we report a case series and a comprehensive review of the literature on GVHD after LT. The epidemiology, risk factors, clinical features, and treatment outcomes are described; and a diagnostic algorithm is proposed. MATERIALS and METHODS University of Iowa Hospitals and Clinics Case Series Medical records of all patients diagnosed with GVHD after LT at the University of Iowa Hospitals and Clinics (UIHC) were reviewed. GVHD cases were identified from a prospectively maintained list of complications after LT. Diagnosis of GVHD was established with skin and gastrointestinal biopsies. Histologic grading of skin and gastrointestinal GVHD was also performed (see supplement). 4, 5 GVHD was documented histologically in all patients. Donor chimerism, using a quantitative assay of short tandem DNA repeats (STR) in the cells of the skin, gastrointestinal mucosa, peripheral blood and/or bone marrow, was recorded when available. This study was approved by the University of Iowa Institutional Review Board. Review of literature on GVHD after LT A comprehensive search of the databases of biomedical literature (Medline and Embase) was performed from 1988 (first case report of GVHD after LT) to 2014. The search strategy is described in Appendix 1. All case reports and case series of GVHD after LT in adults were reviewed. Reference lists of published reports were searched to find additional reports. Data on patient demographics, clinical findings, management and outcomes were extracted. Data was extracted from the United Network for Organ Sharing database, until January 2015, for group comparisons between reported United States cases of GVHD after LT and all US LT patients. Statistical Analysis Observations are reported as frequencies, and central tendencies are expressed as mean or median with standard deviation and interquartile range, based on the distribution of data. Categorical variables are reported as number and percent frequency of occurrence. Categorical data were compared using Pearson’s chi-square or Fisher’s exact test, where appropriate. All statistical testing was 2-sided and assessed for significance at the 5% level using SAS v9.4 (SAS Institute, Cary, NC). RESULTS UIHC Case Series A total of 762 LT were performed in adults from 1988 to January 31st 2015. Five recipients (0.7%) developed GVHD. A summary of the case series at the University of Iowa has been provided in Table 1. Case 1 A 73 year-old diabetic man, with cirrhosis due to nonalcoholic steatohepatitis (NASH), underwent LT in June 2014. He presented 60 days after LT with fever, nausea, vomiting, diarrhea, and maculopapular rash (Figure 1). White blood cell (WBC) count was 1600/mm3, absolute neutrophil count (ANC) 1280/mm3, hemoglobin 6.8 g/mm3, platelet count 108*103/mm3; and ferritin 2225 ng/mL. Skin biopsy showed vacuolar interface alteration of the dermal-epidermal junction, overlying lymphocytic infiltration, and scattered apoptotic keratinocytes (GVHD grade 2) (Figure 2). Colonoscopy showed normal colonic mucosa, but mucosal biopsies showed increased crypt epithelial apoptosis (GVHD grade 1) (Figure 3). STR analysis revealed 21%, 6% and 3% lymphocyte macrochimerism in the skin, colon and peripheral blood, respectively. He was started on methylprednisolone 2 mg/kg/day, and his tacrolimus level was kept at 8–12 ng/mL. His course was complicated by multiple infections (cytomegalovirus viremia, cryptosporidiosis of the gastrointestinal tract, and lobar pneumonia), all managed medically, while continuing methylprednisolone at 2 mg/kg/day. Rash, gastrointestinal symptoms, and pancytopenia resolved, and peripheral blood macrochimerism decreased to 1%. He was discharged on prednisone 80 mg/day for 2 weeks and 60 mg/day for 2 more weeks, before presenting with fever, vomiting and pancytopenia (WBC count 1,000/mm3). Colonoscopy showed inflamed ulcerated mucosa; biopsies showed abundant apoptotic crypt epithelial cells and crypt drop-out (GVHD grade 3). He was again treated with high-dose methylprednisolone, 2 mg/kg, while maintaining the same dose of calcineurin inhibitor (CNI). He developed pneumonia and septic shock and died 220 days after LT. Case 2 A 65 year-old diabetic man underwent LT for alcoholic cirrhosis and hepatocellular carcinoma (HCC) in March 2011. He presented 46 days after transplantation with maculopapular skin rash, fatigue, fever, diarrhea, weight loss, and modest leucopenia (WBC count 2300/mm3, ANC 1350/mm3). Ferritin was 799 ng/mL. Skin biopsy confirmed GVHD (grade 2). He was treated with methylprednisolone and tacrolimus dose increase. Skin and gastrointestinal symptoms improved, and WBC count rose to 6000/mm3. He was discharged on prednisone taper. Four weeks later, he returned with diarrhea, skin rash, septic arthritis (ankle), bacteremia, and WBC count of 900/mm3. Colonoscopy with biopsies showed extensive crypt dropout and denudation of epithelium (grade 4 GVHD). He had 41% donor lymphocytes in peripheral blood and 31% in the bone marrow. Ferritin was 20,333 ng/mL. Tacrolimus dose was decreased. Clinical features of GVHD worsened. Methylprednisolone was restarted; IVIG and the IL-1 antagonist, Anakinra, were added. He developed vancomycin-resistant enterococcal (VRE) bacteremia with septic shock and died 125 days after LT. Case 3 A 60 year-old diabetic man, with cirrhosis and HCC from alcoholic liver disease (ALD) and chronic hepatitis C, underwent LT in November 2011. He presented 117 days after LT with maculopapular skin rash (GVHD grade 2), fever, altered mental status, pancytopenia (WBC 200/mm3, ANC 0, hemoglobin 8.1 g/dL, platelet count 111*103cells/mm3) and ferritin 7232 ng/mL. STR analysis of peripheral blood revealed 78% macrochimerism. Bone marrow biopsy was hypocellular, with 89% macrochimerism. He was treated with an interleukin-2 (IL-2) receptor blocker (basiliximab), anti-thymocyte globulin (ATG), methylprednisolone, and intravenous immunoglobulin (IVIG); and tacrolimus was increased to 12–16 ng/mL. Due to nonresponse to initial treatment, Anakinra was added, without improvement. He developed VRE bacteremia, septic shock and died 128 days after LT. Case 4 A 60 year-old diabetic man, with cirrhosis from ALD and hemochromatosis, underwent LT in 2002. He presented with maculopapular skin rash (GVHD histologic grade 2) and diarrhea (GVHD histologic grade 2) 85 days after LT. CBC was normal. Peak serum ferritin was 733 ng/mL. He was treated with methylprednisolone, IVIG, and topical tacrolimus. Systemic tacrolimus and mycophenolate mofetil were continued at the same dosage. Skin rash and diarrhea resolved. Serum ferritin normalized. He was doing well at follow-up 10 years after LT. Case 5 A 65 year-old diabetic woman with primary biliary cholangitis (PBC) underwent LT in February 1996. Induction immunosuppression regimen included methylprednisolone and tacrolimus. Fourteen days after LT, she developed maculopapular skin rash, altered mental status, pancytopenia (WBC 100/mm3, platelets 17,000/mm3) and septic shock. Skin biopsy was consistent with GVHD. Histologic grading and STR analysis were not performed. She succumbed to septic shock within 5 days of presentation, before she could be started on treatment for GVHD. A summary of the case series has been provided in Table 1. Review of Literature on GVHD after LT A total of 80 articles reported 1 or more case, with a total of 156 cases of GVHD in adult LT recipients. Characteristics of reported cases are summarized in Table 2. Mean age at LT was 55 years, and 67.3% were male. Median time to GVHD onset from LT was 28 days (interquartile range 21–38 days). The most common clinical features in patients with GVHD were skin rash (92%), followed by cytopenias (78%) and diarrhea (65%). HCC (34.7%) was the most common indication for LT in patients who developed GVHD, followed by alcoholic liver disease (22.9%) and acute or chronic hepatitis B (19.5%). The presenting organ involvement for all patients with GVHD in the world and in the US is reported in Table 2. Data on outcome of GVHD management was reported in 138 patients; 73.2% died within 6 months of GVHD onset. There have been no prospective trials of treatment of GVHD after LT. This review found reports of treatment of GVHD after LT in 130 patients. In 8 patients (6.2%) immunosuppression was decreased6–11, while immunosuppression was intensified in 122 patients (93.8%). Six-month mortality was 70.5% in patients who had increased immunosuppression and 62.5% in patients with decreased immunosuppression. This difference was not statistically significant (p=0.68). The most frequently reported treatment regimen for GVHD after LT was high-dose steroids (ranging from 2 mg/kg/day to 20 mg/kg/day). The number of patients treated and mortality rate associated with various treatments regimens are provided in Table 3. The common causes of death in patients with GVHD after LT were sepsis, multi-organ failure and gastrointestinal bleeding. In 61 cases (60.4%), sepsis was documented as cause of death. The causative organism was reported in 25 cases (41%); invasive aspergillosis was noted in 9 cases1, 9, 12–17 (36%), disseminated candidiasis in 7 (28%) (3 albicans, 1 kruseii, 1 glabrata and 2 unspecified species) 1, 9, 18, 19, enterococci in 7 (28%)1, 20–23 and Enterobacter in 2 (8%)1, 24. There were 66 reported cases of GVHD after LT from the US and these were compared to all other LT recipients in the US, as accessed through the UNOS database (Table 2). A significant association between age and GVHD was evident, where patients with GVHD were older than 50-years (p<0.01). Gender was not a risk factor for development of GVHD. Higher GVHD incidence was noted in patients transplanted for HCC (21.6 % vs 13.0%), while chronic hepatitis C infection (HCV) was associated with a lower incidence of GVHD after LT, as compared to all other US patients in UNOS database (11.8% vs 29.9%) (Table 2). There are 37 patients reported in the literature who survived GVHD after LT. The mean age of patients was 56.1 years, 83.3% were males, and mean time from LT to diagnosis of GVHD was 43.3 days (range 13–80). The etiology of liver disease was alcoholic liver disease in 43% of patients; HBV in 27%; NASH in 11%; HCV, PSC and A1AT in 5% each; with PBC and acute liver failure in 2% each. 50% of these patients presented with skin involvement only, 21% with bone marrow involvement only, and 18% with both skin and gastrointestinal involvement. The treatment regimens of patients who survived GVHD after LT are provided in Table 4. DISCUSSION Risk Factors This systematic review demonstrates an association between GVHD after LT with recipient age over 50-years. Additional risk factors reported in the literature include donor-recipient age difference greater than 20 years, younger donor age, any HLA class I match, and glucose intolerance.2, 25 Based on our results, GVHD may occur more frequently in patients transplanted for HCC and less frequently in patients transplanted for hepatitis C. Immune dysregulation plays a major role in the pathogenesis of HCC. Alterations in innate or adaptive immunity, for example a decrease in the CD4+ T lymphocyte function due to chronic inflammation (alcoholic or non-alcoholic steatohepatitis), chronic infection (viral hepatitis), or suppression of immunity (cirrhosis), may tolerance to tumor antigen and promote the development of HCC.26 Furthermore, HCC itself may cause immune system dysfunction.26 It is possible that the immune dysregulation in the recipient that originally led to the development of HCC, or alterations in the immune system caused by HCC, may predispose to alloreactivity and development of GVHD after LT.27, 28 HCV is known to inhibit T cell receptor-mediated signaling required for activation and effector functions of T cells.29 Whether HCV demonstrates the same effect on donor T-lymphocytes, thereby decreasing the incidence of GVHD, is unclear. Clinical Features Our review shows that GVHD usually develops 3 to 5 weeks after LT. Skin rash is erythematous, maculopapular, and can involve any part of the body including palms, soles, and the volar surfaces of extremities and trunk. Skin rashes may be subtle, nonpruritic, and not noticed by the patient. A very careful total-body skin exam in a well-lit room is recommended. Characteristic histologic features are vacuolar alteration at the dermo-epidermal junction, apoptosis of keratinocytes in the epidermis, and lymphocyte exocytosis (Figure 2). GVHD can affect all 3 hematopoietic cell lineages. The alloreactive donor lymphocytes engraft and proliferate in the recipient bone marrow, with subsequent immune-mediated attack on hematopoietic stem cells. Cytopenia in the first few months after LT is common; infection (Herpes virus, cytomegalovirus, Epstein Barr virus and parvovirus B19) and medications (mycophenolate mofetil, valganciclovir, trimethoprim-sulfamethoxazole) are the usual culprits. In GVHD, the presence of cytopenia may be a poor prognostic indicator, and sepsis associated with leucopenia is a commonly reported cause of death. Gastrointestinal manifestations are common in GVHD. Diarrhea is a common symptom in solid organ transplant recipients; up to 10–13% of patients have diarrhea in the first 4 post-transplant months.30, 31 The common etiologies for diarrhea are infection (Clostridium difficile and cytomegalovirus colitis) and medications (mycophenolate mofetil, everolimus, sirolimus and tacrolimus).32 Endoscopic evidence for GVHD is provided by the presence of erythema, exudates and superficial ulceration of gastrointestinal mucosa. However, the sensitivity and specificity of endoscopic findings are sub-optimal to rule in or rule out GVHD; histopathology is necessary. Rectosigmoid biopsies are most sensitive.33, 34 In GVHD, histopathology shows increased crypt epithelial apoptosis, crypt loss and neutrophilic infiltration. Apoptosis of epithelial cells is induced by activated donor cytotoxic T-lymphocytes. It is, however, important to note that epithelial apoptosis can be seen after LT from etiologies other than GVHD, such as cytomegalovirus (CMV) colitis, mycophenolate-induced colitis and non-steroidal anti-inflammatory drugs. CMV colitis can be diagnosed by immunohistochemical demonstration of CMV viral inclusions. Mycophenolate-induced colitis can be differentiated from GVHD by presence of more than 15 eosinophils per high power field, lack of endocrine cell aggregates in lamina propria, and lack of apoptotic microabscesses.35 Donor lymphocyte microchimerism (<1% donor lymphocyte chimerism) is often seen in liver transplant recipients; it is postulated that microchimerism is important for immune tolerance and graft acceptance by the host.3, 36–38 In contrast, patients with GVHD have donor lymphocyte macrochimerism (>1% donor lymphocyte chimerism) in recipient tissues (skin, gastrointestinal mucosa, peripheral blood), ranging from 1% to 80%.3, 19, 38-45 However, donor lymphocyte macrochimerism in peripheral blood alone doesn’t confirm the diagnosis of GVHD.46 Macrochimerism in a patient with clinical and histological features suggestive of GVHD (involvement of the skin, bone marrow and/or gastrointestinal tract) should be considered diagnostic of GVHD. Confirmation of macrochimerism should not be required to start treatment for GVHD, as it may take several days for results to be obtained. Monitoring donor lymphocyte macrochimerism in target organs and peripheral blood may be helpful, even after resolution of symptoms, as persistence of macrochimerism may suggest incomplete resolution of GVHD and a high risk of relapse with tapering of immunosuppression. Ferritin level was checked in 4 of the UIHC GVHD patients and was markedly elevated in all. The mean peak ferritin in patients who died of GVHD in our case series was 9930 ng/mL (range: 2225–20,333) while the peak ferritin in the surviving patient was 733 ng/mL. Marked hyperferritinemia in GVHD after LT has not been previously reported. Though serum ferritin is a nonspecific acute phase reactant, an extreme elevation of ferritin level is seen only in a few conditions.47 Cytokines released by activated donor lymphocytes, and the associated inflammatory response, is the likely mechanism behind hyperferritinemia in GVHD. Treatment and Outcome Fourteen of the 17 reported treatment regimens for GVHD after LT were associated with mortality rates over 70%, including all regimens that included high dose intravenous steroids only or an increase in CNI dose (with both tacrolimus and cyclosporine). Only 3 reported treatment regimens for GVHD after LT yielded mortality rates less than 60%. These regimens, used in a small number of patients, included IL-2 antagonists (basiliximab or daclizumab), the CD2 inhibitor alefacept, or TNF-α inhibitors. The efficacy of IL-2 antagonists in case series of patients with GVHD after hematopoietic stem cell transplantation (HSCT) has shown promise, with survival of 40–60%.48, 49 Though the survival rate may be better with IL-2 antagonists compared to other reported regimens for GVHD after LT, mortality rate is still substantial. Starting high-dose steroids upon diagnosis of GVHD after LT, with addition of Alefacept and ATG when the patient develops pancytopenia 50, 51, was shown to result in the immediate rebound of bone marrow function. Alefacept is a fusion protein that binds to the lymphocyte antigen CD2, inhibits the interaction of CD2 and human leukocyte function antigen-3 (LFA-3), thereby preventing the activation of CD4 and CD8 T-lymphocytes; while ATG eliminates the activated effector T cells. Alefacept also showed potential benefit for treatment of GVHD in bone marrow transplantation recipients.52 Unfortunately, Alefacept, has been discontinued by the manufacturers, without any safety or FDA regulation concerns.53 Sipilizumab is a similar agent that targets the CD2 receptor on T-lymphocytes and natural killer cells. A phase I trial of sipilizumab for treatment of GVHD after bone marrow transplantation in children reported a good response, but a higher incidence of post-transplant lymphoproliferative disorder was noted, raising safety concerns.54 Initial studies of patients with steroid-refractory GVHD post-HSCT showed promising results with the use of the TNF α inhibitor, infliximab.55, 56 Recent studies, including a phase-III study in patients with GVHD after HSCT, showed no benefit of addition of infliximab to methylprednisolone compared to methylprednisolone alone.57 However, higher response rates have been reported with etanercept in patients with GVHD after HSCT.58–62 Etanercept, unlike infliximab, does not lead to antibody-dependent cytotoxicity and induction of apoptosis of TNF-α-positive monocytes, possibly decreasing risk of infection compared to infliximab. The literature on the use of TNF-α inhibitors in GVHD after LT is limited. However, based on the high mortality with the majority of reported regimens, the 75% survival among the 4 patients treated with TNF-α-inhibition, and the data on etanercept in HSCT patients with GVHD, etanercept or other TNF-α antagonists could be useful as a second line agent in patients with GVHD after LT who are steroid-refractory or dependent. The major drawback of increasing immunosuppression in patients with GVHD after LT is the high risk of death from sepsis. Enterobacter septicemia, invasive aspergillosis and disseminated Candida infection are common causes of death with GVHD. A study performed on patients with GVHD post-HSCT showed a significant increase in the risk of non-Candida invasive fungal infections with the use of infliximab.63 Thus, vigilance for development of infection and timely use of antibiotics and antifungal agents is very important. Empiric use of antibiotics to cover gram negatives and anaerobic bacteria, especially VRE, and antifungal prophylaxis, appears reasonable. CMV and Pneumocystis prophylaxis is advised during high-level immunosuppression. The role of granulocyte-monocyte colony stimulating factor in GVHD is unclear, but may be given in patients with marked neutropenia. In patients with gastrointestinal GVHD after HSCT, a step-wise oral “GVHD diet” may be beneficial.64 Severe protein-calorie malnutrition as a result of protein losing enteropathy and malabsorption is treated with 1.5 g/kg/day of protein. In addition, these patients may develop vitamin, micronutrient and essential trace element (including magnesium and zinc) deficiencies. In patients with massive diarrhea, total parenteral nutrition may be needed. When diarrhea is less than 500 mL/day, oral foods are introduced in a step-wise manner.64 This approach may be beneficial in patients with GVHD after LT, though no data is available. Extracorporeal photopheresis, an apheresis and photodynamic therapy, has shown promising results in the treatment of patients with GVHD after HSCT.65 It is an immunomodulator therapy which involves collection of peripheral blood mononuclear cells, irradiation of these leucocyte cells in-vitro by ultraviolet A in the presence of the drug 8-methoxypsoralen, followed by re-infusion of the cells into the patient. The main advantage of this therapy is the absence of generalized immunosuppression, thereby decreasing the risk of developing life-threatening infections. Further trials are needed before establishing extracorporeal photopheresis as a treatment option for GVHD. Proposed diagnostic algorithm and treatment recommendations How then do we diagnose and treat our next patient with GVHD after LT? Based on our interpretation of currently available data, we propose a diagnostic algorithm (Figure 4) for GVHD after LT. Patients who have symptoms involving the most commonly involved organ systems in GVHD, namely skin, gastrointestinal tract and bone marrow, should be evaluated for GVHD. Patients with maculopapular skin rash post-LT should undergo skin biopsy, as it is a simple procedure with low morbidity, and the histology can be diagnostic of GVHD. In patients who present with diarrhea or pancytopenia after LT, the most common causes of these symptoms should be ruled out. If symptoms persist, a colonoscopy with mucosal biopsies should be performed to screen for GVHD changes. Strong treatment recommendations cannot be made due to the absence of prospective studies and due to the high mortality rates for the majority of reported treatment regimens. Multidisciplinary involvement, with hematologists, infectious disease specialists and immunologists, is essential in the management of this complex condition. Study limitations The proposed diagnostic algorithm is based on limited evidence. Comparisons of treatment regimen mortality rates are based on small cohort sizes and do not take into consideration other patient- or disease-related factors which may affect mortality rates. With only summary data available from the UNOS database, comparisons with reported US patients with GVHD are limited to univariate tests of association. Clearly, all US cases of GVHD after LT in the US have not been reported, and occurrence of GVHD after LT is not reported in the UNOS database, limiting the interpretation of statistical analysis. CONCLUSIONS GVHD after LT is infrequent, but is associated with a very high mortality rate. Most patients develop GVHD in 3–5 weeks after LT. GVHD may occur more often in LT patients over 50 years of age and who have diabetes. When reported US GVHD cases were compared to all LT patients in the UNOS database, HCC appeared to be over-represented, and HCV was under-represented. High-dose steroids alone, or combined with increasing CNI dose, are not effective treatment regimens. High-dose steroids combined with IL-2 antagonists or TNF-α inhibitors may be more promising approaches, though experience is limited. Donor macrochimerism and serum ferritin may be helpful for monitoring response to treatment. The participation of multiple institutions in a working group to prospectively study GVHD after LT, along with obligatory reporting of GVHD cases to UNOS, is needed. Supplementary Material Supplemental File Grants and financial support: This project is in part supported by R56 AI 116715 from the NIAID (National Institute of Allergy and Infectious Diseases). No other funding received for the manuscript. List of Abbreviations ALD Alcoholic liver disease ANC Absolute neutrophil count ATG Anti-thymocyte globulin CMV Cytomegalovirus CNI Calcineurin inhibitor GVHD Graft versus host disease HBV Hepatitis B virus HCC Hepatocellular carcinoma HCV Hepatitis C virus HSCT Hematopoietic stem cell transplant IL Interleukin IVIG Intravenous immunoglobulin LT Liver transplantation NASH Nonalcoholic steatohepatitis PBC Primary biliary cholangitis STR Short tandem repeats TNF Tumor necrosis factor UIHC University of Iowa Hospitals and Clinics UNOS United Network for Organ Sharing US United States VRE Vancomycin resistant enterococci WBC White blood cell Figure 1 Maculopapular skin rash in a patient with graft versus host disease after liver transplantation. Figure 2 Skin biopsy demonstrating perivascular mononuclear infiltrate (arrow) in the superficial dermis as well as vacuolar interface change, including scattered apoptotic keratinocytes (Grade 2 Graft Versus Host Disease). Figure 3 Ileal biopsy demonstrates apoptotic crypt epithelial cells (arrow) and degenerating crypts suggestive of graft versus host disease. Figure 4 Proposed diagnostic algorithm for GVHD in liver transplantation recipients. Table 1 Characteristics of patients with GVHD after liver transplantation at UIHC Year Age Sex Etiology DM GVHD onset (days) Involved systems (grade) GVHD related death Survival (days) Treatment for GVHD Peak serum ferritin (ng/ml) 2014 73 M NASH Yes 65 Skin (II) GI (I) BM Yes 161 High dose steroids, continued tacrolimus. 2225 2011 66 M ALD, HCC Yes 46 Skin (I) GI (IV) BM Yes 79 High dose steroids, basiliximab, IVIG and increased tacrolimus. 20,333 2011 60 M ALD, HCV, HCC Yes 117 Skin (II) BM Yes 11 Added ATG, increased tacrolimus, and continued mycophenolate. 7232 2002 60 M ALD, Hemo chromatosis Yes 85 Skin (II) GI (II) No >10 years High dose steroids, continued tacrolimus and mycophenolate. 733 1996 65 F PBC Yes 15 Skin BM Yes 5 High dose steroids, and continued tacrolimus. NA UIHC: University of Iowa Hospitals and Clinics, GVHD: Graft-versus-host-disease, ALD: alcoholic liver disease; ATG: Anti-thymocyte globulin; BM: Bone marrow; DM: Diabetes mellitus; F: Female; GI: Gastrointestinal tract; HCC: Hepatocellular cancer; HCV: Hepatitis C; M: Male; F: Female, NA: Not available; NASH: nonalcoholic steatohepatitis; PBC: Primary biliary cholangitis. Table 2 Patient characteristics of reported cases of acute GVHD after LT in the world literature, US literature, and of all adult liver transplants in UNOS database GVHD after LT (World literature) GVHD after LT (US) UNOS database1 p N 156 66 119,701 Age: n (%)  18 – 35 28 (17.9) 5 (7.6) 9,133 (7.6) <0.01  35 – 49 30 (19.2) 7 (10.6) 34,329 (28.7)  50 – 64 77 (49.4) 43 (65.2) 64,061 (53.5)  ≥65 21 (13.5) 11 (16.7) 12,178 (10.2) Gender, male: n (%) 105 (67.3) 44 (66.7) 84,030 (70.2) 0.53 Etiology of liver disease*: n (%)  1. Acute liver failure 3 (2.5) 1 (2.0) 6,824 (5.7)  2. Alcoholic liver disease 27 (22.9) 12 (23.5) 21,495 (18.0)  3. Chronic Hepatitis C 16 (13.6) 6 (11.8) 35,812 (29.9)  4. Chronic hepatitis B 23 (19.5) 5 (9.8) 5,168 (4.3)  5. Primary Sclerosing cholangitis 9 (7.6) 7 (13.7) 7,153 (6.0)  6. Primary Biliary Cirrhosis 12 (10.2) 5 (9.8) 5,754 (4.8)  7. Nonalcoholic steatohepatitis 13 (11.1) 9 (17.6) 13,415 (11.2)  8. Alpha-1 antitrypsin deficiency 2 (1.7) 0 (0) 1,578 (1.3)  9. Autoimmune hepatitis 4 (3.4) 2 (3.9) 3,802 (3.2)  10.Hemochromatosis 3 (2.5) 3 (5.9) 749 (0.6) Presence of Hepatocellular Carcinoma: n (%) 41 (34.7) 11 (21.6) 15,542 (13.0) Presenting organ involvement+: n(%)  1. Skin only 33 (31) 11 (23)  2. Bone Marrow only 17 (16) 10 (21)  3. Skin + GI + BM 17 (16) 9 (19)  4. Skin + GI 14 (13.2) 6 (13)  5. Skin + BM 14 (13.2) 7 (14.5)  6. GI only 11 (10.4) 5 (10.4) GVHD: graft-versus-host-disease; LT: liver transplantation; US: United States; UNOS: United network for organ sharing. * Etiology of liver disease was reported in 118 total cases, 51 of them were from USA. + Presenting organ involvement was reported in 106 cases. 1 Reported US GVHD cases were subtracted from the respective age and etiology categories in UNOS database for statistical analysis. Table 3 Combination immunosuppression regimens and outcomes of patients with GVHD after liver transplantation Treatment regimen Number of patients Mortality n (%) A. Steroid containing regimens  Steroids only*1, 9, 14, 27, 50, 66–75 25 21 (84)  Steroids + CNI dose increase13, 23, 76–80 8 6 (75)  Steroids + IVIG22, 80, 81 4 4 (100)  Steroids + Azathioprine12, 82, 83 3 3 (100)  Steroids ± OKT31, 11, 84–88 7 5 (71.4) B. ATG containing regimens  ATG only*1, 14, 89, 90 4 3 (75)  ATG + steroids*1, 11, 27, 91–97 22 18 (81)  ATG + Steroids + CNI98, 99 3 3 (100) C. IL-2 antagonist containing regimens  IL 2 antagonist + Steroids*17, 27, 72, 96, 100–103 12 7 (58)  IL 2 antagonist + Steroids + CNI23, 104 2 2 (100)  IL 2 antagonist + Steroids + ATG14, 15, 21, 105 4 4 (100) D. Other treatment regimens  Alefacept + steroids + ATG16, 50, 51 7 2 (28)  TNF alpha inhibitors + steroids + ATG17, 106–108 4 1 (25)  Rituximab Steroids ± ATG ± IL 2 antagonist109–112 4 3 (75) * No addition or dose increase of CNI was reported. GVHD: graft versus host disease; ATG: Anti-thymocyte globulin; CNI: calcineurin inhibitors; IL-2: interleukin-2; IVIG: Intravenous immunoglobulin; MLAG: Minnesota anti-lymphocyte globulin; OKT3: Muromonab-CD3; TNF: tumor necrosis factor. Table 4 Treatment regimen for patients who survived GVHD after Liver transplantation. Treatment regimen Number of patients (n) A. Steroid containing regimens  Steroids only7, 68, 69, 75 4  Steroids + CNI dose increase23, 75, 113 3  Steroids + OKT384, 87 2 B. ATG containing regimens  ATG only1 1  ATG + steroids92, 94, 97 4  ATG + Steroids + CNI98 1 C. IL-2 antagonist containing regimens  IL 2 antagonist + Steroids27, 101–103 5  IL-2 antagonist + Steroids + ATG105 1 D. Other treatment regimens  Alefacept + steroids + ATG50, 51 5  TNF alpha inhibitors + steroids + ATG106–108 3  Rituximab + Steroids + CNI dose increase + IL 2 antagonist109 1 * Immunosuppression was decreased in 3 patients who survived GVHD after liver transplantation. GVHD: graft versus host disease; ATG: Anti-thymocyte globulin; CNI: calcineurin inhibitors; IL-2: interleukin-2; OKT3: Muromonab-CD3; TNF: tumor necrosis factor. No other financial disclosures. No conflicts of interest. Presented in part at DDW 2015, Washington D.C, USA Author contributions 1. Arvind R Murali: study concept and design, acquisition of data, analysis and interpretation of data, drafting of manuscript, statistical analysis 2. Subhash Chandra: study concept and design, acquisition of data, analysis and interpretation of data, drafting of manuscript, statistical analysis 3. Zoe Stewart: critical revision of manuscript 4. Bruce R Blazar: critical revision of manuscript 5. Umar Farooq: critical revision of manuscript 6. M Nedim Ince: obtained funding, critical revision of manuscript 7. 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1092 9 17663410 15 Ghali MP Talwalkar JA Moore SB Acute graft-versus-host disease after liver transplantation Transplantation 2007 83 365 6 16 Rogulj IM Deeg J Lee SJ Acute graft versus host disease after orthotopic liver transplantation Journal of Hematology and Oncology 2012 5 22397365 17 Blank G Li J Kratt T Treatment of liver transplant graft-versus-host disease with antibodies against tumor necrosis factor-alpha Exp Clin Transplant 2013 11 68 71 23387543 18 Pollack MS Speeg KV Callander NS Severe, late-onset graft-versus-host disease in a liver transplant recipient documented by chimerism analysis Hum Immunol 2005 66 28 31 15620459 19 Kohler S Pascher A Junge G Graft versus host disease after liver transplantation - a single center experience and review of literature Transpl Int 2008 21 441 51 18266778 20 Connors J Drolet B Walsh J Morbilliform eruption in a liver transplantation patient Arch Dermatol 1996 132 1161 3 8859025 21 Meves A el-Azhary RA Talwalkar JA Acute graft-versus-host disease after liver transplantation diagnosed by fluorescent in situ hybridization testing of skin biopsy specimens Journal of the American Academy of Dermatology 2006 55 642 6 17010745 22 Post GR Black JS Cortes GY The utility of fluorescence in situ hybridization (FISH) analysis in diagnosing graft versus host disease following orthotopic liver transplant Ann Clin Lab Sci 2011 41 188 92 21844579 23 Chandra SMA Dunkelberg J Stewart Z Graft Versus Host Disease Post-Liver Transplantation: A Single Center Gastroenterology Iran J Med Sci 2015 148 S1042 1043 24 Au WY Lo CM Hawkins BR Evans' syndrome complicating chronic graft versus host disease after cadaveric liver transplantation Transplantation 2001 72 527 8 11502987 25 Elfeki MGP Pungpapong S Nguyen J Harnois D Graft-Versus-Host Disease After Orthotopic Liver Transplantation: Multivariate Analysis of Risk Factors Am J Transplant 2015 15 Abstract 81 26 Sachdeva M Chawla YK Arora SK Immunology of hepatocellular carcinoma World J Hepatol 2015 7 2080 90 26301050 27 Taylor AL Gibbs P Bradley JA Acute graft versus host disease following liver transplantation: the enemy within Am J Transplant 2004 4 466 74 15023138 28 McDonald-Hyman C Turka LA Blazar BR Advances and challenges in immunotherapy for solid organ and hematopoietic stem cell transplantation Sci Transl Med 2015 7 280rv2 29 Bhattarai N McLinden JH Xiang J Conserved Motifs within Hepatitis C Virus Envelope (E2) RNA and Protein Independently Inhibit T Cell Activation PLoS Pathog 2015 11 e1005183 26421924 30 Altiparmak MR Trablus S Pamuk ON Diarrhoea following renal transplantation Clin Transplant 2002 16 212 6 12010146 31 Wong NA Bathgate AJ Bellamy CO Colorectal disease in liver allograft recipients -- a clinicopathological study with follow-up Eur J Gastroenterol Hepatol 2002 14 231 6 11953686 32 Ginsburg PM Thuluvath PJ Diarrhea in liver transplant recipients: etiology and management Liver Transplantation 2005 11 881 90 16035068 33 Ross WA Ghosh S Dekovich AA Endoscopic biopsy diagnosis of acute gastrointestinal graft-versus-host disease: rectosigmoid biopsies are more sensitive than upper gastrointestinal biopsies Am J Gastroenterol 2008 103 982 9 18028511 34 Thompson B Salzman D Steinhauer J Prospective endoscopic evaluation for gastrointestinal graft-versus-host disease: determination of the best diagnostic approach Bone Marrow Transplant 2006 38 371 6 16915225 35 Star KV Ho VT Wang HH Histologic features in colon biopsies can discriminate mycophenolate from GVHD-induced colitis Am J Surg Pathol 2013 37 1319 28 24076772 36 Wood K Sachs DH Chimerism and transplantation tolerance: cause and effect Immunol Today 1996 17 584 7 discussion 588 8991291 37 Starzl TE Demetris AJ Murase N Cell migration, chimerism, and graft acceptance Lancet 1992 339 1579 82 1351558 38 Domiati-Saad R Klintmalm GB Netto G Acute graft versus host disease after liver transplantation: patterns of lymphocyte chimerism Am J Transplant 2005 5 2968 73 16303012 39 Rogulj IM Deeg J Lee SJ Acute graft versus host disease after orthotopic liver transplantation J Hematol Oncol 2012 5 50 22889203 40 Meves A el-Azhary RA Talwalkar JA Acute graft-versus-host disease after liver transplantation diagnosed by fluorescent in situ hybridization testing of skin biopsy specimens J Am Acad Dermatol 2006 55 642 6 17010745 41 Mawad R Hsieh A Damon L Graft-versus-host disease presenting with pancytopenia after en bloc multiorgan transplantation: case report and literature review Transplant Proc 2009 41 4431 3 20005417 42 Key T Taylor CJ Bradley JA Recipients who receive a human leukocyte antigen-B compatible cadaveric liver allograft are at high risk of developing acute graft-versus-host disease Transplantation 2004 78 1809 11 15614155 43 Gulbahce HE Brown CA Wick M Graft-vs-host disease after solid organ transplant Am J Clin Pathol 2003 119 568 73 12710129 44 Chinnakotla S Smith DM Domiati-Saad R Acute graft-versus-host disease after liver transplantation: role of withdrawal of immunosuppression in therapeutic management Liver Transpl 2007 13 157 61 17192857 45 Chaib E Silva FD Figueira ER Graft-versus-host disease after liver transplantation Clinics (Sao Paulo) 2011 66 1115 8 21808887 46 Yao GL Li W Liu AB The experimental results of GVHD following orthotropic liver transplantation Chung Hua Kan Tsang Ping Tsa Chih 2009 17 856 60 19958648 47 Rosario C Zandman-Goddard G Meyron-Holtz EG The hyperferritinemic syndrome: macrophage activation syndrome, Still's disease, septic shock and catastrophic antiphospholipid syndrome BMC Med 2013 11 185 23968282 48 Przepiorka D Kernan NA Ippoliti C Daclizumab, a humanized anti-interleukin-2 receptor alpha chain antibody, for treatment of acute graft-versus-host disease Blood 2000 95 83 9 10607689 49 Massenkeil G Rackwitz S Genvresse I Basiliximab is well tolerated and effective in the treatment of steroid-refractory acute graft-versus-host disease after allogeneic stem cell transplantation Bone Marrow Transplant 2002 30 899 903 12476283 50 Eghtesad B Askar M Bollinger J Graft-versus-host disease (GVHD) following liver transplantation (LT): Comparison of two eras Am J Transplant 2012 12 126 21920020 51 Stotler CJ Eghtesad B Hsi E Rapid resolution of GVHD after orthotopic liver transplantation in a patient treated with alefacept Blood 2009 113 5365 6 19470441 52 Shapira MY Resnick IB Dray L A new induction protocol for the control of steroid refractory/dependent acute graft versus host disease with alefacept and tacrolimus Cytotherapy 2009 11 61 7 19191054 53 National Psoriasis foundation APUSI Amevive (alefacept) voluntarily discontinued in the US Astellas Medical Information Department 2012 54 Brochstein JA Grupp S Yang H Phase-1 study of siplizumab in the treatment of pediatric patients with at least grade II newly diagnosed acute graft-versus-host disease Pediatr Transplant 2010 14 233 41 19671093 55 Yang J Cheuk DK Ha SY Infliximab for steroid refractory or dependent gastrointestinal acute graft-versus-host disease in children after allogeneic hematopoietic stem cell transplantation Pediatr Transplant 2012 16 771 8 22905718 56 Kobbe G Schneider P Rohr U Treatment of severe steroid refractory acute graft-versus-host disease with infliximab, a chimeric human/mouse antiTNFalpha antibody Bone Marrow Transplant 2001 28 47 9 11498743 57 Couriel DR Saliba R de Lima M A phase III study of infliximab and corticosteroids for the initial treatment of acute graft-versus-host disease Biol Blood Marrow Transplant 2009 15 1555 62 19896079 58 Kennedy GA Butler J Western R Combination antithymocyte globulin and soluble TNFalpha inhibitor (etanercept) +/− mycophenolate mofetil for treatment of steroid refractory acute graft-versus-host disease Bone Marrow Transplant 2006 37 1143 7 16699531 59 Busca A Locatelli F Marmont F Recombinant human soluble tumor necrosis factor receptor fusion protein as treatment for steroid refractory graft-versus-host disease following allogeneic hematopoietic stem cell transplantation Am J Hematol 2007 82 45 52 16937391 60 Park JH Lee HJ Kim SR Etanercept for steroid-refractory acute graft versus host disease following allogeneic hematopoietic stem cell transplantation Korean J Intern Med 2014 29 630 6 25228839 61 Uberti JP Ayash L Ratanatharathorn V Pilot trial on the use of etanercept and methylprednisolone as primary treatment for acute graft-versus-host disease Biol Blood Marrow Transplant 2005 11 680 7 16125638 62 Levine JE Paczesny S Mineishi S Etanercept plus methylprednisolone as initial therapy for acute graft-versus-host disease Blood 2008 111 2470 5 18042798 63 Marty FM Lee SJ Fahey MM Infliximab use in patients with severe graft-versus-host disease and other emerging risk factors of non-Candida invasive fungal infections in allogeneic hematopoietic stem cell transplant recipients: a cohort study Blood 2003 102 2768 76 12855583 64 van der Meij BS de Graaf P Wierdsma NJ Nutritional support in patients with GVHD of the digestive tract: state of the art Bone Marrow Transplant 2013 48 474 82 22773121 65 Calore E Marson P Pillon M Treatment of Acute Graft-versus–Host Disease in Childhood with Extracorporeal Photochemotherapy/Photopheresis: The Padova Experience Biol Blood Marrow Transplant 2015 21 1963 72 26183078 66 Collins RH Jr Cooper B Nikaein A Graft-versus-host disease in a liver transplant recipient Ann Intern Med 1992 116 391 2 1736772 67 Mazzaferro V Andreola S Regalia E Confirmation of graft-versus-host disease after liver transplantation by PCR HLA-typing Transplantation 1993 55 423 5 8434393 68 Knox KS Behnia M Smith LR Acute graft-versus-host disease of the lung after liver transplantation Liver Transpl 2002 8 968 71 12360443 69 Nemoto T Kubota K Kita J Unusual onset of chronic graft-versus-host disease after adult living-related liver transplantation from a homozygous donor Transplantation 2003 75 733 6 12640319 70 Schoniger-Hekele M Muller C Kramer L Graft versus host disease after orthotopic liver transplantation documented by analysis of short tandem repeat polymorphisms Digestion 2006 74 169 73 17341849 71 Sun B Zhao C Xia Y Late onset of severe graft-versus-host disease following liver transplantation Transplant Immunol 2006 16 250 3 72 Wang B Lu Y Yu L Diagnosis and treatment for graft-versus-host disease after liver transplantation: two case reports Transplant Proc 2007 39 1696 8 17580224 73 Guo ZY He XS Wu LW Graft-verse-host disease after liver transplantation: A report of two cases and review of literature World J Gastroenterol 2008 14 974 979 18240363 74 Jeanmonod P Hubbuch M Grunhage F Graft-versus-host disease or toxic epidermal necrolysis: diagnostic dilemma after liver transplantation Transplant Infect Dis 2012 14 422 6 75 Mataluni G Mangiardi M Rainone M Central and peripheral nervous system involvement as a manifestation of graft versus host disease after liver transplantation: Case report J Peripher Nerv Syst 2013 18 S20 76 Dumortier J Souraty P Bernard P Graft versus host disease following liver transplantation: Favorable outcome after conversion to tacrolimus. [French] Gastroenterol Clin Biol 2003 27 561 562 12843926 77 Soejima Y Shimada M Suehiro T Graft-versus-host disease following living donor liver transplantation Liver Transpl 2004 10 460 4 15004778 78 Hossain MS Roback JD Pollack BP Chronic GvHD decreases antiviral immune responses in allogeneic BMT Blood 2007 109 4548 56 17289817 79 Yilmaz M Ozdemir F Akbulut S Chronic graft-versus-host disease after liver transplantation: a case report Transplant Proc 2012 44 1751 3 22841262 80 Chen XB Yang J Xu MQ Unsuccessful treatment of four patients with acute graft-vs-host disease after liver transplantation World J Gastroenterol 2012 18 84 9 22228975 81 Whalen JG Jukic DM English JC 3rd Rash and pancytopenia as initial manifestations of acute graft-versus-host disease after liver transplantation J Am Acad Dermatol 2005 52 908 12 15858489 82 Schmuth M Vogel W Weinlich G Cutaneous lesions as the presenting sign of acute graft-versus-host disease following liver transplantation Br J Dermatol 1999 141 901 4 10583176 83 Au WY Ma SK Kwong YL Graft-versus-host disease after liver transplantation: documentation by fluorescent in situ hybridisation and human leucocyte antigen typing Clin Transplant 2000 14 174 7 10770425 84 Redondo P Espana A Herrero JI Graft-versus-host disease after liver transplantation J Am Acad Dermatol 1993 29 314 7 8340506 85 Sanchez-Izquierdo JA Lumbreras C Colina F Severe graft versus host disease following liver transplantation confirmed by PCR-HLA-B sequencing: report of a case and literature review Hepato-Gastroenterol 1996 43 1057 61 86 Burt M Jazwinska E Lynch S Detection of circulating donor deoxyribonucleic acid by microsatellite analysis in a liver transplant recipient Liver Transpl Surg 1996 2 391 4 9346682 87 PAIZIS G TAIT BD ANGUS PW Successfid resolution of severe graft versus host disease after liver transplantation correlating with disappearance of donor DNA fkorn the peripheral blood Aust NZ J Med 1998 28 830 832 88 Neumann UP Kaisers U Langrehr JM Fatal graft-versus-host-disease: a grave complication after orthotopic liver transplantation Transplant Proc 1994 26 3616 7 7998294 89 DePaoli AM Bitran J Graft-versus-host disease and liver transplantation Ann Intern Med 1992 117 170 1 1605435 90 Hara H Ohdan H Tashiro H Differential diagnosis between graft-versus-host disease and hemophagocytic syndrome after living-related liver transplantation by mixed lymphocyte reaction assay J Invest Surg 2004 17 197 202 15371161 91 Chiba T Yokosuka O Goto S Clinicopathological features in patients with hepatic graft-versus-host disease Hepatogastroenterology 2005 52 1849 53 16334791 92 Burdick JF Vogelsang GB Smith WJ Severe graft-versus-host disease in a liver-transplant recipient N Engl J Med 1988 318 689 91 3278235 93 Pageaux GP Perrigault PF Fabre JM Lethal acute graft-versus-host disease in a liver transplant recipient: relations with cell migration and chimerism Clin Transplant 1995 9 65 9 7742585 94 Aziz H Trigo P Lendoire J Successful treatment of graft-vs-host disease after a second liver transplant Transplant Proc 1998 30 2891 2 9745613 95 Merhav HJ Landau M Gat A Graft versus host disease in a liver transplant patient with hepatitis B and hepatocellular carcinoma Transplant Proc 1999 31 1890 1 10371987 96 Hanaway M Buell J Musat A Graft-Versus-Host Disease in Solid Organ Transplantation Graft 2001 4 205 97 Lehner F Becker T Sybrecht L Successful outcome of acute graft-versus-host disease in a liver allograft recipient by withdrawal of immunosuppression Transplantation 2002 73 307 10 11821752 98 Schulman JM Yoon C Schwarz J Absence of peripheral blood chimerism in graft-vs-host disease following orthotopic liver transplantation: case report and review of the literature Int J Dermatol 2014 53 e492 8 24372059 99 Calmus Y Graft-versus-host disease following living donor liver transplantation: High risk when the donor is HLA-homozygous J Hepatol 2004 41 505 507 100 Merle C Blanc D Flesch M A picture of epidermal necrolysis after hepatic allograft. Etiologic aspects Ann Dermatol Venereol 1990 117 635 9 2260804 101 Rinon M Maruri N Arrieta A Selective immunosuppression with daclizumab in liver transplantation with graft-versus-host disease Transplant Proc 2002 34 109 10 11959211 102 Sudhindran S Taylor A Delriviere L Treatment of graft-versus-host disease after liver transplantation with basiliximab followed by bowel resection Am J Transplant 2003 3 1024 9 12859540 103 Husova L Mejzlik V Jedlickova H Graft-versus-host disease as an unusual complication following liver transplant. [Czech] Gastroenterologie a Hepatologie 2012 66 109 115 104 Chaman JC Padilla PM Rondon CF Graft-versus-host disease after liver transplantation in a partial monosomy 11q of chromosoma 11: A case report Liver Transpl 2013 1 S181 105 Lu Y Wu LQ Zhang BY Graft-versus-host disease after liver transplantation: successful treatment of a case Transplant Proc 2008 40 3784 6 19100490 106 Piton G Larosa F Minello A Infliximab treatment for steroid-refractory acute graft-versus-host disease after orthotopic liver transplantation: a case report Liver Transpl 2009 15 682 5 19562700 107 Xu X Zhou L Ling Q Successful management of graft-versus-host disease after liver transplantation with Korean red ginseng based regimen Liver Transpl Conference: 16th Annual International Congress of the International Liver Transplantation Society Hong Kong China. Conference Start 2010 16 108 Thin L Macquillan G Adams L Acute graft-versus-host disease after liver transplant: novel use of etanercept and the role of tumor necrosis factor alpha inhibitors Liver Transp 2009 15 421 6 109 Grosskreutz C Gudzowaty O Shi P Partial HLA matching and RH incompatibility resulting in graft versus host reaction and Evans syndrome after liver transplantation Am J Hematol 2008 83 599 601 18470884 110 Mawad R Hsieh A Damon L Graft-versus-host disease presenting with pancytopenia after en bloc multiorgan transplantation: case report and literature review Transplant Proc 2009 41 4431 3 20005417 111 Young AL Leboeuf NR Tsiouris SJ Fatal disseminated Acanthamoeba infection in a liver transplant recipient immunocompromised by combination therapies for graft-versus-host disease Transplant Infect Dis 2010 12 529 37 112 Cheung CYM Leung AYH Chan SC Fatal graft-versus-host disease after unrelated cadaveric liver transplantation due to donor/recipient human leucocyte antigen matching Inten Med J 2014 44 425 426 113 Hassan G Khalaf H Mourad W Dermatologic complications after liver transplantation: a single–center experience Transplant Proc 2007 39 1190 4 17524929
PMC005xxxxxx/PMC5118144.txt
LICENSE: This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. 7503062 4443 J Am Geriatr Soc J Am Geriatr Soc Journal of the American Geriatrics Society 0002-8614 1532-5415 27641829 5118144 10.1111/jgs.14455 NIHMS793377 Article Psychological Well-being of Grandparents Caring for Grandchildren among Older Chinese Americans: Burden or Blessing? Tang Fengyan PhD 1 Xu Ling PhD 2 Chi Iris DSW 3 Dong XinQi MD 4 1 University of Pittsburgh, Pittsburgh, Pennsylvania 2 The University of Texas at Arlington, Arlington, Texas 3 University of Southern California, Los Angeles, California 4 Rush Medical College, Chicago, Illinois Contact: Fengyan Tang, University of Pittsburgh - School of Social Work, 2217C Cathedral of Learning, Pittsburgh Pennsylvania 15260, fet7@pitt.edu, T: 4126489356, F: 4126246323 10 6 2016 19 9 2016 11 2016 01 11 2017 64 11 23562361 This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. The rapid increase in grandparents caring for grandchildren has received growing attention; however, relatively little research has focused on Chinese American grandparents and their caregiving experiences. Drawing on cross-sectional data from the Population Study of Chinese Elderly (PINE) – a community-engaged, epidemiological study of Chinese American adults aged 60 and older, we examined the relationships between caregiving experiences and psychological well-being. Among 2,365 older adults who answered the question about grandparent caregiving, 818 (35%) were designated as caregivers, spending an average of 12 hours a week on childcare. About one in five caregivers reported caregiving burden, pressure, or negative health effect of caregiving. Compared with noncaregivers, caregivers had better psychological well-being, with significantly lower levels of depressive symptoms, anxiety, stress, and loneliness. But increased levels of caregiving burden, pressure from adult children, and perceived negative effect were related to increased rates for psychological distress. With a strong cultural expectation for family care, grandparent caregiving is generally associated with positive psychological well-being; but it is also a stress process, especially when older adults feel pressured and/or burdened to provide childcare. The study implies that cultural values and life transitions may shape grandparent caregiving experiences and well-being, pointing to the importance of respecting cultural differences in family caregiving. Understanding both positive and negative aspects of grandparent caregiving and the underlying mechanisms will help healthcare professionals identify caregivers at risk of psychological distress and provide proper interventions to attenuate negative outcomes while maximizing positive experience in Chinese American older adults. grandparent caregiver psychological well-being older Chinese Americans PINE Introduction The rapid increase in grandparents caring for grandchildren has received growing attention in research, policy, and practice since the 1990s.1 However, relatively little research has focused on Chinese American grandparents and their caregiving experiences. With a strong cultural expectation of grandparent caregiving, many Chinese older adults have immigrated to meet their adult children’s need for childcare assistance;2 however, migration links to the erosion of traditional culture and intergenerational value differences, which may further complicate caregiving experience.3 Chinese grandparents are expected to engage in co-parenting and care for grandchildren on an extensive daycare basis; 4,5 meanwhile, they have to cope with various practical challenges, including cultural adaptation, language barriers, financial and housing difficulty.6 As a result, they may experience both positive and negative health outcomes related to childcare, as documented in the literature. Yet the mechanisms to health outcomes may differ across racial/ethnic groups. Using the first population-based, epidemiological study of older Chinese Americans, this study examines the mechanisms of the associations between caregiving experiences and psychological well-being. Findings will help healthcare professionals identify caregivers at risk of psychological distress and provide proper interventions to attenuate negative outcomes while maximizing positive experience in Chinese American older adults. Probably due to cultural expectations, Chinese grandparents may not consider caring for grandchildren as a burden, but part of parenthood or family obligation.1.6 Childcare provided by grandparents is viewed as a family adaptive strategy to enhance family well-being by alleviating child mothers’ burden and increasing education and employment opportunities, because caregiving is assumed or considered as a women’s role in Chinese families.7 In fact, assistance with childcare is frequently cited as the main reason of immigration for many Chinese older adults,8 who are valuable resources to their adult children in America and contribute to the family as caregivers.2 If grandparents accept the caregiver role or the changed role in a given situation, e.g., immigration, they likely perceive better health linked with caregiving, as shown in a study of Filipino American grandparents.9 Studies in the U.S. and Hong Kong indicate that Chinese grandparents feel appreciated and loved, and are less depressive when they perceive grandparent role can enhance familial relationships.10,11 Among grandparents in Taiwan, long-term multigenerational caregiving is related to improvement in self-rated health and mobility.12 Caregiving is also associated with negative health outcomes. The incidence of depression, diabetes, hypertension, and insomnia is high among grandparent caregivers, as documented in Western literatue.13 Particularly for older Chinese grandparents, caregiving may exacerbate the immigration-related stresses, increasing the risks for social isolation and intergenerational conflicts.10 According to the role strain theory, grandparents who provide extensive care may experience role strain and the associated effects on their employment, self-care, or relationship with spouse or others.14 Consequently, the elevated level of caregiving stress may negatively affect grandparents’ mental and physical health.14 Yet social support from family networks may mitigate the negative health effects of caregiving, as postulated from the stress-buffering model.15 Grandchild’s parents can become a source of support, conflict/burden, or both.16 Support from adult children may buffer the negative effects of role strain; whereas pressure from them may increase caregiving stress. According to the Census Bureau, the older Chinese American population has increased almost four times as rapidly as the U.S. general older population from 2000 to 2010, with a large share of foreign-born and recent immigrants.17 They have been actively involved in assisting their adult children in raising the next generation. By contrast, the occurrence of grandparent caregiving in other racial/ethnic groups is usually the result of a crisis situation that impairs the ability of birth parents to adequately care for their children.18 Older Chinese Americans may experience struggles with cultural values and conflicts with family members, which further exacerbate childcare burden and the associated psychological distress. To understand how different aspects of caregiving experiences are related to psychological well-being in older Chinese Americans, we examine the mechanisms through which caregiving is associated with well-being and hypothesize that caregiving burden, pressure, and perceived negative effect are related to caregivers’ psychological well-being. The study will illustrate the importance of childcare in grandparents’ lives and the potential negative aspects of caregiving, thus providing implications on how to maximize caregiving benefits and minimize the drawbacks through proper interventions from healthcare professionals. Methods Sample We used the data from the Population-based Study of Chinese Elderly (PINE), a community-engaged, epidemiological study of Chinese Americans aged 60 and older. The PINE study was conducted between 2011 and 2013 in the greater Chicago area. Under the guidance of a community-based participatory research approach, the study was implemented by a team of the Rush Institute for Healthy Aging, Northwestern University Medical Center, and many community-based social services agencies and organizations. To enhance community participation and ensure study relevance, the research team applied culturally and linguistically appropriate community recruitment strategies, including engaging community-based agencies, integrating recruitment with routine services, recruiting through family members, neighbors and various social media, and involving family members in participation decision-making. After participants provided consent, trained bilingual research assistants conducted face-to-face interviews in participants’ preferred language/dialect.3 The study was approved by the Institutional Review Board of the Rush University Medical Center. Among 3,542 eligible adults who were approached, 3,159 participated in the study, reaching a response rate of 92%. According to the U.S. Census 2010 and a random block census project, the PINE study was representative of the Chinese aging population in the greater Chicago area.3 Out of these participants, about 94% were born in China; the majority live in ethnic enclaves where Chinese is used as the main language, and actually 99% chose Chinese in completing the interview. In the current study, we selected the respondents who answered the question about grandparent caregiving (N=2,365) to test the differences between caregivers and noncaregivers, and selected the caregivers (n=818) to assess the mechanisms to negative psychological well-being. Measures Dependent variables of psychological well-being included depressive symptoms, anxiety, stress, and loneliness. Independent variables included grandparent caregiver status in all respondents; and caregiving time, burden, pressure, and perceived negative effect in caregivers. Depressive symptoms Participants completed the Patient Health Questionnaire-9 (PHQ-9) that is appropriate for screening late-life depression with nine validated questions.19 The PHQ-9 contains the somatic domains that are common in Asian older adults with depressive symptoms.20 Respondents were asked how often they had been bothered during the past two weeks by feelings such as little interest in doing things and feeling tired. Responses were scaled from 0 (not at all) to 3 (nearly every day). A summary score were used, with higher scores indicating more symptoms (Cronbach’s α =.82). Anxiety We used the Hospital Anxiety and Depression Scale-Anxiety (HADS-A)21, which has been tested in Chinese populations and shown good inter-rater reliability.22,23 Respondents were asked whether they had experienced the symptoms such as feeling tense or wound up. Responses were scaled from 0 (not at all) to 3 (most of the time). A summary score was used; higher score indicated more anxiety (Cronbach’s α =.80). Stress We used the 10-item version of the Perceived Stress Scale (PSS), a valid and reliable instrument that was designed to measure the degree to which one’s life situations are appraised as stressful.24 The PSS asks about feelings and thoughts during the last month, particularly how unpredictable, uncontrollable, and overloaded respondents find their lives to be and current levels of experienced stress.24 Responses were scaled from 0 (never) to 4 (very often). A summary score was used, and higher scores indicate higher levels of stress (Cronbach’s α =.86). Loneliness We assessed loneliness with the 3-item R-UCLA Loneliness Scale, with good reliability and internal validity in the general population.25 Three questions asked about the feelings of lacking companionship, being left out of life, and being isolated from others. The response categories were coded 1 (hardly ever), 2 (sometime), or 3 (often). A summary score was used; higher scores indicated higher levels of loneliness (Cronbach’s α =.77). Caregiver status Caregiver status was defined if respondents reported any caregiving hours greater than zero, and non-caregiver status was designated if reporting zero hours. Caregiving time This continuous variable was measured by self-reported weekly hours that respondents spent caring for grandchildren. Caregiving pressure It was measured by the response to the question “How often do you feel pressured by your sons/daughters to take care of their children?” Responses ranged from 0 (never) to 4 (always). Caregiving burden It was indicated by the respondent’s feeling of burden to take care of grandchildren, with responses from 0 (never) to 4 (always). Perceived negative effect It was indicated by the thought that health was negatively affected by caring for grandchildren, with responses from 0 (never) to 4 (always). Socio-demographic characteristics and social support were controlled in the regression analyses. Socio-demographics included age (in years), gender (male or female), education (in years), personal income (1=less than $5,000 to 10=$45,000 or more), marital status (married or not), number of children alive, number of grandchildren, years living in the U.S., and self-rated health (1=poor to 4=very good). Social support was assessed by the frequency of receiving support from spouse, family members, and friends, including positive support and negative strain. Positive support was measured by the extent to which respondents opened up to family or friends, and the frequency of relying on them for help. Negative support was measured by how often respondents believed that too much was demanded and they had been criticized. Responses were given on a 3-point scale from 1 (hardly ever) to 3 (often). Positive support and negative support were calculated as the sum of the six items within each category. Higher scores indicated greater positive support (Cronbach’s α =.73), and more negative strain (Cronbach’s α =.63), respectively. Data Analysis We applied bivariate analyses, including independent t-tests, Wilcoxon signed-rank tests, and Chi-square tests to compare caregivers with noncaregivers in psychological well-being and socio-demographics. Then we estimated negative binominal regression models to test the relationships between caregiving experiences and psychological well-being, because four dependent variables were all discretely distributed with a large proportion reporting zeros and only a few cases reaching the critical points (e.g., major depression). In this case, a continuous version of negative binomial model is appropriate to improve the model fit to the data and account for over-dispersion.26 Model results were reported as Incidence Rate Ratios (IRR), which indicate the change in the incident rate of the outcome variable per unit change in the independent variable, while controlling for covariates. Five independent variables, i.e., caregiver status (caregivers being the reference group), caregiving time, pressure, burden, and perceived negative effect were entered and estimated in the models, respectively, after controlling for socio-demographic and social support covariates. Statistical analyses were conducted using SAS version 9.2 (SAS Institute Inc., Cary, NC). Results Among 2,365 respondents who answered the question about grandparent caregiving, 35% (n=818) were designated as caregivers, spending a weekly average of 12 hours on childcare. Over 80% reported no burden in caring for grandchildren, never felt pressured by adult children, or never perceived negative effect (Table 1). Compared to noncaregivers, caregivers had better psychological well-being, with significantly lower levels of depressive symptoms, anxiety, stress, and loneliness. Caregivers reported higher levels of positive and negative support, probably because they received not only more support but more demands from their family. In addition, caregivers were more likely to be younger, married, with less personal income but better self-rated health. They had fewer children and grandchildren but more members living in the household, with fewer years living in the U.S. relative to noncaregivers. No gender and education differences were observed. In four negative binominal regression models, five measures of grandparent caregiving experiences (i.e., caregiver status, caregiving time, burden, pressure, and perceived negative effect) were regressed on one of psychological well-being measures, respectively. Results showed that noncaregivers were 40% more likely to increase depressive symptoms, 20% more likely to feel anxious, 10% more likely to have stress, and 60% more likely to feel lonely than caregivers (Table 2). Generally, caregiving time was not associated with well-being, except a tiny but statistically significant relationship with stress. Caregiving pressure was associated with depressive symptoms, anxiety, and stress, but not with loneliness. In particular, one-unit increase in caregiving pressure was associated with about 40% increase rates in depressive symptoms, anxiety, and stress, respectively, after controlling for socio-demographics and social support. Caregiving burden was associated with about 10% increase rates in all outcomes. One-unit increase in perceived negative effect was related to 50% increase rate in depressive symptoms, 30% increase in stress, and 70% increase in loneliness, respectively. Discussion The study contributes to the limited research on grandparent caregiving among Chinese Americans. Cultural backgrounds and traditions shape expectations and values about grandparent caregiving, and therefore shape grandparent well-being.27 In addition, immigration has immense influence on family dynamics and interactions.28 Different from other ethnic groups, especially those in Western countries, Chinese grandparents provide childcare to maximize family benefits, rather than to solve the caregiving problems in the middle generation. This may explain why the majority of grandparents reported no burden in this study. For Chinese grandparent, caregiving is a family obligation that brings in family solidarity and perhaps future older-age support.5 Some immigrant families even send their children back to China for grandparents to rear. With a strong cultural expectation, caregiving in general is related to positive psychological well-being, probably because grandparents may feel fulfilled and satisfied from involvement in the lives of their adults children and grandchildren, helping adult children who struggle to balance work and childrearing, providing instrumental support, and transferring knowledge to younger generations.27 In addition, caregiving usually occurs in a multigenerational household, increasing the opportunities for family connections and favorable psychological outcomes.28 Caregiving, however, is not always rewarding and some are likely to experience stress.3 Our study shows that those with negative experiences are vulnerable to psychological distress. When caregiving is not a choice and older adults have to take care of their grandchildren under the pressure from adult children, they tend to have negative appraisals about caregiving. Caring for small children is definitely a demanding job, and many older immigrants take on full-time responsibility as the involved grandparents, a practice that is not common in Western culture. 2 It is indeed a burden and may have negative effects on grandparents’ health. Furthermore, some of them have to quit their professional work in China and contribute heavily to the interest of their adult children and grandchildren.2 The loss of primary community and sacrifice of self-interest may incur mental health issues, which further aggravate caregiving stress. Despite similar findings having been documented in the literature on the relationship between caregiving and well-being, this study implies the unique mechanisms of psychological distress in Chinese Americans. Particularly, caregiving pressure from adult children may further intensify problems with family relationships and intergenerational conflicts. Although the exchange of instrumental assistance in the form of grandparent caregiving is normally expected in many Chinese families, too many care demands and tasks are definitely detrimental to older grandparents’ well-being. Study findings imply the importance of balancing reciprocal assistance and the central role of family relationships in maintaining Chinese older adults’ well-being. This study also shows that positive social support plays an important role in coping with caregiving distress, while negative strains from families and friends may increase depressive symptoms and loneliness. In clinical practice, understanding the cultural norms of grandparent caregiving and the underlying mechanism to negative health outcomes is important for healthcare professionals to identify caregivers at risk of psychological distress and provide proper interventions to attenuate negative outcomes while maximizing positive experience. A family-centered perspective is often useful when working with Chinese older adults and culturally specific and relevant care are needed to improve adaptive coping skills and family relationships. The study is limited in generalizability. Although the study sample is representative of Chinese American older adults in a large metropolitan area, the findings are limited in generalizing nationally or internationally. In addition, the cross-sectional design definitely cannot establish the causal relationship between caregiving and psychological well-being. A reciprocal relationship could exist, that is, older adults with better mental and physical health are likely to care for their grandchild, which in turn, helps maintain or improve their evaluations of well-being. Other factors, such as physical and cognitive function, health behaviors, and social networks may explain the variance in psychological well-being among non-caregivers. Future research needs to evaluate the directionality of the longitudinal relationship between mental health and caregiving experiences after controlling for confounding factors. Another limitation is the lack of relevant information in defining caregiving. Caregiver status was defined based on weekly hours on childcare, but did not distinguish between coparenting caregivers and custodial caregivers, between involved caregivers and primary caregivers. Also missing is the length of caregiving, types of caring responsibilities, such as basic needs, personal care, medical care, and financial responsibility, and the number and characteristics of grandchildren being cared. In conclusion, grandchild care could be a burden, a blessing, or both, partly depending on older adults’ self-appraisal of their caregiving experience and partly on how they are treated in the family and in the community. Both informal support system and formal social and healthcare services are central to help older grandparents maintain or regain their psychological well-being in the face of caregiving challenges. Dr. Dong was supported by National Institute on Aging Grants R01AG042318, R01 MD006173, R01 CA163830, R34MH100443, R34MH100393, and RC4AG039085; a Paul B. Beeson Award in Aging; the Starr Foundation; the American Federation for Aging Research; the John A. Hartford Foundation; and the Atlantic Philanthropies. Table 1 Sample Descriptive and Comparisons between Grandparent Noncaregivers and Caregivers. Total sample1 Caregivers (n=818) Noncaregivers (n=1,547) P-value Psychological well-being  Depressive symptoms (range: 0–27), M ± SD 2.7 ± 4.1 1.9 ± 3.1 3.1 ± 4.5 <.001  Anxiety (range: 0–21), M ± SD 2.7 ± 3.3 2.2 ± 2.8 2.8 ± 3.5 <.001  Stress (range: 0–39), M ± SD 10.1 ± 6.6 8.9 ± 5.9 10.9 ± 6.7 <.001  Loneliness (range: 0–6), M ± SD 0.6 ± 1.2 0.4 ± 0.8 0.7 ± 1.3 <.001 Socio-demographics  Age (range: 59–105), M ± SD 72.8 ± 8.3 69.4 ± 6.3 75.0 ± 8.4 <.001  Female, n (%) 1,830 (58.0) 474 (58.0) 920 (59.5) .51  Education (range: 0–26), M ± SD 8.7 ± 5.1 8.6 ± 4.7 8.5 ± 5.2 .84  Income (range: 1–10), M ± SD 1.9 ± 1.1 1.8 ± 1.0 1.9 ± 1.1 <.001  Married, n (%) 2,236 (71.3) 665 (81.3) 1,035 (66.9) <.001  Number of children alive (range: 0–12), M ± SD 2.9 ± 1.5 2.8 ± 1.2 3.1 ± 1.6 <.001  Number of grandchildren (range: 0–15), M ± SD 4.5 ± 3.5 4.6 ± 2.7 5.2 ± 3.6 <.001  Household members (range: 0–10), M ± SD 1.9 ± 1.9 3.0 ± 2.2 1.5 ± 1.7 <.001  Years in the U.S. (range: 0–90), M ± SD 20.0 ± 13.2 16.5 (11.3) 21.2 ± 13.7 <.001  Self-rated health, n (%) <.01   Very good 87 (3.7) 27 (3.3) 60 (3.9)   Good 832 (35.2) 313 (38.3) 519 (33.6)   Fair 966 (40.9) 347 (42.4) 619 (40.0)   Poor 480 (20.3) 131 (16.0) 349 (22.6) Positive social support (range: 6–18), M ± SD 13.9 ± 3.0 12.8 ± 3.5 11.3 ± 3.8 <.001 Negative social support (range: 2–18), M ± SD 14.7 ± 3.6 15.3 ± 3.2 14.4 ± 3.7 <.001 Caregiver experience Caregiving time (range: 0–168), M ± SD _ 11.9 ± 24.9 _ _  Caregiving burden, n (%)   Never _ 664 (81.1) _ _   Little _ 58 (7.1) _ _   Sometimes/often/always _ 96 (11.8) _ _  Caregiving pressure, n(%)   Never _ 691 (84.5) _ _   Little _ 60 (7.3) _ _   Sometimes/often/always _ 67 (8.2) _ _  Perceived negative effect, n (%)   Never _ 657 (80.3) _ _   Little _ 76 (9.3) _ _   Sometimes/often/always _ 85 (10.4) _ _ 1 Sample sizes varied from 2,145 to 3,157 due to inapplicable question or missing values. Depression: 0–9 minor, 15–19 moderate, 20–17 severe Anxiety: 0–7 normal, 8–10 mild, 11–14 moderate, 15–21 severe Stress: 0–13 normal, 14–19 medium, 20–39 high Loneliness: 3–6 moderate/severe Table 2 Negative Binomial Regressions of Caregiving variables on Psychological Well-being. Depressive symptoms Anxiety Stress Loneliness Variables IRR (95% CI) P-value IRR (95% CI) P-value IRR (95% CI) P-value IRR (95% CI) P-value Noncaregiver 1.4 (1.2–1.6) <.001 1.2 (1.1–1.4) <.001 1.1 (1.1–1.2) <.001 1.6 (13–2.0) <.001 Caregiving time 1.0 (0.9–1.0) .16 1.0 (1.0–1.0) .48 1.0 (1.0–1.0) <.05 1.0 (1.0–1.0) .95 Caregiving pressure 1.4 (1.1–1.9) <.05 1.4 (1.1–1.9) <.01 1.4 (1.2–1.6) <.001 1.4 (0.8–2.2) .22 Caregiving burden 1.1 (1.0–1.1) <.05 1.1 (1.0–1.1) <.05 1.1 (1.0–1.1) <.001 1.1 (1.0–1.2) <.05 Perceived negative effect 1.5 (1.2–2.0) <.01 1.3 (1.0–1.6) .06 1.3 (1.2–1.5) <.001 1.7 (1.1–2.7) <.05 Note: Regression analyses controlled for age, gender, education, income, marital status, number of children alive, number of grandchildren, years living in the U.S., self-rated health, positive and negative supports. Conflict of Interest: The authors report no conflict of interest. Conflict of Interest Disclosures: Elements of Financial/Personal Conflicts All authors Author 2 Author 3 Author 4 Yes No Yes No Yes No Yes No Employment or Affiliation X Grants/Funds X Honoraria X Speaker Forum X Consultant X Stocks X Royalties X Expert Testimony X Board Member X Patents X Personal Relationship X Author Contributions: All authors contributed to this paper. Sponsor’s Role: None. 1 Burnette D Sun F Sun J 2013 A comparative review of grandparent care of children in the U.S. and China Ageing International 38 43 57 2 Xie X Xia Y 2011 Grandparenting in Chinese immigrant families Faculty Publications, Department of Child, Youth, and Family Studies Paper 82. http://digitalcommons.unl.edu/famconfacpub/82 3 Dong X Chang E Bergren S 2014a The burden of grandparenting among Chinese older adults in the Greater Chicago area – the PINE study AIMS Medical Science 1 125 140 4 Yee BWK Su J Kim SY Yancura L 2008 Asian American and Pacific Islander families Alvarez A Tewari N Asian American psychology: Current perspectives Mahwah, NJ Lawrence Erlbaum and Associates 5 Chen F Liu G Mair CA 2011 Intergenerational ties in context: Grandparents caring for grandchildren in China Social Forces 90 571 594 6 Zhou YR 2012 Space, time, and self: Rethinking aging in the context of immigration and transnationalism Clinical Key 26 232 242 7 Miyawaki CE 2015 A review of ethnicity, culture, and acculturation among Asian caregivers of older adults Sage Open 5 1 29 8 Lin X Bryant C Boldero J Dow B 2014 Older Chinese immigrants’ relationship with their children: A literature review The Gerontologist Advance Access published 10.1093/geront/gnu004 9 Kataoka-Yahiro MR 2010 Filipino American grandparent caregivers’ roles, acculturation, and perceived health status Journal of Cultural Diversity 17 24 33 20397571 10 Nagata DK Cheng WJY Tsai-Chae AH 2010 Chinese American grandmothering: A qualitative exploration Asian American Journal of Psychology 2 151 161 11 Lou VWQ 2011 Depressive symptoms of older adults in Hong Kong: The role of grandparent reward International Journal of Social Welfare 20 S135 S147 12 Ku LJE Stearns SC Van Houtven CH Lee SYD Dilworth-Anderson P Konrad TR 2013 Impact of caring for grandchildren on the health of grandparents in Taiwan Journals of Gerontology, Series B: Psychological Sciences and Social Sciences 68 6 1009 1021 13 Hayslip B Kaminski PL 2005 Grandparents raising their grandchildren: a review of the literature and suggestions for practice The Gerontologist 45 262 262 15799992 14 Chen F Liu G 2012 The health implications of grandparents caring for grandchildren in China The Journals of Gerontology, Series B: Psychological Sciences and Social Sciences 67 1 99 112 15 Hayslip B Blumenthal H Garner A 2015 Social support and grandparent caregiver health: One-year longitudinal findings from grandparents raising their grandchildren Gerontol B Psych Sci Soc Sci, 2015 70 5 804 812 16 Burnette D 1999 Social relationships of Latino grandparent caregivers: A role theory perspective The Gerontologist 39 49 58 10028770 17 U.S. Census Bureau 2011 2010 census demographic profile Washington, DC Author 18 Conway F Jones S Speakes-Lewis A 2011 Emotional strain in caregiving among African American grandmothers raising their grandchildren Journal of Women and Aging 23 2 113 128 21534103 19 Arean P Ayalon L 2006 Assessment and treatment of depressed older adults in primary care Clinical Psychology: Science and Practice 12 321 335 20 Donnelly PK Kim KS 2008 The Patient Health Questionnaire (PHQ-9K) to screen for depressive disorders among immigrant Korean American elderly Journal of Cultural Diversity 15 24 29 19172976 21 Zigmond AS Snaith RP 1983 The hospital anxiety and depression scale Acta Psychiatr Scand 67 361 370 6880820 22 Lam CL Pan PC Chan AW Chan SY Munro C 1995 Can the Hospital Anxiety and Depression (HAD) Scale be used on Chinese elderly in general practice? 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A cross-cultural perspective Int J Psychosom 40 29 34 8070982 24 Cohen S Kamarch T Mermelstein R 1983 A global measure of perceived stress Journal of Health and Social Behavior 24 385 396 6668417 25 Hughes ME Waite LJ Hawkley LC Cacioppo JT 2004 A short scale for measuring loneliness in large surveys: Results from two population-based studies Research on Aging 26 655 672 18504506 26 Chandra NK Roy D 2012 A continuous version of the negative binomial distribution STATISTICA LXXII 1 81 92 27 Goodman C Silverstein M 2002 Grandmothers raising grandchildren: Family structure and well-being in culturally diverse families The Gerontologist 42 676 689 12351803 28 Tam VC-W Detzner DF 1998 Grandparents as a family resource in Chinese-American families: Perceptions of the middle generation McCubbin HI Thompson EA Thomposon AI Fromer JE Residency in Native American and Immigrant Families Thousand Oaks Sage 243 263
PMC005xxxxxx/PMC5118149.txt
LICENSE: This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. 8918110 2607 Eur J Neurosci Eur. J. Neurosci. The European journal of neuroscience 0953-816X 1460-9568 27657541 5118149 10.1111/ejn.13410 NIHMS818720 Article Optogenetic activation of MCH neurons increases NREM and REM sleep during the night in rats Blanco-Centurion Carlos 1 Liu Meng 1 Konadhode Roda P. 1 Zhang Xiaobing 2 Pelluru Dheeraj 1 van den Pol Anthony N. 2 Shiromani Priyattam J. 13 1 Department of Psychiatry & Behavioral Sciences, Medical University of South Carolina, SC, 29425 2 Department of Neurosurgery, Yale University, CT, 06510 3 Ralph H. Johnson Veterans Administration Medical Center, Charleston, SC, 29401 Corresponding author: Priyattam J. Shiromani, Ph.D., Ralph H. Johnson VA Medical Center, Medical University of South Carolina, Department of Psychiatry, 114 Doughty Street, MSC 404/STB 404, Charleston, SC 29425, shiroman@musc.edu, 843-789-6778 (office) 11 10 2016 16 10 2016 11 2016 01 11 2017 44 10 28462857 This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. Neurons containing melanin-concentrating hormone (MCH) are located in the hypothalamus. In mice optogenetic activation of the MCH neurons induces both NREM and REM sleep at night, the normal wake-active period for nocturnal rodents (Konadhode et al., 2013). Here we selectively activate these neurons in rats to test the validity of the sleep network hypothesis in another species. Channelrhodopsin-2 (ChR2) driven by the MCH promoter was selectively expressed by MCH neurons after injection of rAAV-MCHp-ChR2-EYFP into the hypothalamus of Long-Evans rats. An in vitro study confirmed that the optogenetic activation of MCH neurons faithfully triggered action potentials. In the second study, in Long-Evans rats, rAAV-MCH-ChR2, or the control vector, rAAV-MCH-EYFP, were delivered into the hypothalamus. Three weeks later baseline sleep was recorded for 48h without optogenetic stimulation (0 Hz). Subsequently, at the start of the lights-off cycle, the MCH neurons were stimulated at 5, 10, or 30Hz (1 mW at tip; 1 min on – 4 min off) for 24 h. Sleep was recorded during the 24h stimulation period. Optogenetic activation of MCH neurons increased both REM and NREM sleep at night, whereas during the day cycle only REM sleep was increased. Delta power, an indicator of sleep intensity, was also increased. In control rats without ChR2, optogenetic stimulation did not increase sleep or delta power. These results lend further support to the view that sleep-active MCH neurons contribute to drive sleep in mammals. Graphical abstract Neurons containing melanin concentrating hormone (MCH) or orexin are localized in the posterior hypothalamus. Activation of orexin neurons produces arousal, but the function of the MCH neurons is less clear. In mice, we determined that optogenetic activation of MCH neurons increases sleep at night. We now find that in wildtype rats activating these neurons also increases sleep and delta power. Such consistent results in two mammals underscore the role of the MCH neurons as drivers of sleep. Channelrhodopsin-2 REM sleep rat melanin concentrating hormone recombinant adenoassociated virus Introduction In the last hundred years successive groups of researchers have used new tools to identify neurons responsible for wake, non-rapid-eye movement (NREM) sleep and REM sleep [reviewed by (Konadhode et al., 2014)]. Initially, transections and electrolytic lesions helped locate the brain regions responsible for the different sleep-wake states (Jouvet, 1962). Subsequently, electrophysiology studies in freely-behaving animals identified neurons that were active only during a specific sleep-wake state (McCarley & Hobson, 1971; Chu & Bloom, 1973; McGinty & Harper, 1976; Siegel & McGinty, 1977; Aston-Jones & Bloom, 1981; Szymusiak & McGinty, 1986; Mileykovskiy et al., 2005; Hassani et al., 2009) indicating that activity of specific neurons regulated the sleep-wake states. The introduction of c-FOS as a functional neuroanatomical tool led to identifying the phenotype of neurons that were activated during sleep-wake states and also determined the connectivity between these neurons (Sherin et al., 1996; Basheer et al., 1997). The collective data from those studies has resulted in a neural network map that illustrates the various phenotypes of neurons regulating waking, NREM and REM sleep (Saper et al., 2010; Shiromani, 2011; Pelluru et al., 2013). Currently, optogenetics and pharmacogenetics are being used to directly test specific cell elements of this circuit. For instance, optogenetic activation of the arousal orexin neurons increased transitions to waking (Adamantidis et al., 2007) whereas inhibition resulted in sleep (Tsunematsu et al., 2011). Similar results were observed using the pharmacogenetic approach (Sasaki et al., 2011). Optogenetic activation of the noradrenergic locus coeruleus (LC) neurons also increased waking while photoinhibition decreased the length of the wake bouts (Carter et al., 2010). Pharmacogenetic activation of LC neurons ameliorated the excessive sleepiness in a mouse model of narcolepsy (Hasegawa et al., 2014). Optogenetics has also been used to drive neurons implicated in generating sleep. One phenotype of sleep-active neurons contains melanin concentrating hormone (MCH) (Hassani et al., 2009). MCH neurons are intermingled with the orexin neurons and project to many of the same targets as orexin neurons (Bittencourt et al., 1992; Steininger et al., 2004; Yoon & Lee, 2013). In wildtype mice we found that optogenetic activation of the MCH neurons increased sleep at a time when the mice would be normally awake. Subsequently, another group used MCH-cre mice and determined that acute stimulation during NREM sleep increased entries into REM sleep (Jego et al., 2013). Another group (Tsunematsu et al., 2014) genetically ablated the MCH neurons and found decreased amounts of NREM sleep without changing REM sleep. These studies in mice demonstrate that selective activation of MCH neurons increases sleep, and loss of these neurons decreases NREM sleep. Optogenetic studies need to be performed in other mammalian species that have both NREM and REM sleep, thereby validating the status of specific neurons within neural network models of sleep-wake regulation. To facilitate such studies, we linked the gene encoding channelrhodopsin-2 (ChR2) to the MCH promoter. In the present study, this virus was inserted into wildtype rats to test the hypothesis that activation of MCH neurons induces sleep not only in mice but also in another mammal. Materials and Methods Ethical statement All manipulations done to the animals adhered to the NIH Guide for the Care and Use of Laboratory Animals and were pre-approved by the Medical University of South Carolina (protocol 3355), Ralph H. Johnson VA (protocol 525, 584), and Yale University (protocol 2014-10117) Institutional Animal Care and Use Committee. Viral vectors The parent plasmid containing channelrhodopsin-2 gene (ChR2; H134R) was kindly donated by Dr. Karl Deisseroth (Stanford University/HHMI). The genes for ChR2 and enhanced yellow fluorescent protein (EYFP) were originally driven into neurons by the human synapsin promoter (hSyn-485 bp). We modified it by replacing the hSyn-485 with the MCH promoter sequence (462 bp). The MCH specific plasmid was then packaged by the Vector Core at the University of North Carolina (Chapel Hill, NC). The plasmid was packaged into recombinant adeno-associated viral vectors (rAAV; serotype 5) to a titer of 1×1010 particles per μL. The control vector containing no ChR2 gene (rAAV-MCH-EYFP) was constructed as previously described (Liu et al., 2011). After packaging, the MCH specific viral vectors were always stored at −85°C and thawed just before delivery into the brain. In vitro studies Optogenetic stimulation of the MCH neurons rAAV-MCH-ChR2-EYFP was injected into the lateral hypothalamus of five adult rats. Four to five weeks later, rats with selective ChR2 expression in lateral hypothalamic MCH neurons were deeply anesthetized with isoflurane and decapitated. Brains were immediately removed and immersed in ice-cold high-sucrose solution containing (in mM): 220 sucrose, 2.5 KCl, 6 MgCl2, 1 CaCl2, 1.23 NaH2PO4, 26 NaHCO3, and 10 glucose (gassed with 95% O2/5% CO2; 300–305 mOsm). Coronal brain slices (300 μm thick; vibratome) were transferred to an incubation chamber filled with artificial CSF (aCSF) solution containing (in mM) 124 NaCl, 2.5 KCl, 2 MgCl2, 2 CaCl2, 1.23 NaH2PO4, 26 NaHCO3, and 10 glucose (gassed with 95% O2/5% CO2; 300–305 mOsm) at room temperature (22 °C). Following a recovery period of 1–2 h, slices were transferred to a recording chamber mounted on a BX51WI upright microscope (Olympus, Tokyo, Japan). The slices were perfused with a continuous flow of gassed ACSF. The temperature of the recording solution was maintained at 33 ± 1 °C by a dual-channel heat controller (Warner Instruments, Hamden, CT). For comparison, we also recorded mouse MCH neurons from transgenic mice with GFP expressed in the MCH neurons, as described elsewhere (van den Pol et al., 2004; Zhang & van den Pol, 2012). MCH neurons with ChR2-EYFP expression were visualized using an infrared-differential interference contrast optical system combined with a monochrome CCD camera and monitor. Pipettes were pulled from thin-walled borosilicate glass capillary tubes (length 75 mm, O.D=1.5 mm, I.D.= 1.1 mm, World Precision Instruments, Sarasota, FL) using a P-97 micropipette puller (Sutter Instruments, Novato, CA). A pipette solution containing (in mM) 145 K-gluconate, 1 MgCl2, 10 HEPES, 1.1 EGTA, 2 Mg-ATP, 0.5 Na2-GTP, and 5 Na2-phosphocreatine (pH 7.3 with KOH; 290–295 mOsm) was used for the recording. Recording pipettes showed resistances ranging from 3 to 6 MΩ. An EPC-10 patch-clamp amplifier (HEKA Instruments, Bellmore, NY) and PatchMaster 2.20 software (HEKA Elektronik, Lambrecht/Pfalz, Germany) were used to acquire and analyze data. Neurons with series resistance greater than 20 MΩ and change of greater than 15% were excluded from the statistical analysis. Traces were processed using Igor Pro 6.36 (Wavemetrics, Lake Oswego, OR). The membrane potential for voltage-clamp recording was held at −60 mV. A blue light laser (470 nm, Laserglow Technologies, West Toronto, CA) set at 5–10 mWatts/mm2 was used to activate ChR2 in the MCH neurons. The blue light was delivered by a fiber optic (tip I.D.=100 μm, NA 0.22, Doric lenses, CA) to the recorded neuron. To test the photostimulation-evoked response, stimuli of 10 msec duration with fixed frequencies of 1, 5, 10, 20 and 30 Hz were used. Evoked response of transfected MCH neurons was recorded in voltage and current clamp conditions. In vivo studies Animals and groups Fourteen Long Evans adult rats (545.3 ± 41.3g; male) were used. Ten rats received rAAV-MCH-ChR2-EYFP while the other four rats received the control vector lacking ChR2 (rAAV-MCH-EYFP). All rats were housed singly in an isolated room, with controlled temperature (22 ± 2°C) and lighting (photoperiod =12:12 h; lights-off at 6 PM). Food and water were available ad-libitum. Gene transfection Under deep isofluorane anesthesia (1.5–2%) and aseptic conditions viral vectors were microinjected bilaterally into two adjacent rat brain sites targeting the entire population of MCH neurons (lateral zona incerta and perifornical area: AP= −2.8 mm, lateral= ±1.6 mm, vertical= −7.8 mm; medial zona incerta and dorsomedial hypothalamic area: AP= −3.1 mm, lateral= ± 0.8 mm, vertical= −7.8 mm). The coordinates are relative to bregma, lateral to the sagittal suture and vertical to the dura mater. For the lateral site the volume of injection was 2 μl and for the medial site it was 1 μl. Therefore, in both hemispheres a total of 6 μl was microinjected (virus load of 6×1010 particles per rat). The virus was delivered slowly over 20 min using a 10 μL Hamilton syringe. Following the microinjection, the injection needle (30 Ga) was left in place for an additional 5 min and then withdrawn slowly. Fiber optic and electrodes implant Two weeks after delivery of the viral vectors, the fiber optic probes and sleep recording electrodes were surgically implanted (under 2% isoflurane anesthesia). Two fiber optic probes (0.4 mm diameter), one in each hemisphere, were implanted at antero-posterior −2.9 mm, lateral −1.4 mm and vertical −7.0 mm. To record the electrocorticogram (ECoG) four miniature screws (Plastic One Inc.) were inserted to sit atop the frontal and occipital cerebral cortices. To record the skeletal muscle activity (EMG), two flexible wire electrodes (Plastic One Inc.) were bilaterally embedded into the nuchal muscles. The wires were inserted into a plastic socket, and along with the optic probes, affixed to the skull with dental cement. Optogenetic stimulation of MCH neurons Five weeks after the rAAV vector delivery rats were tethered to a light-weight cable connected to rotary swivels. The swivels allowed the rats to engage in complete freedom of behavior. Rats were adapted to tethering for four days and baseline sleep was recorded for 48 h. During this first sleep recording session there was no optogenetic stimulation and this initial session represents 0 Hz. Following the baseline recording, the rats were given optogenetic stimulation (blue LED, 473 nm wavelength; 1 mW intensity at tip; Doric Lenses, Québec, Canada). A programmable stimulator (Master-9, AMPI, Jerusalem, Israel) generated TTL pulses of 10 msec of duration for driving the photo stimuli. TTLs pulses were also recorded along with the ECoG and EMG activity. MCH neurons were activated by light at three frequencies: 5, 10, or 30 Hz (ON for 1 min and OFF for 4 min). The rats were stimulated for 24 h starting at lights-off (Zeitgeber hour 12). There was a 72 h interval between stimulation days and stimulation protocols were followed in a counterbalanced fashion. In 24 h MCH neurons were given 8.64 × 104 pulses at 5 Hz, 1.73 × 105 at 10 Hz and 5.18 × 105 at 30 Hz. MCH neurons were activated 1.0 % of total time in 24 h at 5 Hz, 2.0% at 10 Hz and 6.0% at 30 Hz. Sleep recording, scoring and spectral analysis The ECoG activity was recorded from the contralateral frontal-occipital electrodes. Using an analog polygraph (Grass Model 12), the ECoG activity was amplified 5000 times and band pass filtered between 0.3–100 Hz. To record the EMG activity, the muscle electrical activity was amplified between 5000–20,000 times and band pass filtered between 100–1 KHz. ECoG and EMG analog signals were then digitized and stored (at 128 Hz sampling rate) onto a computer hard drive by a data acquisition software (Vital Recorder, Kissei Comtec Co., Nagano, Japan). The acquisition software also stored and synchronized video streams of the rat’s behavior. Video was recorded with infrared CCD cameras that allowed recording of the animal’s behavior in the dark. The sleep records were scored in 12 sec epochs based on the Fast Fourier Transformation (FFT) algorithm of the ECoG activity for the delta bandwidth (0.5–4 Hz) along with the EMG integrated activity (SleepSign®, Kissei Comtec Co. Nagano, Japan). Each epoch was then manually scored as wake, non-REM sleep (NREM) or REM sleep (REMS). Video recordings assisted the identification of the sleep-wake states. SleepSign was also used to produce a FFT analysis of the ECoG during NREMS and REMS. Both delta (0.5–4 Hz) and theta (4–8 Hz) power were automatically determined by the software. ECoG FFT data was calculated in 3 h bins. ECoG FFT values for the 0 Hz day were normalized as percent of the 24 h average. Then power values during photostimulation days were expressed as percent of the 0 Hz power. Post mortem analysis of transfected rat brains At the end of the in-vivo experiments, rats were euthanized (5% isofluorane) and the brains perfused with 50 ml 0.9% saline and 150 ml 10% formalin-buffered solution. The brains were removed, left overnight in 10 % formalin PBS at 4 °C, and then transferred to a sucrose 30% PBS solution until equilibration. The brains were cut on a cryostat and 40 μm thick coronal sections obtained. The first and third sections, in a 1 in 5 series, were processed for immunolabeling of the MCH peptide. The brain sections were first washed to remove the cryoprotectant (PBS 0.01 M), then placed in normal donkey serum (2% in PBS+0.3% Triton-x). Sections were then incubated overnight at room temperature (RT) with the primary antibody (rabbit anti-MCH; 1:1000 dilution; Phoenix Pharmaceuticals, Cat # H070-47). Next day, after washing in PBS, the sections were incubated at RT for 1 h with donkey anti-rabbit IgG secondary antibody (Alexa Fluor® 568 conjugate; 1:500 dilutions, Life Technologies; Cat # A10042). Sections were then mounted onto gelatin coated glass slides, cover slipped, and stored at −20 °C. Hypothalamic tissue from one well in the animal depicted in figure 3 was incubated in goat anti-orexin antibody (1:500 dilution, Phoenix Pharmaceuticals, Cat #H003-30) to visualize orexin-immunoreactive neurons in conjunction with EYFP. To further test for specificity of the transgene construct a separate rat (off-site control) was given the rAAV-MCH-ChR2-EYFP into the caudate putamen (one side; 750 nl) where no MCH neurons are located. In this off-site control rat, a single injection (one side; 750nl) was also made in the zona incerta to confirm the efficacy of the vector. The rat was sacrificed 18 days after injection, and brain tissue was processed for visualization of the EYFP+ neurons. A confocal microscope (Nikon A1 + confocal microscope; Nikon Corporation, Tokyo, Japan) was used to visualize the MCH and EYFP positive neurons. The distribution of EYFP+ somata was plotted along with the location of the fiber optic tips. Each coronal section was scanned at low magnification (4×), dual channel (Channel 1:EYFP Laser line at 488 nm; Channel 2=Texas Red Laser line at 560 nm) and the acquired images exported as TIFF image files. The TIFF images were overlaid (Adobe Systems Inc.) and resized onto matching rat brain atlas digital plates. Areas showing strong EYFP positive signal in somata and proximal processes were traced and colored. Fiber optic tips indicated on the images by scar tissue were also traced. Brain sections from rats with extensive transfection and correct fiber optic placements were used to obtain a tally of the MCH neurons expressing EFYP. These sections were examined at high magnification (60×) by a person blinded to the type of treatment given to the rats. Single (MCH+ or EYFP+) and double (MCH+EYFP) labeled neurons were counted in five coronal brain sections separated at least 120 μm apart. Ten bilateral sampling areas per rat (147 × 196 μm) showing high density of EYFP positive somata were tallied. Cells were counted in images while scanning across the vertical plane (Z-axis in 1 μm increments). To assess colocalization between EYFP and MCH, Z-stacks were visualized both in orthogonal view in 2D and as XYZ-planes in 3D rendering. Only cells showing MCH labeling inside the cytoplasm were counted as specifically transfected. The tissue processed for visualization of orexin-immunoreactive neurons was similarly examined. Statistical analysis Sigma Stat software (Systat Software Inc., San Jose, CA) was used to statistically compare group means. Two way and one-way repeated measures ANOVA (General Linear Model) compared group means, followed by post-hoc analysis (Holm-Sidak). Independent and paired t-tests were also used as a-priori tests of hypotheses. Probability values equal or less than 0.05 were set for rejection of the null hypothesis. Results In vitro optogenetic activation of rat MCH neurons An in-vitro electrophysiological analysis with whole cell recording showed that rat MCH neurons that were ChR2-EYFP positive were also responsive to light. Similar to the majority of MCH neurons found within the mouse hypothalamus (van den Pol et al., 2004; Zhang & van den Pol, 2012), rat MCH neurons were generally silent with few if any spontaneous action potentials (Fig. 1A). The resting membrane potential of rat MCH neurons was almost identical to that of the mouse MCH neurons (rat=60.6±1.5 mV vs. mouse=59.4 ±1.1 mV n.s.; Fig. 1B). Blue light pulses (1–10 Hz; 10ms duration) evoked substantive inward currents with similar amplitudes and high fidelity responses. However, light pulses at frequencies faster than 20 Hz evoked relatively lower current amplitudes compared to the first pulse of the stimulation (Fig. 1C). In current-clamp configuration, light stimuli between 1–10 Hz generated action potentials with high fidelity. However, light pulses with a frequency faster than 20 Hz only evoked a single action potential following the initial pulse, and only small amplitude depolarizations evoked by the succeeding pulses (Fig. 1D). As we have demonstrated previously in this region of the hypothalamus, this spike frequency adaptation is a unique feature of MCH neurons, not shared by nearby hypocretin cells (van den Pol et al., 2004). In vivo studies Anatomical distribution of ChR2-EYFP+ somata In rats given rAAV-MCH-ChR2-EYFP the presence of the reporter gene, EYFP, served as proxy for the transfection of the ChR2 gene into MCH neurons. Of the ten rats given rAAV-MCH-ChR2-EYFP, six rats had extensive expression of EYFP. In the other four rats, few if any EYFP neurons were seen, perhaps because the cannula delivering the virus was clogged; these rats were therefore not included for further study. The gross anatomical distribution of the EYFP expression from the six rats with good ChR2 expression is summarized in figure 2. There were numerous EFYP+ somata within the zona incerta, the lateral hypothalamus and the perifornical area (Figure 3). The four WT rats given control vector (rAAV-MCH-EYFP) also had numerous EYFP+ somata. Tally of the MCH+EYFP+ neurons determined that 52.5 (± 2.0)% of MCH neurons were also EYFP+. The MCH promoter expressed the genes in MCH neurons, as shown by the strong and selective expression in which 97.3(± 0.97)% of EYFP+ were also MCH+ (Figure 3 and 4; left panels). In the tissue sections processed for visualization of orexin-ir neurons, none of the orexin+ neurons were also EYFP+ (Figure 4; right panel), which is consistent with our previously published report in mice (Konadhode et al., 2013). The supplementary figure shows the lack of EYFP+ neurons in the off-site (caudate-putamen) control rat. By contrast in the same rat, injection of the rAAV-MCH-ChR2-EYFP into the zona incerta robustly transduced EYFP into many neurons. This further supports the view that the viral gene vector employing the MCH gene promoter shows selective expression in MCH cells. Optogenetic activation of rat MCH neurons and sleep states Figure 5 summarizes the sleep data during the 12h night and day periods. During the night there was a significant difference between the experimental (ChR2) and control rats (no ChR2) in percent waking (F=8.7; df=1,29; p=0.018), NREM (F=6.47; df=1,29; p=0.035) and REM sleep (F=11.03; df=1,29; p=0.011). Within group post-hoc comparisons determined no effect of optogenetic stimulation in the control rats. Moreover, there was no difference between the groups at 0 Hz indicating comparable levels of wake, NREM and REM sleep at night (Holm-Sidak post-hoc test). However, in the rats given ChR2 10 Hz optogenetic stimulation during the 12h night cycle significantly decreased waking (p=0.001), and increased both NREM (p=0.001) and REM sleep (p=0.001) compared to 0 and 5Hz (Fig. 5). 5 Hz only increased REMS whereas 30 Hz did not have an effect (Fig. 5). These results indicate that in rats activation of MCH neurons at night induces both types of sleep, and that 10Hz is more effective compared to 5Hz. During the day cycle, there was no significant effect of stimulation on wake or NREM sleep. However, in rats with ChR2, activation of the sleep-active MCH neurons significantly increased REM sleep in all three frequencies compared to 0Hz (p=0.05) (Figure 5). In rats given the control virus (no ChR2) there were no changes in sleep in response to stimulation in waking, NREM or REM sleep (Figure 5). Thus, in rats stimulating MCH neurons during the day increased REM sleep, a finding consistent with data in MCH-Cre mice (Jego et al., 2013; Tsunematsu et al., 2014). To better understand the time course of the changes in sleep produced by optogenetic stimulation of MCH neurons, the data for 5 and 10Hz stimulation rates were arranged in 3h blocks (Figure 6). A one-way RMANOVA compared means separately for the night and day cycles. At night, 10Hz stimulation immediately increased total sleep time by increasing both NREM (p<0.05) and REM sleep (p<0.05). 5Hz stimulation did not increase NREM but increased REM sleep during the second half of the night cycle (p<0.05). Thus, 10Hz stimulation made the rats sleep more when they should normally be awake. During the day cycle 5Hz stimulation significantly increased REM sleep during all time points compared to 0Hz (p=0.01), while 10Hz increased it during the first 6h of the lights-on cycle compared to 0Hz (p=0.01). Next we examined the effect of MCH neuronal activation on sleep architecture (Figure 7). Only the effects of 10Hz stimulation in ChR2 rats was analyzed as this was most effective during both the night and day cycles. Data from the control rats was not analyzed as there were no changes in sleep in response to stimulation. Activation of rat MCH neurons significantly decreased the number of long wake bouts (>32 min) during both the night and day cycles and increased the number of short NREM and REMS bouts compared to 0Hz (p=0.05). Thus, 10Hz stimulation decreased the length of waking bouts and increased entry into both NREM and REM sleep. We also examined the effects of optogenetic activation of MCH neurons on the spectral ECoG power during sleep states. Figure 8 summarizes the changes observed in NREM sleep delta (0.5–4 Hz; top graph) and REM sleep theta power (4–8 Hz; bottom graph) in the rats given ChR2. With respect to delta power, only 10Hz stimulation data were analyzed since only this frequency significantly increased NREM sleep. At 0 Hz NREMS delta power waxed and waned across the 24 h cycle, a profile that is consistent with data in rats (Shiromani et al., 2000). 10Hz stimulation of the MCH neurons increased delta power, and during the daytime, NREMS delta power continued to progressively increase rather than wane. Activation of rat MCH neurons also increased theta power during REM sleep. Stimulation at 5 Hz resulted in higher theta power during the first 12 h of stimulation. At 10 Hz, REM sleep theta power nearly doubled for 18 h. The increase in theta power is also consistent with the increase in REM sleep time. Thus, activation of MCH neurons in rats not only increased both NREM and REMS, but also increased delta and theta power. Discussion In mammals a distributed network of neurons is implicated in generating wake, NREM and REM sleep. Because these neurons are intermingled with neurons serving other behaviors, optogenetics is used to selectively activate phenotype specific neurons. Previously (Konadhode et al., 2013), we determined that activation of the sleep-active neurons containing melanin concentrating hormone (MCH) in mice robustly induced sleep. We now demonstrate that in wildtype Long-Evans rats, similar to what is found in mice, optogenetic activation of MCH neurons induces both NREM and REM sleep at night when nocturnal rodents are primarily awake. Our two studies utilized the same viral vector, rAAV-MCH-ChR2(H134R)-EYFP, to insert the light-sensitive ChR2 gene into MCH neurons. In-vitro experiments determined that the MCH neurons in mice and rats were similarly activated by light. Both studies utilized the same experimental paradigm (one minute stimulation followed by 4 minutes of no stimulation, every 5 minutes) to stimulate the MCH neurons over 24h. In both studies, to better gauge the influence of the MCH neurons in inducing sleep, the optogenetic stimulation began at the start of the light-off period, which is when nocturnal rodents awaken in response to circadian signals. In our studies, activation of MCH neurons at night induced sleep by decreasing the length of wake bouts. Delta power, a measure of sleep intensity, was also increased in both rats and mice. Such consistent effects in two species that have both NREM and REM sleep validates the status of MCH neurons inducing sleep and suggests that MCH neurons may serve a common function in driving sleep in mammals. In the current study in rats, as in our previous study in mice (Konadhode et al., 2013), ChR2-EYFP was selectively colocalized in MCH neurons in the zona incerta, perifornical area and the lateral hypothalamus. In the present study, 97% of EYFP (proxy for ChR2) positive neurons were also MCH immunoreactive, indicating the selective nature of the gene expression. Specificity of the vector for MCH neurons was also confirmed by lack of colocalization between EYFP+ and orexin+, which is consistent with our previous report in mice (Konadhode et al., 2013). We used orexin neurons because these neurons are intermingled with MCH neurons. Further confirmation was established by an experiment showing the absence of transfection among neurons of the caudate putamen which lacks MCH neurons, and by the similarity of the unique electrophysiological characteristics of rat and mouse MCH neurons determined with whole cell recording. Similar rates of transfection of MCH neurons were observed in both species (52.5% in rats versus 53.4% in mice). Thus, in both our studies about half of the MCH neurons contained the light-sensitive ChR2. However, even if all of the MCH neurons contained ChR2, it is possible that light will not reach all of the light-sensitive MCH neurons, a potential limitation of the optogenetic approach. Nevertheless, there was a robust increase in both NREM and REM sleep at night with optogenetic activation of half of the MCH neurons. This indicates that only a subset of MCH neurons needs to be activated to increase sleep, underscoring the impact of MCH neurons in driving sleep. It is not known whether the subset of MCH neurons containing the light-sensitive opsin and activated by light recruits and activates the other MCH neurons. In the present study in rats, the sleep response was stronger than in our previous study in mice (Konadhode et al., 2013). For instance, in the present study both 5 and 10Hz were effective, whereas in our previous study only 10Hz was effective. This might be because the diameter of the fiber-optic probes in this study was twice as large as those used in our previous study (400μm versus 200μm). We selected the larger probes to reach the MCH neurons that are diffusely scattered along the hypothalamus. Thus, in the present study more MCH neurons were potentially activated by the broader beam of light, producing a stronger effect on sleep. Our two studies have also found that delta power, a marker of sleep intensity, is increased in response to activation of MCH neurons. An increase in delta power was also observed by another group who also activated the MCH neurons (Tsunematsu et al., 2014). In the present study, delta power and NREM sleep time increased upon stimulation at night. During the day 10Hz stimulation increased delta power but not NREM sleep time. We suggest that during the day NREM sleep time is at ceiling levels and cannot be increased further. However, delta power wanes across the day cycle and activating the MCH neurons prevented the decline. Two other groups have also examined the effect of optogenetic stimulation of MCH neurons on sleep (Jego et al., 2013; Tsunematsu et al., 2014). They used mice that were transgenic pMCH-cre (Jego et al., 2013) or the ChR2 was activated in MCH neurons via a tetracycline-controlled system (Tsunematsu et al., 2014). We used wildtype mice (Konadhode et al., 2013) or rats (the present study). They found an increase in REM sleep, while we determined that both NREM and REM sleep were increased in response to optogenetic activation of MCH neurons. One possibility for this difference is related to light-induced activation of specific clusters of MCH neurons. The MCH neurons are located in the zona incerta, lateral hypothalamus and perifornical area, with a smaller cluster located ventrally along the dorsal border of the ventral medial hypothalamus (Konadhode et al., 2014). The cluster of MCH neurons in the lateral and perifornical area innervate the pons (Hanriot et al., 2007; Torterolo et al., 2009; 2013) where REM sleep is generated. In the two studies where REM sleep was increased (Jego et al., 2013; Tsunematsu et al., 2014), the MCH neurons in the lateral and perifornical cluster may have shown a higher probability of activation, whereas in our studies we specifically targeted the probes to activate the MCH neurons in the zona incerta. In the present study, it is possible that because of the bigger probe light reached the lateral and perifornical clusters, which then induced REM sleep during the day. Thus, activating specific subsets of MCH neurons may exert a differential effect on NREM versus REM sleep, a perspective meriting further study. Although activation of MCH neurons promotes sleep, optogenetic inhibition has no effect (Jego et al., 2013; Tsunematsu et al., 2014). Interestingly, selective ablation of approximately 97% of MCH neurons via a cell-specific expression of diphtheria toxin decreases NREM sleep without affecting REM sleep (Tsunematsu et al., 2014). With 30% ablation of MCH neurons there is a decrease in NREM sleep intensity under basal conditions and in response to 4h total sleep deprivation (Varin et al., 2016). Together, the optogenetic and MCH neuron ablation studies underline the potential importance of MCH neurons in both NREM and REM sleep. Pharmacological studies also indicate that the MCH peptide, promotes both types of sleep. MCHR1 antagonists significantly decrease both NREM sleep and REM sleep (Ahnaou et al., 2008). Activation of the MCHR1 is the likely mechanism for the NREM sleep enhancing effect because MCHR1 null mice show significantly less NREM sleep(Ahnaou et al., 2011). Similar reduction of NREM sleep has been measured in the MCH null mice (Willie et al., 2008). In contrast, when MCH was infused ICV to rats, both types of sleep significantly increased (Verret et al., 2003). Local infusion of MCH into the locus coeruleus only increases REM sleep (Monti et al., 2014) suggesting that MCH neurons regulate NREM versus REM sleep depending on the projection site. In humans, MCH release was highest after sleep onset which corresponds to the light stages of NREM sleep (Blouin et al., 2013). In rats, we also measured higher MCH levels in the cerebrospinal fluid during the sleep phase (Pelluru et al., 2013). The MCH neurons are not active in waking, but increase their activity in NREM sleep (1–3Hz; average=0.5Hz), with peak activity in REM sleep (1–22Hz; average=1.1Hz) (Hassani et al., 2009). Thus, activating MCH neurons should promote sleep, which it does in both mice and rats. We and others have stimulated the MCH neurons at 5, 10, 20 and 30 Hz, rates that are higher compared to what may be found in natural NREM and REM sleep. However, as seen in figure 1, MCH neurons can be driven at 1–10Hz, but at 20 and 30Hz there is a decrement in amplitude and triggering of the action potential. We found that 10Hz induced both NREM and REM sleep, whereas 5, 10 and 30Hz induced only REM sleep. These stimulation frequencies are higher than normally recorded in MCH cells, but were necessary to offset the fact that only half the MCH are being stimulated, based on our histochemical corroboration. It seems unlikely that stimulating at 1Hz, the rate that is consistent with NREM and REM sleep, will induce more sleep, especially during the wake-active period because the faster stimulation rates may force the MCH neurons to release more of their contents quickly, thereby hastening the transition to sleep. The released transmitters are also likely to accumulate producing a cumulative effect in driving sleep. Indeed, in the present study, delta power, a very sensitive marker of accumulating endogenous somnogens, increased in response to the chronic stimulation. Optogenetics has been transformative in identifying the impact of specific neurons in behavior. Should the rate of optogenetic stimulation mimic the natural pattern of activity of the neurons? Although optogenetic mimicking of normal neuronal behavior may be ideal, for some behaviors, such as sleep, it may not be necessary to mirror the fine pattern of activity to induce the desired behavior. The cadence of the MCH neurons may be off in wake and on in sleep (loosely defined as binary). It may be sufficient to induce sleep to maintain this on-off cadence. In other words, turn-on the MCH neurons periodically to get a waking brain to fall asleep. Stimulation at 5Hz induced sleep, albeit weakly compared to 10Hz. It is possible that in rats stimulation at rates that may be closer to what occurs naturally may also induce sleep. How might MCH neurons induce sleep? During waking the activity of the MCH neurons is inhibited by the adjacent arousal orexin neurons (Apergis-Schoute et al., 2015). The MCH neurons are able to inhibit the combined activity of the arousal neurons and generate NREMS and REMS because MCH peptide inhibits the orexin neurons (Rao et al., 2008). However, GABA may also be colocalized in MCH neurons and similar to MCH, it may inhibit the arousal neurons (Elias et al., 2001; Del Cid-Pellitero & Jones, 2012); some MCH cells may also contain other fast transmitters (Chee et al, 2015). Another mechanism by which MCH stimulation may increase specifically NREM sleep is through indirect disinhibition of the reticular thalamic nucleus (RT). Recently it was found that optogenetic inhibition of hypothalamic GABA neurons projecting to the RT increase NREM sleep and EEG delta power ( Gutierrez-Herrera et al., 2016). If MCH neurons contact these hypothalamic GABA cells, the optogenetic activation of MCH could indirectly disinhibit the RT resulting in higher NREM sleep and EEG delta power. MCH neurons project throughout the brain, innervating neuronal populations implicated in waking and REMS (Cvetkovic et al., 2003; Cvetkovic et al., 2004; Hanriot et al., 2007; Sita et al., 2007; Croizier et al., 2010; Hong et al., 2011; Lima et al., 2013; Torterolo et al., 2013; Yoon & Lee, 2013). It is not known whether a single MCH neuron projects to multiple ascending and descending targets, but the MCH neurons located in the lateral cluster project primarily to the pons, where REMS generator neurons are located (Cvetkovic et al., 2004). Optogenetic mediated activation of MCH neurons may inhibit the local orexin neurons through release of inhibitory MCH, weakening the orexin drive onto downstream arousal neurons and attenuating the waking bout. It remains to be determined which projection(s) of the stimulated MCH neurons is responsible for the somnogenic effect. MCH neurons project to multiples sites, many of those include regions where the arousal neurons are located. Stimulation of specific projection(s) will be required to address this question. Nevertheless, the converging evidence from optogenetic, selective ablation of MCH neurons, and pharmacology studies underscores the inclusion of the MCH neurons in network models of sleep-wake regulation. That sleep was induced during the normal waking cycle suggests a potential role of MCH neurons in sleep disorders, such as insomnia, and also support the perspective that drugs targeting the MCH system may enhance sleep in certain sleep disorders. Supplementary Material Supp Fig S1 Supplementary Figure. Confocal scanning microscopy imaging of rat brain sections 18 days after microinjection of rAAV-ChR2-EYFP into the caudate-putamen (CPu; left panels) or into the zona incerta (ZI; right panels). At the CPu where there are no MCH neurons, there is no EYFP emission signal among neurons (top left panel). Non-neuronal auto fluorescence was observed under both 488nm and 552nm wavelength light but only in the area of cells damaged by the injection cannula. These autofluorescent cells may be traumatized or dying from direct injury or being scavenger cells infiltrating the damaged tissue. Activated macrophages are known to show strong autofluorescence. In contrast to the CPu, in the ZI numerous green fluorescent neurons along with its fibers are evident upon injection of the rAAV-ChR2-EYFP vector. These neurons were visible only when excited at 488nm wavelength light (top right panel) but not when excited at 552nm (middle right panel). Because EYFP emits light when excited at 488 nm wavelength, it confirms the specificity of the rAAV-ChR2-EYFP vector to transduce MCH neurons. In the ZI non-neuronal green and red autofluorescent cells with no processes are also evident only along the injection cannula track (top, middle and bottom right panels). We thank Wengxue Wang for assistance with the study and Dr. Amanda LaRue for use of the confocal microscope. This study was supported by Medical Research Service of the Department of Veterans Affairs (101 BX000798) and NIH grants 1K01AG041520 (to ML), NS052287, NS084477, NS079940 Abbreviations AP Anteroposterior CPu Caudate-Putamen ChR2 Channelrhodopsin2 ECoG Electrocorticography EMG Electromyography EYFP Enhanced Yellow Fluorescent Protein FFT Fast Fourier Transformation LC Locus Coeruleus MCH Melanin-Concentrating Hormone NREM no Rapid Eye Movement rAAV recombinant Adeno-Associated Virus REM Rapid Eye Movement ZI Zona incerta Figure 1 In vitro optogenetic activation of MCH neurons. A.- Representative traces showing membrane potentials recorded from a typical mouse MCH neuron (above) and a typical rat MCH neuron (bottom). Note how MCH neurons in both species are silent. B.- Bar graph showing similar resting membrane potential of MCH neurons from mice and rats. C.- Representative traces from rat MCH neurons showing the inward currents evoked by photostimulation of different frequencies under whole-cell voltage-clamp recording with cells held at −60 mV. D.- Representative traces showing the membrane depolarization and action potentials evoked by photostimulation of different frequencies under whole-cell current-clamp recording. Figure 2 Anatomical distribution maps of ChR2-EYFP+ expression in rats. ChR2-EYFP expression was evident across the dorsolateral tuberal hypothalamic area particularly within the zona incerta, perifornical, and lateral hypothalamus. ChR2-EYFP emission signal was less prominent in the medial aspect of hypothalamus. Overall EYFP emission signal spread roughly 1.4 mm along the anteroposterior axis and it was present in both hemispheres. Just above the EYFP emission signal, the blue rectangles indicate the locations of the optic fiber tips. Optic fiber locations were drawn based on the presence of its tracks. The alphanumeric codes on top represent the identification number of the rat whereas the numbers on the far left represent the anterior-posterior distance from bregma. Figure 3 rAAV-MCH-ChR2-EYFP vector successfully transfected MCH neurons. Top panel shows a panoramic view (4×) of the extent of transfection following a bilateral injection of rAAV-MCH-ChR2-EYFP. Confocal laser scanning microscopy indicated a robust expression of the reporter gene EYFP (green) across the lateral hypothalamus (LH), perifornical area (PeF) and the zona incerta (ZI). Middle magnification (20×) views of the PeF area (middle and bottom left panels). ChR2-EYFP signal is abundantly present in many somata but mostly its neuropil (middle left panel). Middle right panel shows that PeF contains many MCH-ir+ neurons. Bottom left panel illustrates the abundance of EYFP and MCH co-labeling. Bottom right panel was taken at 60× and it shows in great detail ChR2-EYFP expression associated to the plasma membrane of the neuron whereas MCH signal is located within the neuron’s cytoplasm. Cell counts were done at 60×. There was a selective expression of EYFP in MCH neurons (97.3± 0.97%), but 52.5 (± 2.0)% of MCH neurons were also EYFP+. Red arrows indicate examples of non-transfected MCH neurons whereas yellow arrows point toward multiple examples of positively transfected MCH neurons. Figure 4 EYFP colocalizes with MCH neurons but not with orexin (ORX) neurons. Confocal microscopy photomicrographs depict renderings of Z-stacks in XYZ planes. Left panel depicts colocalization of ChR2-EYFP in MCH-immunoreactive neurons, and right panel shows colocalization in orexin-ir neurons. Images were taken from sections from the same rat shown in figure 3 (WT38). Representative neurons are identified with arrowheads or arrows. White arrowheads identify double labeled somata (EYFP+MCH), white arrows identify either single MCH-ir (left panels) or ORX-ir (right panels) neurons, and green arrows identify single-labeled EYFP+ neurons. X axis=green line, Y axis=red line, Z=axis=blue line. Scale bars indicate the distance in microns. Figure 5 Effect of optogenetic stimulation of MCH neurons on percent (±SEM) of Wake, NREM sleep and REM sleep. The data summarizes the average percent of wake, NREM sleep and REM sleep during the 12 h period (night or day). Optogenetic stimulation started at lights-off and continued for 24 h (1 min on, 4 min off). *= significance versus 5, 10 or 30Hz within the ChR2 group (p=0.01). $= significance versus 0Hz ChR2 (p<0.02). #= significance versus no ChR2 (p=0.05) (Holm-Sidak post-hoc test after 2-RMANOVA). Figure 6 Time course of changes in wake, NREM sleep and REM sleep during 24 h of optogenetic stimulation. Stimulation started at night (lights-off). Grey horizontal bars at the bottom indicate the lights-off period. Data are 3 h percent (±SEM). *=significance versus 0 Hz (p=0.05; Holm-Sidak post-hoc test). Figure 7 Effects of 24 h of optogenetic activation of MCH neurons on sleep architecture. The first 12 h of stimulation occurred during the lights-off period whereas the second 12 h occurred during the lights-on period. To better visualize differences between treatments the number of waking bouts are expressed as log10 scale. NREMS and REMS bouts numbers are represented as linear scale. *=significance versus 0 Hz at p=0.01. Figure 8 Effect of optogenetic activation of rat MCH neurons on NREMS delta power and REMS theta power. ECoG power was determined only during NREM sleep (delta) or REM sleep (theta). To improve visualization hourly data was pooled in 3 h blocks for delta power and in 6 h for theta power. Gray horizontal bars denote the 12h lights-off, night period. *=significance versus 0 Hz (p=0.01). Conflict of Interests: No conflicts of interest, financial or otherwise are declared by the author(s). 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PMC005xxxxxx/PMC5118153.txt
LICENSE: This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. 7605074 6087 Neuroscience Neuroscience Neuroscience 0306-4522 1873-7544 27746349 5118153 10.1016/j.neuroscience.2016.10.022 NIHMS823004 Article C3 transferase gene therapy for continuous conditional RhoA inhibition Gutekunst Claire-Anne PhD 1cguteku@emory.edu Tung Jack K. PhD 13jtung@emory.edu McDougal Margaret E. 1mmcdoug@emory.edu Gross Robert E. MD, PhD 123rgross@emory.edu 1 Department of Neurosurgery, Emory University School of Medicine, Atlanta, Georgia 2 Department of Neurology, Emory University School of Medicine, Atlanta, Georgia 3 Wallace H. Coulter Department of Biomedical Engineering, Emory University School of Medicine and Georgia Institute of Technology College of Engineering, Atlanta, Georgia Corresponding Authors: Claire-Anne Gutekunst, PhD, Emory University, Department of Neurosurgery, 101 Woodruff Circle, WMB, Suite 6000, Atlanta, GA 30322. cguteku@emory.edu. Robert E. Gross, MD, PhD, Emory University, Department of Neurosurgery, 101 Woodruff Circle, WMB, Suite 6000, Atlanta, GA 30322. rgross@emory.edu 15 10 2016 13 10 2016 17 12 2016 17 12 2017 339 308318 This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. Regrowth inhibitory molecules prevent axon regeneration in the adult mammalian central nervous system (CNS). RhoA, a small GTPase in the Rho family, is a key intracellular switch that mediates the effects of these extracellular regrowth inhibitors. The bacterial enzyme C3-ADP ribosyltransferase (C3) selectively and irreversibly inhibits the activation of RhoA and stimulates axon outgrowth and regeneration. However, effective intracellular delivery of the C3 protein in vivo is limited by poor cell permeability and a short duration of action. To address this, we have developed a gene therapy approach using viral vectors to introduce the C3 gene into neurons or neuronal progenitors. Our vectors deliver C3 in a cell-autonomous (endogenous) or a cell-nonautonomous (secretable/permeable) fashion and promote in vitro process outgrowth on inhibitory chondroitin sulfate proteoglycan substrate. Further conditional control of our vectors was achieved via the addition of a Tet-On system, which allows for transcriptional control with doxycycline administration. These vectors will be crucial tools for promoting continued axonal regeneration after CNS injuries or neurodegenerative diseases. Graphical abstract Introduction The Rho family of small GTPases comprises intracellular molecular switches that play critical roles in regulating diverse cellular processes from cell division and migration to axon outgrowth (Luo, 2000, Stankiewicz and Linseman, 2014). Three Rho GTPases – RhoA, Rac1 and Cdc42 – are central to the regulation of the actin and microtubule cytoskeleton involved in axon growth. In simplified terms, Rac1 regulates lamellipodia formation, Cdc42 regulates filipodia, and RhoA regulates axon retraction (stress fiber formation in non-neural cells). As such, RhoA is a pivotal switch in the axonal response to environmental cues that regulate axon extension versus retraction (Gross et al., 2007). The injured central nervous system (CNS) in the adult contains several types of molecules that inhibit the outgrowth and lead to retraction of axon growth cones, thus contributing to degeneration of fiber pathways and preventing regeneration of CNS pathways after various types of injury. Overcoming inhibitory molecules associated with myelin and the glial scar could greatly improve regeneration in the nervous system (McKerracher and Rosen, 2015). RhoA mediates the effects of diverse extracellular cues present after injury, including the myelin associated inhibitors (e.g. Nogo66), chondroitin sulfate proteoglycans (CSPGs), and some semaphorins that are commonly found in glial scars. Indeed, biochemical blockade of RhoA activity promotes axon growth and increased axon regeneration in the presence of these inhibitory molecules after CNS injury (Niederost et al., 2002, Fu et al., 2007). These promising effects of RhoA blockade are currently being evaluated in human clinical trials for the treatment of spinal cord injury (Fehlings et al., 2011). C3 transferase (C3) is a bacterial exoenzyme that specifically and irreversibly inhibits activation of RhoA by ADP ribosylation. Direct delivery of C3 to neurons has been shown to promote axon outgrowth (Niederost et al., 2002). However, C3 is not cell-permeable so modifications have been made to improve its entry into cells (Winton et al., 2002, Tan et al., 2007). In vivo inhibition of RhoA by direct injection of C3 promotes robust axonal regeneration in the CNS, as demonstrated in models of optic nerve crush (ONC) or spinal cord injuries (SCIs). C3 recombinant protein delivered directly to the injured optic nerve at the crush site allowed processes to extend beyond the lesion site, but was limited by the short period during which injured axon processes could take up the C3 reagent (Lehmann et al., 1999). A single application of a cell-permeable version of recombinant C3, C3-07, resulted in neuroprotection of RGCs for one week, as well as increased outgrowth of RGC axons across an ONC lesion (Bertrand et al., 2005). Additional injections resulted in improved survival and regeneration over a 2 week period over the single injection (Bertrand et al., 2007). Similarly, groups have documented axon regeneration by RhoA inhibition after SCIs. In rats, permeable C3 was delivered to a T7 dorsal -hemisection SCI model resulting in extensive axonal sprouting into the lesion site and scar. Subsequent SCI studies reconfirmed that a single injection of a cell permeable C3 (Cethrin) was detectable in cells 7 days later and blocked SCI – induced RhoA activation and apoptosis for that period (McKerracher and Higuchi, 2006). Further results following permeable C3 (Cethrin) injections into SCI have yet to be reported, but are the subject of a human clinical trial (Fehlings et al., 2011, McKerracher and Anderson, 2013). Although these modifications have increased the versatility of utilizing C3 for RhoA inhibition, these studies indicate that without a continuous source of cell-permeable C3, its cellular actions are limited to a duration of several days, which is likely insufficient for the regeneration of long axon pathways that are commonly damaged in neurodegenerative diseases. To address these limitations, we have generated viral vectors expressing C3 transferase to achieve specific, widespread, long term, and conditional RhoA inactivation. These novel vectors express either an endogenous C3 (eC3) or a secretable/permeable C3 (spC3) fused to the green fluorescent protein (GFP). Borrowing from the genetic nomenclature, we have called these C3 variants cell autonomous eC3 for expression within infected cells, and cell nonautonomous spC3, for an effect beyond the infected cells, respectively. We hypothesize that the latter should be able to affect a greater number of neurons than those infected with the cell autonomous approach. To temporally regulate and reduce any potential risks or side effects of C3 expression, we also developed expression vectors that are regulated by doxycycline (Szulc et al., 2006). As proof of principal, we have tested our transgenes in vitro and shown that C3 expression from both cell autonomous and cell non-autonomous vectors inhibit RhoA activation and promote neurite growth on inhibitory substrates. C3 expression in the rat striatum could also be conditionally controlled by doxycycline treatment with no significant adverse effects on striatal integrity. This novel toolbox of C3 vectors provides a versatile means of inhibiting RhoA in the nervous system and offers a promising translatable therapy for the regeneration of injured CNS pathways. EXPERIMENTAL PROCEDURES Plasmid construction The myc-tagged C3 gene was polymerase chain reaction (PCR) amplified from the pRK5-mycC3 vector generously provided by Dr. Alan Hall (Aktories et al., 1989) and inserted into the multiple cloning site of the pEGFP-N2 plasmid (Clontech, Mountain View, CA), in frame with the amino terminus of enhanced GFP (EGFP) to generate pEGFP-N2-C3 that expresses an endogenous form of C3GFP (eC3GFP). Next, a vector that expresses a secretable and permeable form of C3GFP was generated. Overlapping primers containing the DNA sequence for the synthetically modified trans-acting activator of transcription (TATκ) permeability peptide were PCR amplified and inserted at the amino terminus of C3GFP to create pEGFP-N2-TATκC3 (Tunnemann et al., 2006). The cassette containing TATκC3GFP was then PCR amplified and inserted into the multiple cloning site of the pSecTag2 Hygro A plasmid (Invitrogen) to add an immunoglobulin K (IgK) peptide signal sequence to the N-terminus of TATκC3GFP, thus allowing for the secretion of TATκC3GFP (spC3GFP) into the extracellular milieu. A control IgK-TATκGFP (spGFP) cassette was generated in the same fashion. The cassettes containing eGFP, eC3GFP, spGFP and spC3GFP were subsequently cloned into the FUGW lentiviral and the pAAV backbone plasmids for production of 2nd generation lentivirus and adeno-associated serotype 2 virus (AAV2), respectively. Cell culture Human embryonic kidney (HEK) 293T cells and NIH3T3 cells were both maintained in a humidified 5% CO2 atmosphere at 37°C in complete medium consisting of Dulbecco’s Modified Eagle’s medium (DMEM) supplemented with 10% fetal bovine serum, 2 mM L-glutamine, 100 international units (IU)/ml penicillin, and 100 μg/ml streptomycin. Western Blot (WB) Transient transfections were carried out with the Lipofectamine 2000 reagent (Invitrogen). HEK293 cells were seeded in 6-well plates at 2×105 cells per well, grown for 24 hours (hr) and then incubated for 16hr with 1 ml of serum-free medium containing 2.5 μg of plasmid and 5 μl of Lipofectamine 2000 (Invitrogen, Carlsbad, CA). After incubation for 16hr, the medium was replaced by fresh medium containing 10% fetal calf serum for 24hr. Cell extracts were prepared in lysis buffer (Promega, Madison, WI) and protein concentration was determined using a bicinchoninic acid protein assay kit (ThermoFisher Scientific, Waltham, MA). Samples were subjected to sodium dodecyl sulfate polyacrylamide gel electrophoresis (SDS-PAGE) and transferred to a nitrocellulose membrane. The membrane was blocked and incubated with either rabbit anti-C3 (generously provided by Dr. Lisa McKerracher, Bioaxone, Cambridge, MA (Winton et al., 2002)) or rabbit anti-GFP antibody (Clontech, Mountain View, CA) followed by a donkey anti-rabbit DyLight 800 secondary antibody (Pierce, ThermoFisher Scientific, Waltham, MA). Infrared (IR) detection was performed on an Odyssey IR scanner (Li-cor Biotechnology, Lincoln, NE). Rhotekin assay NIH3T3 cells were seeded in 10 cm dishes at 5×105 cells per plate and transfected as described above. NIH3T3 cells were incubated with permeable C3 (2 μg/ml for 4hr, Cytoskeleton Inc.), or dimethyl sulfoxide (DMSO). The next day, the effect of C3 expression on RhoA activation was measured using a pull down assay performed according to the manufacturer’s recommendations (Cytoskeleton Inc., Denver, CO). Briefly, cells were rinsed with ice-cold phosphate buffer solution (PBS), and then 250 μl of ice-cold 1X lysis/wash buffer was added. Lysates were cleared by centrifugation for 10 minutes. An aliquot of lysate was collected for measuring the total amount of Rho protein. The remaining lysate was added to Rhotekin agarose beads and incubated on ice for 45 minutes and washed three times. Beads and total Rho samples were then subjected to SDS-PAGE and transferred to a nitrocellulose membrane. The membrane was blocked and incubated with anti-Rho antibody followed by a DyLight 680 secondary antibody. IR detection was again performed on an Odyssey IR scanner (Li-cor Biotechnology, Lincoln, NE). Lentiviral vector production The FUGW and pLVUT-tTR-KRAB (pLVUT) backbones were obtained from Addgene (plasmids 14883 and 11651, respectively). FUGW is a 3rd generation lentiviral plasmid using the human Ubiquitin C (hUbC) promoter to drive enhanced GFP expression (Lois et al., 2002). pLVUT is a Tet-regulated (Tet-on) lentiviral vector for transgene expression under hUbC promoter control and a woodchuck hepatitis virus posttranscriptional regulatory element (WPRE) (Szulc et al., 2006). Lentivirus were produced in-house based on methods described by Dr. Didier Trono (Barde et al., 2010). In brief, HEK293FT cells were grown in multiple 10 cm cell culture dishes to 90% confluency on the day of transfection. Each dish was then transfected with 7.5 μg Δ8.9 packaging vector, 3 μg VSVG envelope vector, and 10 μg of the transfer vector by calcium phosphate precipitation. Transfection efficiency was confirmed the following day by fluorescence microscopy and lentivirus was subsequently harvested for 2 days following transfection. The harvested lentivirus was purified through a 0.45 μM polyethersulfone (PES) filter and concentrated by ultracentrifugation with a 20% sucrose cushion to an approximate titer of 108–1010 infectious particles/ml. AAV viral vector production The AAV backbone with a chicken β-actin (CBA) promoter and WPRE was generously provided by Dr. Michael G. Kaplitt, Weill Cornell Medical Center, New York, NY. Stock of AAV serotype 2 expressing GFP (AAV-eGFP) was obtained from the University of North Carolina Vector Core (www.med.unc.edu/genetherapy/vectorcore). The laboratory of Dr. Michael G. Kaplitt prepared virus stocks for AAV-eC3GFP, AAV-spGFP and AAV-spC3GFP. Briefly, vector plasmids were packaged into AAV2 particles using a helper-free plasmid transfection system. The vectors were purified by heparin affinity chromatography and dialyzed against PBS. AAV titers were determined by quantitative PCR using primers to a fragment of the AAV backbone and adjusted to 1012 genomic particles per ml (Sondhi et al., 2012). Dot blot Dot blot assay was used to confirm the secretion of spGFP and spC3GFP. HEK293T cells were plated in 10 cm dishes and transfected as described. After several days in culture, cells were incubated overnight in unsupplemented DMEM. The next day, media was collected and concentrated using Amicon Ultra centrifugal filters (EDM Millipore, Billerica, MA). Concentrated samples were then bound to nitrocellulose membrane. The membrane was blocked and incubated with a rabbit polyclonal anti-GFP antibody (632460, Clontech, Mountain View, CA) followed by a donkey anti-rabbit DyLight 800 secondary antibody (Rockland, Limerick, PA). Again, IR detection was performed on an Odyssey IR scanner (Li-cor Biotechnology, Lincoln, NE). spC3 functional assay HEK293 cells were plated in a 6 well tray and transfected as described above with spC3GFP or DsRed2 expressing plasmids. Ten hours later, media was changed and DsRed2 expressing cells were passaged and transferred to a well containing either spC3GFP transfected cells or no cells. After 48 hr, the effect of spC3 on process outgrowth of the DsRed2 expressing cells was evaluated by fluorescence microscopy. CSPG spot assay Spots were prepared by placing six 2 μl droplets of Neurobasal media containing mixed CSPGs (50 μg/ml; CC117, EDM Millipore, Billerica, MA) and laminin (5 μg/ml; 23017-015, Invitrogen, Carlsbad, CA) onto poly-L-lysine (PLL) (20 μg/ml; P9155, Sigma-Aldrich, St Louis, MO) pretreated glass coverslips and allowed to dry completely. Rhodamine was added to the droplets at 1 μg/ml to help visualize the permissive/repulsive interface. Cortical neurons were dissociated from rat embryos at day 18 (E18) as described previously (Gutekunst et al., 2003). Neurons were plated on pre-coated coverslips and transduced with control or C3 expressing viruses. Five days post transduction cells were fixed with 4% paraformaldehyde and coverslipped with Vectashield mounting media (Vector Laboratories, Burlingame, CA) and visualized using a Leica DMREI fluorescent microscope equipped with a QImaging Retiga EXi camera and Simple PCI acquisition software. Expression of the GFP reporter was visible starting 3 days post infection. Twelve and eleven micrographs along the interface between PLL/CSPG were taken at random for eGFP and eC3GF infected cultures respectively, and the number of processes crossing the PLL/CSPG interface counted for each micrograph. For statistical analysis, the mean number of crosses were compared using a Student t-test independent sample, one tail, two sample equal variance with alpha (α)=0.05. Process outgrowth Mouse primary cortical neurons were dissociated and plated in 8-well slide chambers (3 chambers/viral vector) precoated with CSPGs (50 μg/ml; EDM Millipore, Billerica, MA) onto PLL (20 μg/ml) and infected with control or C3 expressing AAV2 at 1010 particles/ml. Three days post infection cells were fixed 4% paraformaldehyde and immunostained using mouse monoclonal anti-acetylated tubulin antibodies (T7451 at 1:500, Sigma-Aldrich, St Louis, MO). Cells were permeabilized in 0.01% Triton-X100 (Sigma-Aldrich, St Louis, MO) in PBS. Length of primary and secondary processes was assessed using free software ImageJ/NeuronJ (NIH) (Schneider et al., 2012). In this study a primary process is defined as directly extending from the cell body, while a secondary process is defined as a branch off the primary. Data are representative of a culture for which each vector was tested in triplicates and primary and secondary processes for 20, 19, and 31 neurons were used for analysis for eGFP, eC3GFP, and spC3GFP, respectively. For statistical analysis, a mixed linear model was used to estimate the means and variances (within- and -between neuron) for ln length (natural log) of the primary processes for each type of expression (eGFP, eC3GFP, and spC3GFP) using the SAS MIXED Procedure. A compound-symmetric variance-covariance form was assumed for the outcome and estimates of the standard errors of parameters were used to perform statistical tests and construct 95% confidence intervals (Diggle et al., 1994). The model-based means are unbiased with unbalanced and missing data, so long as the missing data are non-informative (missing at random). Since a significant overall difference was detected between the 3 types of expression, t-tests were used to compare the differences between the 3 model-based means for expression. The specific statistical tests were done within the framework of the mixed effects linear model. All statistical tests were 2-sided and unadjusted for multiple comparisons. A value of P < 0.05 indicated statistical significance for the overall expression effect. Length are reported as means along with 95% confidence intervals (CI). Similar analyses were performed for secondary processes and for longest length of primary and secondary processes. Immunocytochemistry HEK293T cells were prepared in 6-well plates (as described for WB) and infected with control or C3 expressing AAV vectors (final concentration 109 particles/ml). Three days post transduction, cells were fixed in 4% paraformaldehyde (PFA) in PBS for 15 min and processed for immunocytochemistry (ICC) using rabbit anti-C3 antibodies. Briefly, cells were permeabilized with 0.01% Triton X-100 in PBS for 5 min, (Sigma-Aldrich, St Louis, MO) in PBS for 5 min, blocked in 4% normal donkey serum (NDS, Jackson ImmunoResearch Laboratories, West Grove PA) for 30 min and incubated with rabbit anti-C3 antibodies (5 μg/ml) in 2% NDS in PBS overnight. After several washes, the cells were incubated in Alexa 594 donkey anti-rabbit secondary antibodies (Invitrogen) in PBS for 1hr. Cells were imaged using an inverted Leica DMIRE2 scope equipped with a QImaging Retiga EXi camera and Simple PCI acquisition software. The captured images were stored and processed using Adobe Photoshop software. In vivo viral vector injection Adult male Sprague Dawley rats (200–280gm, Charles River Laboratories) were housed in the Emory animal vivarium with a 12hr light/12hr dark cycle and ad libitum access to food and water. All procedures were conducted in accordance with approved guidelines from the Emory University Institutional Animal Care and Use Committee. Animals received bilateral injections of either LV-eGFP (n=3), LV-eC3GFp (n=3) or LV-spC3GFP (n=3) at 1010 viral particles/ml. Virus were injected (1 μl and 3μl on each side, respectively) using a pulled glass pipette connected to a Nanoject (Drummond Scientific, Bromall, PA) at 280 nl/min at the following stereotactic coordinates: at Bregma; ± 3 mm lateral to midline; 5.2 mm below dura. Starting 5 days post-injection, rats were randomly assigned to drink either sugar water or doxycycline supplemented sugar water (Szulc et al., 2006). For rat experiments, we added 0.2 g/l doxycycline (D3447, Sigma-Aldrich, St Louis, MO) and 5% sucrose into drinking water. The sugar was added to mask the bitterness of the doxycycline. Immunohistochemistry and double immunofluoresence After two weeks rats were deeply anesthetized with a lethal dose of Euthasol (130 mg/kg), injected intraperitoneally, and then perfused intracardially with 0.9% NaCl, followed by 4% PFA in 0.1 M PBS at pH 7.2 (PB) for 15 min at a rate of 20 ml per min. Brains were removed and cryoprotected in 30% sucrose at 4°C, sectioned in coronal plane at 50 μm thickness using a freezing microtome, collected and rinsed in 0.1 M PBS, pH 7.2. Immunohistochemistry was performed as described previously (Gutekunst et al., 1995, Gutekunst et al., 2010). Free-floating sections were incubated in 0.1% TritonX-100 and 3% hydrogen peroxide to eliminate endogenous peroxidase, rinsed in PBS, and preblocked in 4% normal goat serum (NGS) in PBS for 30 min at room temperature (RT). Sections were incubated in rabbit anti-GFP antibodies (2555, Cell Signaling Technology, Beverly, MA) in PBS containing 2% NGS at 4°C for 48hr, then rinsed and incubated for 1hr at RT in biotinylated anti-rabbit antibody (ABC Elite; Vector Laboratories, Burlingame, CA) in PBS containing 2% NGS. After several rinses in PBS, the sections were incubated in avidin-biotin complex (ABC Elite; Vector) for 90 min at 4°C. Immunoreactivity was visualized by incubation in 0.05% 3,3′-diaminobenzidine tetrahydrochloride (DAB; Sigma, St. Louis, MO) and 0.01% hydrogen peroxide in PBS, until a dark brown reaction product was evident (5–10 min). Sections were rinsed and mounted on glass slides, air dried and coverslipped. Sections were visualized using either a Nikon eclipse E400 microscope and images captured using a color digital camera (Nikon Instruments Inc, Melville, NY). Double immunofluorescence was used to co-localize C3 and KRAB as previously described (Gutekunst et al., 2012). Free-floating striatal sections were rinsed in PBS, blocked in 5% NDS and 0.1% Triton-X for 30 min at RT and rinsed in PBS. After rinses in PBS, sections were incubated overnight at 4°C in mouse anti-GFP and rabbit anti-KRAB (AB72609, Abcam, Cambridge, MA) in PBS containing 1% NDS. Sections were rinsed in PBS and incubated in Alexa Fluor 594 conjugated donkey anti-rabbit (Jackson Immunoresearch Laboratories, West grove, PA) and Alexa Fluor 488 conjugated donkey anti-mouse (Jackson Immunoresearch Laboratories, West grove, PA) secondary antibody in 1% NDS for 1hr at RT. Sections were rinsed with PBS, then mounted on glass slides with hard set Vectashield mounting medium (Vector Laboratories, Burlingame, CA). Sections were visualized using either a Nikon eclipse E400 microscope equipped with 4 fluorescent cubes, a monochrome and color digital camera and Nikon BR software (Nikon Instruments Inc, Melville, NY). Immunofluorescence was also used to quantify brain response to C3 expression. Free floating sections were stained by immunofluorescence using mouse anti-glial fibrillary acidic protein (GFAP; G3893, Sigma-Aldrich, St. Louis, MO) or mouse anti-rat CD11b/c (OX42, 554859, Pharmingen, SanDiego, CA), followed by an Alexa Fluor 594 conjugated donkey antimouse (Jackson Immunoresearch Laboratories, West grove, PA) secondary antibody. Sections were mounted on glass slides with hard set Vectashield mounting medium (Vector Laboratories, Burlingame, CA). For each animal, an image was taken at the level of the injection site and GFAP and OX42 immunofluorescence intensity was assessed in 4 random windows per image using free software ImageJ/NeuronJ (NIH) (Schneider et al., 2012). For statistical analysis, mean intensity levels were compared between groups mixed model as described previously. RESULTS Development of an endogenous C3GFP (eC3GFP) cassette To generate a vector co-expressing C3 and GFP as a fusion protein (C3GFP), the C3 cDNA was PCR amplified and inserted into the cloning site of the pEGFP-N2 plasmid encoding an enhanced GFP (EGFP) variant that has been optimized for brighter fluorescence and higher expression in mammals (Di Polo et al., 1998, Harvey et al., 2009, Hellstrom et al., 2009). Transfected HEK293T cells expressed a band at ~ 60 kDa only in pEGFP-N2-C3 transfected cells, corresponding to the added molecular weights of EGFP and C3, confirming proper expression of the fusion protein (Figure 1A). The effectiveness of the C3GFP cassette in reducing RhoA activation was assessed with a Rhotekin RhoA activation assay. NIH3T3 cells, which are commonly used in Rho activation assays (Zheng et al., 2009), were treated with permeable C3/DMSO, DMSO alone, or transfected with either pEGFP-N2 or pEGFP-N2-C3. Cell lysates were incubated with beads coated with the Rho binding domain (RBD) of the Rho effector protein, Rhotekin, which shows high affinity for GTP-RhoA, and the Rhotekin- RBD/GTP-RhoA complexes bound to the beads were immunoprecipitated with RhoA antibodies; total RhoA (GTP- and GDP- bound) levels were assessed in the absence of immunoprecipitation. As expected, there were equal amounts of total RhoA across samples but decreased levels of active RhoA (RhoA-GTP) in C3 treated and pEGFP-N2-C3 transfected cells as compared to untreated cells and cells transfected with endogenous GFP control (pEGFP-N2) (Figure 1B). Functional cassettes were then moved into an AAV backbone and viral vectors were generated. C3 was only seen in cells transfected with pEGFP-N2-C3 (Figure 1C). Both GFP and C3GFP were present in the cytoplasm, filling the soma and processes consistent with endogenous and cytoplasmic protein expression (Figure 1C). eC3GFP promotes crossing at PLL/CSPG interface To confirm the functionality of C3 in the C3GFP fusion protein we used a CSPG spot assay and analyzed the effect of C3 expression on the growth of neuronal processes as they encounter an inhibitory substrate interface. CSPG is a key component of glial scars and a known potent inhibitor of axon regeneration (Fawcett and Asher, 1999, Sandvig et al., 2004, Silver and Miller, 2004, Wang et al., 2008). An interface between PLL and CSPG was created by placing CSPG/laminin-Rhodamine (CSPG-Rhod) or laminin-Rhodamine (Rhod) drops onto laminin coated glass coverslips. Rhodamine was used to visualize the interface and also served as a negative control. Primary dissociated rat E18 cortical neurons were plated on PLL/laminin with a CSPG drop in the center, and after 3 days infected with either eGFP or eC3GFP-expressing AAV. After 5 days most of the processes in cultures infected with eGFP-expressing vector turned at the PLL/CSPG interface, rarely crossing over to the CSPG side. In contrast, processes in cultures transduced with eC3GFP crossed the interface and extended onto the CSPG drop (Figure 2A). The mean number of crosses was 7 times greater in eC3GFP infected cultures compared to eGFP controls (Figure 2B) (Student t-test: t=3.882, df=21, p=0.004). Development of a secretable/permeable C3GFP (spC3GFP) cassette The functional eC3GFP cassette was then used to generate a vector that expresses a secreted and permeable form of C3GFP (spC3GFP). The synthetically modified trans-acting activator of transcription (TATκ) protein transduction domain from human immunodeficiency virus type 1 was used as a permeability tag (Tunnemann et al., 2006). TATκ is a commonly used transport peptide and has proven effective at transporting cargo to both the cytosol and the nucleus (Fawell et al., 1994, Vives et al., 1997, Schwarze et al., 1999, Flinterman et al., 2009). A secretable IgK signal peptide was then added to the amino terminus of TATκC3GFP using the pSecTag2 plasmid. C3 antibodies detected appropriately sized (~ 70 kDa) spC3GFP fusion proteins only in HEK293 cells transfected with pSecTag2-TATκ-C3GFP (Figure 3A). The IgK- TATκ-C3GFP cassette was subsequently moved into an AAV backbone; transfection of HEK293T cells with AAV-spC3GFP resulted in expression of spC3GFP, which appeared punctated as expected for secreted proteins (Figure 3B). Proper processing and secretion of spC3GFP was confirmed with a dot blot assay performed on media collected from transfected HEK293 cells (Figure 3C). GFP antibodies detected transgene expression only in the media of spC3GFP-transfected cells with no signal detected in the media of non-transfected cells or cells transfected with endogenous GFP or C3GFP (Figure 3C). The functional property of spC3GFP was also confirmed by culturing HEK293 cells expressing DsRed2 (as a marker) either alone or together with HEK293 cells that had been previously transfected to express spC3GFP. When co-cultured with spC3GFP expressing cells, DsRed-HEK293 cells developed long processes compared to when cultured alone (Figure 3D). The permeable property of the transgenes is again further characterized in a subsequent in vivo experiment (described below). eC3GFP and spC3GFP promote process outgrowth on CSPG substrate C3 transferase promotes growth of processes on inhibitory substrates. To confirm the functionality of endogenous and secretable/permeable C3GFP cassettes we assessed the growth of processes of cortical neurons growing on CSPG substrate. Primary cortical neurons were plated on CSPG substrate and infected with either eGFP-, eC3GFP- or spC3GFP-expressing AAV vectors. After 3 days, GFP was visible in neurons and cultures were immunostained with tubulin antibodies to visualize and measure primary and secondary processes (Figure 4). The average length of the primary processes was significantly increased in cultures expressing eC3GFP and spC3GFP compared to control cultures only expressing eGFP (p<0.05, t-tests). Whereas the mean length of primary processes in control cultures was 47.8 μm 95% CI (36.7, 58.8), the average length was 62.5 μm 95% CI (50, 75) and 96.4 μm 95% CI (79.8, 113.1) for eC3GFP and spC3GFp infected cultures respectively (Figure 4B). The effect of spC3GFP was significantly stronger than that of eC3GFP (p<0.005, t-test) and the average length of primary processes of spC3GFP cultures was twice as long than in the control cultures (p<0.001, t-test). When considering only the longest primary process for each neuron examined, eGFP and eC3GFP had similar longest primary processes (159 μm and 153 μm respectively), whereas the mean longest primary process of neurons in cultures infected with spC3GFP was significantly longer at 242.8 μm 95% CI (198.4, 287.1) (p<0.05, t-test) (Figure 4C). Unlike spC3GFP, eC3GFP also had a significant effect in increasing the average length of secondary processes compared to eGFP control (Figure 4B). The average length of secondary processes was 25.6 μm, 95% CI (21.1, 30) for eGFP, 21.4 μm, 95% CI (17.4, 25.3) for eC3GFP, compared to 31.5 μm, 95% CI (27.4, 35.6) for spC3GFP (p<0.05, t-test). The longest secondary processes were also significantly longer in spC3GFP infected cultures compared to control eGFP but not eC3GFP with an average length of 77.0 μm, 95% CI (59.5,94,5) (p<0.05, t-test), 46.1 μm, 95% CI (27.9,64.3) and 52.5 μm, 95% CI (28.8, 76.22) respectively (Figure 4C). In vivo expression of tet-on conditional eC3GFP and spC3GFP To validate in vivo expression, the eGFP, eC3GFP, and spC3GFP cassettes were moved into the tet-on lentiviral plasmid pLVUT for the production of inducible lentiviral vectors (LV). One of the advantages of using pLVUT is its drug-inducible design, which allows control of gene expression in mammalian cells (Szulc et al., 2006). In the absence of doxycycline, the Kruppel associated box (KRAB) transcriptional repressor binds to a tetracycline operator (tetO) and suppresses the expression of the transgene. Upon the addition of doxycycline, the suppression is released (Szulc et al., 2006). The incorporation of such controls in C3 gene therapy would ensure that C3 expression is turned on only during the desired time frame for regeneration. In addition, cells infected with pLVUT express KRAB constitutively (Groner et al., 2012). As such, KRAB can be used as a marker of expression and, for the purposes of this study, can be used to differentiate LV-spC3GFP-infected cells from those surrounding cells that have taken up the secreted and permeable C3GFP in the absence of cell-autonomous expression. Following injections of either LV-eGFP, LV-eC3GFP or LV-spC3GFP in the striatum, half of the rats received doxycycline-supplemented drinking water for 14 consecutive days. GFP expression was visible only in those animals that had received doxycycline-supplemented water (Figure 5A a–f). GFP immunohistochemistry confirmed GFP expression in cell bodies and processes and uncovered more GFP+ cells and processes than were visible by direct GFP visualization (Figure 5A j–l). More GFP was present in the neuropil of spC3GFP injected striatum (Figure 5A i) compared to eGFP and eC3GFP (Figure 5A g and h). GFP was found in all striatal neuronal cell types including DARPP-32+ medium spiny neurons and large ChAT+ cholinergic interneurons (data not shown). As expected with lentivirus, there was no detectable infection of glial cells. To further confirm the permeable aspect of secreted spC3GFP, striatal sections from rats injected with spC3GFP were stained for KRAB and GFP (Figure 5B). KRAB immunostaining is visible in the nuclei of many GFP+ cells, but in addition a number of cells positive for GFP but negative for KRAB (Figure 5B) were seen; the latter are most likely cells that are not infected but have taken up the secreted and permeable C3GFP in a cell-nonautonomous manner. The response of glial cells to C3 expression was also examined. Sections with comparable infection with GFP, eC3GFP or spC3GFP expression (confirmed by GFP ICC on adjacent sections) showed no difference in GFAP (reactive astrocytes) or OX42 (microglia) immunoreactivity (Figure 5C), early evidence of absence of inflammation. DISCUSSION In the present study we describe the development and validation of several viral vectors for long term and regulated expression of C3 transferase. We designed our first vector to express an endogenous form of full-length C3 transferase fused to GFP. There are only two other studies for which viral vectors have been developed to express C3 transferase. In both studies vectors were engineered to express C3 and GFP separated by an internal ribosomal entry site (IRES) (Fischer et al., 2004, Liu et al., 2005). In addition, for one of the vectors, a sequence encoding the first 10 amino acids of GAP-43 was added to the amino terminus of C3 to target its localization to the cell membrane (Fischer et al., 2004). Similar to our construct, these vectors express an endogenous form of full-length C3 transferase. However, in our design C3 and GFP are combined as a single fusion protein where GFP can be used as a direct reporter of not only infected cells but also the localization and potential site(s) of action of C3 transferase within the cell compartments. Conversely, with an IRES sequence, GFP can only report which cells have been transduced, and the precise location of C3 requires further manipulation such as immunohistochemistry. Consistent with previous studies, transfection with eC3GFP induced RhoA inhibition, which led to the reorganization of the cytoskeleton and process growth indicating that fusing GFP to C3 did not affect the activity of C3 transferase. Similarly, AAVeC3GFP was able to promote the growth of processes on an inhibitory substrate. This vector can be used as a gene therapy when aiming at inactivating RhoA within a specific cell population. The virus can be injected directly into the CNS or applied to tissue or cells prior to implantation. Although in the present form the construct utilizes the strong ubiquitous chicken β-actin promoter for fast expression with relatively high levels, more specific promoters and/or viral serotypes can be explored to obtain cell type specificity. One limitation of the eC3GFP and the two previously developed vectors is that the transgenes are expressed as cytoplasmic proteins, therefore limiting the effect of C3 to only cells that are transduced. To enable a more widespread distribution of C3, we designed our second vector to express a secretable/permeable form of full-length C3 transferase fused to GFP. In this approach, a cell non-autonomous spC3GFP cassette was engineered so that cells adjacent to those constitutively expressing C3 can also benefit from its effect. To our knowledge, this is the first development of a secretable/permeable C3 expression system. Similar to eC3GFP, spC3GFP promoted growth of processes on inhibitory substrate but showed an enhanced effect compared to eC3GFP, with 25% and 40% longer growth of primary and secondary processes, respectively. This novel vector can be used as a therapeutic approach when RhoA inhibition is needed in a large population of cells or when the cells needing treatment are too fragile to transduce or perhaps unable to express high levels of transgene. For example, instead of infecting degenerating neurons, a virus could be targeted at the healthy adjacent cells (i.e. different neuronal subtype or glia). Again, specific promoters and/or serotypes would be incorporated in the vector design to achieve specificity. It has been suggested that C3 may increase the glial inflammatory response post injury (Holtje et al., 2005, Hoffmann et al., 2008), an effect that may intensify with longer-term expression, which distinguishes our experiments from others with short-term direct C3 delivery. In this case, the spC3GFP vector design, which allows for a more widespread distribution of C3, could have deleterious side effects. With this in mind, we developed a third vector designed with a controllable system. Such an approach might maximize effectiveness vs. toxicity and can be used to identify the optimal interval for expression via dose and time–response curves with doxycycline. In addition, KRAB-mediated repression eliminates the leaky, nonspecific expression seen in other conditional systems based on transactivation (Szulc et al., 2006). Of note, this study found that the C3-expressing vectors did not appear to induce any glial response when injected directly into a healthy rat brain. Further studies need to be done to determine their effect in the context of an injury model. Virally mediated C3 expression can significantly reduce RhoA activation and represents a novel gene therapy approach that could be used alone or in conjunction with other therapies to promote axon regrowth in neurodegenerative disorders or injuries of the CNS. To validate the functionality of the eC3GFP and spC3GFP in vivo, the vectors are currently being tested in a rat optic nerve crush (ONC) model. The optic nerve offers several advantages for testing new approaches for CNS regeneration (Vidal-Sanz et al., 1987, Villegas-Perez et al., 1993, Berry et al., 1996, Fournier et al., 2003). Injured optic nerves were treated via intravitreous injection of AAV2-eC3GFP or AAV2-spC3GFP. Both vectors increased RGC survival and axon regeneration compared to controls up to 8 weeks post-injury (submitted). In summary, these new vectors are promising therapeutic approaches to regenerating and protecting neurons after CNS injury or neurodegenerative diseases. Depending on the need, they can be injected directly into the injured tissue to reverse the degenerative process or transduced to stem cells for cell replacement therapies. Further work is underway to test these vectors in other in vivo settings including implantation of ex-vivo infected neurons. We thank Elizabeth Jackson for her help with viral production and cell culture assays, Patty Murphy, Olga Laur, and Samantha Neumann for helping with vector construction, and Joseph Mertz for his help with viral injections and immunohistochemistry. We also thank Dr. Kirk Easley, MApStat, for help with statistical analysis. GRANT SUPPORT Supported by a National Institutes of Health grant 1R03NS091699-01 (CAG and REG) Supported by the National Center for Advancing Translational Sciences of the National Institutes of Health under Award Number UL1TR000454. The content is solely the responsibility of the authors and does not necessarily represent the official views of the National Institutes of Health. (CAG and REG) Supported by the Emory University Research Committee (REG) Neurosurgery Research and Education Foundation via a Medical Student Summer Research Fellowship award (MEM) Viral Vector Core of the Emory Neuroscience NINDS Core Facilities grant, P30NS055077. The funding sources had no involvement in the study design, collection, analysis and interpretation, nor in the writing or the decision to submit this manuscript. Abbreviations AAV2 adeno-associated serotype 2 virus CNS central nervous system C3 C3 transferase CBA chicken β-actin CSPGs chondroitin sulfate proteoglycans DMEM Dulbecco’s Modified Eagle’s medium eC3 endogenous C3 EGFP enhanced GFP HEK Human embryonic kidney ICC immunocytochemistry ONC optic nerve crush SCIs spinal cord injuries KRAB Kruppel-associated box LV lentiviral vectors NGS normal goat serum NDS normal donkey serum PLL poly-L-lysine PCR polymerase chain reaction spC3 secretable/permeable C3 TATκ trans-acting activator of transcription Tet-on Tet-regulated hUbC Ubiquitin C WPRE woodchuck hepatitis virus posttranscriptional regulatory element Figure 1 Development of an endogenous C3GFP (eC3GFP) cassette A) Western blot of cell lysates from HEK293T cells transiently transfected with pEGFP-N2 and pEGPF-N2-C3 and stained with C3 antibodies. A band is visible in the pEGFP-N2-C3 transfected cells only. Molecular weight in KDa. B) Western-blot analysis of RhoA activity obtained from lysates of untreated NIH3T3 cells of cells pretreated as indicated. Active RhoA (aRhoA) fraction was isolated from freshly prepared NIH3T3 lysates using GST-Rhotekin-RBD beads following the manufacturer’s protocol (upper blot). The total RhoA (tRhoA) levels were determined in all lysates (lower blot). Xfect: transfected with. C) Micrographs of HEK293T cells infected with AAV2-eGFP or eC3GFP (green) as indicated and stained with C3 antibodies (red). Nuclei are stained with DAPI (blue). Scale bar: C) 10 μm. Figure 2 eC3GFP promotes crossing at PLL/CSPG interface A) Micrographs of neurons plated on coverslips showing the behavior of neurites at the PLL/CSPG interface. Rhodamine (red) was used to identify the CSPG drop. B) Graph of Average number of neurites crossing the PLL/CSPG interface + SEM. Scale bar A) 100 μm. *** p<0.05, Student t-test. Figure 3 Development of a secretable/permeable C3GFP (spC3GFP) cassette A) Western blot of cell lysates from HEK293T cells transiently transfected with pSecTag2 and pSecTag2- TATkC3GFP and stained with C3 antibodies. A band is visible in the pSecTag2-TATkC3GFP transfected cells only. Arrow head shows the molecular weight for pEGFP-N2-C3. Molecular weight in KDa. B) Micrographs of HEK293T cells infected with AAV2-spC3GFP (green) and stained with C3 antibodies (red). Nuclei are stained with DAPI (blue). C) Dot blots of concentrated media from HEK293T cells transiently transfected with pEGFP-N2 (eGFP), pEGPF-N2-C3 (eC3GFP) or pSecTag2-TATkC3GFP (spC3GFP) as indicated and stained with GFP antibodies. D) Micrographs of DsRed2-HEK293 cells growing alone (a–c) or in culture with spC3GFP expressing cells (d–f). DsRed2 fluorescence is shown in grey scale. Extensive processes (arrows) are seen in the cell in co-cultured. Scale bar: B) 10 μm, D) 100 μm, Figure 4 eC3GFP and spC3GFP promote process outgrowth on CSPG substrate A) Micrographs of neurons infected with AAV-eGFP, AAV-eC3GFP or AAV-spC3GFP plated on CSPG coated coverslips and stained with tubulin (red) for neurite length measurement analysis. B) Box and whisker plot showing length of primary and secondary processes with box quartiles (25–75%) and whiskers marking the 5–95% CI C) Box and whisker plot showing length of longest primary and secondary process with box quartiles and (25–75%) and whiskers marking the 5–95% CI. Scale bar: A) 100 μm. Statistics: * P<0.05, ** p<0.01, *** p<0.001, t-test. Figure 5 Conditional expression of eC3GFP and spC3GFP in rat striatum A) Micrographs of brain sections through the striatum of rats injected with LV-eGFP (a, d, g, j), LV-eC3GFP (b, e, h, k) or LV-spC3GFP (c, f, i, l) and subsequently given ad lib drinking sugar water unsupplemented (a–c) or supplemented (d–i) with doxycycline (Dox). Sections were stained for GFP (a–i) and DAB reaction product is seen in gray (a–f) or brown (g–i). At higher magnification (g–i), DAB reaction product is visible in neuronal cell bodies (g–i), neurite (g–i), and neuropil (i). GFP fluorescence can also be seen in unstained sections (j–l). DAPI (blue) is used as a nuclear marker. B) Micrographs of brain section of the striatum of an LV-spC3GFP injected rat immunostained for KRAB (red). GFP is visible in infected KRAB+ neurons (arrows) as well as non-infected KRAB− neurons (arrowheads). Panel a and b show composite images whereas panels c and d show spC3GFP and KRAB ICC respectively. C) Micrographs of brain section through the striatum of LV-spC3GFP injected rats receiving Dox or No Dox in their drinking water immunostained for GFAP or OX42 (red). Box and whisker plots showing intensity level of GFAP and OX2 with OX42 in the striatum of rats injected with LV-eGFP, LV-eC3GFP or LV-spC3GFP as indicated with box quartiles (25–75%) and whiskers marking the 5–95% CI. Scale bars: A) a–f: 0.3 mm, g–l: 20 μm; B) a: 20 μm, b–d: 10 μm. Author Contributions: Conception and design: Gutekunst, Gross Data collection: Gutekunst, Tung, McDougal Analysis and interpretation: Gutekunst, Tung, McDougal Manuscript Preparation: Gutekunst, Tung, McDougal, Gross This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final citable form. Please note that during the production process errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain. 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PMC005xxxxxx/PMC5118174.txt
LICENSE: This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. 7605074 6087 Neuroscience Neuroscience Neuroscience 0306-4522 1873-7544 27746346 5118174 10.1016/j.neuroscience.2016.10.013 NIHMS827286 Article Elevated Levels of Calcitonin Gene-Related Peptide in Upper Spinal Cord Promotes Sensitization of Primary Trigeminal Nociceptive Neurons Cornelison Lauren E. MS Hawkins Jordan L. MS Durham Paul L. PhD Center for Biomedical and Life Sciences, Missouri State University, Springfield, MO USA Corresponding Author: Paul L. Durham, PhD, Distinguished Professor, Director, Center for Biomedical & Life Sciences, Missouri State University, Springfield, MO USA, Phone: 417-836-4869, Fax: 417-836-7602, pauldurham@missouristate.edu 5 11 2016 13 10 2016 17 12 2016 17 12 2017 339 491501 This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. Orofacial pain conditions including temporomandibular joint disorder and migraine are characterized by peripheral and central sensitization of trigeminal nociceptive neurons. Although calcitonin gene-related peptide (CGRP) is implicated in the development of central sensitization, the pathway by which elevated spinal cord CGRP levels promote peripheral sensitization of primary trigeminal nociceptive neurons is not well understood. The goal of this study was to investigate the role of CGRP in promoting bidirectional signaling within the trigeminal system to mediate sensitization of primary trigeminal ganglion nociceptive neurons. Adult male Sprague Dawley rats were injected in the upper spinal cord with CGRP or co-injected with the receptor antagonist CGRP8-37 or KT 5720, an inhibitor of protein kinase A (PKA). Nocifensive head withdrawal response to mechanical stimulation of trigeminal nerves was investigated using von Frey filaments. Expression of PKA, GFAP, and Iba1 in the spinal cord and P-ERK in the trigeminal ganglion was studied using immunohistochemistry. Some animals were co-injected intracisternally with CGRP and Fast Blue dye and trigeminal ganglion imaged using fluorescent microscopy. Intracisternal CGRP increased nocifensive responses to mechanical stimulation when compared to control levels. Co-injection of CGRP8-37 or KT 5720 with CGRP inhibited the nocifensive response. CGRP stimulated expression of PKA and GFAP in the spinal cord, and P-ERK in trigeminal ganglion neurons. Seven days post injection, Fast Blue was observed in trigeminal ganglion neurons and satellite glial cells. Our results demonstrate that elevated levels of CGRP in the upper spinal cord promote sensitization of primary trigeminal nociceptive neurons via a mechanism that involves activation of PKA centrally and P-ERK in trigeminal ganglion neurons. Our findings provide evidence of bidirectional signaling within the trigeminal system that can facilitate increased neuron-glia communication within the trigeminal ganglion associated with peripheral sensitization. calcitonin gene-related peptide nociception neuronal sensitization protein kinase A trigeminal ganglion glia Peripheral and central sensitization of trigeminal nociceptive neurons is associated with the pathology of prevalent and debilitating orofacial pain conditions including migraine and temporomandibular joint disorder (TMD). Migraine is a neurological disorder characterized by a severe headache, photophobia, phonophobia, and nausea that can persist up to 72 hours (Goadsby, 2005, Olesen et al., 2009). Similarly, TMD is a chronic painful condition that is characterized by persistent pain in the muscles and temporomandibular joint (TMJ) associated with mastication (Poveda Roda et al., 2007, Greenspan et al., 2011, Ohrbach et al., 2011, Furquim et al., 2015). The pathological pain and inflammation associated with migraine and TMD involves activation of trigeminal ganglion nerves, which provide sensory innervation of the head and face and relay nociceptive signals to the upper cervical spinal cord (Ballegaard et al., 2008, Bevilaqua Grossi et al., 2009, Dahan et al., 2015). Following peripheral activation of trigeminal nerves in response to tissue injury, the neuropeptide calcitonin gene-related peptide (CGRP) and other inflammatory mediators facilitate excitation of second order neurons and glial cells involved in the initiation and maintenance of central sensitization and persistent pain (Seybold, 2009, Sessle, 2011). Elevated CGRP levels in the spinal cord are implicated in the development of central sensitization by mediating changes in the expression of ion channels, receptors, and inflammatory genes in second order neurons and glial cells including astrocytes and microglia. Activation of astrocytes and microglia results in a prolonged inflammatory response that helps to sustain central sensitization and promotes a pathological pain state (Xie, 2008, Davies et al., 2010, Ikeda et al., 2012). CGRP is involved in the initiation and maintenance of central sensitization via activation of CGRP receptors that are localized on secondary neurons and glial cells within the spinal cord (Moreno et al., 2002, Marvizon et al., 2007, Lennerz et al., 2008). The CGRP receptor complex is comprised of three separate proteins: a G-protein-coupled receptor (GPCR), calcitonin receptor-like receptor (CLR), and an accessory protein, receptor activity-modifying protein 1 (RAMP1) that confers ligand-binding specificity (Benemei et al., 2007, Russell et al., 2014). Activation of CGRP receptors in neurons and glial cells causes an increase in intracellular levels of the secondary messenger cAMP that binds to and stimulates activation of protein kinase A (PKA). The signaling protein PKA induces expression of pro-inflammatory genes such as cytokines that are involved in sustaining a sensitized state of second order neurons (Staud, 2015). Elevated PKA levels in the cytosol are correlated with sensitization and activation of nociceptive neurons and glial cells via modulation of receptor expression and ion channel activity (Sun et al., 2004, Seybold, 2009). CGRP is also known to cause activation of the mitogen activated protein (MAP) kinases including p38, c-Jun kinase (JNK), and extracellular regulated kinase (ERK) in trigeminal neurons and glia (Thalakoti et al., 2007, Cady et al., 2011), that facilitate inflammation and nociception in the spinal cord (Ji et al., 2009). Similar to PKA, increased expression of these signaling proteins leads to a prolonged state of sensitization via modulation of ion channels, receptors, and transcription factors. In acute models of pain, peripheral sensitization, which results from the interaction of nociceptors with inflammatory substances released when tissue is damaged or inflamed (Sessle, 2011), has been shown to promote cellular changes that mediate central sensitization of second order neurons involved in pain transmission to the thalamus (Dodick and Silberstein, 2006, Sessle, 2011, Bernstein and Burstein, 2012). However, in prolonged pain states, central sensitization is maintained in the absence of evidence of peripheral tissue damage. In our study, we wanted to determine if elevated levels of CGRP in upper cervical spinal cord could promote bidirectional signaling and thus mediate peripheral sensitization of primary trigeminal neurons to mechanical stimulation. Findings from this study demonstrate that CGRP promotes sensitization of primary trigeminal nociceptive neurons via a mechanism involving PKA activation centrally, and is associated with increased levels of P-ERK and increased neuron-satellite glial cell coupling in the trigeminal ganglion. Furthermore, our results provide evidence of bidirectional signaling within the trigeminal system that may help explain how trigeminal nociceptive neurons become sensitized, as reported in chronic orofacial pain conditions, in the absence of any physical trauma. EXPERIMENTAL PROCEDURES Animals Sixty-seven Sprague-Dawley rats were used for this study. All animal studies were performed in accordance with the protocols approved by the Missouri State University Institutional Animal Care and Use Committee and were in agreement with guidelines set forth in the National Institutes of Health and the Animal Welfare Act of 2007. An effort was made to reduce the number of animals used in the study as well as to minimize suffering. Adult, male Sprague-Dawley rats (350-500 g) were obtained from Charles River Laboratories Inc. (Wilmington, MA) or purchased from Missouri State University (internal breeding colonies). All animals were housed in clean, plastic standard rat cages (VWR, West Chester, PA) in an animal holding room on a 12-hour light/dark cycle starting at 7 A.M. with ambient temperature maintained from 22-24 °C and access to food and water ad libitum. Animals were acclimated to the environment for a minimum of 1 week upon arrival prior to use. Reagents Stock solutions of CGRP or CGRP8-37 (American Peptide Company, Sunnyvale, CA) were prepared at a concentration of 1 mM in 0.9% saline solution (Fisher-Scientific, Fair Lawn, NJ). The PKA inhibitor KT 5720 (Tocris, Bristol, UK) was prepared at a stock concentration of 1 mM in DMSO (Sigma-Aldrich, St. Louis, MO). On the day of the experiment, an aliquot of 1 mM CGRP was thawed and diluted in 0.9% sterile saline to a concentration of 1 μM either alone or in solution with one of the two inhibitors. The inhibitors CGRP8-37 and KT 5720 were prepared in 0.9% saline solution with CGRP at concentrations of 5 μM and 500 nM, respectively. The retrograde labeling dye Fast Blue (Polysciences Inc., Warrington, PA) was diluted to a concentration of 4% in sterile phosphate buffered saline (PBS) containing 1 μM CGRP. Behavioral Testing All behavioral procedures were conducted between the hours of 7 A.M. and 11 A.M. Behavioral assessments were performed essentially as described in previously published studies in our laboratory using the Durham Animal Holder (Ugo Basile, Varese Lakes, Italy) (Garrett et al., 2012, Cady et al., 2014, Hawkins et al., 2015) on a total of 48 animals. Prior to testing, the rats were acclimated by guiding them into the holding device and secured in the holder for 5 minutes using a plastic blockade inserted behind the hindpaws. To minimize false responses during von Frey filament testing, a pipette tip was used to touch the animal’s head and face to acclimate the rats to having the cutaneous tissue over the masseter muscle touched with a filament. This was done for the three consecutive days prior to testing with von Frey filaments. During this acclimation period, if a rat appeared to be unwilling to go into the device or was continuously moving and shifting within the device, the animal was removed from the study. Following acclimations, nocifensive thresholds were determined in response to a series of calibrated von Frey filaments (North Coast Medical, Inc., Gilroy, CA; 60, 100, 180 grams) applied to the cutaneous tissue over the masseter muscle. A positive response was recorded when an animal visibly withdrew its head from a filament prior to it bending, while pressure was being applied. Each filament was applied 5 times on each side of the face, and the data are reported as the median number of responses obtained from 5 applications of each specific calibrated filament ± the interquartile range. The 100 g force was used for subsequent studies since the average number of positive head withdrawal responses to this force was less than 1 out of 5 for both right and left masseter muscles under basal conditions. Once baseline values were established, the animals were anesthetized by inhalation of 5% isoflurane. Animals were then injected intracisternally using a 26 ½ gauge needle (Becton Dickinson, Franklin Lakes, NJ) and a 50 μL Hamilton syringe (Hamilton Company, Reno, NV) at the midline between the occipital bone and the first cervical vertebrae (C1) with 20 μl of CGRP (1 μM) either alone, or co-injected with CGRP8-37 (5 μM) or KT 5720 (500 nM), a selective signaling inhibitor of PKA. Control animals were injected with saline alone or received no injection (naïve). Mechanical testing for nocifensive reactions at 2 h and days 1, 2, and 3 post injections was done using the same method as baseline values. Immunohistochemistry Twenty-three animals were used for immunohistochemical studies. To correlate behavioral responses to cellular changes in protein levels within the spinal cord, injections were performed as described above with CGRP alone or co-injected with KT 5720. The upper spinal cord (6 mm posterior to the obex) was removed at 2 h and at days 2 and 3 following injection and incubated in 4% paraformaldehyde at 4 °C for approximately 24 h. Tissues were then placed in 12.5% sucrose at 4 °C for approximately 1 h and then incubated in 25% sucrose for a minimum of 8 h. Following cryopreservation, tissues were stored at −20 °C. Tissues were embedded in Optimal Cutting Temperature compound (OCT; Sakura Finetek, Torrance, CA) and transverse sections 14 μm in thickness were taken between 4 and 5 mm caudal to the obex of the upper spinal cord, using a cryostat set at −24 °C. Sections from control and treated animals were placed on Superfrost Plus slides (Fisher Scientific, Pittsburg, PA) with the caudal side of the spinal cord in contact with the glass and stored at −20 °C. To determine changes in levels of the active form of ERK (P-ERK) in trigeminal ganglia, both ganglion were removed 2 h after intracisternal injection of CGRP and prepared for immunohistochemistry as described for the spinal cord tissue. Sections were blocked and permeabilized in a solution of 0.1% Triton X-100 in 5% donkey serum (Jackson ImmunoResearch Laboratories, West Grove, PA) for 20 min at room temperature. Following thorough rinsing in PBS, sections were incubated with primary antibodies for proteins of interest (Table 1) for either 3 h at room temperature or overnight in a humidified chamber at 4 °C. Sections were next incubated in solutions of secondary antibodies (Table 1) for one hour at room temperature, then mounted in Vectashield medium (H-1200) containing 4’,6-diamidino-2-phenylindole (DAPI; Vector Laboratories, Burlingame, CA) to stain cell nuclei in preparation of viewing using fluorescent microscopy. As a control, some slides were incubated with only secondary antibodies to confirm specificity. Images were taken using a Zeiss Axiocam mRm camera mounted on a Zeiss Imager Z2 fluorescent microscope with an Apotome. Image acquisition was performed using Zeiss Zen 2012 software (Thornwood, NY). Retrograde labeling In initial studies, the fluorescent dye Fast Blue was injected into the intracisternal space between the occipital bone and C1 and its localization in the trigeminal ganglion observed using fluorescent microscopy. To directly investigate if CGRP could promote bidirectional signaling from terminals of primary sensory nerves fibers localized in the spinal cord, 50 μL of Fast Blue and 1 μM CGRP diluted in PBS were co-injected, while some animals were only injected with Fast Blue. Seven days later, the animals in both groups were euthanized via asphyxiation with carbon dioxide followed by decapitation. Trigeminal ganglia were removed and prepared for fluorescent microscopy as for tissue immunostaining. Briefly, longitudinal sections (14 μm) were prepared using a cryostat and mounted on Superfrost Plus slides with the caudal side in contact with the glass. Tissues were rehydrated with PBS and then mounted in Vectashield medium without DAPI to localize fluorescent staining from retrograde transport of the dye from the spinal cord. Statistical analysis Statistical analysis was performed essentially as described in previous published studies from our laboratory (Cady et al., 2014, Hawkins et al., 2015, Hawkins and Durham, 2016). For the mechanical stimulation studies, the data are reported as the median number of withdrawal responses ± the interquartile range to 100 g of force at each condition and time point. Subsequent analysis was then performed on data with n = 6 or greater for each experimental condition using a Friedman’s ANOVA to test for general statistical significance between time points for each group, followed by a Wilcoxon test to find changes within groups from basal, and a Kruskal Wallis followed by a Mann-Whitney U test for differences between groups at each time-point. Statistical significance was set at P < 0.05. For analysis of the immunohistological images of the spinal cord (n = at least 3 independent experiments per condition), relative levels of the proteins of interest were analyzed using NIH image J software. Fluorescent intensity was measured in ten rectangular regions in laminas I-III in the medullary horn. To normalize intensity measurements within each image, background intensity values were obtained from five non-overlapping regions in either the acellular area of the outer lamina as determined by DAPI, and average values subtracted from region of interest staining intensity values. All data are presented as mean fold-change from the average naïve value ± S.E.M. All immunohistochemical data were normally distributed as determined by a Shapiro-Wilk test. Analysis was performed for each separate time point using a one-way ANOVA with a Tukey’s post-hoc. For quantification of P-ERK expression in the trigeminal ganglion, the number of neuronal cells exhibiting nuclear localization of P-ERK was divided by the total number of visible neuronal nuclei as identified by NeuN staining in the overlapping V1/V2 region and distinct V3 region. Results are reported as the average percent ± S.E.M of neurons with P-ERK nuclear staining. Statistical significance was set at P < 0.05. RESULTS CGRP Mediates Nociceptive Response in Trigeminal Ganglion Neurons To evaluate the effect of increased CGRP levels in the upper spinal cord on primary nociceptor sensitivity, nocifensive responses were examined in response to mechanical stimulation of the cutaneous region over the masseter muscle. The number of withdrawals from the 100 g filament by animals was tested basally, 2 h post-injection, and on days 1, 2, and 3 post-injection (Fig. 1A). A Friedman test on all behavioral data indicated a significant difference between time-points for CGRP-injected animals (Χ2=15.921, n = 14, P ≤ 0.01), but not saline or naïve animals. Subsequent pairwise analysis showed no significant difference in basal responses between conditions. In contrast, significantly increased nocifensive responses were observed at 2 h (2.5 ± 3, Z = −2.9, n = 14, P ≤ 0.01) and on days 1 (2.5 ± 3, Z = −2.9, n = 14, P ≤ 0.05) and 2 (3.0 ± 4, Z = −3.0, n = 14, P ≤ 0.01) in animals injected with 1 μM CGRP when compared to basal values (0.0 ± 1). Nocifensive responses from animals injected with CGRP were also significantly different from saline controls at 2 h (0.5 ± 1.25, U = 32.5, nCGRP = 14, nsaline = 11, P ≤ 0.05) and on day 1 (1.0 ± 1.25, U = 35.0, n = 11, P ≤ 0.05) and day 2 post-injection (0.0 ± 2, U = 24.0, n = 11, P ≤ 0.01). Nocifensive responses in CGRP animals were also significantly higher than naïve control levels at 2 h (0.0 ± 1, U = 20.0, nCGRP = 14, nnaive = 10, P ≤ 0.01) and on day 1 (0.0 ± 1, U = 24.0, nCGRP = 14, nnaive = 10, P ≤ 0.01) and day 2 post-injection (0.0 ± 1, U = 27.0, nCGRP = 14, nnaive = 10, P ≤ 0.05). However, CGRP-induced responses were again similar to naïve and saline control values 3 days after injection. PKA Is Involved in CGRP-Mediated Nociception To investigate the signaling pathways involved in CGRP-mediated increases in nociception, animals were co-injected with a truncated version of CGRP (CGRP8-37) that is a known competitive CGRP receptor inhibitor or KT 5720, a selective inhibitor of the downstream signaling enzyme PKA. A Friedman test on behavioral data from animals receiving CGRP and CGRP8-37 showed no significance between time-points. Responses from animals that received CGRP8-37 in conjunction with CGRP were not significant from saline or naïve controls at 2 h, or days 1 and 2 post-injection. Nocifensive responses from these animals also failed to reach significance from basal levels at 2 h, or days 1 or 2 following injections. A Friedman test on behavioral data from animals receiving CGRP and KT 5720 indicated a significant difference between time-points (Χ2= 13.289, n = 7, P 0.01). Animals co-injected with CGRP and the PKA inhibitor KT 5720 exhibited significant increases in nocifensive responses to the 100 g filament at 2 h post-injection (2.0 ± 3.75) as compared to naïve control groups (U = 8.0, nnaive = 10, nKT5720 = 7, P ≤ 0.01), saline control groups (U)= 16.0, nsaline = 11, nKT5720 = 7, P ≤ 0.05), and basal readings (0.50 ± 1, Z = −2.2, n = 7, P ≤ 0.05) (Fig. 1B). In contrast, co-injected animals did not exhibit significantly increased nocifensive responses on day 1 (0.0 ± 2) or day 2 post-injection (0.0 ± 1) as compared to saline and naïve groups, as well as basal levels. Animals that received CGRP and KT 5720 reacted significantly less to the 100 g filament than those receiving CGRP alone at 1 d (U = 16.0, nCGRP = 14, nKT5720 = 7, P ≤ 0.5) and 2 d (U = 13.5, nCGRP = 14, nKT5720 = 7, P ≤ 0.05). Expression of PKA and GFAP but Not Iba1 Were Increased in Response to CGRP To identify the cell types influenced by CGRP, the expression of PKA, GFAP, and Iba1 were investigated using immunohistochemistry of upper spinal cord tissue. In naïve animals, low levels of the active form of PKA were detected in the upper spinal cord tissue (1.00 ± 0.06, n = 3; Fig. 2). General statistical significance was detected at 2 h (F(2, 6) = 14.4, P ≤ 0.01, η2 = 0.827) and 2 d (F(2, 6) = 17.3, P ≤ 0.05, η2 = 0.733) post-treatment. These changes were no longer statistically significant by 3 d post-treatment. The level of PKA staining was not significantly different from naïve controls in animals injected with sterile saline alone at any time point. At 2 h, CGRP-injected animals exhibited an increase in PKA immunostaining intensity (2.43 ± 0.11 fold, n = 3) in comparison to levels in naïve (P ≤ 0.01) and saline animals (P ≤ 0.01). PKA levels were still significantly elevated at 2 days post-injection (2.43 ± 0.15, n = 3) as compared to both naïve (P ≤ 0.05) and saline (P ≤ 0.05) animals. After 3 days, PKA levels in CGRP-injected animals were no longer significantly elevated when compared to naïve and saline control levels. Based on co-staining results, CGRP-mediated increase of PKA was observed in NeuN (neuronal nuclei marker) and GFAP stained cells, but not with Iba1. Thus, the stimulating effect of PKA involves changes in neurons and astrocytes. Levels of GFAP were compared between treatment conditions to evaluate changes in astrocyte activity in the spinal cord (Fig. 3A). Low levels of glial fibrillary acidic protein (GFAP) were observed in upper spinal cord tissues of naïve animals (1.00 ± 0.07, n = 3). Initial testing indicated a significant difference in GFAP levels in tissues taken 2 hours (F(2, 6) = 7.1, P ≤ 0.05, η2 = 0.702) 2 days (F(2, 6) = 17.3, P ≤ 0.01, η2 = 0.852) and 3 days post-injection (F(2, 6) = 9.3, P ≤ 0.05, η2 = 0.755). Post-hoc analysis showed that injection of sterile saline alone was not sufficient to elicit a change in expression of GFAP in astrocytes in the upper spinal cord at any time point as compared to naïve levels. Animals injected with CGRP were significantly different from naïve levels 2 h post-injection (1.88 ± 0.13, P ≤ 0.05), but did not show significant changes compared with saline controls at 2 h. In contrast, levels of GFAP in animals injected with CGRP were significantly higher from both naïve (P ≤ 0.01, n = 3) and saline controls (P ≤ 0.01, n = 3) 2 days after injection (3.03 ± 0.17). Three days post injection, spinal cord tissue from rats injected with CGRP still showed significantly different GFAP levels to naïve (1.93 ± 0.20, P ≤ 0.05) and saline (P ≤ 0.05) tissues. Relative levels of Iba1, a marker for active microglia, were assessed in the spinal cord to evaluate whether there were changes in microglia activity in response to CGRP (Fig. 3B). Statistically significant differences were not detected at any time point, indicating that neurons and astrocytes are primarily responsible for changes of sensitivity in the medullary horn. Expression of P-ERK in Trigeminal Ganglion Having shown that elevated levels of CGRP in the upper spinal cord led to an increased sensitivity of V3 trigeminal neurons that provide sensory innervation of the TMJ tissues, immunohistochemistry was utilized to study changes in P-ERK levels in primary neurons. While P-ERK immunostaining was observed primarily in the cytosol of neuronal cell bodies in naïve animals, the active form was more localized in the nuclei of trigeminal neurons in animals 2 h post CGRP injection (Fig. 4). P-ERK expression in neuronal nuclei was confirmed through tissue morphology and its colocalization with the NeuN expression. Nuclear localization of P-ERK expression was evaluated as a percentage of the total neuronal nuclei present in an image, normalized to number of visible neurons identified by DAPI staining. The staining pattern in the V3 region of naïve tissues (n = 3) showed an average of 65.3 ± 2.8 visible neuronal nuclei, with an average of 33.7 ± 0.72, or 51.9 ± 3.2%, of these expressing nuclear P-ERK. Animals injected with saline at 2 h post-injection (n = 3) contained an average of 64.3 ± 3.4 neurons present in pictures taken of the V3 region of the trigeminal ganglion, with 31.7 ± 2.3, or 49.2 ± 2.9%, of those neurons exhibiting nuclear P-ERK. Animals injected with CGRP at 2 h post-injection (n = 3) had an average of 57.7 ± 7.6 neurons present in pictures taken of the V3 region of the trigeminal ganglion. On average, 47.7 ± 5.6 of those neurons showed nuclear localization of P-ERK, making up 83.0 ± 1.4% of the total neurons per image. There was a statistically significant difference in nuclear P-ERK levels between groups (F(2, 6) = 39.8, P ≤ 0.001, η2 = 0.930). The difference in nuclear P-ERK between naïve and saline tissues was not significant. The percentage of nuclear P-ERK in the V3 region of CGRP tissues was significantly higher than that in naïve tissues (P 0.001) and saline tissues (P ≤ 0.001). In the V1/V2 region of the ganglion, naïve tissues (n = 3) had an average of 77.0 ± 14.6 neuronal nuclei visible in each tissue, with an average of 23.3 ± 5.25 of those neurons exhibiting nuclear P-ERK expression, comprising 30.2 ± 2.2% of the total neurons. Ganglia from animals that had been injected with saline alone (n = 3) had an average of 68.3 ± 7.3 neuronal nuclei visible in each tissue, with an average of 31.3 ± 4.8 neurons, or 45.9 ± 4.6% of total neurons exhibiting nuclear P-ERK expression. Tissues from animals injected with CGRP at 2 h post-injection (n = 3) were evaluated as having an average of 65.0 ± 7.7 neurons present in pictures taken of the V1V2 region of the trigeminal ganglion. On average, 52.3 ± 8.9 of those neurons showed nuclear localization of P-ERK, making up 79.1 ± 4.0% of the total neurons per tissue. A one-way ANOVA showed a statistically significant difference of nuclear P-ERK levels between groups (F(2, 6) = 34.3, P ≤ 0.001, η2 = 0.920). A Tukey post-hoc showed no significant difference in nuclear P-ERK between naïve and saline tissues. However, the percentage of nuclear P-ERK in the V1V2 region of CGRP tissues was significantly higher than that in naïve (P ≤ 0.001) or saline tissues (P ≤ 0.01). Evidence of Bidirectional Signaling within Trigeminal System The retrograde fluorescent tracer dye Fast Blue was observed in neuronal cell bodies located in the V3 region of the trigeminal ganglion seven days after dye injection into the upper spinal cord in unstimulated animals (Fig. 5). To test whether elevated CGRP levels in the spinal cord could promote increased neuron-glial signaling in the trigeminal ganglion, animals were co-injected with Fast Blue and 1 μM CGRP. Seven days post injection, the Fast Blue was observed in the cell body of trigeminal neurons and surrounding satellite glial cells throughout all three branches of the ganglion. In contrast, Fast Blue was not detected in Schwann cells, which are the other prevalent glial cell type present within the ganglion. DISCUSSION Elevated levels of CGRP are implicated in the development and maintenance of central sensitization and an enhanced pain state characterized by hyperalgesia and allodynia in diseases involving trigeminal nerves including TMD and migraine (Sun et al., 2003, Sun et al., 2004, Seybold, 2009, Sessle, 2011). However, the mechanisms by which elevated levels of CGRP in the upper spinal cord promote peripheral sensitization of primary nociceptive trigeminal neurons that provide sensory innervation to tissues in the head and face is not well understood. We found that administration of CGRP in the upper spinal cord resulted in a significant increase in the number of nocifensive head withdrawals in response to mechanical stimulation of the trigeminal nerve. This finding is in agreement with data from human studies in which both TMD and migraine patients report increased sensitivity to mechanical pressure applied to the head and face during an attack (Burstein et al., 2015, Dahan et al., 2015, Furquim et al., 2015). Under normal physiological conditions, the increase in pain sensitivity could provide a protective mechanism to minimize further damage to the tissue. As shown in our study, the enhanced nocifensive response was seen as early as 2 h post administration and this sensitized state was maintained for at least 48 h with resolution by 72 h post intracisternal CGRP injection. This finding is in agreement with the time course reported by migraine patients during an acute attack in which the severe pain and enhanced sensitivity is rarely sustained past 72 hours (Olesen et al., 2009). Our finding that elevated levels of CGRP within the upper spinal cord can lower the activation threshold of trigeminal primary sensory neurons to mechanical stimulation provide evidence to help explain the association of CGRP and the enhanced pain states reported by migraine and TMD patients. The physiological and cellular effects of CGRP are mediated via activation of the CGRP receptor, which is expressed on primary trigeminal neurons that synapse in the outer lamina of the spinal cord and the associated glial cells, astrocytes, and microglia (Wang et al., 2010, Hansen et al., 2016). To demonstrate the specificity of the CGRP-mediated response, we co-administered CGRP with the truncated CGRP molecule (CGRP8-37), which acts as a competitive inhibitor of the CGRP receptor (Chiba et al., 1989, Edvinsson et al., 2007). We found that CGRP8-37 could inhibit the stimulatory effect of CGRP on nociception at each of the time points. This finding provides evidence that blocking the CGRP receptor within the spinal cord is sufficient to suppress the initiation and maintenance of peripheral sensitization of trigeminal nociceptive neurons. Our result is in agreement with other studies that reported intrathecal administration of a CGRP receptor antagonist can block mechanically evoked nocifensive responses in tissues innervated by dorsal root ganglion sensory neurons (Sun et al., 2004, Adwanikar et al., 2007, Tzabazis et al., 2007, Hansen et al., 2016). Following binding of CGRP to its G-protein-coupled receptor, there is an increase in adenylate cyclase activity within those cells leading to an increase in the intracellular level of the secondary messenger cAMP (Brain and Cox, 2006). Elevated levels of cAMP then cause an increase in expression of the active form of the signaling kinase PKA via binding to an allosteric site in the protein. In contrast to blocking the CGRP receptor, we found that co-injection of the PKA inhibitor (KT 5720) with CGRP did not inhibit trigeminal sensitization to mechanical stimulation at the 2 h time point. However, blocking PKA activation did suppress mechanical sensitivity 24 and 48 h post CGRP injection. We can only speculate that the difference in temporal response may be due to CGRP eliciting an immediate increase in nuclear P-ERK in primary neurons, as shown in our study, independent of PKA activity in the central nervous system. The maintenance of the sensitization, however, is likely mediated by central PKA expression at least partially in astrocytes since CGRP stimulated GFAP expression, which is used as a biomarker of activated astrocytes. Taken together, our data support the notion that the initial increase in neuronal sensitivity in trigeminal nociceptors is due to cellular changes within the primary neurons while the more sustained sensitized state is attributable, at least in part, to activation of glial cells. Data from our behavioral studies provide evidence of the involvement of PKA activation in mediating the downstream stimulatory effects of CGRP. To determine if elevated CGRP levels in the spinal cord could stimulate increased expression of the active form of PKA in neurons and glial cells within the medullary horn, we used immunohistochemistry to directly study changes in PKA levels. The rationale for investigating PKA is further supported by evidence from other studies that PKA activation is associated with development of central sensitization (Levy and Strassman, 2002, Hu et al., 2003, Kohno et al., 2008). Based on colocalization of PKA with the proteins NeuN and GFAP, we found that PKA levels were significantly increased in cell bodies of second order neurons and astrocytes in response to CGRP at 2 hours post injection when compared to levels in naïve and saline treated animals. PKA levels remained significantly elevated at 48 and 72 h post injection. This finding is suggestive that, although a CGRP-mediated enhancement in nociceptive sensitivity had resolved by 72 h, the neurons and glia within the upper spinal cord retained a level of cellular sensitization. Our finding is in agreement with other studies that have shown that elevated levels of PKA within the lower spinal cord are involved in the initiation and maintenance of central sensitization (Aley and Levine, 1999, Hu et al., 2003, Hucho and Levine, 2007). The modulatory effects of PKA are thought to involve activation of pathways and transcription factors that regulate the expression and activity level of ion channels and receptors in nociceptive neurons and increase expression of pro-inflammatory molecules in both neurons and glial cells (Seybold, 2009). For example, elevated PKA levels in the spinal cord are implicated in the development of central sensitization by enhancing the activity of glutamate receptors that are expressed on second order nociceptive neurons (Aley and Levine, 1999, Hucho and Levine, 2007, Latremoliere and Woolf, 2009). Furthermore, activation of PKA intracellular signaling pathways have been shown to promote the initiation and prolonged state of sensitization and persistent pain via ion channel phosphorylation (Fitzgerald et al., 1999, Bhave et al., 2002, Han et al., 2005), and inducing pro-inflammatory cytokine genes containing CRE regulatory promoter sequences (Kawasaki et al., 2004). Further evidence for an important role of PKA in mediating nociception was provided by results demonstrating that blocking PKA signaling inhibits inflammation-induced hyperalgesic behaviors (Malmberg et al., 1997, Aley and Levine, 1999). In sum, our results provide evidence to further support the notion that PKA signaling plays a central role in mediating the stimulatory effects of CGRP, and thus is likely to be an important signaling pathway in promoting central sensitization associated with TMD and migraine. Sensitization of nociceptive neurons associated with the development of prolonged pain states is known to involve activation of spinal cord glial cells (Wieseler-Frank et al., 2004, Ren and Dubner, 2008, Gosselin et al., 2010). In support of this notion, we detected elevated immunoreactive levels of GFAP, which is a protein implicated in astrocyte activation, of CGRP injected animals. The observed increase in GFAP occurred at the 2 hour time point with levels greatest after 48 hours post injection, and remained significantly elevated even at 72 hours, a finding similar to our PKA results. In contrast, CGRP did not cause an increase in the expression of Iba1 in microglia when compared to control levels at any of the time points. Astrocytes can promote and sustain sensitization of peripheral and central neurons through the release of cytokines and other inflammatory molecules by increasing neuron-glial cell interactions in the spinal cord (Miller et al., 2009). Based on our findings, the stimulatory effects in response to intracisternal administration of CGRP appears to be mediated primarily by astrocytes with minimal contribution from microglial cells. To investigate a possible mechanism by which elevated CGRP levels in the spinal cord could lead to our observed increase in nocifensive head withdrawal response mediated by primary trigeminal nociceptive neurons, we determined changes in the level of the MAP kinase ERK in trigeminal neurons. Intracisternal CGRP caused a significant large increase in the nuclear localization of active, phosphorylated form of ERK (P-ERK) in the cell bodies of trigeminal neurons throughout the entire ganglion 2 hours post injection. In contrast in naïve control ganglion, P-ERK was mostly localized in the cytosol of neurons. Elevated P-ERK levels are reported to mediate a sensitized state of primary nociceptive neurons via modulating expression and activation levels of ion channels and membrane receptors (Cheng and Ji, 2008, Takeda et al., 2009). The importance of MAP kinases in the development of peripheral sensitization and an enhanced level of nociceptor sensitivity is supported by findings that selective inhibition of MAP kinase activity can suppress nociceptive cellular events (Milligan et al., 2003, Tsuda et al., 2004, Ji et al., 2009). Results from our study provide evidence that CGRP induces cellular changes of trigeminal ganglion neurons that correlate with the development of peripheral sensitization of primary nociceptive neurons. These data are in agreement with a previous study from our laboratory that demonstrated that nicotine, which promotes central sensitization by promoting an increase in neuron-glial signaling and cytokine production within the upper spinal cord, caused an significant elevation in P-ERK levels in primary trigeminal nociceptive neurons (Hawkins et al., 2015). Taken together, our findings provide evidence to support the notion of bidirectional signaling within the trigeminal system such that central sensitization can induce changes in trigeminal nociceptive neurons. To directly demonstrate that CGRP can promote retrograde signal transduction from the spinal cord to neuronal cell bodies located in the trigeminal ganglion, the retrograde dye Fast Blue was co-injected with CGRP in the upper spinal cord. Fast Blue is a fluorescent dye most commonly used as a retrograde neuronal tracer since it has been shown to be effectively transported retrogradely over long distances in various animal models (Casatti et al., 1999, Bossowska et al., 2009, Ivanusic, 2009). While we detected Fast Blue in the cell bodies of neurons throughout all regions of the trigeminal ganglion seven days post intracisternal injection in unstimulated animals, we observed the dye in both neuronal cell bodies and associated satellite glial cells in response to intracisternal CGRP. To our knowledge, these data for the first time provide direct evidence of bidirectional signaling from the cerebrospinal fluid to neuronal cell bodies within the trigeminal ganglion and coupling to satellite glial cells. The movement of the dye from neuronal cell bodies to the satellite glial cells likely involved the formation of gap junctions between these two cells. This type of neuron-glia coupling within the trigeminal ganglion has been observed following peripheral inflammation or in response to inflammation and nerve injury (Cherkas et al., 2004, Vit et al., 2008, Durham and Garrett, 2010, Villa et al., 2010). Importantly, increased signaling between neurons and glia with the ganglion is associated with development and maintenance of peripheral sensitization of nociceptive neurons. Our results support the idea that elevated levels of CGRP within the spinal cord can facilitate bidirectional signaling and sensitization of primary trigeminal neurons by mediating increased neuron-glial cell coupling in the trigeminal ganglion. In summary, findings from this study demonstrate that CGRP promotes peripheral sensitization of primary trigeminal nociceptive neurons to mechanical stimulation via a mechanism involving CGRP induction of PKA activity in neurons and glia and upregulation of GFAP in astrocytes in the upper spinal cord. Elevated levels of CGRP increased neuronal expression of P-ERK and promoted neuron-satellite glial cell coupling in the trigeminal ganglion. Thus, our results provide evidence to support the notion that CGRP-mediated central sensitization leads to an increase in trigeminal nociceptor sensitivity. Furthermore, we speculate that central to peripheral signaling as observed in our study may help to explain how peripheral nociceptors become sensitized, as reported in chronic orofacial pain conditions, even in the absence of any physical trauma or signs of inflammation. ACKNOWLEDGEMENTS We would like to thank Jennifer Cashler and Angela Goerndt for their assistance with the animals. This work was supported by the National Institutes of Health [DE024629]. Abbreviations CGRP calcitonin gene-related peptide TMJ temporomandibular joint PKA protein kinase A PBS phosphate buffered saline P-ERK phosphorylated extracellular signal-regulated kinase GFAP glial fibrillary acidic protein SEM standard error of the mean Iba1 ionized calcium-binding adapter molecule 1 Figure 1 A. Intracisternal injection of CGRP in upper cervical spinal cord increased nociceptive responses to mechanical stimulation of trigeminal neurons. The median number of nocifensive head withdrawals to the 100 g filament in naïve animals compared to animals basally and at 2 h, 1 day, 2 days, or 3 days post intracisternal injection of saline or CGRP is shown. B. The median number of nocifensive withdrawal responses to the 100 g filament was decreased in a time-dependent manner by inhibiting CGRP or PKA activity. Animals were injected intracisternally with CGRP or co-injected with CGRP and the truncated CGRP receptor antagonist peptide CGRP8-37 (CGRP + 8-37) or the selective PKA inhibitor KT 5720 (CGRP + KT 5720). Figure 2 CGRP injection increased expression of PKA in upper spinal cord compared to naïve and saline control. Representative images of sections from the upper spinal cord obtained from naïve (left), and saline treated (center) or CGRP treated (right) animals 2 days post injection are shown. All cell nuclei are identified by DAPI staining (top panel). The same sections were also stained for PKA or co-stained for PKA and the astrocyte biomarker GFAP. Enlarged images of the region of the medullary horn are shown. Scale bars = 200 μm. Figure 3 Intracisternal injection of CGRP increased expression of GFAP and transiently elevated Iba1 levels. Representative images of sections from the medullary horn of upper spinal cords obtained from naïve (left), and saline (center) or CGRP treated (right) animals 2 days post CGRP administration are shown. All cell nuclei identified by staining with DAPI are shown in the top panels, while immunostaining of the same tissue sections for GFAP (A) or Iba1 (B) are seen in the lower panels. Scale bars = 200 μm. Figure 4 Intracisternal CGRP injection increased expression of P-ERK in trigeminal ganglion neurons. Representative images of sections from the V1/V2 region of trigeminal ganglia obtained from naïve and CGRP treated animals are shown. All cell nuclei are identified by the nuclear dye DAPI (left panel), while the same tissue sections that were positive for P-ERK are seen in the second panel. Enlarged images of the region of the ganglion containing numerous neuronal cell bodies (white box) stained for neuronal protein NeuN (third panel) and the same region co-stained for P-ERK (far right panel) are shown. Scale bars = 100 μm. Figure 5 Evidence of bidirectional signaling within the trigeminal system from the upper spinal cord to trigeminal ganglion cells and increased neuron-glia coupling in response to CGRP. The fluorescent dye Fast Blue was localized primarily in the cell body of neurons 7 days after dye injection in unstimulated animals but the dye was seen in both neuronal cell bodies and satellite glial cells in animals co-injected with dye and CGRP. A white asterisk was used to indicate the cell body of several neurons, while arrows identify satellite glial cells containing the dye. Scale bars = 100 μm. Table 1 Antibodies and Incubation Conditions Used for Immunohistochemistry. Protein Dilution Company Incubation Time Incubation Temperature GFAP 1:5,000 Abcam 3 hours 20-22 °C Iba1 1:500 Abcam 3 hours 20-22 °C NeuN 1:1,000 Millipore 3 hours 20-22 °C P-ERK 1:500 Bioworld Overnight 20-22 °C PKA 1:500 Abcam 3 hours 4 °C Alexa 488 1:200 Life Technologies 1 hour 20-22 °C Alexa 567 1:200 Life Technologies 1 hour 20-22 °C Alexa 647 1:200 Life Technologies 1 hour 20-22 °C Intrathecal CGRP promotes sensitization of primary trigeminal nociceptive neurons Stimulatory effects of CGRP are mediated by PKA and involve astrocyte activation CGRP-dependent behavioral changes associate with increased P-ERK levels in ganglion Elevated CGRP levels in spinal cord promote neuron-glia communication in ganglion Our results provide direct evidence of bidirectional signaling within trigeminal system This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final citable form. Please note that during the production process errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain. Conflict of interest: The authors of this paper do not have any conflicts of interest to report. REFERENCES Adwanikar H Ji G Li W Doods H Willis WD Neugebauer V Spinal CGRP1 receptors contribute to supraspinally organized pain behavior and pain-related sensitization of amygdala neurons Pain 2007 132 53 66 17335972 Aley KO Levine JD Role of protein kinase A in the maintenance of inflammatory pain J Neurosci 1999 19 2181 2186 10066271 Ballegaard V Thede-Schmidt-Hansen P Svensson P Jensen R Are headache and temporomandibular disorders related? 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PMC005xxxxxx/PMC5118180.txt
LICENSE: This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. 7605074 6087 Neuroscience Neuroscience Neuroscience 0306-4522 1873-7544 27717807 5118180 10.1016/j.neuroscience.2016.09.047 NIHMS820879 Article Sex differences in astrocyte and microglia responses immediately following middle cerebral artery occlusion in adult mice Morrison Helena W. PhD ab Filosa Jessica A. PhD jfilosa@augusta.edu a a Augusta University, 1120 15th St, Augusta, GA 30912 b Present address. University of Arizona, 1305 N. Martin Ave, P.O. Box 210203, Tucson, AZ 85721, hmorriso@email.arizona.edu 16 10 2016 4 10 2016 17 12 2016 17 12 2017 339 8599 This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. Epidemiological studies report that infarct size is decreased and stroke outcomes are improved in young females when compared to males. However, mechanistic insight is lacking. We posit that sex-specific differences in glial cell functions occurring immediately after ischemic stroke are a source of dichotomous outcomes. In this study we assessed astrocyte Ca2+ dynamics, aquaporin 4 (AQP4) polarity, S100β expression pattern, as well as, microglia morphology and phagocytic marker CD11b in male and female mice following 60 minutes of middle cerebral artery (MCA) occlusion. We reveal sex differences in the frequency of intracellular astrocyte Ca2+ elevations (F(1,86)=8.19, P=0.005) and microglia volume (F(1,40)=12.47, P=0.009) immediately following MCA occlusion in acute brain slices. Measured in fixed tissue, AQP4 polarity was disrupted (F(5,86)=3.30, P=0.009) and the area of non-S100β immunoreactivity increased in ipsilateral brain regions after 60 min of MCA occlusion (F(5,86)=4.72, P=0.007). However, astrocyte changes were robust in male mice when compared to females. Additional sex differences were discovered regarding microglia phagocytic receptor CD11b. In sham mice, constitutively high CD11b immunofluorescence was observed in females when compared to males (P=0.03). When compared to sham, only male mice exhibited an increase in CD11b immunoreactivity after MCA occlusion (P=0.006). We posit that a sex difference in the presence of constitutive CD11b has a role in determining male and female microglia phagocytic responses to ischemia. Taken together, these findings are critical to understanding potential sex differences in glial physiology as well as stroke pathobiology which are foundational for the development of future sex-specific stroke therapies. ischemic stroke calcium aquaporin 4 S100β microglia morphology CD11b The age-adjusted stroke mortality rate, which has been in decline since 2010, has been attributed to improved control of modifiable stroke risk factors such as hypertension, smoking, and dyslipidemia (Hoyert DL, 2012; Mozaffarian et al., 2015; Murphy et al., 2013). Yet In comparison, our understanding of a non-modifiable factors, such as sex differences, is lacking and therefore sex specific treatments are absent among stroke therapies. Emerging evidence taken from both epidemiological and pre-clinical stroke research supports the compelling assertion that sex has a dichotomous role in brain injury and functional outcomes after ischemic stroke (Go et al., 2014; Miller et al., 2011; Reeves et al., 2008). However, the diverging mechanisms of protection versus injury, which underlie this sexual dimorphism, have yet to be fully described and are not well understood (Banerjee et al., 2013; Ritzel et al., 2013). Brain ischemia, caused by stroke, results in immediate neuronal death and the inevitable release of cell contents which then further disrupts finely tuned neuronal functions and promotes neuroinflammation (Dirnagl et al., 1999; Dirnagl, 2012; Gelderblom et al., 2009). Structurally, astrocytes are well positioned to intervene because of their intimate association with other glial cells, neurons, and blood vessels (Filosa et al., 2015). Functionally, astrocytes have a vital role in maintaining, mediating and restoring neuronal function during physiologic and pathologic conditions (Araque et al., 1999; del Zoppo, 2010; Nedergaard et al., 2010). In this role, astrocytes are key in maintaining K+ homeostasis (Kofuji and Newman, 2004), removal of excess glutamate (Cheung et al., 2015), local blood flow regulation (Attwell et al., 2010; Kim et al., 2015), synaptogenesis and synaptic maintenance (Franke et al., 2012), among other functions. On the other hand, astrocyte dysfunction after ischemia may exacerbate brain injury via aberrant astrocyte Ca2+ signaling which can result in glutamate excitotoxicity (Nedergaard et al., 2010) or through the release of astrocyte-derived proteins and small molecular messengers such as ATP, TNFα, and S100β, which further increases neuroinflammation (Agulhon et al., 2012; Liu et al., 2011; Pascual et al., 2012). In addition, astrocyte aquaporin 4 (AQP4) is a water channel and key player in the development of brain edema. AQP4 is primarily localized to astrocyte endfeet rather than non-endfeet processes and this polarized location has an important role in brain fluid clearance (Gaberel et al., 2014; Iliff et al., 2013). AQP4 polarity is disrupted in the days following traumatic brain injury (Kress et al., 2014; Plog et al., 2015) and transient focal ischemia (Fukuda and Badaut, 2012; Vella et al., 2015) which may contribute to brain edema after injury. Importantly, brain edema is accompanied by increased astrocyte intracellular Ca2+ (Thrane et al., 2011). However, it is yet unknown if changes in astrocyte Ca2+ dynamics, the expression pattern of S100β and AQP4 polarity is altered immediately following middle cerebral artery (MCA) occlusion in adult male and female mice. Adding to the complexity of cell-to-cell interactions, microglia are phagocytes and, in conjunction with astrocytes, contribute to the inflammatory milieu after ischemic stroke. Microglia cells are highly sensitive to altered brain physiology because of their constant monitoring and immediate inflammatory response to pathophysiology (i.e. ischemia). These important functions are made possible by their ramified morphology (Morrison and Filosa, 2013), dynamic process movement (Davalos et al., 2005), consistent distribution throughout the brain (Lawson et al., 1990), and continuous input from neurons and astrocytes via small molecular messengers (i.e. fractalkine and S100β respectively) (Bianchi et al., 2010; Madry and Attwell, 2015). We previously reported that microglia morphology and phagocytic receptor CD11b are immediately changed by brain ischemia and therefore can be used as an indicator of an early microglia response to stroke (Morrison and Filosa, 2013). However, sex differences in microglia responses to ischemia are largely unknown. Microglia phagocytosis, initiated in part by CD11b-ligand interactions, is a double-edged sword; necessary for wound healing but also well documented in pre-clinical research as a source of secondary inflammatory injury after stroke (Brown and Neher, 2012; Lee et al., 2014). Understanding this balance in both males and females is relevant to future stroke therapies which are developed to promote brain recovery and yet must also account for inherent secondary injury. Unfortunately, few pre-clinical stroke-related studies have examined glial (astrocyte and microglia) responses to injury in male and female adult mouse models prior to 24 hours post-ischemia (Cordeau et al., 2008). As a result, our understandings of early glial events that may be central brain injury after ischemic stroke are only beginning to be revealed (Zheng et al., 2010; Zheng et al., 2013). Moreover, it is not clear if early astrocyte and microglia responses to ischemia are different between male and female mice. Such information is vital in establishing a timeline of sex differences after ischemic stroke and therefore vital to the discovery and implementation of potential sex-specific stroke treatment regimens. In this study, we determine sex differences in astrocyte and microglia responses to 60 min of MCA occlusion in adult male and female mice by assessing changes in astrocyte Ca2+ dynamics and microglia volume in acute brain slices. In addition, we illustrate sex differences in astrocyte S100β and AQP4 immunofluorescence patterns as well as microglia CD11b immunoreactivity after 60 min of MCA occlusion. 1.1 Experimental Procedures Animals Male CX3CR1GFP/ GFP mice with a C57BL6/J background (Jackson Laboratories, no. 005582) were bred to female C56BL6/J mice. Heterozygous male and female offspring CX3CR1GFP/+ weighing 20–25 g (6–8 weeks old) were used to record somatic astrocyte Ca2+ elevations and microglia volume after ischemia and in acute brain slices. For consistency, CX3CR1GFP/+ mice were used for additional immunohistochemistry (IHC) experiments. All animals were housed in climate controlled rooms with a 12-h light cycle. Female mice were not subjected to estrous cycle synchronization, but were allowed to cycle naturally. Female mice were sampled randomly to determine if ischemia induced astrocyte and microglia responses were present despite possible variations in sex hormone levels, an occurrence that more accurately models the human condition and an appropriate initial inquiry (McCarthy et al., 2012). All animal experiments were performed according to methods approved by and in compliance with the Augusta University Institutional Animal Care and Use Committee. Middle cerebral artery occlusion Focal cerebral ischemia to the right hemisphere was achieved using the filament method to occlude the right MCA for 60 min in male and female animals under isoflurane anesthesia delivered via a 20% oxygen/80% air mixture as previously described (Morrison and Filosa, 2013). After common, internal and external artery dissection, a heat blunted and silicone-coated filament (tip diameter 0.20–0.25 mm) was advanced to the ostea of the MCA through the external and internal common carotid artery. Cerebral ischemia to the right MCA region was verified by laser Doppler flowmetry (Perimed Periflux 5000, North Royalton, OH); animals were included in the study if ischemia resulted in a > 70% reduction in blood flow. Focal ischemia was maintained for 60 min. The sham procedure included all elements up to filament placement. All animals were euthanized without reperfusion and prior to brain tissue collection for acute brain slices or tissue processing for IHC methods. Acute brain slices and brain cell imaging Acute brain slices were acquired for ex vivo astrocyte and microglia imaging in a group of naïve animals (no surgery) or immediately after 60 min MCA occlusion. Brain tissue was extracted immediately after euthanasia in ice-cold artificial cerebral spinal fluid (aCSF) and immediately sliced into 280 µm coronal sections using a vibratome as previously described (Leica VT 1200S, Leica Microsystems, Wetzlar, Germany)(Morrison and Filosa, 2013). The composition of aCSF was (in nM): KCl 3, NaCl 120, MgCl2 1, NaHCO3 26, NaH2PO4 1.25, glucose 10, CaCl2 2 and 400 µM L-ascorbic acid; osmolarity was 300–305 mOsM and pH to 7.4 after 95% O2 and 5% CO2 equilibration. Brain hemisphere sections (no surgery, contralateral and ipsilateral) were incubated in aCSF containing the Ca2+ indicator Rhod-2AM (Molecular Probes, MP 01244, 5µM) and 2.5 µL 20% pluronic acid (Molecular Probes P3000MP) in a 95% O2/5% CO2 oxygenated chamber for 60 min just prior to imaging. Figure 1A summarizes the experimental protocol for Ca2+ imaging after 60 min MCA occlusion. Astrocyte Ca2+ imaging All images were acquired in cortical layers I–III using a 40× objective (Zeiss Achroplan 40×/0.8w) at a rate of 4 images per second. To test astrocyte viability, ATP (Sigma, A 9187, 500 µM) was bath applied at the end of each experiment; only astrocytes responsive to ATP, determined by a robust increase in intracellular Ca2+, were included in the data analysis. Live imaging was limited to a 3 hour window following incubation with the Ca2+ indicator. Calcium imaging was analyzed as previously described using Sparkan software [Dr. Adrian Bonev, University of Vermont (Filosa et al., 2004)]. Fluorescence intensity (F) was determined within 10 × 10 pixel squares placed over Rhod-2 loaded astrocytes with baseline fluorescence (F0) determined from 20 images showing no activity. Fractional fluorescence (F/F0) was calculated and peaks were automatically detected from oscillations crossing a set threshold value (>0.2 F/F0) and summarized as Ca2+ oscillations peak frequency (Hz) for each cell. We quantified the area under the curve (AUC) of each Ca2+ trace as an additional indicator of astrocyte Ca2+ which accounts for both peak frequency, amplitude and duration. Using the same 10 × 10 pixel region of interest, AUC was calculated as the integral over time for each cell exhibiting Ca2+ activity included in the study (Kim et al., 2015). All data was normalized to appropriate male and female naïve/no surgery group for statistical analysis. Microglia imaging CX3CR1GFP/+ microglia adjacent to astrocytes were imaged immediately following astrocyte Ca2+ imaging. We imaged microglia soma and associated processes by acquiring Z-stack confocal images every 1 µm for 30–35 µm to ensure that we included the same imaging plane used for astrocyte Ca2+ acquisition. IMARIS software (Bitplane) and filament building protocols were used to create representative 3D microglia models, necessary to quantify the volume of each microglia. Data were normalized to appropriate male and female naïve/no surgery group prior to two-way statistical analysis. Immunohistochemistry Immunohistochemistry (IHC) images were acquired in additional male and female groups of mice. After 60 min MCA occlusion or sham surgery, animals were euthanized, brain tissue removed, fixed for 24h in 4% paraformaldehyde and incubated in a 30% sucrose solution for 72h. Brain tissue was kept at −80°C until sectioning into coronal sections (Leica cryostat CM3050, 50µm) and stored at −20°C in a cryoprotectant solution until tissue processing for IHC staining. To identify astrocytes and microglia, free-floating brain sections were blocked in a 10% horse serum solution (0.01M PBS 0.05% Triton and 0.04% NaN3) for 1h followed by a 72h incubation with primary antibodies: rabbit anti-GFP 1:1,000 (Invitrogen A-6455), rat anti-Mac-1 1:500 (Chemicon MAB1387Z), rabbit anti-S100β 1:200 (Dako Z031101-2), and goat anti-AQP4 1:500 (Santa Cruz sc-9888). A 4-h incubation of 1:250 secondary primaries followed: donkey anti-rabbit Alexa 488, (711-546-152); donkey anti-rat CY3, (712-166-153); donkey anti-chicken Alexa 649 (702-605-155) and donkey anti-goat 594, (705-585-147, Jackson ImmunoResearch Laboratories). Our IHC protocol was for double staining of anti- AQP4 and anti-S100β in one set of male and female tissue and, in another set of tissue, double staining of anti-GFP and anti-CD11b. Male and female tissues from sham and ischemic groups were incubated together for consistent IHC staining. In addition, sections of ipsilateral proximal female brain tissue that was subjected to all aspects of our ICH protocol but without primary antibody. This secondary only antibody staining assessed unspecific binding that may have been prevalent in the infarcted area. All reactions were carried forward at room temperature; washes between incubations were done with 0.01M PBS for 15min. Slices were then mounted onto slides using Vectashield (Vector Laboratories, H-1000). Image acquisition and analysis A confocal microscope was used to acquire photomicrographs (30-µm Z-stack at 2-µm intervals, Zeiss 510, 40×/1.3 oil objective) of cortical layers I–III after IHC preparation in brain regions depicted in Figure 3A. Photomicrographs were stacked and split to obtain maximum intensity projections for all channels and saved as TIFF files prior to analysis. The location of astrocyte AQP4 and S100β was determined as well as microglia morphology and CD11b after 60 min MCA occlusion in male and female tissue. Astrocyte S100β analysis With injury, S100β is released in macro-molar concentrations from the astrocyte soma to the extracellular space. We determined changes in S100β location, from primarily somatic to non-somatic areas, after 60min MCA occlusion and tested if post-stroke changes were different between male and female mice. The distribution pattern of S100β was determined from photomicrographs with a three step analysis technique using Image J software (http://imagej.net). The S100β analysis technique was derived from previous studies examining changes in the area of AQP4 distribution [(Ren et al., 2013; Wang et al., 2012) described below]. For each photomicrograph, we first we determined the area of S100β positive immunofluorescence which included both somatic and non-somatic S100β immunoreactivity (Figure 3B low threshold). Second, we determined the area of S100β positive immunofluorescence that included primarily somatic S100β immunofluorescence (Figure 3B high threshold). Third, the area of non-somatic S100β was calculated: (area of somatic and non-somatic S100β immunoreactivity) − (area of somatic S100β immunoreactivity) = area of non-somatic immunoreactivity. An example of this process is illustrated in Figure 3B. Astrocyte AQP4 analysis In astrocytes, the water channel AQP4 is constitutively expressed and polarized to astrocyte endfeet rather than astrocyte soma or other processes. AQP4 polarity is disturbed with brain injury and this change in AQP4 distribution (from endfeet to non-endfeet locations) has been previously quantified using IHC photomicrographs and image analysis (Ren et al., 2013; Wang et al., 2012). We employ this method by first determining the area of AQP4 immunoreactivity at astrocyte endfeet as well as in non-endfeet astrocyte processes (Figure 4A low threshold). Second, we determined the area of AQP4 immunoreactivity in astrocyte endfeet (Figure 4A high threshold). AQP4 polarity was calculated: (area of endfeet and non-endfeet AQP4 immunoreactivity) − (area of endfeet AQP4 immunoreactivity) = un-polarized AQP4 immunoreactivity. An example of this process is illustrated in Figure 4A. Microglia analysis Microglia were analyzed for changes in morphology and phagocytic function using a computer-aided skeleton analysis method (microglia processes length and number of endpoints) and CD11b immunofluorescence, respectively, as previously described (Morrison and Filosa, 2013). For computer-aided morphological analysis, anti-GFP images were despeckled and then processed to create skeletonized images using Image J software. The Analyze Skeleton Plugin (Arganda-Carreras et al., 2010) was used to identify (tag) and microglia skeletons relevant to quantify ramification: slab voxels, junctions and endpoints. Figure 5B illustrates the conversion from despeckled to tagged image. We summarized the number of endpoints and averaged the length of all processes (slab voxels) from the Analyze Skeleton plugin data output. We then normalized all data by the number of somas/image to result in number of endpoints/cell and microglia process length/cell. Microglia CD11b total fluorescence intensity (TFI) was determined in male and female tissue as previously published. Briefly, microglia CD11b TFI was determined by multiplying the percent area of the image with positive immunoreactivity by the mean fluorescence intensity of CD11b immunoreactivity. Statistical Analysis Sex differences in control conditions (no surgery and sham groups) were determined using Student’s t-test. Data collected after 60min MCA occlusion were normalized to male or female no surgery or sham conditions and two-way ANOVA was then used to test for sex differences and brain regions affected by the MCA occlusion. Sidak’s multiple comparisons post-hoc test was used to test for specific differences between groups. All data are presented as the mean ± standard error of mean (SEM). GraphPad Prism 6 was used for all analyses. 1.2 Results Sex differences in astrocyte Ca2+ elevations after 60 min MCA occlusion We examined the effect of MCA occlusion on astrocyte Ca2+ dynamics in cortical brain regions immediately following 60 min MCA occlusion in adult male and female acute brain slices. A summarized protocol and brain regions (contralateral, ipsilateral distal and ipsilateral proximal) for astrocyte Ca2+ imaging are shown in Figure 1A. Representative astrocyte Ca2+ traces used to analyze AUC and peak frequency (Hz) are shown in Figure 1B. There were no sex differences in astrocyte Ca2+ AUC between male and female no surgery groups (Figure 1C, left). Data summarized by Figure 1C (right) was normalized to the no surgery group in each sex to determine changes in astrocyte AUC in brain regions affected by the MCA occlusion. There was no significant region or sex effect observed for Ca2+ AUC after 60min MCA occlusion (Two-way ANOVA: region F(3,72)=0.20, p = 0.9, sex: F(1,72)=2.639, p=0.11, interaction F(3,72)=0.50, p=0.68). We also summarized astrocyte Ca2+ peak frequency from astrocyte Ca2+ traces; there were no sex differences in astrocyte Ca2+ peak frequency between male and female no surgery groups (Figure 1D, left). Data summarized by Figure 1D (right) was normalized to the no surgery group in each sex to determine changes in the frequency of astrocyte Ca2+ elevations in brain regions affected by the MCA occlusion. A two-way ANOVA analysis reveals sex differences in Ca2+ peak frequency after ischemia but astrocyte Ca2+ peak frequency was not significantly different between brain regions (Figure 1D; region F(3,86)=0.25, p=0.86, sex: F(1,86)=8.19, p=0.005, interaction F(3,86)=1.75, p=0.16). Post-hoc testing of sex differences revealed that astrocyte Ca2+ peak frequency was increased in female ipsilateral tissue when compared to males. Sex differences in microglia volume resulting from 60 min MCA occlusion We imaged microglia from male and female CX3CR1GFP/+ mice subjected to 60 minutes MCA occlusion in mice in order to quantify changes in microglia volume. Microglia volume was calculated from 3D models generated using IMARIS (Bitplane) filament tracer protocols. A representative image of a microglia in each region (no surgery, contralateral, ipsilateral distal and ipsilateral proximal) and its corresponding IMARIS model used to determine volume is shown in Figure 2A. There were no sex differences in microglia volume between male and female no surgery groups (Figure 2B, left). Microglia volume data was normalized to male or female no surgery group in order to determine changes in volume affected by the MCA occlusion and summary data are shown in Figure 2B (right). Microglia volume was not significantly changed in brain regions after MCA occlusion but was different between male and female mouse groups after ischemia (two-way ANOVA: region F(3,40)=11.87, p<0.08, sex: F(1,40)=12.47, p=0.009, interaction F(3,4)=8.80, p=0.17). Post-testing of sex differences revealed no specific differences in microglia volume in the ipsilateral hemisphere after MCA occlusion. Sex differences in S100β expression pattern after 60 minutes of MCA occlusion The Ca2+ binding protein S100β is typically expressed in astrocyte soma, its release is a biomarker of brain injury (Dayon et al., 2011; Plog et al., 2015). Figure 3A illustrates the representative brain regions for data collection in proximity to the ischemic injury (contralateral, distal ipsilateral and ipsilateral proximal region); matching regions were acquired in sham tissue. The protocol used to measure non-somatic S100β expression, described in Methods, is illustrated in Figure 3B. Exemplar photomicrographs used for image analysis and data collection are shown in Figure 3C. Cropped images, shown below the full sized photomicrographs, illustrate the details of S100β immunofluorescence and changes to the expression pattern after MCA occlusion in male and female animals. We determined the change in S100β expression pattern after 60 min ischemic stroke in male and female mice using uncropped photomicrographs. Unspecific secondary binding of anti-rabbit 594 to the ipsilateral proximal region was not detectable. There were also no sex differences in the area of non-somatic S100β between male and female sham groups (Figure 3D, left). S100β data were normalized to the male or female sham group in order to determine changes in the area of S100β immunoreactivity after MCA occlusion according to sex and brain regions (Figure 3D, right). Significant effects were noted for both region and sex (two-way ANOVA: region: F(5,86)=4.72, p=0.007, sex: F(1,86)=10.25, p=0.0019, interaction F(5,86)=1.81, p=0.12). Post-hoc testing revealed that in the male, but not female, non-somatic S100β immunoreactivity was robustly increased after MCA occlusion in the proximal ipsilateral region when compared to sham and contralateral regions. Sex differences in AQP4 polarity after 60 minutes of MCA occlusion Changes in AQP4 expression are well documented in ischemic stroke (Ribeiro Mde et al., 2006; Vella et al., 2015; Wang et al., 2012). However, the expression pattern in male and female brain tissue has not been previously addressed. The protocol used to measure un-polarized AQP4 expression, described in Methods, is illustrated in Figure 4A. Examples of IHC-AQP4 images used for our image analysis protocol are shown in Figure 4B with cropped photomicrographs shown below to better illustrate changes in the AQP4 expression pattern. Unspecific secondary binding of anti-goat 647 to the ipsilateral proximal region was not detectable. In sham mice, sex differences exist in AQP4 polarity (Figure 4C, left). However, this change in AQP4 polarity was only observed in the proximal region (Student’s t-test, p = 0.05). AQP4 data were normalized to male or female sham group in order to determine changes in AQP4 polarity after MCA occlusion according to sex and brain regions (Figure 4C, right). Changes to AQP4 polarity was significantly changed in brain regions and according to sex after 60 min MCA occlusion (two-way ANOVA: region F(5,86)=3.30, p=0.009, sex: F(1,86)=17.21, p<0.0001, interaction F(5,86)=2.17, p=0.06). Post-hoc testing reveals significant changes in AQP4 polarity in ipsilateral brain regions after MCA occlusion in male and not female mice. Sex differences exist in AQP4 polarity in distal contralateral and ipsilateral brain regions. Sex differences in microglia morphology after 60 min MCA occlusion We investigated sex differences in microglia neuroinflammatory responses to ischemia in addition to astrocyte responses. We first quantified microglia morphology after 60 min MCA occlusion in male and female mice in sham, contralateral and ipsilateral (proximal and distal) regions as shown in Figure 3A. Cropped single cells from photomicrographs are included to better visualize microglia morphology details; data analysis was conducted on uncropped images. Microglia morphology (number of microglia process endpoints/cell and process length/cell) was determined from anti-GFP photomicrographs using a skeleton analysis method that was modified from our previous publication (Morrison and Filosa, 2013) and summarized in Figure 5B. As expected, unspecific secondary binding (anti rabbit 488) to the ipsilateral proximal region was not detected, however, faint GFP fluorescence of microglia in the CX3CR1GFP/+ mouse was present, not shown. There were no sex differences in microglia process length/cell or endpoints/cell between male and female sham groups (Figure 3D left and Figure 4D left, respectively). Microglia morphology data were normalized to male or female sham group in order to determine changes after MCA occlusion according to sex and brain regions; summary graphs of these normalized data are shown in Figure 5D and Figure 5E. Our analysis reveals that microglia process endpoints/cell were different after MCA occlusion according to region and sex (two-way ANOVA: region F(5,86)=4.74, p = 0.0007, sex: F(1,86)=18.29, p < 0.0001, interaction F(5,86)=4.74, p = 0.0007). However, a significant interaction effect, observed here, indicates that the two factors sex and ischemia are interdependent. On the other hand, microglia process length/cell after MCA occlusion was not altered by either sex or region (Figure 5D; two-way ANOVA: region F(5,86)=1.93, p=0.10, sex: F(1,86)=1.04, p=0.31, interaction F(5,86)=0.49, p=0.78). Sex differences in microglia CD11b in sham mice and after 60 min MCA occlusion In addition to morphology, we examined microglia function after 60 min MCA occlusion; microglia CD11b is an important receptor to microglia phagocytosis. Example images in all male and female tissue after sham and MCA occlusion are shown in Figure 6A. Cropped single cells from photomicrographs are included to better visualize CD11b immunofluorescence. The CD11b receptor is located on cell processes as well as, to a lesser extent, on the soma (Perego et al., 2011) which we show in Figure 6B (anti-GFP shows microglia (top) with matching anti-CD11b immunofluorescence below). Unspecific secondary binding of anti-rat CY3 secondary to the ipsilateral proximal region was not detectable. Typically, the intensity of CD11b immunoreactivity is increased in response to injury (Morrison and Filosa, 2013; Perego et al., 2011). However, we show that microglia CD11b immunofluorescence staining is prevalent in female sham tissue when compared to male sham tissue (Figure 6C; Student’s t-test: p = 0.03). In addition to these baseline sex differences, we also observed sex differences in microglia CD11b immunofluorescence after 60 min MCA occlusion. For this analysis, CD11b data was normalized to male or female sham group in order to determine changes after MCA occlusion according to sex and brain regions; summary graphs of these normalized data are shown in Figure 6D (two-way ANOVA: region F(5,86)=8.74, p=0.07, sex: F(1,86)=13.12, p=0.0001, interaction F(5,86)=7.44, p=0.11). Post-hoc testing reveal that changes to microglia CD11b is robust after 60 min of MCA occlusion in male proximal brain regions but absent in the female tissue. To summarize: 1) constitutive CD11b immunofluorescence is greater in females than males; 2) in female mice, constitutively high CD11b remains unchanged after 60 min MCA occlusion whereas, 3) in male mice, constitutively low CD11b is robustly increased in proximal ipsilateral regions after 60 min of MCA occlusion. 1.3 Discussion We provide evidence of sex differences in the frequency of astrocyte Ca2+ elevations and microglia volume after 60 min MCA occlusion which was measured in acute brain slices. Using IHC methods, we show that astrocytes and microglia have a robust immediate response to MCA occlusion that is sex dependent. Significant changes in the ipsilateral hemisphere immediately after MCA occlusion included: increased presence of non-somatic S100β; un-polarized AQP4; and higher microglia CD11b immunofluorescence in male but not female mice. In addition, the prevalence of microglia CD11b immunofluorescence at baseline in females, when compared to males, brings to light sex differences in constitutive microglia function which, we suggest, may have a role in determining male and female microglia responses to ischemia. Detrimental neuronal cortical spreading depolarizations and glutamate excitotoxicity, hypothesized to occur in the peri-infarct region following ischemia (Hinzman et al., 2015), stands as an early injurious event following stroke as well as a mechanism of delayed neuronal cell death (Dirnagl et al., 1999). Increased astrocyte Ca2+ elevations, mediated in part by neuronal release of glutamate (Kim et al., 1994), also contributes to edema (Thrane et al., 2011) and the neurotoxic events after ischemia (Ding et al., 2009; Hansson and Ronnback, 2003; Iwabuchi and Kawahara, 2009; Nedergaard and Dirnagl, 2005; Takano et al., 2009). We did not observe sex differences between our control (no surgery) groups and therefore baseline conditions did not have an effect on our post-ischemia analysis. Out data suggest that changes in the frequency of astrocyte Ca2+ elevations were small in the ipsilateral brain regions after 60 min of MCA occlusion in both male and female mice. Our findings differ from Ding and colleagues (2009) who revealed robust and sustained increases in astrocyte Ca2+ elevations measured in male mice using a photothrombotic stroke in vivo model (Ding et al., 2009). Methodological factors could account for observed differences between studies. For example, the bulk loading of Ca2+ indicators, a method used in this study, limits data collection to the cell soma and excludes detection of astrocyte Ca2+ responses in processes (Bazargani and Attwell, 2016). Therefore, our data may under-represent astrocyte Ca2+ dynamics after ischemic stroke (Srinivasan et al., 2015). Also possible, the focal ischemic injury from the filament method and MCA occlusion may not have provided sufficient cortical injury for a robust astrocyte Ca2+ response in the ipsilateral hemisphere. Methodologic constrains limited our ability to directly measure brain cell injury concurrent to ex vivo astrocyte imaging. In lieu, we measured microglia volume as an indirect indicator of cell injury. We show that microglia volume in control groups were similar and were not significantly changed after MCA occlusion in either male or female mice which suggests that brain injury was mild at this early time point. Similar to microglia volume, we did not observe sex differences in astrocyte Ca2+ elevations at baseline. However, we observed sex differences in astrocyte Ca2+ elevations after 60 min MCA occlusion. The frequency of astrocyte Ca2+ elevations in the ipsilateral hemisphere was increased in females when compared to males. It is possible that estradiol has a role in increasing astrocyte Ca2+ dynamics in female mice. In cell culture models, estradiol is shown to promote signaling mechanisms that increase intracellular Ca2+ concentrations and corresponding astrocyte Ca2+ dependent functions (Chaban et al., 2004; Kelly and Ronnekleiv, 2009). While not tested in our preparation, estradiol was reported to increase cytoplasmic Ca2+ release in cultured hypothalamic astrocytes collected from both males and females but not in females with estrogen receptor knockout (Kuo et al., 2010). It has also been shown that elevated intracellular Ca2+ stimulates astrocyte mitochondrial metabolism to maintain vital energy resources during the first few hours after ischemia. In this case, increased intracellular Ca2+ is associated with markedly improved post-stroke neurological outcomes (Zheng et al., 2010; Zheng et al., 2013). Taken together our data supports increased frequency of astrocyte Ca2+ elevation as a mechanism driving dichotomous stroke outcomes between males and females. However, it remains that our understanding of sex differences on constitutive or injury-evoked astrocyte Ca2+ dynamics in adult mice and resulting influence on brain function remains incomplete and is an area of study that warrants additional investigation. In addition to measuring astrocyte Ca2+ dynamics, we investigated the potential of sex differences in the location of astrocyte AQP4 and S100β, proteins suspected to play a role in brain injury after ischemic stroke (Benfenati et al., 2011; Donato et al., 2009; Kitchen et al., 2015; Vella et al., 2015). Under physiological conditions, AQP4 is highly polarized to astrocyte endfeet rather than non-endfeet processes and/or soma (Potokar et al., 2013). Our analysis reveals that AQP4 polarity is different between sham male and female mice, however, this finding was not consistent to both distal and proximal brain regions. Others have determined that estrogen increases AQP4 mRNA and protein quantities in adult mice (Shin et al., 2011). Following brain injury and ischemia, AQP4 expression is also increased (Fukuda and Badaut, 2012; Ribeiro Mde et al., 2006; Vella et al., 2015). Un-polarized AQP4 has been reported in proximity to the brain injury following more extended time points after stroke (Wang et al., 2012) and traumatic brain injury (Liu et al., 2015; Ren et al., 2013); a change in AQP4 polarity or absence of AQP4 impairs glymphatic clearance after injury (Iliff et al., 2014). Thus, we examined sex differences in AQP4 polarity (a distribution pattern) after 60 min MCA occlusion, rather than AQP4 quantity. Similar to others, we demonstrate that AQP4 is un-polarized in brain regions proximal to the ischemia induced by MCA occlusion in male mice. AQP4 also became un-polarized in female tissue, however, not as profoundly different as observations in male tissue. The lesser response noted in female proximal region is likely influenced by the normalization to sham, which was increased the female proximal region versus male. Therefore, our data best illustrate that the change from sham conditions was not as profound in female mice when compared to male. A change in AQP4 polarity just after 60 min of MCA occlusion is an indicator that AQP4 vesicle trafficking or insertion to the plasma membrane surface is disturbed due to cytotoxic events, cell swelling, and/or rearrangement of the cytoskeleton during gliosis (Potokar et al., 2013). Ensuring that AQP4 is correctly localized to endfeet is central to managing edema and ensuring efficient glymphatic clearance (Plog et al., 2015), both factors important to stroke recovery. S100β is an astrocyte Ca2+ binding protein and small molecular messenger present in the astrocyte cytoplasm. Astrocytes release S100β in macro-molar concentrations after brain injury to act as a damage-associated molecular pattern (DAMP) molecule to promote inflammatory responses and affect astrocyte-microglia communication (Bianchi et al., 2010; Donato et al., 2009; Zhang et al., 2011). As such, S100β is of increasing interest as a potential biomarker of brain injury and for its role in exacerbating inflammatory responses after stroke and traumatic brain injury (Dayon et al., 2011; Kiechle et al., 2014; Pham et al., 2010). The area of non-somatic S100β immunoreactivity was similar between male and female sham mice and therefore did not influence post-ischemia analysis. After ischemia, the area of non-somatic S100β is increased in males, with a lesser effect observed in female mice. In its role as a biomarker, Plog et al. (2015) provide evidence that S100β moves from brain parenchyma to the plasma via the glymphatic system and that the clearance of S100β to plasma is significantly impaired by un-polarized AQP4 distribution after traumatic brain injury or with the absence of AQP4 (APQ4-null mice). It will be vital to further clarify the role of sex differences in AQP4 polarity and glymphatic clearance of biomarkers such as S100β to the plasma. Such data is necessary to ensure the validity of interpreting peripheral concentrations of S100β as a biomarker of brain injury after stroke in males and females. In conjunction with astrocytes, microglia cells have a robust and immediate response to injury. In a previous study we characterized the early microglia morphologic and functional response to 60 min MCA occlusion in male mice (Morrison and Filosa, 2013). We extend these findings and now show sex differences in microglia morphology immediately following MCA occlusion, however these changes are subtle. There was no sex differences in baseline microglia ramification observed in sham animals. However, following MCA occlusion, there were sex differences in the number of microglia process endpoints per cell and no sex differences in process length/cell. We also reveal evidence of sex differences in microglia function. Microglia CD11b is an integrin receptor key to microglia phagocytosis of endogenous structures and debris after ischemia (Kettenmann et al., 2011; Wake et al., 2009). We show that CD11b immunofluorescence is constitutively high in female sham tissue compared to males and remains unchanged after ischemic stroke whereas, in males, constitutively low levels of CD11b immunofluorescence is increased after brain ischemia. We suggest that elevated CD11b expression pattern prior to ischemia, observed in female mice, enhances microglia capacity to phagocytize necrotic debris and cell contents that may otherwise exacerbate neurotoxicity and neuronal death after stroke. Additional studies are necessary to clarify the benefits of early microglia phagocytosis to improve stroke outcomes. We employ IHC methods in this study rather than other methods that quantify targeted antigens in tissue lysate; IHC is ideally suited to assess the location and distribution of targeted antigens. We and others have noted changes in AQP4 or S100β distribution, to become more diffuse, under experimental conditions or cell distribution (Dyck et al., 1993; Ren et al., 2013; Wang et al., 2012). However, IHC methods have inherent limitations and several factors must be considered when determining changes in AQP4 and S100β location and data interpretation (e.g. tissue integrity and associated diffusion of antibodies, unspecific immunodetection). To address this, we determined that there was negligible unspecific secondary immunoreactivity (for both astrocyte and microglia ICH protocols) in ipsilateral proximal tissue regions. In addition we provide evidence that after just 60 min of MCA occlusion (without reperfusion) cortical tissue integrity remians. We demonstrate that astrocytes remained active and viable and microglia volume was unchanged in the ipsilateral hemisphere after 60 min of MCA occlusion. In addition, using IHC, microglia morphology in the ipsilateral proximal tissue remained ramified and complex rather than amoeboid. Taken together, our observations support the notion that tissue integrity in cortical regions imaged in this study were not severely compromised (as seen after ischemia and 24hr of reperfusion) so as to introduce unspecific biding during IHC protocols that would confound data analysis and interpretation. We also acknowledge that sex differences in brain infarct size in this mouse model of ischemic stroke has been previously shown after ischemia and 24hr of reperfusion, a conventional time point to measure infarct size due to the methodological constraints of 2,3,5-Triphenyltetrazolium chloride (TTC) staining (Banerjee et al., 2013; Bederson et al., 1986; Isayama et al., 1991; Liszczak et al., 1984; Shin et al., 2011). In this study, infarct size was not measured after 60 min of MCA occlusion because of the early time point and methodological constraints. Sex differences in ischemic injury at this early time-point post stroke may exist and therefore may be a source of variability we observe in our data analysis. 1.4 Conclusions We present data of sex differences in astrocyte Ca2+ elevations as well as the astrocyte and microglia proteins known to have an important role in the evolution of brain injury after stroke. These findings are critical to contributions toward understanding sex differences not only in brain physiology but also stroke pathobiology. As we continue to elucidate origins of dichotomous stroke outcomes between the sexes, we move closer to the development of sex-specific and successful stroke therapies. Importantly, we address changes occurring at an early time point (prior to reperfusion) following ischemia with the goal to better understand and define the cellular targets involved in the evolution of ischemic stroke injury. This study received financial support from NIHLB (R01HL089067) to JAF, NINR (1F32NR013611) to HWM Abbreviations Ca2+ Calcium MCA Middle Cerebral Artery AQP4 Aquaporin 4 Figure 1 Astrocyte Ca2+ elevations in male and female mice after 60 min MCA occlusion A) Experimental protocol for ex vivo Ca2+ imaging of acute brain slices after 60 min MCA occlusion. B) Representative Ca2+ traces acquired from male and female mice: no surgery (aCSF), contralateral, distal ipsilateral and proximal ipsilateral brain regions. C) Summary data of area under the curve (AUC) from Ca2+ traces acquired from spontaneously active astrocytes in male and female brain slices without surgery (left) and after 60 min MCA occlusion (right). N (male/female animals): No surgery (11/10), contralateral (16/11), distal ipsilateral (7/9); and proximal ipsilateral (5/11). AUC in male and female no surgery groups (left, mean and SEM) are compared using unpaired Student’s t-test: p = 0.54. Astrocyte Ca2+ AUC after 60min MCA occlusion (right), are compared using two-way ANOVA (mean and SEM): region: p = 0.89, sex: p = 0.11, interaction: p = 0.68. D) Summary data of Ca2+ peak frequency from spontaneously active astrocytes from male and female brain slices without surgery (left) and after 60 min MCA occlusion (right). N (male/female animals): No surgery (12/10), contralateral (16/12), distal ipsilateral (10/10); and proximal ipsilateral (8/11). Astrocyte Ca2+ peak frequency in male and female no surgery groups (left, mean and SEM) are compared using unpaired Student’s t-test: p = 0.11. Peak frequency after 60min MCA occlusion (right) are compared using two-way ANOVA (mean and SEM): region: p = 0.16, sex: p = 0.005, interaction: p = 0.16 with Sidak multiple comparison analysis reported in figure. Figure 2 Sex differences in microglia volume after 60 min MCA occlusion A) Example of microglia photomicrographs from ex vivo imaging (left) and rendered IMARIS model (right) after 60 min MCA occlusion according to group: no surgery, contralateral and ipsilateral brain regions. Scale bar = 10µm. B) Summary data of microglia volume in male and female brain slices without surgery (left) and after 60 min MCA occlusion (right). N (male/female animals): No surgery (4/5), contralateral (11/6), distal ipsilateral (6/4) proximal ipsilateral (5/8). Microglia volume in male and female no surgery groups (left, data and SEM) are compared using unpaired Student’s t-test: p = 0.84. Microglia volume (mean and SEM) after 60min MCA occlusion (right) is compared using two-way ANOVA: region, p < 0.08, sex, p = 0.009, interaction: p = 0.17 with Sidak multiple comparison analysis reported in figure. Figure 3 Sex differences in S100β expression pattern after 60 min MCA occlusion A) Schematic drawing depicting regions imaged within cortical layers I–III in matching ipsilateral and contralateral brain sides with corresponding proximal and distal regions relative to the ischemic region. B) Example of high and low threshold binary images used to calculate non-somatic S100β. C) S100β immunostaining in male and female tissue after 60 MCA occlusion in sham, contralateral, and ipsilateral (distal and proximal) brain regions. Cropped photomicrographs corresponding to highlighted square shown in first row illustrate additional detail of somatic and non-somatic immunofluorescence. All data was collected using full sized photomicrographs (Scale bars = 10µm). D) Summary data of non-somatic S100β after sham procedure (left) and after 60 min MCA occlusion (right) in male and female mice. N (male/female animals): Distal: Sham (9/6), contralateral (9/8), ipsilateral (9/8); Proximal: Sham (9/6), contralateral (9/8), ipsilateral (9/8). Non-somatic S100β in male and female sham mice (mean and SEM) are compared using an unpaired Student’s t-test: distal p = 0.89; proximal, p = 0.81. Non-somatic S100β after 60min MCA occlusion in male and female mice (mean and SEM) are compared using two-way ANOVA: region, p= 0.0007, sex, p= 0.0019, interaction: p= 0.12 with Sidak multiple comparison analysis is reported in the figure. Figure 4 Sex differences in astrocyte AQP4 polarity after 60 min MCA occlusion A) Example of high and low threshold binary images used to calculate AQP4 polarity. B) AQP4 immunostaining in male and female tissue after 60 min MCA occlusion in sham, contralateral, and ipsilateral brain regions. Cropped photomicrographs corresponding to highlighted squares shown in first row depicting additional details of polarized and un-polarized AQP4 expression pattern. All data was collected using full sized photomicrographs (Scale bars = 10µm). C) Summary data of AQP4 polarity after sham procedure (left) and after 60 min MCA occlusion in male and female mice. N (male/female animals): Distal: Sham (9/6), contralateral (9/8), ipsilateral; Proximal: Sham (9/6), contralateral (9/8), ipsilateral. Un-polarized AQP4 in male and female sham mice (mean and SEM) are compared using an unpaired Student’s t-test: distal, p = 0.10; proximal p = 0.05. Un-polarized AQP4 after MCA occlusion in male and female mice (mean and SEM) are compared using two-way ANOVA: region p = 0.0089, sex: p < 0.0001, interaction: p = 0.064. Sidak multiple comparison analysis is reported in the figure. Figure 5 Microglia morphology in male and female mice after 60 min MCA occlusion A) Microglia GFP immunostaining in male and female tissue after sham or 60 min MCA occlusion in contralateral, and ipsilateral distal and proximal brain regions. Cropped photomicrographs (below) show processes morphology details of an individual microglia. Analysis was completed on full sized photomicrographs (Scale bar = 10µm). B) Example of photomicrographs showing the computer-aided microglia morphology analysis method using ImageJ: photomicrographs are despeckled, converted to a binary image, skeletonized and then tagged using skeleton analysis plugin for data collection. The analyze skeleton plugin identifies and tags skeletonized processes (orange) and endpoints (blue) http://imagejdocu.tudor.lu/doku.php?id=plugin:analysis:analyzeskeleton:start. C) Summary data of microglia process endpoints/cell after sham procedure (left) and after 60 min MCA occlusion in male and female mice: N (male/female animals): distal: sham (7/6), contralateral (9/9), ipsilateral (9/9); proximal: sham (7/6), contralateral (9/9), ipsilateral (9/9). Microglia endpoints/cell in male and female sham mice (mean and SEM) are compared using an unpaired Student’s t-test: distal, p = 0.44; proximal p = 0.74. Process length/cell after MCA occlusion in male and female mice (mean and SEM) are compared using two-way ANOVA: region p = 0.0001, sex: p < 0.0001, interaction: p = 0.0007 with Sidak multiple comparison analysis is reported in figure. D) Summary data of microglia process length/cell after sham procedure (left) and after 60 min MCA occlusion in male and female mice. N (male/female animals): distal: sham (7/6), contralateral (9/9), ipsilateral (9/9); proximal: sham (7/6), contralateral (9/9), ipsilateral (9/9). Microglia process length/cell in male and female sham mice (mean and SEM) are compared using an unpaired Student’s t-test: distal, p = 0.98; proximal p = 0.57. Process length/cell after MCA occlusion in male and female mice (mean and SEM) are compared using two-way ANOVA; region p=0.10, sex: p<0.31, interaction p=0.78. Figure 6 Microglia CD11b immunofluorescence in sham male and female mice and after 60 min MCA occlusion A) Microglia CD11b immunostaining in male and female tissue after sham or 60 min MCA occlusion in contralateral, and ipsilateral distal and proximal brain regions. Bottom row, cropped photomicrographs showing details for an individual microglia CD11b distribution. B) GFP and CD11b immunostaining from a single microglia. C) Summary data of microglia CD11b after sham procedure (left) and after 60 min MCA occlusion in male and female mice. N (male/female animals): Distal: Sham (8/6), contralateral (9/8), ipsilateral (9/8); Proximal: Sham (8/6), contralateral (9/8), ipsilateral (9/8). Summary data and analysis of microglia CD11b total fluorescence intensity (TFI)/cell in male and female sham tissue using Student’s t-test: distal, p = 0.07; proximal, p = 0.05. Microglia CD11b TFI/cell after 60min MCA occlusion (mean and SEM) are compared using two-way ANOVA: region p = 0.07, sex: p < 0.0001, interaction: p = 0.11 with Sidak multiple comparison analysis is reported in figure. Highlights Astrocyte Ca2+ dynamics are different in male and female mice after ischemia. Sex differences in astrocyte AQP4 polarity and non-somatic S100β after ischemia. Constitutive microglia CD11b is high in female sham cortex when compared to males. After ischemia, microglia CD11b immunoreactivity is not changed in female mice. Low baseline CD11b immunoreactivity is increased after ischemia in male mice. This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final citable form. Please note that during the production process errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain. Disclosure HWM contributed to the experimental design, execution of data collection, data analysis, data interpretation, and manuscript writing. JAF contributed to design of experiments, overall interpretation of data and manuscript editing. All authors read and approved the final manuscript. 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PMC005xxxxxx/PMC5118182.txt
LICENSE: This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. 8902541 3967 Head Neck Head Neck Head & neck 1043-3074 1097-0347 27265898 5118182 10.1002/hed.24519 NIHMS812089 Article Effect of surgical intervention on circulating tumor cells in patients with squamous cell carcinoma of the head and neck using a negative enrichment technology Jatana Kris R. MD 12* Balasubramanian Priya PhD 3 McMullen Kyle P. MD 2 Lang Jas C. PhD 2 Teknos Theodoros N. MD 2 Chalmers Jeffrey J. PhD 3 1 Department of Pediatric Otolaryngology – Head and Neck Surgery, Nationwide Children's Hospital, Columbus, Ohio 2 Department of Otolaryngology – Head and Neck Surgery, Wexner Medical Center at Ohio State University, Columbus, Ohio 3 William G. Lowrie Department of Chemical and Biomolecular Engineering, Ohio State University, Columbus, Ohio. * Corresponding author: K. R. Jatana, Department of Otolaryngology – Head and Neck Surgery, Nationwide Children's Hospital, 555 South 18th Street, Suite 2A, Columbus, Ohio 43205. Kris.Jatana@osumc.edu 1 9 2016 5 6 2016 12 2016 01 12 2016 38 12 17991803 This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. Background The purpose of this study was to investigate the impact of surgical intervention on detection of circulating tumor cells (CTCs) in patients with squamous cell carcinoma of the head and neck (SCCHN.) Methods We utilized a negative depletion technique to identify cytokeratin (CK)-positive CTCs. The numbers of CTCs immediately before and after surgical resection were compared. Results Seventy-six blood samples from 38 patients with SCCHN were examined. Seventy-nine percent of the patients had CTCs detected before and after surgery. A total of 7.89% had no CTCs before surgery, yet had CTCs identified after surgery. Overall, 60.5% of patients had an increased number of CTCs/mL after surgery with a mean increase of 6.63-fold. A statistically significant increase in CTCs was seen after surgery (p = .02). Conclusion The timing of sample collection in patients with SCCHN who have surgical intervention can potentially impact the number of CTCs identified. circulating tumor cell squamous cell carcinoma surgery immunomagnetic separation INTRODUCTION Cancer of the upper aerodigestive system is estimated to have 59,340 cases in the United States in 2015 and comprise 3.5% of all cancers.1 Squamous cell carcinoma of the head and neck (SCCHN) makes up approximately 95% of these tumors. Despite medical advances, the overall 5-year survival rate of approximately 50% has not changed significantly over the last several decades.2–4 Studies in other solid cancers, such as breast,5 prostate,6 lung,7,8 and colon cancers,9 have shown that the presence of circulating tumor cells (CTCs) that disseminates from the primary tumor has prognostic significance, and this dissemination may be an important step in hematogenous metastasis. We have demonstrated that CTCs can be detected in the peripheral blood of patients with SCCHN and the presence of CTCs correlated with reduced short-term disease-free survival.10 Before our studies, Partridge et al11 used a similar negative depletion technology and found that detection of disseminated tumor cells in patients with SCCHN correlated with a higher risk of local/distant recurrence as well as reduced survival.11 In inoperable SCCHN, the presence of CTCs has been linked to regional lymph nodal staging of 2b or higher.12 To date, the presence of lymph node metastasis in SCCHN is the most predictive prognostic factor that impacts survival.13,14 Beyond basic enumeration of CTCs in a patient's blood, it has also been reported that CTCs may appear in the blood stream because of mechanical manipulation of the tumor during surgical intervention,15–18 fine-needle aspirations,19 during colonoscopy,20 and endorectal ultrasound.21 The release of these cells is a potential concern on multiple levels, the least of which is influencing traditional CTC counts. As far as we know, CTC counts before and after open surgical resection in the operating room has not been performed in SCCHN. Our previously published SCCHN studies have used blood samples taken after surgical intervention. The head and neck region is a highly vascularized tissue. A released cell, such as a CTC, potentially could enter circulation after physical manipulation during surgery, through lymphatics or veins that return blood to the superior vena cava to the right atrium and subsequently the ventricle of the heart. From the right side of the heart, this blood circulates to the lungs for oxygenation through a capillary network and then returns to the heart for pumping into arterial circulation where distal end organs again contain a capillary network before entering venous circulation and returning to the heart. A common assumption of CTC is that they are relatively large compared to normal peripheral blood cells; several methodologies to identify CTCs are based on size alone.22,23 With head and neck surgery, the first small vasculature that such a proposed released cell would encounter would be the capillary network in the lungs. It should be noted, however, as we have reported previously, that the relative size of the putative CTCs in our previous studies are similar in size to normal peripheral blood cells. Such cells may continue to repeatedly circulate around the body. MATERIALS AND METHODS This study was approved by the Institutional Review Board. Informed consent was obtained from patients who were undergoing surgical intervention at the Arthur G. James Cancer Hospital and Solove Research Institute and Comprehensive Cancer Center at The Ohio State University. Inclusion criteria were adults >18 years with histologically confirmed SCCHN undergoing an open surgical excision of the primary tumor. Exclusion criteria included patients with known metastases and any patient who received a blood transfusion intraoperatively. Peripheral venous blood samples were procured from 38 patients (total of 76 samples.) Five to 10 mL were collected in green-top BD Vacutainer tubes immediately before and after surgery while in the operating room. Each venous sample was collected from an extremity (arm or leg) where the intravenous fluids were not being administered and the initial 2 to 3 mL was drawn off and discarded to prevent contamination. A fresh syringe was then used to obtain the sample. The samples were stored at 4°C and were processed within 24 hours. Operators were completely blinded to the time point of the samples as well as the clinical and correlative information during the sample processing and CTC enumeration steps. The CTC enrichment process has been previously discussed in detail.24 Briefly, the red blood cells were lysed using a lysis buffer and the remaining leukocytes were immunomagnetically labeled using anti-CD45 tetrameric antibody complex and dextran-coated magnetic nanoparticles (cat #18259; Stem Cell Tech, Vancouver, BC). The magnetically labeled cells were then passed through our optimized immunomagnetic separation system, to deplete a majority of the leukocytes. An aliquot of the enriched sample containing the CTCs was used for CTC enumeration. Cell suspension containing CTCs was stored in 10% neutral buffered formalin until further processing. Cells were cytospun onto a microscopic slide using a Shandon Cytospin instrument at 1800 rpm for 5 minutes. The cytospun slides were hydrated in phosphate-buffered saline before staining with anti-cytokeratin fluorescein isothiocyanate (FITC) antibody (1:10, Miltenyi Biotech, clone:CK3-6H5, 130-080-101) targeting cytokeratins 8, 18, and 19 for 30 minutes at 37°C before mounting with mounting media containing 4′,6′-diamidino-2-phenylindole (DAPI; Vector Laboratories, H-1500). Slides were observed under a Nikon 80i epifluorescent microscope equipped with band pass filters for diamidino-phenylindole (DAPI) and FITC emission, and cells that were positive for both FITC and DAPI and had high nuclear to cytoplasmic ratios were counted as CTCs. Images of the slides were taken using a Zeiss LSM510 confocal microscope. The number of CTCs per mL of peripheral blood was calculated. Blood samples were drawn from healthy volunteers or patients with benign conditions and processed in the same manner as a clinical sample. Statistical analyses were performed using GraphPad Prism version 6 (San Diego, CA). The D'Agostino and Pearson omnibus normality test was performed to test if the CTC counts before or after surgery were normally distributed. Wilcoxon matched-pair sign rank test was used to determine if there was a statistically significant difference between CTC numbers before and after surgery. Any p value ≤ .05 was considered statistically significant. RESULTS A total of 38 patients with SCCHN (mean age, 64.2 years; range, 51–83 years) who all underwent open surgical excision in the operating room, had their venous blood examined for CTCs. Men comprised 63% and women comprised 37% of the patients. The sites were 62% in the oral cavity, 15% in the oropharynx, and 23% in the larynx. Overall staging included: 14% stage 1; 20% stage 2; 26% stage 3; and 40% stage 4. Figures 1 and 2 display examples of enriched patient samples from a patient in which no change in putative CTC concentration was observed, and a second patient in which a large increase in CTC concentration was observed. Overall, as shown in Table 1, CTCs were detected in 79.0% of patients before and after surgery. It was noted that 7.89% of patients had detected CTCs after surgical intervention when none were detected in the before sample. An additional 10.5% of patients had CTCs detected in sample before surgery, but not in the after surgery sample. The D'Agostino & Pearson omnibus normality test showed that the data were not normally distributed (p value < .0001 for both presurgery and postsurgery). Because the data were not normally distributed, a nonparametric Wilcoxon matched-pair sign rank test was performed to test for statistical significance. There was a significant difference in CTC counts using matched pairs analysis as a result of surgical intervention (2-tailed p value = .0224). In particular, CTCs measured soon after surgery were significantly higher than CTCs measured before surgery (1-tailed p value = .0112). There was no correlation to age, sex, or overall stage of cancer. There was no correlation between CTCs and positive margins, disruption of tumor or aerodigestive tract, or length of surgery. It was found that 60.5% of patients had an increased number of CTCs after surgical intervention (see Figure 3). The range of CTCs in the peripheral blood before/after surgical intervention from oral cavity, oropharyngeal, and laryngeal sites is shown in Figure 4. None of the healthy control blood samples had similar, brightly stained, cytokeratin-positive cells, or cells with any morphology resembling CTCs. DISCUSSION There has been limited data on the impact of an intervention on SCCHN with regard to CTCs. Ramani et al25 looked at the presence of cytokeratin (CK)-19 by reverse transcriptase-polymerase chain reaction before and after incisional biopsy of oral cavity squamous cell carcinoma. They found that, in the 10 patients studied, there was no dissemination of cancer cells after incisional biopsy in these patients.25 A prior study by Kusukawa et al26 demonstrated the detection of CK-19 reverse transcriptase-polymerase chain reaction in this same tumor site, and reported that dissemination of cancer cells into circulation does occur after an incisional biopsy. Although both of these studies looked at the presence of mRNA alone, neither had visual conformation of CTCs. Studies by Ohtake et al27 have shown that an incision has caused increased lymph node metastasis in dimethylbenz[a]anthracene-induced tongue cancer in the hamster model; the incidence of regional lymph node metastasis increased by 65.9% after repeated incisions of the lesion. It is not clear what the clinical relevance of such findings is at this time. It has been suggested that CTCs may be destroyed in the microvascular capillary networks by the host immune surveillance system, including macrophages and natural killer cells.28 We have identified CTCs in the blood from the distal extremity venous system with patients with SCCHN undergoing open surgical resection +/− cervical lymphadenectomy, meaning that these CTCs have gone through a minimum of 2 capillary networks (likely circulating numerous times) before detection. The open surgical procedures ranged from approximately 90 minutes to 6 hours duration. As shown in Figures 1 and 2, clumps of CTCs are seen postsurgery, but these aggregates likely would form intravascularly after passing through capillary circulation. The mechanisms by which this happens is not yet elucidated, but the CTCs in SCCHN are likely of similar size to circulating leukocytes. Some have reported that CTCs may be only transiently detectable, and that it is a dynamic and periodic event.29 There are several unanswered questions with regard to timing of blood sample collection when any tumor-related intervention is performed, the location of venous blood sample collection with regard to the tumor location, and what clinical relevance exists. Each solid cancer should be individually investigated as the specific protocols of sample collection with invasive procedures may be critical and influence CTC detection. This is important as most published studies with CTCs in all solid cancers have not addressed this issue in the literature. Even within a specific type of cancer, like SCCHN, the tumor location may also influence identification of CTCs, as shown in Figure 4. Another important concept to consider with respect to the concentration of these rare cells is the intravascular fluid balance in patients under general anesthesia during these surgical procedures. There is always an estimated blood loss that occurs. None of the patients in this study received any blood transfusion; however, all surgical patients had a positive fluid balance, indicating they received additional intravenous fluid (directly into a distal vein, unrelated to the location of the blood sample taken for this study), which increases blood volume several fold more than the estimated blood loss, resulting in hemodilution. Because of dilution of the blood, the concentration of CTCs/mL blood may be underestimated. We have previously demonstrated some of the cells we are reporting as putative CTC in this study are also epithelial cell adhesion molecule negative, cytokeratin and vimentin positive, and can be further positive for epidermal growth factor receptor or CD44.30 At this point, it is unclear what, if any, clinical significance can be associated with these changes in concentrations of putative CTC after surgery. Epithelial to mesenchymal transition may occur as cancer cells acquire a more aggressive migratory phenotype.31–34 It is possible that these surgically released CTCs are inherently different than CTCs that enter the intravascular space naturally. None of the 7.89% of patients who had CTCs detected postoperatively, not preoperatively, developed locoregional disease recurrence or distant disease recurrence. Further characterization of these CTCs identified before and after surgery, with multimarker analysis in combination with long-term clinical follow-up may yield a greater understanding of the role of surgically released CTCs in SCCHN. CONCLUSIONS A statistically significant increase in the CTC counts immediately after surgical intervention, while still in the operating room, was seen in patients with SCCHN. The timing of blood sample collection for such solid cancers that undergo surgical intervention, such as SCCHN, can potentially impact the number of CTCs identified. Although a prognostic blood test for CTCs could have important treatment and surveillance implications, the viability and clinical significance of potentially surgically released CTCs in SCCHN is still not known; it is possible that these cells have a different phenotype than CTCs that enter the intravascular space by other mechanisms. Contract grant sponsor: This work was supported by the following agencies: the National Science Foundation (BES-0124897); the National Cancer Institute (R01 CA97391-01A1); the State of Ohio Third Frontier Program (ODOD 26140000:TECH 07-001); the National Cancer Institute CCC Core Grant (P30 CA16058), and the National Science Foundation (EEC 0425626). FIGURE 1 Representative patient with squamous cell carcinoma of the head and neck (SCCHN) sample with no change in circulating tumor cells/mL peripheral blood post-surgery (a) compared to pre-surgery (b), as determined by dual color immunofluorescent staining: green = cytokeratin; blue = diamidino-phenylindole. FIGURE 2 Representative patient with squamous cell carcinoma of the head and neck (SCCHN) sample demonstrating a 2.5-fold change in circulating tumor cells/mL peripheral blood post-surgery (a) compared to pre-surgery (b), as determined by dual color immunofluorescent staining: green = cytokeratin; blue = diamidino-phenylindole. FIGURE 3 Ladder plots displaying the number and degree of circulating tumor cell increase (left) and decrease (right) in pre-surgical and post-surgical specimens. [Color figure can be viewed in the online issue, which is available at wileyonlinelibrary.com] FIGURE 4 Changes in circulating tumor cells (CTCs)/mL of peripheral blood before and after surgical intervention by general site of tumor (L = larynx; OC = oral cavity; OP, oropharynx). Each data point, minimum and maximum, is shown for these sites. [Color figure can be viewed in the online issue, which is available at wileyonlinelibrary.com] TABLE 1 Correlation between circulating tumor cell detection and the time of distal venous blood draw (presurgery or postsurgery) in 38 patients undergoing surgical intervention for squamous cell carcinoma of the head and neck. Before surgical intervention After surgical intervention Overall frequency Negative Negative 1/38 (2.6%) Negative Positive 3/38 (7.89%) Positive Negative 4/38 (10.5%) Positive Positive 30 (79.0%) 34/38 (89.5%) positive 33/38 (86.8%) positive REFERENCES 1 Siegel RL Miller KD Jemal A Cancer statistics, 2015. 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PMC005xxxxxx/PMC5118191.txt
LICENSE: This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. 101129617 30409 Genes Brain Behav Genes Brain Behav. Genes, brain, and behavior 1601-1848 1601-183X 27489246 5118191 10.1111/gbb.12314 NIHMS807658 Article Functional conservation of MBD proteins: MeCP2 and Drosophila MBD proteins alter sleep Gupta Tarun 1 Morgan Hannah R. 2 Bailey Jessica A. 2 Certel Sarah J. 12* 1 Neuroscience Graduate Program, The University of Montana, Missoula, MT 2 Division of Biological Sciences and Center for Structural and Functional Neuroscience, The University of Montana, Missoula, MT 59812 * Corresponding author: sarah.certel@umontana.edu 12 8 2016 6 9 2016 11 2016 01 11 2017 15 8 757774 This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. Proteins containing a methyl-CpG-binding domain (MBD) bind 5mC and convert the methylation pattern information into appropriate functional cellular states. The correct readout of epigenetic marks is of particular importance in the nervous system where abnormal expression or compromised MBD protein function, can lead to disease and developmental disorders. Recent evidence indicates the genome of Drosophila melanogaster is methylated and two MBD proteins, dMBD2/3 and dMBD-R2, are present. Are Drosophila MBD proteins required for neuronal function, and as MBD-containing proteins have diverged and evolved, does the MBD domain retain the molecular properties required for conserved cellular function across species? To address these questions, we expressed the human MBD-containing protein, hMeCP2, in distinct amine neurons and quantified functional changes in sleep circuitry output using a high throughput assay in Drosophila. hMeCP2 expression resulted in phase-specific sleep loss and sleep fragmentation with the hMeCP2-mediated sleep deficits requiring an intact MBD-domain. Reducing endogenous dMBD2/3 and dMBD-R2 levels also generated sleep fragmentation, with an increase in sleep occurring upon dMBD-R2 reduction. To examine if hMeCP2 and dMBD-R2 are targeting common neuronal functions, we reduced dMBD-R2 levels in combination with hMeCP2 expression and observed a complete rescue of sleep deficits. Furthermore, chromosomal binding experiments indicate MBD-R2 and MeCP2 associate on shared genomic loci. Our results provide the first demonstration that Drosophila MBD-containing family members are required for neuronal function and suggest the MBD domain retains considerable functional conservation at the whole organism level across species. methyl-CpG Binding Protein 2 (MeCP2) MBD proteins Drosophila sleep octopamine methylation Introduction Gene expression and even more fundamentally, DNA architecture, is controlled by chemical modifications on histone proteins and DNA. In plants, vertebrates and more recently Drosophila, the chemical mark is an added methyl group at position 5 of cytosine (5mC) (Capuano et al., 2014, Gehring, 2013, Schubeler, 2015, Takayama et al., 2014, Varriale, 2014, Zilberman, 2008). Most methyl-CpG binding domain (MBD)-containing proteins bind methylated DNA and function to translate the chemical modification into appropriate cellular states (Bogdanovic & Veenstra, 2009, Fatemi & Wade, 2006, Sasai & Defossez, 2009). By interacting with diverse partners, MBD-containing proteins regulate the differentiation and function of a cell by maintaining or altering chromatin structure, interpreting genomic imprinting, gene-specific transcriptional activation/repression and controlling RNA splicing (Chahrour & Zoghbi, 2007, Lyst & Bird, 2015, Samaco & Neul, 2011). Due to this wide array of nuclear functions, MBD-containing proteins and in particular, the MBD family member, methyl-CpG-binding protein 2 (MeCP2), have been described as genome-wide modulators of gene expression and cellular differentiation (Cohen et al., 2011, Della Ragione et al., 2012, Skene et al., 2010, Yasui et al., 2013). Alterations in MeCP2 levels, either through loss-of-function mutations or gene duplication, results in the postnatal neurodevelopmental disorders, Rett Syndrome (RTT) and MeCP2 duplication syndrome. MeCP2 dysregulation is also an important component of neuropsychiatric and neurological disorders ranging from Alzheimer’s and Huntington’s to depression and drug addiction (Ausio et al., 2014, Hutchinson et al., 2012, Lv et al., 2013, Ramocki et al., 2009, Zimmermann et al., 2015). One prevalent phenotype among children with alterations in MeCP2 function and a common feature of neurodegenerative disease and neuropsychiatric disorders is sleep abnormalities (Angriman et al., 2015, Kakkar & Dahiya, 2015, Mccarthy & Welsh, 2012, Musiek et al., 2015). Such sleep impairments include delays in the onset of sleep, alterations in total sleep, and frequent wakings resulting in fragmented sleep (Cortesi et al., 2010, Nomura, 2005, Piazza et al., 1990, Souders et al., 2009, Young et al., 2007). Recently, it has become increasingly clear that epigenetic factors play fundamental roles in transcriptional and post-transcriptional regulation within the circadian clock network (Liu & Chung, 2015, Qureshi & Mehler, 2014). For example, mouse studies indicate day length changes alter promoter DNA methylation within the SCN and in humans methylation levels display a 24-hr rhythmicity (Angriman et al., 2015, Kakkar & Dahiya, 2015) (Azzi et al., 2014). In Drosophila, many oscillatory transcripts including several non-coding RNAs have been identified, (Hughes et al., 2012), in mice two miRNAs, miR-134 and miR-132, are implicated in circadian regulation, MeCP2 regulates miR-134 processing in the brain, and finally the levels of MeCP2 are regulated during the circadian cycle (Alvarez-Saavedra et al., 2011, Cheng et al., 2014, Gao et al., 2010) Therefore, as sleep is a relevant behavior at the molecular and phenotypic level, we used the well-characterized sleep paradigm in Drosophila to ask if MBD-containing protein family members from different species retain the functional conservation required for neuronal output. Sleep and arousal are regulated by multiple neurotransmitters including octopamine, dopamine, γ-aminobutyric acid (GABA), and serotonin (5HT) through different but interacting circuits (Cirelli, 2009, Crocker & Sehgal, 2010, Potdar & Sheeba, 2013). Due to the defined role of octopamine (OA, the invertebrate homolog of mammalian noradrenaline) in promoting wakefulness, we manipulated the OA system through a series of experiments. First, we expressed human MeCP2 (hMeCP2, the e2 isoform) and examined the cell-type specific effects on OA neuron function. Human MeCP2 was selected due to the extensive characterization of its MBD domain, the availability of a series of hMeCP2 alleles capable of conditional expression in Drosophila, and the opportunity to examine if MBD domain function is conserved from fly to human. We found that hMeCP2 expression in Drosophila leads to phase-specific sleep deficits, increased sleep latency, and sleep fragmentation. To separate the role of disrupted amine production versus disrupted neuron function, we expressed hMeCP2 in OA neurons that lacked OA and established that a portion of the nighttime sleep reduction is dependent on amine function. Next by using multiple MeCP2 alleles including the RTT-causing allele, MeCP2R106W, we determined the MBD-domain is required for the MeCP2-mediated sleep deficits. Second, as the Drosophila genome contains two proteins with extended homologies to vertebrate MBD family members and the recent confirmation of cytosine methylation in Drosophila, we asked if reducing dMBD2/3 and dMBD-R2 could also change the function of OA neurons. As with hMeCP2 expression, sleep fragmentation occurred upon dMBD2/3 and dMBD-R2 manipulation. If OA neuron function is altered due to the targeting of similar or the same genomic areas by hMeCP2 and the endogenous MBD proteins, then reducing dMBD2/3 or dMBD-R2 in conjunction with hMeCP2 expression should decrease or eliminate the hMeCP2-mediated sleep deficits. Our results indicate the phase-specific sleep deficits that occur due to hMeCP2 are rescued with a concomitant reduction in dMBD-R2 and by labeling 3rd instar larval polytene chromosomes, we found that hMeCP2 and dMBD-R2 accumulate together at distinct chromosomal bands. Finally, increasing the expression of dMBD2/3 in OA neurons decreased phase-specific sleep levels in the same manner as hMeCP2 expression. Taken together, our results provide the first demonstration that a reduction in Drosophila MBD-containing proteins can alter neuron output and indicate conservation in the cell-specific functions of epigenetic translators. Materials and methods Drosophila Stocks Canton-S, UAS-Red Stinger (BL 8545, BL 8546), UAS-mCD8:GFP (BL 5130), UAS-MBD-R2-IR (BL 30481), UAS-dMBD2/3-IR (BL 35347), UAS-EP1112 (BL16987), and UAS-EP04582 (BL15753) were obtained from the Bloomington Stock Center (Bloomington, IN). Tested EP lines obtained from the Kyoto Stock Center include DGRC #’s 201-693, 204-320, and 206-139. The UAS-MeCP2, UAS-MeCP2R294X, UAS-MeCP2R106W, and UAS-MeCP2Δ166 lines were generously provided by Juan Botas (Cukier et al., 2008). dTdc2-Gal4 was obtained from Jay Hirsh (Cole et al., 2005), th-Gal4 was provided by Sirge Birman (Friggi-Grelin et al., 2003), and trh-Gal4 was a gift from Olga Alekseenko (Alekseyenko et al., 2010). Husbandry All fly stocks were maintained in a temperature (25 °C) and humidity-controlled (~50%) environment on a standard cornmeal based medium (agar, cornmeal, sugar, yeast extract, Triton-X). During development and post-eclosion, all flies were entrained to standard 12hr-12hr light:dark (L:D) conditions under 1400 ± 200 lx fluorescent light intensity. Transgenic control males were generated by crossing Canton S females with males from the respective UAS- or gal4-lines. Before experimentation, male pupae were isolated and aged individually in 16X100mm borosilicate glass tubes containing standard food medium described above. Behavioral Analysis For activity and sleep monitoring, 2–3 day old socially naive males were transferred to 65×5mm glass tubes with 15mm food on one end and a cotton plug on the other. Flies were transferred under CO2 anesthesia and allowed 24-hr to recuperate and acclimatize to new housing conditions before data collection. The locomotor activity counts were recorded for both control and experimental males using Drosophila Activity Monitoring (DAM) system (Trikinetics, Waltham, MA) for a period of 10 consecutive days at 1-min bin acquisition mode. Count data for the first and the last day were removed to minimize mechanical noise. Data from 8 consecutive days was analyzed further using Counting Macro 5.19.5 (CM) program generously provided by R. Allada (Northwestern University, Evanston, IL). Various indices of sleep including temporal organization, duration and latency of sleep and the number and length of sleep bouts were analyzed as described previously (Pfeiffenberger et al., 2010). Sleep was defined as complete inactivity for a period of 5 consecutive minutes (Shaw et al., 2000). Graphs were generated with Graphpad Prism and Adobe Illustrator CS5. Immunohistochemistry and Imaging Adult male brains were dissected and fixed in 4% paraformaldehyde (Electron Microscopy Sciences) for 40 minutes and labeled as described previously (Certel et al., 2010). The following primary antibodies were used: rabbit anti-MeCP2 (1:30, Cell Signaling Technologies), mouse anti-MeCP2 (1:500, Abcam), rat anti-CD8 (1:100, Molecular Probes), monoclonal rabbit anti-GFP (1:200, Molecular Probes), mouse nc82 (1:100) and anti-MBD-R2 (1:200) (Prestel et al., 2010). Secondary antibodies include Alexa Fluor 488-conjugated donkey anti-mouse, Alexa Fluor 594-conjugated goat anti-rabbit, Alexa Fluor 647-conjugated donkey anti-mouse, Alexa Fluor 488-conjugated goat anti-rat cross-adsorbed antibodies (Jackson ImmunoResearch Laboratories, West Grove, PA). Brain samples were mounted in a drop of Vectashield™ (Vector Laboratories Inc, Burlingame, CA) and Images were collected on an Olympus Fluoview FV1000 laser scanning confocal mounted on an inverted IX81 microscope and processed with Image-J 1.33 (NIH) and Adobe Photoshop (Adobe, CA). Polytene Chromosome Immunofluorescence For Drosophila polytene chromosomal preparation and immunofluorescence, third instar larvae raised at raised at 25°C and dissected in 0.1% Triton X-100 solution in phosphate buffer saline (PBS). Salivary glands were placed in 250μm of solution 2 (3.7% paraformaldehyde, 1% Triton X-100 in PBS) for 30–45 seconds. Solution 2 was replaced with solution 3 (3.7% paraformaldehyde, 50% acetic acid) for another 2 minutes. Salivary glands were pipetted along with 20μl of solution 3 on siliconised glass cover slips and picked up onto a poly-L-lysine coated slide (Sigma), tapped to aid chromosomal spreading and frozen in liquid nitrogen. Cover slips were removed and slides were processed for IF as described previously (Capelson et al., 2010). Mouse α-MeCP2 was used at 1:100 and rabbit anti-dMBDR2 at 1:200 (a gift from Dr. Peter Becker). Secondary antibodies include Alexa Fluor 594-conjugated goat anti-rabbit and Alexa Fluor 647-conjugated donkey anti-mouse for spectral non-overlap with DAPI (1μg/ml) which was used as a DNA counterstain. Polytene samples were mounted in a drop of Vectashield™ and imaged as described previously. Images were processed for background subtraction and contrast enhancement with contrast-limited adaptive histogram equalization (CLAHE) in ImageJ. Theoretical PSF (point spread function) was calculated for images used for colocalization analysis followed by an iterative 2D deconvolution for each channel (macro code and algorithm parameters are available upon request). Pearson’s correlation coefficient (PCC) and Manders colocalization coefficient (MCC) were estimated and then PCC was statistically evaluated against randomized images using Costes’ randomization methods (Costes et al., 2004). Percentile based thresholding was applied to segment polytene chromosomes from the background for MCC calculations within the JaCoP plugin for ImageJ. RT-qPCR dMBD2/3 and dMBD-R2 expression levels were measured quantitatively by RT-qPCR. Heads from socially naive 3–5 day old adult males from control and experimental (n-syb-Gal4;UAS-dMBD2/3-IR, n-syb-Gal4;UAS-dMBD-R2-IR groups were extracted under CO2 anesthesia and frozen immediately in sets of three in 1.5-ml Eppendorf tubes kept in dry ice. Total RNA from each pool (~35 heads / pool) was isolated by Tri-Reagent, (Molecular Research Center, Cincinnati, OH). RNA samples were DNase treated and reverse transcribed as described previously (Hess-Homeier et al, 2014). qPCR reactions were carried out in quadruplicate for each gene and genotype on an Agilent Stratagene Mx3005P platform using following thermal protocol: 95°C – 10min; 40 X (95°C – 30sec; 53°C – 1min; 72°C – 1min) followed by 0.5°C stepwise increment from 65°C to 95°C. Cdc2c (cyclin-dependent kinase 2) reference gene was used for data normalization. Expression levels were calculated using the ΔCT method. dMBD-R2 expression was quantified from the total head RNA using the following primer pair: F: 5′-GGCCAGTTTGGATATAGCATCCC-3′ and R: 5′-GCACGATAACAGTGGGTTTCTGG-3′. For dMBD2/3, the primers used were: F: 5′-AGAAGCGACTGGAACGACTACG-3′ and R: 5′-CGGTCTGTTCGTTGACATTGGG-3′. For cdc2c reference gene, pre-designed exon-spanning primer pair PP1255 was used from the FlyPrimerBank: F: 5′-CGAGGGCACCTACGGTATAGT-3′ and R: 5′-CGCCTTCTAGCCGAATCTTTTTG-3′. Using the same experimental protocol, total RNA was recovered from UAS-AP-1muEP1112(BL#16987) controls and tdc2-gal4;UAS-AP-1muEP1112 experimental males. The tdc2-gal4 driver was used as n-syb-Gal4;UAS-AP-1muEP1112 males had subpar viability. dMBD2/3 expression was quantified using F: 5′-ACTGCCCAAGACCATAC-3′ and R: 5′-TGTCGTCCTCCGAAATG-3′. RPL32 expression was used as a reference in the EP line qPCR reactions and was amplified using the following primer set, F: 5′-ATGCTAAGCTGTCGCACAAATG-3′ AND R: 5′-GTTCGATCCGTAACCGATGT-3′. qPCR reactions were carried out in quadruplicate for each gene and genotype on an Agilent Stratagene Mx3005P platform using following thermal protocol: 95°C – 10min; 40 X (95°C – 30sec; 55°C – 1min; 72°C – 1min) followed by 0.5°C stepwise increment from 65°C to 95°C. HPLC For HPLC analysis, brains from socially naive 3–5-day old adult males from control and experimental groups were dissected in ice-cold PBS (137 mM NaCl/2.7 mM KCl/10 mM Na2HPO4/1.8 mM KH2PO4, pH 7.4) and frozen immediately in sets of three in 1.5-ml Eppendorf tubes at −20°C. To measure OA levels from the central brain, the photoreceptors were removed in all dissections. Each pool (n=15) of brains were homogenized in 150μL of ice-cold 0.05M perchloric acid containing 30 ng/mL DBA and chilled on ice before analysis. Immediately before analysis, the samples were centrifuged at 14,100g for 20 min at 4ºC. The supernatant was removed and 50μL injected into the HPLC. Amine levels were measured with an ESA CoulArray Model 5600A HPLC with electrochemical detection equipped with a C18 column (Varian), and a 200μl loop (Rheodyne). The flow rate was set at 0.8 ml/min. The mobile phase was composed of 10% acetonitrile (Fisher, HPLC grade), 14.18g monochloroacetic acid, 4.80g NaOH (pH adjusted to 3.0–3.5 with glacial acetic acid), and 0.301g sodium octyl sulfate (SOS) in 1000mL of sterile, polished water and filtered with 0.2μm filter. The electrodes were set at −50, 0, 100, 200, 300, 400, 500, 600, 700, 800, 900, and 920 mV. OA was detected in the 600-mV channel. Retention times and concentrations of the amines were determined by comparison to a standard composed of 80, 160, 320, 800, and 1200pg of octopamine hydrochloride in 0.1 M perchloric acid containing 30ng/mL DBA. The data from three groups of pooled males (n=15 in each pool) were averaged. Peaks were identified based on elution times. Statistical Analysis One-way ANOVA with Holm-Sidak’s multiple comparisons test was used to evaluate effects of genotype on various sleep parameters in three or more groups. Multiplicity-adjusted p-values are obtained for each pairwise comparison and only the most conservative/numerically higher values are reported here. Data was examined for Gaussian distribution and homogeneity of variance using D’Augustino Pearson omnibus normality test and Brown-Forsythe test respectively. Data were log-transformed or central limit theorem was assumed for datasets with n>30 in case of violations of assumptions of normality. Otherwise, non-parametric Kruskal-Wallis with Dunn’s post-hoc test was used. Generalized ESD test (Rosner, 1993) was used to examine outliers. Results are presented as either mean±s.e.m. or mean±c.i., as indicated in the text. The consolidation index is defined as a weighted average bout length where each sleep bout was weighted according to its duration in minutes. To calculate the consolidation index, we summed the square of all sleep bout lengths (in minutes) and divided by the total amount of sleep according to (Pitman et al., 2006). This calculation reduces the influence of transient awakenings during the sleep phase. The empirical cumulative distribution (CDF) for sleep bouts was plotted using the ecdf function in MATLAB (The MathWorks, Natick, MA). Ordinary two-way Multivariate ANOVA (MANOVA) was carried out in SPSS23 using the general linear model (GLM) procedure to explore interactions between the effect of hMeCP2 and dMBDs on linear composite of various measures of sleep. Multivariate outliers were detected for all sleep parameters based on a chi-square distribution using Mahalanobis distance (MD). Cases with MD>18.47 (critical χ2 value assessed at p < .001, df = 4) were identified as outliers and removed. Box-Cox transformed dependent variables (i.e. total sleep, waking activity, consolidation index, and number of sleep bouts) were auto-scaled for the purposes of scale standardization and univariate outliers were identified using +3.0 z-score criterion. Multi-collinearity was checked against the variance inflation factor (VIF; threshold=5). As our dataset contained an unbalanced design (unequal sample size across groups), and violated the assumption of homogeneity of covariance matrices, Pillais’ trace criterion (which is most robust to such violations) was reported. These results were cross-validated by employing a non-parametric or permutation MANOVA (NPMANOVA / PERMANOVA) in PASTv3.09 (Hammer et al., 2001) which is insensitive to such violations (Anderson, 2001). Homology modeling The SWISS-MODEL template library (SMTL version 2015-04-15, PDB release 2015-04-17) was searched with Blast (Altschul et al., 1997) and HHBlits (Remmert et al., 2012) for evolutionary related structures matching the target MBD amino acid sequence for both MBD-R2 and MBD2/3. The templates with the highest quality predicted from features of the target-template alignment were then selected for model building. Models were built based on the target-template alignment using Modeller (Sali & Blundell, 1993) within the UCSF Chimera package (Pettersen et al., 2004). The model quality/reliability was assessed using the z-DOPE (Shen & Sali, 2006) and GA341 (Melo et al., 2002) scoring functions through ModEval Model Evaluation Server (http://modbase.compbio.ucsf.edu/evaluation/). RESULTS MeCP2 expression in octopamine neurons results in fragmented and reduced sleep Examining sleep output in fruit flies provides an ideal paradigm for investigating the role of MBD proteins in neuronal function for several reasons. First, numerous behavioral parameters can be quantified in a large cohort of genetically identical control and experimental populations (Bellen et al., 2010, Venken & Bellen, 2014). Second, behavioral output can be measured at the single minute level, which provides a formidable temporal resolution of function, and finally this functional output is responsive to changing environmental stimuli thus requiring an active readout of the neuronal nuclear state. To determine if MeCP2 expression in distinct amine neurons can alter sleep-wake circuitry function, we used the Gal4-UAS gene expression system and previously generated UAS-hMeCP2 transgenic lines (Cukier et al., 2008). As norepinephrine and OA regulate sleep levels by promoting wakefulness (Crocker & Sehgal, 2008, Mitchell & Weinshenker, 2010, Robbins, 1997), we expressed hMeCP2 (the MeCP2e2 isoform) in OA/tyramine (TA) neurons via the tyrosine decarboxylase2 (tdc2)-gal4 driver (Cole et al., 2005) (Fig. 1a-a′) and quantified sleep-wake patterns, sleep onset, duration, and the quality of sleep over a 10-day period using a standard automated high-throughput activity monitoring system (Ho & Sehgal, 2005) (Drosophila Activity Monitor, Trikinetics, Waltham, MA). Groups of experimental and control adults were assayed concurrently. Adult males expressing hMeCP2 in OA neurons exhibited specific deficits in sleep quantity and quality including a significant reduction in total sleep as compared to transgenic controls (tdc2-gal4/+, and UAS-hMeCP2/+) and the nuclear protein expression control (tdc2-Gal4;UAS-dsRed) (Fig. 1b). This sleep reduction occurred during day and night time frames (Zeitgeber hours ZT04-10 and ZT14.5-22) (Fig. 1c, d). A comparison across the 10-day assay time and replicate groups indicating the consistency of the hour-specific deficit is provided in Fig. S1. We found that the sleep of hMeCP2-expressing males was fragmented as measured by an increase in the average number of sleep bouts (Fig. 1e) and a significant decrease in the consolidation index (C.I.), a weighted measure of average bout length (Fig. 1f, see Materials and Methods). This difficulty in maintaining sleep was also evident by plotting sleep bout data using the empirical cumulative distribution function (ECDF). The ECDF demonstrates that longer consolidated bouts of sleep are replaced with a greater proportion of short sleep bouts in experimental males but not controls (Fig. 1g). Experimental males also displayed a significant reduction in the latency to initiate sleep (Fig. 1h), suggesting the need for recovery after sleep loss and homeostatic relevance of the observed sleep deficits. This sleep loss and hMeCP2 expression in OA neurons in general did not shorten the lifespan of experimental vs. control males rather median lifespan is significantly increased (Fig. S2). In addition to controlling for nuclear protein expression, we further verified the sleep defects observed in tdc2-gal4;UAS-hMeCP2 adults are not due to general changes by asking if different sleep deficits occur as a result of hMeCP2 expression in serotonin neurons (Fig. S3). Males expressing hMeCP2 in 5HT neurons via the tryptophan hydroxylase (trh)-Gal4 line (Alekseyenko et al., 2010) did exhibit sleep loss similar to hMeCP2 effects in OA neurons during specific nighttime hours (ZT19-22.5; Fig. S3). However, the nighttime sleep deficits caused by hMeCP2 expression in 5HT neurons were not accompanied by sleep fragmentation changes (Fig. S3). The conserved nighttime sleep reduction suggests that hMeCP2 expression may alter a specific aspect of neuronal function that is shared by neurons that express different neurotransmitters, yet other sleep impairments are cell-specific. OA is required for a subset of hMeCP2-mediated sleep deficits Alterations in the duration of sleep and a reduction in the latency to initiate sleep are phenotypes observed in flies lacking OA (Crocker & Sehgal, 2008). Therefore, one possible explanation for this particular sleep deficit is that the expression of genes necessary for OA synthesis has been altered. To address this question, we quantified OA levels extracted from the heads of control and experimental males using High Performance Liquid Chromatography (HPLC). Heads were removed during the period of decreased daytime sleep, ZT04-10, to determine if OA levels changed during the sleep reduction time periods. OA concentrations per head did not differ between control (tdc2-gal4/+; and UAS-hMeCP2/+) and experimental (tdc2-gal4;UAS-hMeCP2) males (Fig. 2a). Although we cannot rule out the possibility of OA level differences in specific neurons contributing to sleep deficits, these results demonstrate that a global reduction in OA production does not occur as a result of hMeCP2 expression. Although hMeCP2 expression in OA neurons does not alter OA production, it is possible that the observed sleep deficits require OA function. To test this possibility, we expressed hMeCP2 in flies that completely lack OA due to a null mutation in tyramine-β-hydroxylase (TβhnM18), the rate-limiting enzyme in OA biosynthesis (Monastirioti et al., 1996). Although the total amount of sleep by OA null males expressing hMeCP2 was not different from controls (Fig. 2c), TβhnM18 tdc2-gal4;;UAS-hMeCP2 males exhibited daytime hourly specificity in sleep reduction like wildtype males expressing hMeCP2 (Fig. 2b,d). Strikingly however, the nighttime sleep deficit (ZT14-17.5) quantified in Figure 1 is completely rescued in hMeCP2-expressing males that lack OA (Fig. 2d). This result suggests OA is required to translate the hMeCP2-mediated neuronal defects into a reduction in nighttime sleep during specific hours. Not all hMeCP2-mediated sleep deficits rely on OA neurotransmitter function, as the consolidation index and sleep bout number alterations (Fig. 2e, f) were similar between hMeCP2-expressing males lacking OA or hMeCP2-expressing males with OA. In contrast to the rescued dark phase sleep reduction, the daytime sleep deficits observed during ZT04-10 in tdc2-Gal4;UAS-hMeCP2 adults persisted in males that lack OA (Fig. 2d). A possible explanation for any sleep reduction is a concomitant increase in activity. As Tβh converts tyramine (TA) to OA, the absence of this enzyme results in an accumulation of TA [3,4]. To determine if the periods of sleep reduction observed in males lacking OA are due to elevated TA-induced increases in locomotion rather than hMeCP2 expression (Hardie et al., 2007, Monastirioti, 1999), we quantified activity levels. Changes in waking activity were not observed in the absence of OA (Fig. 2g). Finally, hMeCP2 expression in the nucleus of octopamine neurons may provide some protection against the OA deficient circuit alterations as the increase in sleep observed in OA null males is returned to control levels in the same males now expressing hMeCP2 (TβhnM18 tdc2-gal4;;UAS-hMeCP2) (Fig. 2c, dark gray vs. yellow column). The C-terminal region of hMeCP2 is not sufficient to generate sleep deficits in OA neurons One approach to understanding the potential targets of multi-domain containing proteins is to link protein domain(s) with a corresponding phenotype, therefore we investigated which conserved domains are essential in generating the observed sleep impairments by expressing hMeCP2 alleles that lack the CTD and separately the MBD (Cukier et al., 2008). Due to the relatively sparse distribution of 5mC methylation in Drosophila, we first postulated hMeCP2 exerts its affects through methylation-independent interactions mediated by the C-terminal transcriptional repression domain (TRD) and the C-terminal domain (CTD). The TRD functions as a recruitment center for several transcriptional and epigenetic regulators including components of the transcription repression machinery Sin3a, HDAC1, and HDAC2 (Ghosh et al., 2010, Nan et al., 1998), while the CTD (residues 295 to 486) contains one or more chromatin binding regions (Ausio et al., 2014, Roloff et al., 2003). Together the TRD and CTD domains have been implicated in nucleosomal clustering, array compaction and oligomerization, and gene repression (Nikitina et al., 2007). To remove the C-terminus, we expressed the early truncating mutation encoded by the hMeCP2R294X allele which is found in ~5–6% of RTT patients (Laccone et al., 2001, Wan et al., 1999). In the resulting R294X protein, the TRD is partially truncated and the CTD is completely removed (Fig. 3a) (Wan et al., 1999). The Gal4-driven protein expression of UAS-hMeCP2R294X was previously verified by western blot analysis (Cukier et al., 2008). If the sleep deficits observed in males expressing hMeCP2 in OA neurons were mediated through the C-terminus, we would predict sleep would be normal in males expressing hMeCP2R294X. However, removing TRD and CTD function, did not eliminate the daytime sleep reduction observed in tdc2-gal4;UAS-hMeCP2 males, and only a partial recovery in the nighttime sleep deficits occurred (ZT14.5-22, Figure 3b,c). Males expressing R294X exhibited a decrease in the latency to initiate sleep (Fig. 3d) and changes in sleep architecture (Fig. 3e–g) in a manner similar in males expressing full-length hMeCP2. Specifically, the number of sleep bouts and weighted average bout lengths exhibited by tdc2-gal4;UAS-hMeCP2R294X males remained significantly different than controls (Fig. 3e, f). These results indicate that the hMeCP2-induced changes that drive sleep alterations in the OA neuronal population do not occur primarily through the CTD and TRD domains. The N-terminus and MBD domain are necessary for MeCP2-induced alterations in sleep architecture We next asked if the majority of the sleep deficits observed in tdc2-gal4;UAS-hMeCP2 males are due to the conserved MBD domain. To test this question, we used the UAS-hMeCP2Δ166 line to express a truncated hMeCP2 allele that lacks the N-terminal and MBD domain (Cukier et al., 2008) (Fig. 4a, b). We found the sleep deficits caused by hMeCP2 expression including the amount of sleep, latency to sleep, sleep bout number, and sleep bout length were absent in tdc2-gal4;UAS-hMeCP2Δ166 males (Fig. 4c–h). This lack of sleep defects could be explained if the Δ166 protein was not expressed, however hMeCP2 Δ166 accumulates in the nucleus of tdc2-gal4;UAS-hMeCP2 Δ166 adult brains as demonstrated by immunohistochemistry (Fig. 4b). In addition, previous studies determined hMeCP2 Δ166 is present along polytene chromosomes, is phosphorylated at amino acid S423, and is able to cause Drosophila neuronal morphology and dendritic defects (Cukier et al., 2008, Vonhoff et al., 2012). To determine if the MBD domain itself is required for the MeCP2-induced changes in sleep output, we expressed the severe RTT-causing missense hMeCP2R106W allele. MeCP2-induced alterations in sleep output are dependent on the MBD domain The R106W mutation in the MBD domain impacts the MeCP2 protein by severely disrupting its ability to bind methylated DNA (Chapleau et al., 2009, Kudo et al., 2001), thus potentially altering target gene repression and chromatin condensation. Males expressing hMeCP2R106W in OA neurons (tdc2-gal4;UAS-hMeCP2R106W), completely lack the sleep deficits including all sleep reductions and fragmentation phenotypes caused by wildtype hMeCP2 function (Fig. 5a–e). These results demonstrate that an intact MBD domain is necessary to cause the hMeCP2-mediated changes in sleep behavior. Furthermore, if the hMeCP2-induced changes were a result of non-specific methylation-independent cellular effects in OA neurons, we would expect the sleep deficits to remain as was observed in a previous study describing R106W-induced neuron morphology and motor performance defects (Cukier et al., 2008). However, our results indicate methylation-dependent mechanisms may play a key role in hMeCP2-induced changes in OA neuron output. Recent experiments examining hMeCP2-induced motorneuron dendritic defects also reported an absence of morphology changes upon R106W expression (Vonhoff et al., 2012). Males with reduced dMBD-R2 levels in OA neurons displayed increased sleep levels At this point, our results describe specific hMeCP2-induced sleep deficits and establish the MBD of MeCP2 is a critical component. We next simply asked if endogenous MBD-containing proteins are required for amine neuron function and sleep-wake circuitry output. At least two diverse proteins in Drosophila belong to the MBD family: a) dMBD-R2 and b) dMBD2/3 (Fig. 6a) (Hendrich & Tweedie, 2003, Roder et al., 2000). dMBD2/3 is a small protein consisting strikingly of three MBD domains (Fig. 6b) in contrast; dMBD-R2 contains a THAP, TUDOR, and PHD-type Zinc finger in addition to the MBD domain (Fig. 6c). dMBD2/3 and the dMBD2/3Δ splice variant associate with the nucleosome remodeling and deacetylase (NuRD) complex (Marhold et al., 2004a), repress transcription in in vitro assays (Ballestar & Wolffe, 2001), and dMBD2/3Δ preferentially recognizes mCpG-containing DNA through its MBD (Roder et al., 2000). In addition, the expression of both dMBD2/3 and MBD2/3Δ is developmentally regulated and is present in adult tissues suggesting selective roles in transcriptional regulation (Marhold et al., 2004a, Marhold et al., 2004b). Unlike dMBD2/3, it has not been determined if MBD-R2 binds 5mC, however, dMBD-R2 is a part of the multi-subunit chromatin remodeling NSL (non-specific lethal) complex, which regulates gene expression at genome wide levels (Roder et al., 2000). The human MeCP2 MBD contains 8 known DNA binding sites, half of which are lysine residues (K107, K109, R111, K119, D121, K130, R133 and E137; Conserved domain database: 238690). At least five of these eight DNA-binding sites are present in the Drosophila dMBD-R2 protein (R111, K119, D121, K130, R133) and four in dMBD2/3 (R111, K119, D121, K130). These conserved sites and their location in reference to the hMeCP2 residue positions are depicted in Fig. 6a. In addition, a predicted homology model suggests similarity between specific secondary structural features among the MBD domains of dMBD-R2, dMBD2/3 MBD domains and hMeCP2 (Fig. 6d, f). Therefore, we asked if reducing dMBD2/3 or dMBD-R2 levels using RNA interference could alter the function of neurons as measured by changes in the sleep network. To measure the RNAi effect on transcript levels, quantitative reverse transcription PCR (RT-qPCR) was performed on RNA extracted from the heads of n-syb-Gal4;UAS-dMBD2/3-IR (IR=inverted repeats) and n-syb-Gal4;UAS-dMBD-R2-IR adults. Transcript levels were reduced by 26.84% (Fig. 6e and 36.79% respectively (Fig. 6f). When dMBD-R2 and dMBD2/3 levels were reduced in OA neurons by separately expressing the UAS-dMBD-R2-IR and UAS-dMBD2/3-IR lines under control of the tdc2-gal4 driver, we found that sleep fragmentation and sleep deficits occurred in both tdc2-Gal4;UAS-dMBD-R2-IR and tdc2-Gal4;UAS-dMBD2/3-IR males. Sleep fragmentation was quantified by the increase in sleep bout number along with a decrease in the consolidation index (Figs. 7a–d). Males with reduced dMBD-R2 levels in OA neurons exhibited an increase in the amount of total sleep over a 24 hr period (Fig. 7a,b) with phase ZT1-3 (Fig. 7a, arrow), contributing significantly to the overall increase (tdc2-gal4;UAS-dMBD-R2-IR, 27.7 ± 0.12 vs. tdc2-gal4/+, 13.1 +/− 0.4, UAS-dMBD-R2-IR/+, 19.4 ± 0.5, F=105.2, p=6.66E-08 (i.e. p<0.0001; Welch F test in the case of unequal variances)). This increase in total sleep exhibited by dMBD-R2 deficient adults was not due to diminished locomotor activity as the experimental males were more active during waking periods than controls (Fig. 7c). Males with reduced dMBD-R2 levels also displayed changes in sleep architecture as sleep bout number increased and the weighted average bout length (consolidation index) decreased (Fig. 7d,e). Reducing dMBD-R2 rescues hMeCP2-mediated phase-specific sleep deficits The observation that total sleep increased with a reduction in dMBD-R2 levels is the opposite of the reduction in sleep due to hMeCP2 expression. This result led us to speculate that as both are able function as potential gene repressors, a reduction in dMBD-R2 could lead to an increase in specific gene expression whereas hMeCP2 may be reducing specific gene expression. If hMeCP2 and dMBD-R2 are functioning at similar gene loci or genomic regions, then we predict a reduction in dMBD-R2 levels in combination with hMeCP2 should rescue the phase-specific sleep loss. We tested this hypothesis by generating tdc2-gal4;UAS-hMeCP2/UAS-dMBD-R2-IR adults and found the hMeCP2-mediated night and daytime sleep deficits are indeed restored to control levels when dMBD-R2 levels are reduced (Fig. 7f). These results indicate reducing the levels of a Drosophila MBD protein can generate the same phenotype as the expression of hMeCP2 and suggests possible functional conservation. In support of this hypothesis, we tested whether the effect of relative dMBD levels on sleep output varies in the presence or absence of hMeCP2 by performing a two-way multivariate analysis of variance (MANOVA). A significant interaction (dMBD-R2 × hMeCP2) effect was observed between relative dMBD-R2 and hMeCP2 expression on combined measures of sleep (F(3, 190) = 28.192, p < 0.0001; V = 0.308; Obs. Power = 1.00, Fig. 7g,h). To examine on a genomic level if hMeCP2 and MBD-R2 are able to associate together at chromosomal locations, we expressed hMeCP2 in polytene salivary gland chromosomes using the 48B10-gal4 driver. Isolated larval polytene chromosomes from 48B10-gal4;UAS-hMeCP2 larvae were labeled with MBD-R2 and MeCP2 antibodies. As expected, dMBD-R2 localizes to many sites on polytene chromosomes due to its role as a general facilitator of transcription and as a component of the non-specific-lethal and male-specific-lethal complexes (Pascual-Garcia et al., 2014, Prestel et al., 2010). However, hMeCP2 and dMBD-R2 are detected together at a number of chromosomal sites (Fig. 7i–k, arrows, n=6) suggesting the possibility of common gene loci or chromatin organization targets. As a whole, our results indicate the conserved MBD domain even among disparate MBD-containing proteins, such as hMeCP2 and dMBD-R2, is capable of conferring shared neuronal phenotypes and shared genomic binding sites. Increased MBD2/3 expression recapitulates the hMeCP2-mediated sleep deficits To determine if increasing the levels of endogenous MBD-containing proteins alters sleep parameters in the same manner as hMeCP2, we searched for Enhancer and Promoter (EP)-element inserted lines upstream of dMBD-R2 or dMBD2/3. When crossed to a Gal4 driver, the UAS-containing EP lines can induce the overexpression of the gene of interest (Rorth, 1996). Five EP stocks were tested (see Materials and Methods). Two lines, P{EP}MBD2/3EY0482 and P{EP}AP1muEP1112 located upstream and within dMBD2/3 (Fig. 8a) altered sleep output in the same manner. An increase in MBD2/3 transcript levels were verified in tdc2-gal4;UAS-AP1muEP1112 adults (Fig. 8a). To compare with specific sleep phenotypes observed upon hMEeCP2 expression, we quantified the effects of dMBD2/3 overexpression on sleep during the two specific day and night phases (see Fig. 1d). tdc2-gal4;UAS-AP1muEP1112 males exhibited a reduction in sleep during day and night time frames (ZT04-10 and ZT15-17.5) (Fig. 8b) as well as sleep fragmentation as measured by an increase in the average number of sleep bouts (Fig. 8c). Likewise, tdc2-gal4;UAS-MBD2/3EY0482 males displayed sleep reductions during the same day and night phases (Fig. 8d). Next we asked if sleep alterations occur in dMBD2/3 deficient males. In contrast to hMeCP2 and dMBD2/3 overexpression, tdc2-gal4;UAS-dMBD2/3-IR males did not display a decrease in sleep during specific day and night phases (Fig. 8e and see Fig. 1d), however reducing dMBD2/3 levels in OA neurons did result in sleep fragmentation (Fig. 8f) and an increase in locomotor activity (data not shown). Finally, we generated tdc2-gal4;UAS-hMeCP2/UAS-MBD2/3-IR males and observed a significant interaction (dMBD2/3 × hMeCP2) effect between relative dMBD2/3 and hMeCP2 expression on sleep fragmentation using Pillais’ trace with 0.05 significance criterion (F(3, 194) = 30.665, p < 0.0001; V = 0.322; Obs. Power = 1.00, Fig. 8h,i). Discussion In this study, we tested the hypothesis that MBD-containing proteins retain considerable functional conservation by measuring neuronal output through an automated, reproducible sleep assay. Sleep impairments are a major feature in a substantial number of neurodegenerative and neuropsychiatric disorders [37]. However more fundamentally, this data can be viewed as a relevant behavioral representation of circuit dysfunction in general, which is a common theme in neurodevelopmental syndromes including RTT (Cortesi et al., 2010, Shepherd & Katz, 2011). A powerful advantage of using Drosophila sleep to analyze the functional differentiation of circuits and neurons is the ability to measure behavior at the single minute level. This formidable temporal resolution in combination with amine neuron-specific manipulation allowed us to analyze the functional consequences of wildtype hMeCP2, domain-specific mutations, and Drosophila MBD proteins with powerful phenotypic resolution. Our results demonstrate that adults expressing hMeCP2 in OA neurons sleep less, however this sleep loss is not a general or random phenomena but rather occurs during specific day and nighttime intervals. In a similar manner, hMeCP2 expression in 5-HT neurons also results in a loss of nighttime sleep however, with the fine temporal resolution, we can identify sleep loss intervals that are both unique and overlapping when compared to hMeCP2 expression in OA neurons. Finally, in a previous study we determined that hMeCP2 expression in astrocytes non-cell-autonomously alters the sleep network only during distinct nighttime hours (Hess-Homeier et al., 2014). How might hMeCP2 expression in amine neurons reduce sleep amounts and sleep quality? At the DNA level, MeCP2 binds to the promoters of genes involved in amine synthesis including dopa decarboxylase (Urdinguio et al., 2008) and MeCP2 levels themselves are under circadian cycle control (Martinez De Paz et al., 2015). Previous studies have demonstrated that a loss of OA promotes sleep (Crocker & Sehgal, 2008) and our HPLC studies indicate OA brain levels are not reduced upon hMeCP2 expression. However, it is possible that the MeCP2-induced reduction in nighttime sleep is mediated through an increase in OA signaling. This hypothesis is consistent with previous observations including an overexpression of Tdc2 or genetically activating OA neurons significantly decreases nighttime but not daytime sleep (Crocker & Sehgal, 2008). In addition, components of the arousal circuitry respond to OA wake-promoting signals including the large-lateral ventral neurons (l-LNvs) neurons (Crocker et al., 2010). When hyper-excited, l-LNv neurons result in a reduction in sleep quality and amount and express octopamine receptors (Kula-Eversole et al., 2010, Shang et al., 2008). In our experiments, MeCP2 expression could potentially increase OA neuron activity by modulating presynaptic function either through changes in levels of OA biosynthetic enzymes, or components of OA transport and release, or conserved RNA-binding proteins such as Lark, which regulate neuronal excitability in the circadian system (Ishimoto et al., 2012). Finally, our results notably demonstrate a loss of OA function can completely rescue the most severe hMeCP2-mediated reduction in nighttime sleep found within ZT14-17.5 (Fig. 2c). As MBD family members have a highly similar DNA-binding surface that shows high affinity for methylated DNA, a key question is whether individual proteins bind differentially to distinct regions within the genome. Variations in the affinity for binding methylated targets include double-stranded vs. single-stranded, sequence dependent vs. sequence independent, and CpG vs. non-CpG (CpH; H=A/C/T) methylation (Baubec et al., 2013, Fatemi & Wade, 2006, Guo et al., 2014). Recently, a role for MeCP2 binding to CpH sites and regulating the expression of genes enriched for neuronal function has been described (Chen et al., 2015). Non-CpG methylation has been reported in vertebrate neurons (Fatemi & Wade, 2006, Guo et al., 2014, Pinney, 2014) and in Drosophila; the methylation present in the adult genome is enriched on non-CpG motifs, particularly CpT and CpA dinucleotides (Boffelli et al., 2014, Capuano et al., 2014, Takayama et al., 2014). In our sleep experiments, MeCP2 may be functioning to translate endogenous CpH methylation into changes in gene expression. This idea is especially compelling as we demonstrated that an intact MBD-binding domain is required for all hMeCP2-induced sleep deficits (Fig. 5). Furthermore, males with reduced levels of dMBD2/3, which binds methylated DNA, exhibited overlapping sleep quality deficits (Fig. 7, SF4). In this context, Drosophila may provide an ideal in vivo system to examine the functional consequences of CpH-mediated MBD protein interactions as future studies can address the significance of CpH methylation at candidate genes that control circadian rhythm and aspects of sleep. In conclusion, epigenetically modifying chromatin structure in response to different stimuli may be a key mechanism in generating shifts in gene expression not only at successive stages of neuron development but successive stages of neuron function. Such functional changes may include responses to pheromones (predators or conspecifics), odors (food resources), or light (sleep) all critical aspects of reproduction and survival in any organism. In this study we examined the consequences of a hypomorphic reduction of endogenous MBD proteins in a relevant neuronal subpopulation to provide a whole organism readout of changes in neuron function that should be interpretable at the chromatin level in future studies due to ever-increasing advances in circadian rhythm and sleep gene identification. Our results provide the first demonstration that Drosophila MBD proteins are required for neuron function and that MBD-containing proteins indicate conservation in the cell-specific functions of epigenetic translators. Supplementary Material Supp Fig S1 Supplemental Figure 1: hMeCP2 expression in OA neurons reduces the sleep of adult males: Comparison across days and replicates (a) The sleep of control (tdc2-gal4/+, and UAS-hMeCP2/+) males and experimental tdc2-gal4;UAS-hMeCP2 adults was recorded and averaged across a 10-day time period. The data shown are subsets of controls and reflect the results from batch 1 of the experimental males. (b) The average sleep recorded per batch of experimental males does not differ. Supp Fig S2 Supplemental Figure 2: Males expressing hMeCP2 in OA neurons live longer than controls A Kaplan-Meier survival curve with the dotted boundaries around the curves representing standard error (SE). The survival distribution of experimental males, tdc2-gal4;UAS-hMeCP2 males is statistically different than controls (standard log-rank test, P≪0.0001). Supp Fig S3 Supplemental Figure 3: Adults expressing hMeCP2 in 5HT neurons exhibit a nighttime sleep reduction (a) hMeCP2 nuclear expression (green) in 5HT neurons from a trh-gal4; UAS-MeCP2/+ male brain. (b–h) The quality and amount of sleep in individual adult males averaged over an 8-day period from control and experimental groups. (b) The total amount of sleep per 24-hr day is not significantly changed in experimental males as compared to UAS-hMeCP2/+ controls (Padj=0.2051). (c) Eduction graph displaying the average amount of sleep per 30 minute bin (daytime/light phase: white bar; nighttime/dark phase: black bar, shaded grey) in control and experimental males. trh-gal4/+; UAS-MeCP2/+ males displayed a reduction in sleep during Zeitgeber hours ZT19-22.5 (arrow). These deficits are quantified in (d) P=0.0011, Mann Whitney test. (e–h) Sleep fragmentation in males expressing MeCP2 in 5HT neurons. (e) The daytime consolidation index is significantly reduced in experimental vs. control males (Padj<0.0001). The nighttime consolidation index is not altered (Padj=0.7262). (f) The average number of daytime sleep bouts is increased in experimental males vs. controls (Padj<0.0001), without alterations in the average number of nighttime sleep bouts (Padj=0.8316). (g) Daytime, but not nighttime, waking activity is increased in experimental males vs. controls (Padj<0.0001). (h) The empirical cumulative distribution function demonstrates experimental males exhibit a greater proportion of short sleep bouts as compared to controls. Data are shown as means ± standard error of the mean (SEM). Unless noted otherwise, results were analyzed by one-way ANOVA with Holm-Sidak’s multiple comparison test. The authors thank Juan Botas, Jay Hirsh, Sirge Birman, Olga Alekseenko, Edward Kravitz and the Bloomington Stock Center for fly stocks. We are grateful to Conor Jacobs for initial sleep studies, Peter Becker for the MBD-R2 antibody, Jennene Lyda for assistance with HPLC analysis, and members of the Certel lab for helpful discussions. We also thank the University of Montana Molecular Histology and Fluorescence Imaging Core and Lou Herrit for technical expertise. The nc82 antibody was developed by Eric Buchner obtained from the Developmental Studies Hybridoma Bank developed under the auspices of the NICHD and maintained by the Department of Biology, University of Iowa (Iowa City, IA). The National Institutes of Health Center of Biomedical Research Excellence grant P20RR015583 and the University of Montana Research Grant Program to SJC supported this work. Figure 1 hMeCP2 expression in OA neurons reduces the sleep of adult males (a-a″) hMeCP2 expression (red) in OA neurons from an adult tdc2-gal4/UAS-mCD8:gfp; UAS-hMeCP2/+ male (anti-GFP, green; mAb nc82, labels neuropil regions, blue). (b–h) Sleep profiles of individual adult males averaged over 8 days from control and experimental groups. Controls: tdc2-gal4/+ (white), UAS-hMeCP2/+ (light grey), tdc2-gal4/+; UAS-dsRed/+ (dark grey) and experimental: tdc2-gal4/+; UAS-hMeCP2/+ (red). (b) Total sleep per 24-hr day is reduced in experimental males as compared to controls (Padj=0.0013; one-way ANOVA with Holm-Sidak’s multiple comparison test). (c) Eduction graph displaying 30 minute bins of averaged sleep (daytime/light phase: white bar; nighttime/dark phase: black bar, shaded grey). tdc2-gal4/+; UAS-hMeCP2/+ males displayed a reduction in the average amount of sleep during both day and night (arrows) as compared to controls. These deficits are quantified in (d) for Zeitgeber hours ZT04-10, (P<0.0001; two-tailed Mann Whitney test) and ZT14.5-22, (P<0.0001; two-tailed Mann Whitney test). (e–g) Sleep fragmentation in males expressing MeCP2 expression in OA neurons. As compared to controls, the average number of sleep bouts per day (e) is increased (Padj<0.0001) and weighted average bout length measured by the consolidation index (f) is reduced significantly in experimental males (Padj<0.0001). (g) The empirical cumulative distribution function (ECDF) demonstrating experimental males exhibit a greater proportion of short sleep bouts as compared to controls. (h) Latency to initiate sleep (the delay in minutes from the lights OFF to the time to the first sleep bout) is significantly reduced in tdc2-gal4/+; UAS-hMeCP2/+ males as compared to controls (Padj=0.0009; one-way ANOVA with Holm-Sidak’s multiple comparison test). Data are shown as means ± standard error of the mean (SEM). Figure 2 The loss of OA rescues a subset of hMeCP2-induced sleep deficits (a) HPLC quantification of OA levels in whole brain extracts of 3–5 day old adult males collected during ZT04-10. OA levels between control and experimental groups did not differ. (b–f) Sleep profiles of individual adult males averaged over an 8-day period from control and experimental groups. Controls: tdc2-gal4/+ (white bar), UAS-hMeCP2/+ (light grey), tβhnM18 tdc2-gal4 (dark grey) and experimental: tdc2-gal4; UAS-hMeCP2 (red), tβhnM18 tdc2-gal4; UAS-hMeCP2 (yellow). (b) Eduction graph displaying average amount of sleep per 30 minute bin (daytime/light phase: white bar; nighttime/dark phase: black bar) in control and experimental males. hMeCP2-induced sleep deficits (red line) are restored to control levels in tβhnM18 tdc2-gal4; UAS-hMeCP2 males during ZT14-17.5 (yellow line, arrow). (c) Total sleep increased in the OA deficient control males (tβhnM18 tdc2-gal4, black column) as compared to transgenic controls (white/gray columns, Padj = 0.0070). Expression of hMeCP2 in OA deficient males (tβhnM18 tdc2-gal4; UAS-hMeCP2, black vs. yellow columns) returned total sleep values to wildtype levels (Padj = 0.6563; one-way ANOVA with Holm-Sidak’s multiple comparison). (d) The reduction in sleep during ZT04-10 remained in OA deficient males expressing hMeCP2. The sleep reduction during ZT14-17.5 was completely rescued in the absence of OA (multiplicity adjusted P-value for pooled controls vs. tβhnM18 tdc2-gal4; UAS-hMeCP2 experimental males; P= 0.8447). (e–f) Sleep fragmentation remains in hMeCP2-expressing OA deficient males. The consolidation index (e) is reduced significantly in both experimental groups (Padj = 0.1658) and the average number of sleep bouts is increased (f) (Padj = 0.2409). (g) No difference was observed in the waking activity between OA deficient controls (tβhnM18 tdc2-gal4) and experimental males (tβhnM18 tdc2-gal4; UAS-hMeCP2/+; Padj = 0.6325). Figure 3 hMeCP2-induced sleep deficits remain in males expressing the R294X allele (a) Schematic depicting the structural domains MeCP2 and the loss of domains due to the R294X mutation. (b–h) The sleep profiles of control and experimental adult males averaged over an 8-day period. (b) Eduction graph displaying the average amount of sleep per 30 minute bin (daytime/light phase: white bar; nighttime/dark phase: black bar, shaded grey). Average sleep during Zeitgeber hours ZT04-10 and ZT14.5-22 are quantified in (c). Males expressing the R294X allele displayed a similar reduction in the average amount of sleep during ZT04-10 as males expressing the full-length allele (Padj=0.0103). During ZT14.5-22, the average sleep deficit in males expressing R294X allele remains reduced as compared to controls (P<0.0001). This 294X-induced sleep reduction is partially recovered in comparison to hMeCP2-expressing males (P<0.0001). (d) Males expressing full-length or R294X alleles exhibited a reduction in the latency to initiate sleep as compared to controls (Padj=0.0001). (e–g) Sleep fragmentation in males expressing the full-length MeCP2 and R294X alleles in OA neurons. (e) The average number of sleep bouts increases to a lesser extent in R294X males as compared to males expressing full-length MeCP2 (Padj<0.0001) however the increase in sleep bouts of tdc2-gal4;UAS-hMeCP2294X is significantly higher than controls (P<0.0001). (f) The consolidation index was reduced significantly in both full-length and R294X males as compared to controls (Padj<0.0001). (g) Experimental males exhibited a greater proportion of short sleep bouts as calculated by the empirical cumulative distribution function. Data are shown as means ± standard error of the mean (SEM). Unless noted otherwise, one-way ANOVA with Holm-Sidak’s multiple comparison test was used. Figure 4 Sleep fragmentation and sleep deficits are rescued in males expressing the hMeCP2Δ166 allele in OA neurons (a) Schematic diagram depicting MeCP2 structure and the loss of domains due to the Δ166 truncation. (b) hMeCP2Δ166 (green) is expressed in adult OA neurons via the tdc2-gal4 driver (tdc2-gal4; UAS-MeCP2Δ166). (c–h) The sleep profiles of control and experimental adult males averaged over an 8-day period. (c) The latency to initiate sleep is not significantly reduced in males expressing hMeCP2Δ166 as compared to controls (Padj=0.2611). (d) Eduction graph displaying average amounts of sleep per 30-minute bin in control and experimental males. The overall sleep profile and average sleep during Zeitgeber hours ZT04-10 and ZT14.5-22 is completely rescued in males expressing hMeCP2Δ166. (e) The average amount of sleep does not differ between controls and males expressing hMeCP2Δ166: ZT04-10, (Padj=0.514), and ZT14.5-22, (P=0.7853). (e–h) Sleep is not fragmented in males expressing hMeCP2Δ166 in OA neurons. (f) The average number of sleep bouts is not significantly different in tdc2-gal4; UAS-MeCP2Δ166 vs. the tdc2-gal4 and UAS-MeCP2 control (Padj=0.2923). (g) The consolidation index does not differ between males expressing hMeCP2Δ166 and controls (Padj=0.1308). (h) The empirical cumulative distribution function demonstrates experimental males exhibit a greater proportion of short sleep bouts as compared to controls. Data are shown as means ± standard error of the mean (SEM). The one-way ANOVA with Holm-Sidak’s multiple comparison test was used. Figure 5 Expression of the MeCP2 R106W allele does not confer sleep deficits or fragmentation (a–e) Sleep patterns averaged over a period of 8 days from control and experimental males. (a) Eduction graph displaying average amount of sleep per 30-min bin. The sleep patterns and sleep quality of males expressing hMeCP2R106W in OA neurons are the same as controls. (b) The average sleep during Zeitgeber hours ZT04-10 and ZT14.5-22 does not differ between males expressing R106W and controls: ZT04-10, Padj=0.7406, and ZT14.5-22, P=0.0974. (c–e) Sleep fragmentation does not occur in males expressing R106W. (C) The average number of sleep bouts in males expressing R106W is not significantly different from controls (Padj=0.8849). (d) The consolidation index does not differ from the R106W-expressing experimental males and controls (Padj=0.9843). (e) Experimental males exhibited a greater proportion of short sleep bouts as calculated by the empirical cumulative distribution function. Data are shown as means ± standard error of the mean (SEM). The one-way ANOVA with Holm-Sidak’s multiple comparison test was used. Fig 6 Alignment and conservation of MBD-containing proteins (a) The structural domains of hMeCP2 with domain-specific multiple sequence alignment of select MBD-family proteins in human (h) and Drosophila (d). Identical sequences are highlighted in various shades of blue depending on the degree of conservation across groups. The histogram (yellow) represents conserved physico-chemical properties for each column of the alignment. Higher scores (max=10) for non-identical columns indicate amino acid substitutions that belong to the same physico-chemical class (Livingstone & Barton, 1993). (b) A schematic diagram depicting the size and conserved domains of dMBD-2/3. (c) Schematic representation of dMBD-R2 showing the conserved structural domains. (d) A structural model of the dMBD2/3 MBD domain (Template: MBD3 (pdb: 2mb7), sequence identity = 40.9%, GA341 score = 0.955, z-DOPE score = −0.234. (e) For semi-quantitative RT-PCR experiments, RNA from the heads of adults expressing dMBD2/3-IR in OA neurons (n-syb-Gal4-gal4;UAS-dMBD2/3-IR, blue column), and controls (n-syb-gal4-Gal4/+, white column; UAS-dMBD2/3-IR/+, gray column). dMBD-2/3 transcript levels were significantly reduced in n-syb-Gal4-gal4;UAS-dMBD2/3-IR adults as compared to age-matched control adults (Ordinary one way ANOVA, Padj=0.0026). Reactions were performed in quadruplicate. Rpl32 expression was used as the reference control to normalize expression between treatment groups (error bars indicate s.e.m.). (f) A structural model of the dMBD-R2 MBD domain (Template: MeCP2 (pdb: 3c2i), sequence identity = 34%, GA341 score = 0.931, z-DOPE score = −0.213). (g) RNA from the heads of adults expressing dMBD-R2-IR (n-syb-Gal4-gal4;UAS-dMBD-R2-IR, blue column), and controls (n-syb-gal4-Gal4/+, white column; UAS-dMBD-R2-IR/+, gray column) were used for semi-quantitative RT-PCR experiments. dMBD-R2 transcript levels were significantly reduced in n-syb-Gal4-gal4;UAS-dMBD-R2-IR adults as compared to age-matched control adults (Ordinary one way ANOVA, Padj=0.0045). Reactions were performed in quadruplicate. Cdc2 expression was used as the reference control to normalize expression between treatment groups. Fig 7 Concomitant reduction of dMBD-R2 and hMeCP2 expression rescues hMeCP2-mediated sleep deficits (a–e) Sleep quality and quantity exhibited by individual males averaged over an 8-day period from control and experimental groups. (a) Eduction graph displaying 30 minute bins of averaged sleep between males expressing dMBD-R2-IR in OA neurons (tdc2-gal4;UAS-dMBD-R2-IR) and controls (daytime: white bar; nighttime: black bar, shaded grey). Total sleep over a 24 hr period is increased (see quantification in panel e) with the ZT1-3 interval (arrow) of increased sleep noted. (b) MBD-R2-deficient males displayed an increase in total sleep as compared to controls (Padj<0.0001). (c) Waking activity is increased in experimental males (tdc2-gal4;UAS-dMBD-R2-IR) vs. controls (Padj<0.0001). (c) Sleep fragmentation as measured by an increase in the number of sleep bouts (Padj<0.0) and a decrease in the consolidation index (e) occurred in tdc2-gal4;UAS-dMBD-R2-IR males as compared to controls (Padj=0.001Data are shown as means ± standard error of the mean (SEM). (f) Eduction graph displaying 30 minute bins of averaged sleep between males expressing hMeCP2 in OA neurons, males expressing hMeCP2 and dMBD-R2-IR (tdc2-gal4;UAS-hMeCP2/UAS-dMBD-R2-IR) and controls (daytime: white bar; nighttime: black bar, shaded grey). The phase-specific sleep reductions quantified in tdc2-gal4;UAS-hMeCP2 males (red square line) have been rescued to control levels with the reduction in dMBD-R2 levels (arrows). (g–h) The effect of relative dMBD-R2 expression on sleep output in the presence or absence of hMeCP2, was quantified using a two-way multivariate analysis of variance (MANOVA). Using Pillais’ trace and 0.05 criterion for significance, a significant interaction (dMBD-R2 × hMeCP2) effect was observed between relative dMBD-R2 expression and hMeCP2 gain of function on combined measures of sleep (F(3, 190) = 28.192, p < 0.0001; V = 0.308; Obs. Power = 1.00). This interaction effect explained 32.2% of multivariate variance of sleep composite in dMBD2/3-deficient males and 30.8% of multivariate variance in dMBDR2-deficient males (V = partial η2). This interaction effect explained 32.2% of multivariate variance of sleep composite in dMBD2/3-deficient males and 30.8% of multivariate variance in dMBDR2-deficient males (V = partial η2). (i–k) Polytene chromosomes from 48B10-gal4 UAS-hMeCP2 3rd instar larvae. Both dMBDR2 (red) and hMeCP2 (green) display extensive chromosomal binding. Co-immunofluorescence is observed at selected bands (arrowheads, PCC: r = 0.508; MCC1: 0.64, MCC2: 0.694 ; Costes’ randomization test: P-value=100%). Individual channels in panels (e–f) correspond to the white ROI. Fig 8 Overexpression of dMBD2/3 in OA neurons causes phase-specific sleep decreases similar to hMeCP2 expression (a) Locations of the overexpression EP lines, AP-1mu[EP1112] (red arrowhead) and MBD2/3[EP04582] (orange arrowhead) are depicted in relation to the MBD2/3 loci as well as the approximate location of the targeted UAS-driven inverted repeat sequences (blue). RNA from the heads of tdc2-Gal4-gal4;UAS-AP-1muEP1112adults (red column) and the UAS-AP-1muEP1112/+ (gray column) were used for semi-quantitative RT-PCR experiments. dMBD2/3 transcript levels were significantly increased in tdc2-Gal4-gal4;UAS-AP-1muEP1112 adults as compared to age-matched control adults (unpaired t test, P=0.0103). Reactions were performed in quadruplicate. RPL32 expression was used as the reference control to normalize expression between treatment groups. (b) tdc2-gal4/;UAS-AP-1muEP1112 males (n=46) displayed a reduction in the average amount of sleep during Zeitgeber hours ZT04-10, (p<0.0001; Kruskal Wallis test) and ZT15-17.5, (p<0.0001) as compared to controls, tdc2-gal4/+ (n=28) and UAS-AP-1muEP1112/+ (n=20). (c) Sleep fragmentation as measured by the average number of sleep bouts per day in tdc2-gal4/;UAS-AP-1muEP1112 males is increased as compared to controls (Padj<0.0001, Kruskal-Wallis with Dunn’s post-hoc test). (d) A reduction in the average amount of sleep during ZT04-10, (p<0.0001; Kruskal Wallis test) and ZT15-17.5, (p<0.0001) decreased in tdc2-gal4/; UAS-MBD2/3EP04582 males (n=23, orange column) as compared to controls, tdc2-gal4/+ (n=28) and UAS-MBD2/3EP04582/+ (n=57). (e) The average amount of sleep is not altered between controls (tdc2-gal4/+, n=43, white column; UAS-dMBD2/3-IR/+, n=33, gray column) and males with reduced dMBD2/3 levels in OA neurons, tdc2-gal4;UAS-dMBD2/3-IR, n=31, blue column) during ZT14.5-22 (P=0.1374). During ZT04-9 the average sleep of tdc2-gal4;UAS-dMBD2/3-IR males does not differ from the UAS-dMBD2/3-IR/+ control (P=0.4801). The two control groups are statistically different (P<0.0001). (f) The average number of sleep bouts per 24-hr period is increased in tdc2-gal4; UAS-dMBD2/3-IR males as compared to controls (Padj=0.0041). (g) The consolidation index is significantly reduced in dMBD2/3-deficient males as compared to controls (Padj=0.0032). (h, i) The effect of relative dMBD2/3 expression on sleep output in the presence or absence of hMeCP2, was quantified using a two-way multivariate analysis of variance (MANOVA). Using Pillais’ trace and 0.05 criterion for significance, a significant interaction (dMBD2/3 × hMeCP2) effect was observed between relative dMBD2/3 expression and hMeCP2 gain of function on combined measures of sleep (F(3, 194) = 30.665, p < 0.0001; V = 0.322; Obs. Power = 1.00). 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Parkinsons disease: Current and future pharmacotherapy Eur J Pharmacol 750 74 81 25637088 Kudo S Nomura Y Segawa M Fujita N Nakao M Dragich J Schanen C Tamura M 2001 Functional analyses of MeCP2 mutations associated with Rett syndrome using transient expression systems Brain Dev 23 Suppl 1 S165 173 11738866 Kula-Eversole E Nagoshi E Shang Y Rodriguez J Allada R Rosbash M 2010 Surprising gene expression patterns within and between PDF-containing circadian neurons in Drosophila Proc Natl Acad Sci U S A 107 13497 13502 20624977 Laccone F Huppke P Hanefeld F Meins M 2001 Mutation spectrum in patients with Rett syndrome in the German population: Evidence of hot spot regions Hum Mutat 17 183 190 11241840 Liu C Chung M 2015 Genetics and epigenetics of circadian rhythms and their potential roles in neuropsychiatric disorders Neuroscience bulletin 31 141 159 25652815 Livingstone CD Barton GJ 1993 Protein sequence alignments: a strategy for the hierarchical analysis of residue conservation Comput Appl Biosci 9 745 756 8143162 Lv J Xin Y Zhou W Qiu Z 2013 The epigenetic switches for neural development and psychiatric disorders J Genet Genomics 40 339 346 23876774 Lyst MJ Bird A 2015 Rett syndrome: a complex disorder with simple roots Nat Rev Genet 16 261 275 25732612 Marhold J Brehm A Kramer K 2004a The Drosophila methyl-DNA binding protein MBD2/3 interacts with the NuRD complex via p55 and MI-2 BMC Mol Biol 5 20 15516265 Marhold J Kramer K Kremmer E Lyko F 2004b The Drosophila MBD2/3 protein mediates interactions between the MI-2 chromatin complex and CpT/A-methylated DNA Development 131 6033 6039 15537686 Martinez de Paz A Vicente Sanchez-Mut J Samitier-Marti M Petazzi P Saez M Szczesna K Huertas D Esteller M Ausio J 2015 Circadian Cycle-Dependent MeCP2 and Brain Chromatin Changes PLoS One 10 e0123693 25875630 McCarthy MJ Welsh DK 2012 Cellular circadian clocks in mood disorders J Biol Rhythms 27 339 352 23010657 Melo F Sanchez R Sali A 2002 Statistical potentials for fold assessment Protein Sci 11 430 448 11790853 Mitchell HA Weinshenker D 2010 Good night and good luck: norepinephrine in sleep pharmacology Biochem Pharmacol 79 801 809 19833104 Monastirioti M 1999 Biogenic amine systems in the fruit fly Drosophila melanogaster Microsc Res Tech 45 106 121 10332728 Monastirioti M Linn CE Jr White K 1996 Characterization of Drosophila tyramine beta-hydroxylase gene and isolation of mutant flies lacking octopamine J Neurosci 16 3900 3911 8656284 Musiek ES Xiong DD Holtzman DM 2015 Sleep, circadian rhythms, and the pathogenesis of Alzheimer disease Exp Mol Med 47 e148 25766617 Nan X Ng HH Johnson CA Laherty CD Turner BM Eisenman RN Bird A 1998 Transcriptional repression by the methyl-CpG-binding protein MeCP2 involves a histone deacetylase complex Nature 393 386 389 9620804 Nikitina T Shi X Ghosh RP Horowitz-Scherer RA Hansen JC Woodcock CL 2007 Multiple modes of interaction between the methylated DNA binding protein MeCP2 and chromatin Mol Cell Biol 27 864 877 17101771 Nomura Y 2005 Early behavior characteristics and sleep disturbance in Rett syndrome Brain Dev 27 Suppl 1 S35 S42 16182496 Pascual-Garcia P Jeong J Capelson M 2014 Nucleoporin Nup98 associates with Trx/MLL and NSL histone-modifying complexes and regulates Hox gene expression Cell Rep 9 433 442 25310983 Pettersen EF Goddard TD Huang CC Couch GS Greenblatt DM Meng EC Ferrin TE 2004 UCSF Chimera--a visualization system for exploratory research and analysis J Comput Chem 25 1605 1612 15264254 Pfeiffenberger C Lear BC Keegan KP Allada R 2010 Processing sleep data created with the Drosophila Activity Monitoring (DAM) System Cold Spring Harb Protoc 2010 pdb prot5520 Piazza CC Fisher W Kiesewetter K Bowman L Moser H 1990 Aberrant sleep patterns in children with the Rett syndrome Brain Dev 12 488 493 2288379 Pinney SE 2014 Mammalian Non-CpG Methylation: Stem Cells and Beyond Biology (Basel) 3 739 751 25393317 Pitman JL McGill JJ Keegan KP Allada R 2006 A dynamic role for the mushroom bodies in promoting sleep in Drosophila Nature 441 753 756 16760979 Potdar S Sheeba V 2013 Lessons from sleeping flies: insights from Drosophila melanogaster on the neuronal circuitry and importance of sleep J Neurogenet 27 23 42 23701413 Prestel M Feller C Straub T Mitlohner H Becker PB 2010 The activation potential of MOF is constrained for dosage compensation Mol Cell 38 815 826 20620953 Qureshi IA Mehler MF 2014 Epigenetics of sleep and chronobiology Current neurology and neuroscience reports 14 432 24477387 Ramocki MB Peters SU Tavyev YJ Zhang F Carvalho CM Schaaf CP Richman R Fang P Glaze DG Lupski JR Zoghbi HY 2009 Autism and other neuropsychiatric symptoms are prevalent in individuals with MeCP2 duplication syndrome Ann Neurol 66 771 782 20035514 Remmert M Biegert A Hauser A Soding J 2012 HHblits: lightning-fast iterative protein sequence searching by HMM-HMM alignment Nat Methods 9 173 175 Robbins TW 1997 Arousal systems and attentional processes Biol Psychol 45 57 71 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The proteins that recognize methylated DNA in eukaryotes Int J Dev Biol 53 323 334 19412889 Schubeler D 2015 Function and information content of DNA methylation Nature 517 321 326 25592537 Shang Y Griffith LC Rosbash M 2008 Light-arousal and circadian photoreception circuits intersect at the large PDF cells of the Drosophila brain Proc Natl Acad Sci U S A 105 19587 19594 19060186 Shaw PJ Cirelli C Greenspan RJ Tononi G 2000 Correlates of sleep and waking in Drosophila melanogaster Science 287 1834 1837 10710313 Shen MY Sali A 2006 Statistical potential for assessment and prediction of protein structures Protein Sci 15 2507 2524 17075131 Shepherd GM Katz DM 2011 Synaptic microcircuit dysfunction in genetic models of neurodevelopmental disorders: focus on Mecp2 and Met Curr Opin Neurobiol 21 827 833 21733672 Skene PJ Illingworth RS Webb S Kerr AR James KD Turner DJ Andrews R Bird AP 2010 Neuronal MeCP2 is expressed at near histone-octamer levels and globally alters the chromatin state Mol Cell 37 457 468 20188665 Souders MC Mason TB Valladares O Bucan M Levy SE Mandell DS Weaver TE Pinto-Martin J 2009 Sleep behaviors and sleep quality in children with autism spectrum disorders Sleep 32 1566 1578 20041592 Takayama S Dhahbi J Roberts A Mao G Heo SJ Pachter L Martin DI Boffelli D 2014 Genome methylation in D. melanogaster is found at specific short motifs and is independent of DNMT2 activity Genome Res 24 821 830 24558263 Urdinguio RG Lopez-Serra L Lopez-Nieva P Alaminos M Diaz-Uriarte R Fernandez AF Esteller M 2008 Mecp2-null mice provide new neuronal targets for Rett syndrome PLoS One 3 e3669 18989361 Varriale A 2014 DNA methylation, epigenetics, and evolution in vertebrates: facts and challenges Int J Evol Biol 2014 475981 24551476 Venken KJ Bellen HJ 2014 Chemical mutagens, transposons, and transgenes to interrogate gene function in Drosophila melanogaster Methods 68 15 28 24583113 Vonhoff F Williams A Ryglewski S Duch C 2012 Drosophila as a model for MECP2 gain of function in neurons PLoS One 7 e31835 22363746 Wan M Lee SS Zhang X Houwink-Manville I Song HR Amir RE Budden S Naidu S Pereira JL Lo IF Zoghbi HY Schanen NC Francke U 1999 Rett syndrome and beyond: recurrent spontaneous and familial MECP2 mutations at CpG hotspots Am J Hum Genet 65 1520 1529 10577905 Yasui DH Xu H Dunaway KW Lasalle JM Jin LW Maezawa I 2013 MeCP2 modulates gene expression pathways in astrocytes Mol Autism 4 3 23351786 Young D Nagarajan L de Klerk N Jacoby P Ellaway C Leonard H 2007 Sleep problems in Rett syndrome Brain Dev 29 609 616 17531413 Zilberman D 2008 The evolving functions of DNA methylation Curr Opin Plant Biol 11 554 559 18774331 Zimmermann CA Hoffmann A Raabe F Spengler D 2015 Role of mecp2 in experience-dependent epigenetic programming Genes (Basel) 6 60 86 25756305
PMC005xxxxxx/PMC5119462.txt
LICENSE: This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. 101190261 31733 Nat Rev Microbiol Nat. Rev. Microbiol. Nature reviews. Microbiology 1740-1526 1740-1534 27211789 5119462 10.1038/nrmicro.2016.46 NIHMS829529 Article Reassortment in segmented RNA viruses: mechanisms and outcomes McDonald Sarah M. 12 Nelson Martha I. 3 Turner Paul E. 4 Patton John T. 5 1 Virginia Tech Carilion School of Medicine and Research Institute, 2 Riverside Circle, Roanoke, Virginia 24016, USA 2 Department of Biomedical Sciences and Pathobiology, Virginia–Maryland College of Veterinary Medicine, 205 Duck Pond Drive, Blacksburg, Virginia 24061, USA 3 Fogarty International Center, National Institutes of Health, 31 Center Drive, MSC 2220, Bethesda, Maryland 20892, USA 4 Department of Ecology and Evolutionary Biology, Yale University, Osborn Memorial Labs, 165 Prospect Street, P. O. Box 208106, New Haven, Connecticut 06520, USA 5 Virginia–Maryland College of Veterinary Medicine, University of Maryland, 8075 Greenmead Drive, College Park, Maryland 20742, USA Correspondence to S.M.M. mcdonaldsa@vtc.vt.edu 12 11 2016 23 5 2016 7 2016 22 11 2016 14 7 448460 This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. Segmented RNA viruses are widespread in nature and include important human, animal and plant pathogens, such as influenza viruses and rotaviruses. Although the origin of RNA virus genome segmentation remains elusive, a major consequence of this genome structure is the capacity for reassortment to occur during co-infection, whereby segments are exchanged among different viral strains. Therefore, reassortment can create viral progeny that contain genes that are derived from more than one parent, potentially conferring important fitness advantages or disadvantages to the progeny virus. However, for segmented RNA viruses that package their multiple genome segments into a single virion particle, reassortment also requires genetic compatibility between parental strains, which occurs in the form of conserved packaging signals, and the maintenance of RNA and protein interactions. In this Review, we discuss recent studies that examined the mechanisms and outcomes of reassortment for three well-studied viral families — Cystoviridae, Orthomyxoviridae and Reoviridae — and discuss how these findings provide new perspectives on the replication and evolution of segmented RNA viruses. Viruses that maintain their genomes as several distinct RNA molecules are called segmented RNA viruses. They are ubiquitous in nature, infecting a wide variety of animals, plants and bacteria. To date, 11 different segmented RNA virus families have been described in the literature: Arenaviridae, Birnaviridae, Bromoviridae, Bunyaviridae, Chrysoviridae, Closteroviridae, Cystoviridae, Orthomyxoviridae, Partitiviridae, Picobirnaviridae and Reoviridae (TABLE 1). These families and their type species can differ considerably in their virion structure, genome architecture, replication cycle, host tropism and pathology. For example, some segmented RNA virus species, such as influenza A virus and rotavirus A, are associated with substantial human disease and serious economic burdens to society1–3. Other segmented RNA virus species affect humans indirectly through the infection of domestic animals and crops (for example, bluetongue virus, infectious bursal disease virus and tomato spotted wilt virus)4–6. However, a shared feature of all segmented RNA viruses is their capacity to exchange genome segments in toto during co-infection through a process called reassortment. Specifically, when two or more viruses infect a single host cell, they can package each other’s genome segments into a nascent virion, thereby producing hybrid progeny (FIG. 1a). For multipartite viruses in the Bromoviridae, Chrysoviridae, Partitiviridae and Picobirnaviridae families, which incorporate their genome segments into several independent virus particles (TABLE 1), reassortment is stochastic and creates virions that have a random mix of genome segments from each parent. By contrast, for viruses that package their genome segments into a single virion, such as species in the Cystoviridae, Orthomyxoviridae and Reoviridae families, reassortment generally results in segment replacement, such that one co-infecting virus incorporates the genome segment (or segments) of another co-infecting virus in place of its own. In this case, genetic exchange requires the conservation of intricate assortment signals and preservation of the RNA–RNA and/or RNA–protein interactions that mediate genome packaging. For this reason, strain-specific differences in the sequences or structures of homologous RNAs and/or in the packaging proteins of co-infecting parent viruses can severely restrict the generation of reassortant progeny during co-infection. Moreover, for reassortants to selectively emerge at appreciable levels in the viral population, they must have a genomic composition that confers at least some modest advantage to viral fitness. Conceptually, reassortment shares some features with sexual reproduction in eukaryotes, whereby chromosomes are segregated during meiosis and combined in various ways during gamete fusion (FIG. 1b). Sexual reproduction is argued to be evolutionarily advantageous to eukaryotes, in part, because it purges deleterious mutations and increases population-level genetic diversity, which is a prerequisite to evolution by natural selection7–9. Thus, by analogy to sexual reproduction, one theory posits that the reassortment capacity of segmented RNA viruses contributes to the maintenance of this genome structure10–13. However, rapidly evolving viral populations have more opportunities to remove unfit mutations than eukaryotes, and reassortment is clearly not necessary for the evolutionary success of the numerous non-segmented viruses. Therefore, it is possible that reassortment is a by-product of genome segmentation, rather than a key evolutionary driver of such a genome structure. Indeed, the evolution of genome segmentation may have been driven by other advantages that are conferred by this arrangement, such as the control of gene expression14, increased coding potential of the genome15 and enhanced stability of such virus particles16. Regardless of the original drivers of segmentation, the capacity of important human pathogens such as influenza A viruses and rotavirus A strains to reassort has important implications for their ongoing evolution and impact on global health. The mechanisms and outcomes of reassortment can differ from recombination, which is another form of genetic exchange that occurs readily for some non-segmented RNA viruses, particularly those with positive-sense RNA ((+)RNA) genomes17 (FIG. 1c). During recombination, the viral polymerase begins copying the RNA template of one parental strain, and it then switches templates mid-synthesis to use that of a different parental strain. Therefore, the result of recombination is the generation of chimeric RNA molecules that contain regions of nucleotide sequence derived from each parent. Unlike reassortment, during which entire genes (or sets of genes) are exchanged by the swapping of segments, recombination can occur nearly anywhere in the RNA genome, even in the middle of a gene. Therefore, recombination can result in the formation of non-functional chimeric fusion proteins, whereas reassortment cannot17. In other words, reassortment is a mechanism that maintains the ORF of a gene and, consequently, maintains protein integrity, whereas recombination typically introduces changes in ORFs and their encoded proteins. Recombination has rarely been reported for segmented RNA viruses18–21, and some of the detected recombination events may be the result of sequencing artefacts22. The lack of robust recombination among segmented RNA viruses is likely to be a reflection of their biology, specifically related to the manner in which their polymerases transcribe and replicate the genome segments in the absence of template switching. A detailed discussion of the mechanism, origins and evolutionary consequences of recombination in RNA viruses compared with reassortment is provided in REF. 23. In this Review, we focus on the mechanisms and outcomes of reassortment for non-multipartite, segmented RNA viruses in the well-studied Cystoviridae, Orthomyxoviridae and Reoviridae families. In particular, we describe the strategies that are used by these viruses to ensure efficient incorporation of their genome segments into nascent virions, and we discuss how genetic incompatibilities during segment assortment and packaging can directly restrict the generation of reassortants during co-infection. We also highlight recent experimental and comparative genomic studies that elucidate the possible selection pressures that promote or temper the emergence of reassortant viruses in the population. Our goal is to provide new perspectives on the replication and evolution of segmented RNA viruses, which may in turn stimulate the development of measures for the prevention of disease. Genome segment assortment and packaging Cystoviridae The Cystoviridae family is composed of segmented double-stranded RNA (dsRNA) viruses that infect Gram-negative bacteria20. The type species for this family is Pseudomonas phage φ6 (hereafter referred to as φ6), an extensively researched bacteriophage that primarily replicates within the various pathovars of the plant pathogen Pseudomonas syringae. Since its discovery in the early 1970s24, φ6 has been used as a tractable model system to test evolutionary hypotheses within controlled laboratory settings and to uncover mechanisms of virus biology. Additional Cystoviridae family members have been found at various geographical locations around the world, which suggests that these viruses are widespread in nature25–27. The φ6 virion consists of an outer lipid envelope surrounding a nucleocapsid shell and an icosahedral procapsid core28. Within the core reside three dsRNA genome segments, totalling >13 kb in length and encoding 13 viral proteins25 (FIG. 2a). The segments each contain several ORFs that are flanked by 5′ and 3′ UTRs, and they are named according to their sizes: small (S; 2.9 kb), medium (M; 4.1 kb) and large (L; 6.4 kb). During the replication cycle of φ6, dsRNA genome segments are transcribed into (+)RNA molecules by viral polymerases29. In addition to acting as templates for protein synthesis, these (+)RNAs are the form of the φ6 genome that is incorporated into nascent particles25 (FIG. 2b). Using an in vitro packaging system, it was shown that φ6 (+)RNAs are inserted individually and sequentially into a pre-formed procapsid core through an entry portal at one five-fold icosahedral axis30,31 (FIG. 2b). The empty core initially displays only the binding site for the S (+)RNA segment, leading to its recruitment and packaging. Thereafter, a conformational change occurs in the core that reveals a binding site for the M (+)RNA segment32. Again, only after packaging of the M segment is the binding site for the L (+)RNA segment revealed. It was also demonstrated through in vitro assays that the cis-acting RNA sequence and structural elements that are crucial for packaging are located in the 5′ UTRs33 (FIG. 2a). A 5′-terminal 18 bp sequence is shared among the S, M and L segments and enables φ6 to distinguish between viral RNAs and host RNAs. The gene-specific packaging signals that differentiate S, M and L segments during packaging are located ~200 bp downstream of the 18 bp conserved sequence. Following encapsidation of all three φ6 (+)RNAs, the procapsid core expands, thereby triggering the core-associated viral polymerases to convert the (+)RNAs into dsRNA genome segments through a single round of negative-sense RNA ((−) RNA) synthesis20. Additional virion morphogenesis, including the acquisition of an outer envelope, leads to the production of fully infectious φ6 particles. It is predicted, albeit not experimentally demonstrated, that the vast majority of nascent φ6 virions that are produced during the viral life cycle contain all three genome segments. This prediction is based on the observations that (+)RNA packaging is sequential and inter-segmentally dependent, and that the three φ6 genome segments are present in equimolar amounts at the viral population level. Nevertheless, it has been shown that φ6 packaging can be drastically manipulated in vitro, yielding particles with more or fewer than three genome segments or with rearranged genome segments34–36. For example, one study created a φ6 mutant that did not package the S segment owing to an amino acid substitution in one of its core proteins35. This mutant still efficiently packaged and replicated the M and L segments, thereby propagating a virus that contains two segments in a non-lytic carrier state in the bacterial host. Furthermore, it was shown that the entire φ6 genome can be concatenated into a single RNA molecule and still produce a viable mutant with only moderate replication defects36. The observation that non-segmented variants of φ6 can be created in the laboratory but do not emerge at detectable levels in nature suggests that genome segmentation provides a fitness advantage. Orthomyxoviridae The Orthomyxoviridae family of segmented (−)RNA viruses consists of six different genera, three of which (Influenzavirus A, Influenzavirus B and Influenzavirus C) cause respiratory disease in humans37. Of these three genera, Influenzavirus A (consisting of a single species, influenza A virus) imparts the largest medical and economic burdens; seasonal epidemics of strains of influenza A virus account for 27,000–55,000 deaths each year in the United States alone, with an annual cost of US$87.1 billion to the healthcare system2,38. Influenza A viruses can also cause pandemics, the most severe of which occurred in 1918–1919 and is estimated to have killed 20–50 million people globally39. In addition to infecting humans, influenza A viruses are endemic in several other animal species, including pigs, dogs, horses, bats and birds, which provide natural reservoirs for viral evolution40. Influenza A viruses exist as pleomorphic, enveloped virion particles, each encasing a genome of eight (−)RNA molecules (FIG. 2c). The individual genome segments of an influenza A virus range in size from 0.9–2.3 kb in length, and the total genome length is approximately 13.5 kb (REF. 41). Each (−)RNA contains 13 ORFs, in the antisense orientation, which are flanked by 3′ and 5′ UTRs. Altogether, an influenza A virus encodes at least 13 proteins in its eight genome segments. The termini of the viral (−)RNA consist of highly conserved 12–13 bp sequences that can partially anneal with each other in cis so that the molecules fold over and form a corkscrew shape (FIG. 2c). Multiple copies of the viral nucleocapsid protein (NP) bind to the length of each (−)RNA, and a heterotrimeric polymerase complex is attached to the end where the 3′ and 5′ termini connect. Thus, the eight influenza A virus genome segments are packaged into virions as eight distinct ribonucleoprotein (RNP) complexes42,43 (FIG. 2c). The manner in which influenza A viruses package each of their eight genome segments has not yet been fully resolved. However, the available data are most consistent with the notion that this is a selective, non-random process that it is mediated by interactions between the (−)RNA molecules themselves44,45 (FIG. 2d). Individual RNPs are assembled in the nucleus, and they must then translocate to the plasma membrane, where they are incorporated into a budding enveloped virion. Using fluorescence in situ hybridization, it was shown that the RNPs are exported from the nucleus as subcomplexes, which further assort into a supramolecular complex that contains all eight RNPs while trafficking to budding sites46–48. Additional studies support the idea that the subcomplexes consist of specific pairs of (−)RNAs that directly engage each other and that the supramolecular complex is formed through an elaborate interaction network between the (−)RNAs of the subcomplexes49–52. Although an in vitro packaging system is lacking for influenza A viruses, studies of defective-interfering RNAs have shed light on which regions of the viral genome are crucial for the assortment process. Specifically, defective-interfering RNAs have been engineered to contain large deletions in the central ORFs but to maintain the extreme ORF termini as well as the 3′ and 5′ UTRs of the genome segments, and such RNAs are capable of competing with full-length segments for packaging53. This indicates that the segment-specific assortment signals are located within ~300 bp from the termini of the (−)RNA molecules (FIG. 2c). Furthermore, several studies have used reverse genetics approaches to engineer viruses that encapsidate reporter genes, thereby defining those nucleotides that are crucial for the packaging of each (−)RNA segment into a virion44. However, how these sequence elements are recognized in the context of the RNP is unclear. One possibility is that some regions of the (−)RNA termini lack NP, enabling them to adopt local secondary or tertiary structures and to mediate RNA–RNA interactions. It was originally proposed that the packaging efficiency for influenza A viruses was very high and that most nascent virions contained a full complement of all eight RNPs44,45. This theory was supported by structural analysis of individual virions using thin-section electron microscopy and electron tomography43,52,54. However, influenza A virions can be engineered in the laboratory to contain more or fewer than eight genome segments, which suggests that some level of inefficiency is tolerated55,56. Furthermore, additional studies have demonstrated that when cells are infected at a low multiplicity, most fail to express at least one of the viral proteins57, providing evidence for a model of influenza A virus packaging that is less than perfect. This result suggests that the gene encoding the protein that failed to be expressed was defective or missing altogether in these semi-infectious particles. Moreover, the efficiency of segment packaging was found to vary between virus strains and to be influenced by mutations in specific viral proteins57,58. Finally, semi-infectious particles are estimated to outnumber complete particles by 6/1 (REF. 58), and they readily participate in reassortment events during co-infection with complete particles59. Thus, further studies aimed at elucidating the effect of semi-infectious particles on the long-term evolution of influenza A viruses are warranted. Reoviridae The Reoviridae family of segmented dsRNA viruses includes several clinically and economically important human, animal and plant pathogens, such as rotaviruses, bluetongue viruses and rice dwarf viruses1,4,60. Rotaviruses are well-studied members of the Reoviridae family because they cause life-threatening gastroenteritis in infants and young children. Before the worldwide introduction of two vaccines in 2006, strains of the rotavirus A species were estimated to have killed ~450,000 children each year1,61. Strains of rotavirus A also infect numerous mammalian and avian species, including pigs, cows, horses, rabbits, cats, dogs, mice and birds, which are reservoirs for viral evolution. Ongoing epidemiological surveillance data also show that strains from the divergent species rotavirus B and rotavirus C are important causes of morbidity and mortality in pigs and cows62–65, and that they may be underappreciated causes of disease in humans66–69. The rotavirus A virion is a non-enveloped, triple-layered particle that encloses a dsRNA genome of 11 segments70. The viral genome segments range in size from 0.5–3.3 kb, and the genome as a whole totals 23.0 kb (FIG. 2e). The segments are each organized as a central ORF flanked by 5′ and 3′ UTRs. In general, each gene is monocistronic, encoding a single viral protein. An additional ORF has been described in one segment for some rotavirus strains71, enabling the expression of up to 12 proteins in total. The assortment and packaging process of rotaviruses is very poorly understood because the field lacks both in vitro packaging assays and efficient reverse genetics methods. Nevertheless, the available data suggest that this process shares aspects of both φ6 and influenza A virus assortment and packaging72 (FIG. 2f). For example, as for φ6, the dsRNA genome segments of rotavirus A are transcribed by viral polymerases into (+)RNA molecules, which are the form of the genome that is assorted and packaged into nascent virion particles73–76. However, unlike the φ6 genome, the rotavirus A (+)RNAs are not inserted one by one into a pre-formed core. Instead, it is hypothesized that rotavirus A genome assortment occurs in a manner that is similar to influenza A virus genome assortment. In particular, it is thought that the 11 distinct (+)RNAs engage each other through cis-acting RNA elements to form a supramolecular complex that is encapsidated by the core shell protein during early virion assembly (FIG. 2f). The 5′ and 3′ UTR sequences differ for each of the 11 (+)RNAs, but these sequences are highly conserved among homologous gene segments from different strains of rotavirus A. The segment-specific packaging signals for rotavirus A (+)RNAs are predicted to reside within these 5′ and 3′ termini. In silico analyses of nucleotide sequences from strains of rotavirus A have identified several putative RNA structural elements in these terminal regions that may represent assortment signals77,78. For strains of the bluetongue virus and mammalian orthoreovirus species, two other Reoviridae family members, some packaging signals have been identified with the help of in vitro assembly and reverse genetics; they involve the 5′ and 3′ UTRs, and include some coding sequences79–83. Therefore, the location of the packaging signals for rotavirus A strains and other Reoviridae family members may be similar to the location of the influenza A virus signals (FIG. 2f). During or immediately following their packaging into a core assembly intermediate, rotavirus A (+)RNAs are converted into dsRNAs by viral polymerases70. The nascent core assembly intermediate then undergoes additional morphogenesis to become an infectious triple-layered, non-enveloped particle. The efficiency of genome packaging is poorly understood for the Reoviridae family, members of which have 9, 10, 11 or 12 dsRNA genome segments. The observation that no family members have 13 or more segments may be a reflection of the packaging process and the icosahedral capsid architecture. Specifically, each of the 12 fivefold axes of the inner core shell is predicted to have space for only one dedicated polymerase complex and one associated genome segment84. However, it is unclear why some Reoviridae family members package fewer than 12 segments, thereby leaving one or more fivefold vertices unoccupied. For example, strains of rotavirus A have 11 genome segments, which are present in equimolar amounts at the population level. Moreover, variants of rotavirus A with partially duplicated genome segments and/or foreign sequence insertions have been isolated or engineered85–87. This suggests that these viruses can accommodate extra nucleic acid and, theoretically, that they may be able to package additional segments. That being said, there have been no reports of strains of rotavirus A that contain an extra copy of a genome segment, nor have there been reports of variants that lack one or more genome segments. This particular observation is intriguing, given that some strains do not express the accessory protein NSP1 owing to spontaneous deletions or mutations in the NSP1-coding genome segment88,89. For these strains, the defective NSP1-coding genome segment is still efficiently packaged into nascent virions, which suggests that the (+)RNA molecule itself is crucial for viral replication, perhaps during assortment. Therefore, we hypothesize that rotaviruses and other members of the Reoviridae family use an all-or-none packaging mechanism similar to that of φ6. More specifically, we predict that the full complement of (+) RNA segments must be incorporated into a core assembly intermediate for genome replication to take place. In this model, each packaged (+)RNA would have a dedicated polymerase that acts only on the specific associated segment but that functions in concert with the ten other polymerases to simultaneously replicate the dsRNA genome. Future investigations into the details of rotavirus assortment, packaging and genome replication are warranted, but such investigations may require the development of robust in vitro assays. Generation of reassortants during co-infection Given the exquisite selective packaging mechanisms for Cystoviridae, Orthomyxoviridae and Reoviridae family members, it is no surprise that successful reassortment between two parental strains during co-infection requires a high degree of genetic compatibility. More specifically, the capacity of one parental strain to package the genome segment of another requires the maintenance of intricate RNA–RNA and/or protein–RNA interactions. Indeed, there has been no description of reassortment occurring between segmented RNA viruses that belong to different families (for example, an Orthomyxoviridae member and a Reoviridae member); these viruses are simply too divergent to participate in genetic exchange. Even for more closely related viruses within the same genus, subtle differences in viral RNAs and proteins can temper the efficiency with which reassortants are generated during co-infection. It is likely that molecular failures at the level of segment assortment and packaging are a major reason for why the frequency of reassortants is lower than expected following experimental co-infections in the laboratory setting. For influenza viruses, the compatibility of packaging signals in the form of conserved RNA–RNA interactions is a primary determinant that dictates the reassortment potential for any two co-infecting parental strains44 (FIG. 3a). A remarkable example of this was provided by the demonstration that the reassortment restriction between influenza A viruses and influenza B viruses can be overcome, at least for the genome segment encoding haemagglutinin (HA), simply by using reverse genetics to swap the packaging signals90. However, it is important to note that studying the molecular determinants of reassortment restriction using reverse genetics does not fully recapitulate restrictions during co-infection because such studies do not take into account the important role of competition among homologous segments. In support of this idea, it was shown that although reverse genetics can create all possible reassortants between an avian and a human influenza A virus strain, such hybrid progeny are not readily produced during co-infection91. The reason for this discrepancy is related to the fact that the human influenza A virus RNAs interact suboptimally with those from avian strains (FIG. 3a). In other words, low-affinity interactions between the non-cognate RNAs (that is, those that are derived from different parental viruses) are readily outcompeted by the optimal, higher-affinity interactions between cognate RNAs (that is, those that are derived from the same parental virus). In addition to influencing the overall frequency of reassortants for influenza A viruses, subtle differences in RNA–RNA interactions during assortment and packaging also affect the constellation of genome segments in any resulting hybrid progeny. In fact, it has long been observed that some segments are preferentially packaged together such that the genotypes of influenza A virus reassortants are not random. For example, the segment-specific RNA–RNA interactions that occur during assortment have been shown to differ from strain to strain, suggesting that only reassortants that co-package interacting segments would maintain the supramolecular network and produce viable progeny49. Furthermore, in the absence of segment mismatch, influenza A viruses reassort with high frequency, demonstrating that there are few extrinsic barriers to exchange92. The genetic limitations on the capacity to create reassortants during co-infection may be less stringent for the Cystoviridae family than for the Orthomyxoviridae family. In fact, isolates from the Cystoviridae family with a high level of sequence divergence are able to reassort with φ6 in the laboratory setting and in nature26,93. However, in vitro packaging assays suggest that there may be some direct restrictions to genetic exchange. For example, it was shown that Pseudomonas phage φ13 (hereafter referred to as φ13) can efficiently package the φ6 M (+)RNA segment, even though this segment carries a packaging signal very divergent from the φ13 packaging signal94. By contrast, φ6 was incapable of packaging the M (+)RNA segment of φ13 unless the φ6 packaging sequences were appended to the molecule94. This result for these members of the Cystoviridae family is similar to the reports for influenza A viruses and suggests that even if genetic exchange can occur, not all combinations of genome segments are tolerated, and restrictions to reassortment may be strain specific. Similar to the restriction on reassortment between influenza A viruses and influenza B viruses, strains of rotavirus A are incapable of reassorting with strains of other rotavirus species following experimental co-infection of cells or animals. However, there seem to be restrictions that prevent successful genetic exchange even in strains of rotavirus A, which are closely related, as the frequency of reassortants in a given population of progeny is usually much lower than the frequency predicted based on chance alone95. Similar observations have been made for other members of the Reoviridae family, including mammalian orthoreoviruses96,97 and bluetongue viruses98. However, for all members of the family Reoviridae, it remains to be tested whether reassortants are simply not generated during co-infections, or whether they are generated but do not emerge in the population because they are less fit than their parental strains (see below). An interesting aspect of the replication cycles of members of the Reoviridae and Cystoviridae families, and a factor that may influence the generation of hybrid progeny during co-infection, is that genome replication (that is, dsRNA synthesis) occurs following segment assortment and packaging. Thus, for a reassortant progeny to be generated, the viral polymerase of one strain must be capable of replicating the packaged (+)RNAs of a different parental strain. For rotaviruses, the polymerase recognizes the (+)RNA template by a sequence-specific interaction with seven nucleotides that are located at the 3′ end of the molecule99. Rotavirus A, rotavirus C, rotavirus D and rotavirus F strains have a similar seven-nucleotide sequence (UGUGACC or UGUGGCU), which differs substantially from that of rotavirus B, rotavirus G and rotavirus H strains (AAAACCC, AAGACCC or UAUACCC)100. Therefore, the polymerases of rotavirus A, C, D and F strains would not be able to efficiently bind to and replicate the (+)RNA templates of rotavirus B, G and H strains, and vice versa (FIG. 3b). Similar strain-determined template specificities were found for the polymerases of Cystoviridae members φ6, φ13 and Pseudomonas phage φ8 (REF. 101). In light of this, suboptimal protein–RNA interactions during assortment, packaging and replication are expected to influence the generation of reassortants for viruses in the Cystoviridae and Reoviridae families. Emergence of reassortants in nature The increased capacity for whole-genome sequencing has facilitated new approaches that have revealed the importance of reassortment in the emergence of viruses with novel phenotypes (FIG. 4), including those that are associated with outbreaks. Large-scale comparative genomics studies of Cystoviridae, Orthomyxoviridae and Reoviridae family members in various hosts have detected numerous reassortants in viral populations26,102–114. For example, reassortment can lead to the creation of more-fit variants that outcompete previously circulating strains, and such cases are extremely well documented for influenza A viruses. Several influenza A viruses endemic in swine or birds have been successfully transmitted to humans, and in many cases, reassortment has been instrumental in the major evolutionary transition that is required for this transmission to humans. This is illustrated by the 1957 ‘Asian’ and 1968 ‘Hong Kong’ pandemics, which were both associated with reassortant viruses comprising both human and avian virus genome segments. Similarly, the 2009 pandemic resulted from a reassortment event between highly divergent North American swine viruses and Eurasian swine viruses. In all three pandemics, the reassortment event resulted in novel human viruses that carried divergent genes encoding HA and neuraminidase (NA) derived from the animal viruses; these human viruses express HA and NA antigens that are not well recognized by human adaptive immune responses (FIG. 4a). Reassortment among co-circulating human strains of the same HA–NA subtype is also important for the evolution and emergence of seasonal strains of influenza A virus115, including those that are antigenically novel106, those with enhanced transmissibility105 and those that are resistant to antiviral drugs116. Although reassortment can provide fitness advantages to the progeny virus if that progeny acquires a beneficial allele, reassortment can alternatively confer fitness costs if it uncouples a set of alleles that operate best when kept together (FIG. 4b). For example, reassortment has the potential to unlink RNAs or their encoded proteins that interact functionally during the viral replication cycle. As a consequence, a reassortant might exhibit suboptimal RNA–RNA, protein–RNA and/or protein–protein interactions during its de novo replication cycle, thereby making it less able to propagate and spread (that is, less fit) than the non-reassortant parental strains. The observation that reassortment can lead to attenuated viruses with reduced replicative fitness in this way has fostered the development of vaccine strains for influenza A viruses and rotavirus A (BOX 1). Box 1 Reassortant viruses as live-attenuated vaccine strains The capacity of influenza viruses and rotaviruses to generate functional new variants through reassortment has been harnessed to produce highly effective vaccines that stimulate immune responses without causing disease. The vaccines contain reassortants generated in the laboratory that combine the immunogenic surface proteins from field strains within the genetic backbones of specific laboratory-adapted ‘master donor’ strains that exhibit desired properties, such as high titre growth or attenuation. For example, in the Unites States, the seasonal influenza immunization programme is anchored by two types of vaccines, an inactivated influenza vaccine (IIV) and a live-attenuated influenza vaccine (LAIV; called FluMist)128,129. Both vaccines are quadrivalent formulations that consist of two strains of influenza A virus (H3N2 and H1N1) and two strains of influenza B virus (Yamagata and Victoria lineages). During vaccine production, 6/2 reassortants are generated; these contain the 6 internal genome segments from the laboratory-adapted master donor strain and the 2 haemagglutinin (HA)-encoding and neuraminidase (NA)-encoding gene segments from the field isolates. These vaccines are modified bi-annually on the basis of genetic and antigenic analyses of the dominant circulating global strains. However, the extensive lead time that is required to produce and evaluate candidate vaccine strains occasionally results in mismatches between vaccine strains and field strains, which results in reduced vaccine effectiveness. In the future, the use of reverse genetics to directly engineer reassortant vaccine candidates may shorten this lead time and reduce mismatches. Moreover, the directed introduction of growth-restricting mutations into field isolates through reverse genetics may bypass the need to create reassortants and could enable the rapid production of new live-attenuated vaccines that more closely match circulating strains. For human strains of rotavirus A, two live-attenuated vaccines are widely used globally: the monovalent Rotarix vaccine (GlaxoSmithKline) and the pentavalent RotaTeq vaccine (Merck). The RotaTeq vaccine is composed of five bovine–human reassortant strains (10/1 or 9/2) that contain 9 or 10 internal bovine rotavirus genes (from strain WC3), the human virus VP7 coding genes with rotavirus G1, G2, G3 and G4 genotype specificities, and the human virus VP4 coding gene with a strain P[8] genotype specificity130. The attenuated phenotype that is conferred by the reassortant gene constellation of the RotaTeq vaccine strains enables them to induce intestinal mucosal immunity without causing disease. Interestingly, although rotaviruses and influenza A viruses are both segmented viruses that use reassortment to advance their evolution and diversity, the pace of antigenic change among circulating influenza viruses has necessitated frequent adjustments of the IIV and LAIV vaccine formulations, whereas the rotavirus reassortant vaccine has remained effective for nearly 10 years without change61,128. Importantly, in some cases, the failure to detect reassortants following experimental co-infection might reflect the poor fitness of hybrid progeny caused by mismatched alleles, rather than restrictions on the actual generation of the reassortant during co-infection. For example, for influenza A viruses, uncoupling of the three polymerase-coding genes (PA, PB1 and PB2) by reassortment can lead to the formation of viruses with a diminished capacity for RNA synthesis117–119. Essentially, the polymerase proteins of some non-cognate strains are not able to effectively interact to form a functional enzyme complex (proteins of human viruses do not interact with proteins of avian viruses, for instance). Similar observations have been made for rotavirus replicase complex proteins, whereby the subunits of rotavirus A and rotavirus C strains cannot functionally substitute for each other120–122. Furthermore, comparative genomics studies also support the notion that inter-segmental RNA or protein co-adaptation tempers reassortment among co-circulating strains. For example, a mutual information-based algorithm was used to define amino acid residues that co-varied in multi-sequence alignments of proteins from rotavirus A strains112. The data revealed a vast network of interconnected amino acids in various viral proteins, some of which are not known to physically interact with each other. Thus, reassortment may also be limited by the selective constraints that are placed on functionally co-adapted, albeit non-interacting, proteins. However, it is also important to mention that less-fit reassortants with mismatched-allele constellations can acquire corrective mutations that restore interaction interfaces between non-cognate (that is, not co-adapted) proteins (FIG. 4c). In fact, it has been shown that low-fitness influenza A virus reassortants can accumulate fitness-restoring mutations in functionally interacting proteins if the reassortants are serially passaged in the laboratory117,123–126. There is also increasing evidence to support the notion that reassortment events cause a temporary increase in the rate of amino acid changes for influenza A viruses as the viral proteins adapt to a new genetic environment127. To date, there have been no studies that address the role of co-adaptive changes influencing RNA–RNA interactions and, in turn, reassortment for segmented RNA viruses, but this remains an important area for future investigation. These observations for influenza A viruses and strains of rotavirus A regarding allele combinations are in contrast to those for φ6 and members of the Cystoviridae family in general. As mentioned above, even members of the Cystoviridae family with a high level of sequence divergence were found to undergo frequent reassortment in nature26. It is interesting to speculate that perhaps members of the Cystoviridae family are not subjected to the same purifying selection pressures that are imposed on influenza A viruses and strains of rotavirus A following reassortment, maybe simply because of the way the genes are organized within the segments. In particular, the genes that encode interacting proteins of φ6 are usually located on the same segment (for example, all procapsid proteins are encoded by the L segment); therefore, reassortment would not uncouple functionally interacting alleles. Thus, φ6 represents an ideal experimental system for further investigation of the genetic linkages among genome segments for members of the Cystoviridae family and the effect of those linkages on the frequency of reassortment. Outlook In summary, segmented RNA viruses include some of the most important human, animal and plant pathogens in recent history. The biological mechanism that originally produced these viruses from non-segmented precursors remains unknown (BOX 2), but one of the most apparent consequences of this genome structure is the generation of novel reassortant progeny during co-infection. Reverse genetics and other experimental advances have increased our ability to investigate the molecular constraints on reassortment under controlled experimental conditions. Moreover, recent advances in genome-sequencing technologies have furthered our understanding of segmented RNA virus diversity and have shed light on the frequency of reassortants in natural populations. Importantly, for influenza A viruses and rotaviruses, these discoveries have shown how reassortment contributes to viral pathogenic and zoonotic potentials, and have enabled the generation of live-attenuated reassortant vaccines. However, some key outstanding questions remain unanswered and should be the focus of future research endeavours. How do influenza viruses and rotaviruses selectively package their genome segments? What are the relative contributions of failed RNA–RNA, protein–RNA and protein–protein interactions to reassortment restriction between any given strains? Are there virus-extrinsic barriers to reassortment within the infected host or within the environment? What are the biological and temporal dynamics that are required to achieve robust reassortment? What is the contribution of semi-infectious particles or defective-interfering particles to viral replication, reassortment and evolution? Do some individual genome segments evolve biased packaging so that they are over-represented in the reassortant progeny (that is, are there ‘selfish genes’)? The answers to these questions are expected not only to inform disease prevention and control strategies, but also to shed light on our basic understanding of organismal evolution. Box 2 Possible origins of RNA virus genome segmentation It is unknown how an ancestral non-segmented RNA virus underwent genome segmentation in the first place, but different theories have been proposed to explain the origin of segmented RNA viruses. One theory posits that genome segmentation may have arisen following the accidental merging of RNA genomes from two different viruses (see the figure, part a). This theory is supported by a recent analysis of Jingmen tick virus (a taxonomically unclassified segmented RNA virus), as two of the four positive-sense RNA ((+)RNA) genome segments are genetically related to those of flaviviruses, whereas the other two are completely unique, which suggests that they were acquired independently from a still-unidentified parental ancestor131. It is possible that the acquisition of a novel RNA virus genome provided the Jingmen tick virus ancestor an evolutionary advantage over parental strains that lacked such extra genome segments. Alternatively, genome segmentation could have arisen as a downstream consequence of diploidy or polyploidy, whereby the precursor non-segmented RNA virus may have randomly packaged more than one copy of its genome into a nascent virion (see the figure, part b). Diploidy and polyploidy are argued to be evolutionarily advantageous in complex organisms because they buffer against the effects of deleterious mutations. Accumulation of mutations over time may have enabled the ‘duplicate’ genome to encode new proteins, evolving into a new genome segment132. Indeed, diploidy and polyploidy have been documented for measles viruses and Ebola viruses, which normally have single-stranded negative-sense RNA ((−)RNA) genomes133–135. Moreover, diploidy is a hallmark of the RNA genome structure of several retroviruses, including HIV. As diploidy and polyploidy require that there are few restrictions on the amount of nucleic acid that can be packaged into a virus particle, such genomes may have evolved more easily for enveloped viruses than for non-enveloped viruses with stringent capsid sizes. S.M.M. receives financial support from the Virginia Tech Carilion School of Medicine and Research Institute and the US National Institutes of Health (NIH; grants R01AI116815, R21AI113402 and R21AI119588). P.E.T. receives financial support from the US National Science Foundation BEACON Center for Study of Evolution in Action and the NIH (grant R01AI09164601). J.T.P. is supported by funding from the University of Maryland, College Park, USA. Segmented RNA viruses Viruses in which the genome consists of more than one RNA molecule (that is, segments). The genome segments can be packaged within a single virion particle or into separate particles Type species A representative viral strain that is studied to understand the biology of an entire viral genus or family Reassortment A process of genetic exchange whereby two or more parental viruses co-infect a single host cell and exchange genome segments. The outcome is the formation of hybrid viral progeny with genome segments derived from multiple parental strains Assortment The mechanism by which a segmented virus packages one of each genome segment into a virion particle Viral fitness The capacity of an individual virus to generate infectious progeny, relative to other virus genotypes in the population Pathovars Bacterial strains with the same or similar characteristics In vitro packaging system A simplified experimental system in which viral genome segments are incorporated into a virion particle; this occurs in a test tube and outside the context of an infected host cell Defective-interfering RNAs Spontaneously generated mutant RNA molecules that usually contain large gene deletions but maintain sequences that are crucial for their replication and packaging. These RNAs reduce the fitness of full-length viruses during cellular co-infection HA–NA subtype A binomial system of classification for influenza A viruses that is based on the neutralizing antibody response to the virion structural proteins haemagglutinin (HA) and neuraminidase (NA) Diploidy or polyploidy, In virology when an individual virus encapsidates two (diploidy) or more (polyploidy) copies of the genome into a single virus particle Figure 1 Reassortment, sexual reproduction and recombination a | Reassortment in non-multipartite RNA viruses. Two virus particles are shown, each with a full complement of three viral genome segments. Following reassortment, hybrid progeny can be formed that contain segments derived from both parents. b | Sexual reproduction. Two parent gamete cells are shown, each with a haploid genome of three chromosomal segments. Following sex between the two parents, a hybrid diploid progeny is produced that contains one copy of each chromosome from each parent. c | Recombination in non-segmented, single-stranded RNA viruses. Following recombination between two virus particles, chimeric genomes are produced that have regions derived from each parent. Figure 2 Pseudomonas phage φ6, influenza A virus and rotavirus genome organization and assortment a | The Pseudomonas phage φ6 genome consists of three double-stranded RNA (dsRNA) segments: small (S), medium (M) and large (L). Blue indicates ORFs, and grey represents intergenic regions; lines at the 5′ and 3′ termini represent UTRs. Sequences that are known to be important for the selective packaging of φ6 single-stranded positive-sense RNA ((+)RNA) replication intermediates are shown in red. b | A model of φ6 genome segment assortment and packaging. φ6 (+)RNAs are packaged sequentially. Initially, the procapsid has a binding site only for the S (+)RNA segment, enabling it to be inserted. Following the packaging of the S segment, a binding site for the M (+)RNA segment is revealed in the procapsid, enabling that segment to be inserted. Finally, a binding site for the L (+)RNA segment is revealed, the segment is inserted, and the entire complement of φ6 (+)RNAs are encapsidated. Following packaging of all three (+)RNA segments, the procapsid core expands, which triggers the conversion of the three (+)RNAs into double-stranded RNA (dsRNA) genome segments by viral polymerases. c | The influenza A virus genome comprises eight negative-sense RNA ((−)RNA) segments. A representative segment is shown as a linear (−)RNA molecule (top) and as a ribonucleoprotein (RNP; bottom), in which the (−)RNA is bound by a heterotrimeric polymerase complex and nucleocapsid protein (NP). The ORF, UTRs and sequences that are important for selective genome packaging are coloured as in part a. d | A model of genome segment assortment and packaging in influenza A viruses. Eight influenza A virus RNPs are synthesized in the nucleus and individually exported into the cytosol, where they pair up with each other. While en route to the plasma membrane, the eight RNPs form a supramolecular complex that is encapsidated by a lipid envelope during budding to form the virion. e | The genome of rotavirus A is composed of 11 dsRNA segments, one of which is shown as a (+)RNA precursor in linear form (top) and folded into a putative panhandle shape (bottom). The ORF, UTRs and sequences that are important for selective packaging are coloured as in part a and part b. A polymerase–capping enzyme complex is thought to be bound to the 3′-terminal UGUGACC sequence. A putative stem–loop structure may act as an assortment and/or packaging signal. f | A model of genome segment assortment and packaging in rotaviruses. The 11 (+)RNAs, each with a bound polymerase–capping enzyme complex, are thought to pair up and eventually form a supramolecular complex that is encapsidated by a forming virion particle. During or immediately after encapsidation, the (+)RNAs are converted into dsRNA genome segments by their dedicated polymerase. The polymerases function while tethered to the viral capsid (not shown). Figure 3 Direct restrictions on the generation of reassortants a | Incompatibility of RNA–RNA interactions. Two influenza A virus genome segments are shown as ribonucleoproteins (RNPs), each derived from a parent strain (strain A is shown in red and strain B is shown in blue). If the packaging signals are compatible (left), the RNA molecules can interact, which leads to co-packaging and reassortment. However, if the packaging signals are not compatible, the RNA molecules will interact suboptimally, thereby preventing their co-packaging. b | Incompatibility of protein–RNA interactions. A rotavirus A positive-sense RNA ((+)RNA) molecule from one strain may be recognized only by the polymerase from that same strain. If the polymerase in the virion is from a different strain and is unable to recognize the (+)RNA molecule, replication does not occur, thus restricting the generation of reassortants. Figure 4 Fitness consequences of reassortment a | Increase in viral fitness. Following reassortment, hybrid progeny can be formed that contain segments derived from both parents. In some cases, the new allelic combination confers phenotypic changes to the reassortant. For example, reassortment can produce an antigenically novel variant that is not recognized by the host immune system. This more-fit reassortant emerges in the host, whereas the less-fit parental strains are eliminated. b | Decrease in viral fitness. In some cases, reassortment can uncouple essential cognate protein sets that interact optimally when kept together. If non-cognate proteins do not interact, the reassortant would be less fit than parental strains and would therefore be eliminated from the population. c | Post-reassortment adaptations. A less-fit reassortant can accumulate mutations that restore the interaction interface between the non-cognate proteins. Such post-reassortment adaptive changes will enable the reassortant to regain fitness and emerge. Table 1 Segmented RNA virus families: genome organization, type species and hosts Family Genome organization Packaging Type species of genera within family Hosts Arenaviridae 2 (−)RNA or ambisense* molecules Single virion Lymphocytic choriomeningitis mammarenavirus Animals Birnaviridae 2 dsRNA molecules Single virion Infectious bursal disease virus Animals Bromoviridae 3 (+)RNA molecules Multipartite Brome mosaic virus Plants Bunyaviridae 3 (−)RNA or ambisense molecules Single virion Rift Valley fever virus, Tomato spotted wilt virus Animals and plants Chrysoviridae 4 dsRNA molecules Multipartite Penicillium chrysogenum virus Fungi Closteroviridae 2 (+)RNA molecules Multipartite Lettuce infectious yellows virus Plants Cystoviridae ‡ 3 dsRNA molecules Single virion Pseudomonas phage φ6, Pseudomonas phage φ10, Pseudomonas phage φ13 Bacteria Orthomyxoviridae ‡ 6–8 (−)RNA molecules Single virion Influenza A virus, Influenza B virus Animals Partitiviridae 2 dsRNA molecules Multipartite White clover cryptic virus 1 Plants, fungi and protozoa Picobirnaviridae 2 dsRNA molecules Multipartite Human picobirnavirus Animals Reoviridae ‡ 8–12 dsRNA molecules Single virion Rotavirus A, Bluetongue virus Animals and plants dsRNA, double-stranded RNA; (+)RNA: positive-sense RNA; (−)RNA, negative-sense RNA. * Ambisense refers to an RNA molecule that is positive-sense in some regions and negative-sense in other regions. ‡ This Review focuses on these three families. 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Virol 20 380 391 2010 20853340 44 Gerber M Selective packaging of the influenza A genome and consequences for genetic reassortment Trends Microbiol 22 446 455 2014 This review article summarizes the genetic, biochemical and structural data supporting the current model of genome segment assortment and packaging in influenza A viruses 24798745 45 Hutchinson EC Fodor E Transport of the influenza virus genome from nucleus to nucleus Viruses 5 2424 2446 2013 24104053 46 Chou YY One influenza virus particle packages eight unique viral RNAs as shown by FISH analysis Proc Natl Acad Sci USA 109 9101 9106 2012 22547828 47 Chou YY Colocalization of different influenza viral RNA segments in the cytoplasm before viral budding as shown by single-molecule sensitivity FISH analysis PLoS Pathog 9 e1003358 2013 23671419 48 Lakdawala SS Influenza A virus assembly intermediates fuse in the cytoplasm PLoS Pathog 10 e1003971 2014 This investigation uses multicolour single-molecule fluorescent in situ hybridization to show that influenza A virus RNAs assort in the cytoplasm while en route to the plasma membrane 24603687 49 Gavazzi C An in vitro network of intermolecular interactions between viral RNA segments of an avian H5N2 influenza A virus: comparison with a human H3N2 virus Nucleic Acids Res 41 1241 1254 2013 23221636 50 Gavazzi C A functional sequence-specific interaction between influenza A virus genomic RNA segments Proc Natl Acad Sci USA 110 16604 16609 2013 This paper describes in vitro experiments that identify direct intermolecular interactions between influenza A virus genomic RNA segments, shedding light on the mechanism of assortment 24067651 51 Fournier E Interaction network linking the human H3N2 influenza A virus genomic RNA segments Vaccine 30 7359 7367 2012 23063835 52 Fournier E A supramolecular assembly formed by influenza A virus genomic RNA segments Nucleic Acids Res 40 2197 2209 2012 22075989 53 Hutchinson EC Genome packaging in influenza A virus J Gen Virol 91 313 328 2010 19955561 54 Sugita Y Configuration of viral ribonucleoprotein complexes within the influenza A virion J Virol 87 12879 12884 2013 This study uses electron microscopy to analyse the fine structure of purified RNPs and their configuration within influenza A virions, thereby revealing novel aspects of assortment and packaging 24067952 55 Enami M An influenza virus containing nine different RNA segments Virology 185 291 298 1991 1833874 56 Gao Q A nine-segment influenza a virus carrying subtype H1 and H3 hemagglutinins J Virol 84 8062 8071 2010 20519387 57 Brooke CB Most influenza A virions fail to express at least one essential viral protein J Virol 87 3155 3162 2013 This article reports experiments showing that the vast majority of influenza A virus particles do not express at least one viral protein. This implies that the genome segment packaging efficiency for influenza A viruses may be lower than previously predicted 23283949 58 Brooke CB Influenza A virus nucleoprotein selectively decreases neuraminidase gene-segment packaging while enhancing viral fitness and transmissibility Proc Natl Acad Sci USA 111 16854 16859 2014 25385602 59 Fonville JM Influenza virus reassortment is enhanced by semi-infectious particles but can be suppressed by defective interfering particles PLoS Pathog 11 e1005204 2015 This work shows that influenza A virus particles that lack a full complement of functional genome segments (that is, semi-infectious particles) can reassort with infectious particles 26440404 60 Otuka A Migration of rice planthoppers and their vectored re-emerging and novel rice viruses in East Asia Front Microbiol 4 309 2013 24312081 61 Tate JE Parashar UD Rotavirus vaccines in routine use Clin Infect Dis 59 1291 1301 2014 25048849 62 Marthaler D Rapid detection and high occurrence of porcine rotavirus A, B, and C by RT-qPCR in diagnostic samples J Virol Methods 209 30 34 2014 25194889 63 Moutelikova R Prodelalova J Dufkova L Prevalence study and phylogenetic analysis of group C porcine rotavirus in the Czech Republic revealed a high level of VP6 gene heterogeneity within porcine cluster I1 Arch Virol 159 1163 1167 2014 24212886 64 Amimo JO Vlasova AN Saif LJ Prevalence and genetic heterogeneity of porcine group C rotaviruses in nursing and weaned piglets in Ohio, USA and identification of a potential new VP4 genotype Vet Microbiol 164 27 38 2013 23428382 65 Park SI Genetically diverse group C rotaviruses cause sporadic infection in Korean calves J Vet Med Sci 73 479 482 2011 21099189 66 Lobo PD Phylogenetic analysis of human group C rotavirus in hospitalized children with gastroenteritis in Belem, Brazil J Med Virol 88 728 733 2016 26369400 67 Luchs A do Carmo Sampaio Tavares Timenetsky M Phylogenetic analysis of human group C rotavirus circulating in Brazil reveals a potential unique NSP4 genetic variant and high similarity with Asian strains Mol Genet Genom 290 969 986 2015 68 El-Senousy WM Ragab AM Handak EM Prevalence of rotaviruses groups A and C in Egyptian children and aquatic environment Food Environ Virol 7 132 141 2016 69 Lahon A Walimbe AM Chitambar SD Full genome analysis of group B rotaviruses from western India: genetic relatedness and evolution J Gen Virol 93 2252 2266 2012 22815276 70 Trask SD McDonald SM Patton JT Structural insights into the coupling of virion assembly and rotavirus replication Nat Rev Microbiol 10 165 177 2012 22266782 71 Rainsford EW McCrae MA Characterization of the NSP6 protein product of rotavirus gene 11 Virus Res 130 193 201 2007 17658646 72 McDonald SM Patton JT Assortment and packaging of the segmented rotavirus genome Trends Microbiol 19 136 144 2011 21195621 73 Lawton JA Estes MK Prasad BV Mechanism of genome transcription in segmented dsRNA viruses Adv Virus Res 55 185 229 2000 11050943 74 Gallegos CO Patton JT Characterization of rotavirus replication intermediates: a model for the assembly of single-shelled particles Virology 172 616 627 1989 This seminal investigation analyses the protein composition and activity of rotavirus replication–assembly intermediates and suggests a model for genome segment assortment 2552662 75 Patton JT Gallegos CO Structure and protein composition of the rotavirus replicase particle Virology 166 358 365 1988 2845649 76 Patton JT Gallegos CO Rotavirus RNA replication: single-stranded RNA extends from the replicase particle J Gen Virol 71 1087 1094 1990 2161046 77 Suzuki Y A candidate packaging signal of human rotavirus differentiating Wa-like and DS-1-like genomic constellations Microbiol Immunol 59 567 571 2015 26224654 78 Li W Genomic analysis of codon, sequence and structural conservation with selective biochemical-structure mapping reveals highly conserved and dynamic structures in rotavirus RNAs with potential cis-acting functions Nucleic Acids Res 38 7718 7735 2010 20671030 79 Burkhardt C Structural constraints in the packaging of bluetongue virus genomic segments J Gen Virol 95 2240 2250 2014 24980574 80 Sung PY Roy P Sequential packaging of RNA genomic segments during the assembly of bluetongue virus Nucleic Acids Res 42 13824 13838 2014 25428366 81 Roner MR Steele BG Localizing the reovirus packaging signals using an engineered m1 and s2 ssRNA Virology 358 89 97 2007 This paper describes reverse genetics experiments that enabled the localization of the packaging signals for two viral genome segments of Reoviridae family members 16987539 82 Roner MR Bassett K Roehr J Identification of the 5′ sequences required for incorporation of an engineered ssRNA into the reovirus genome Virology 329 348 360 2004 15518814 83 Roner MR Joklik WK Reovirus reverse genetics: incorporation of the CAT gene into the reovirus genome Proc Natl Acad Sci USA 98 8036 8041 2001 11427706 84 Zhang X In situ structures of the segmented genome and RNA polymerase complex inside a dsRNA virus Nature 527 531 534 2015 26503045 85 Desselberger U Genome rearrangements of rotaviruses Arch Virol Suppl 12 37 51 1996 9015100 86 Troupin C Rearranged genomic RNA segments offer a new approach to the reverse genetics of rotaviruses J Virol 84 6711 6719 2010 20427539 87 Navarro A Trask SD Patton JT Generation of genetically stable recombinant rotaviruses containing novel genome rearrangements and heterologous sequences by reverse genetics J Virol 87 6211 6220 2013 This study uses reverse genetics to show that additional RNA, including heterologous gene sequences, can be packaged into rotavirus virions 23536662 88 Tian Y Genomic concatemerization/deletion in rotaviruses: a new mechanism for generating rapid genetic change of potential epidemiological importance J Virol 67 6625 6632 1993 8411365 89 Taniguchi K Kojima K Urasawa S Nondefective rotavirus mutants with an NSP1 gene which has a deletion of 500 nucleotides, including a cysteine-rich zinc finger motif-encoding region (nucleotides 156 to 248), or which has a nonsense codon at nucleotides 153 to 155 J Virol 70 4125 4130 1996 This report describes a naturally occurring rotavirus mutant that does not express a functional NSP1 protein but that efficiently incorporates the NSP1-coding gene. The implications of this study are that the NSP1-coding RNA molecule itself is essential for assortment and packaging of the other ten genome segments 8648754 90 Baker SF Influenza A and B virus intertypic reassortment through compatible viral packaging signals J Virol 88 10778 10791 2014 This article presents experiments showing that an influenza A virus can package an influenza B virus genome segment, provided that the segment contains cognate influenza A virus packaging signals 25008914 91 Essere B Critical role of segment-specific packaging signals in genetic reassortment of influenza A viruses Proc Natl Acad Sci USA 110 E3840 E3848 2013 This investigation shows the importance of compatible packaging signals for efficient reassortment to occur among divergent influenza A virus strains 24043788 92 Marshall N Influenza virus reassortment occurs with high frequency in the absence of segment mismatch PLoS Pathog 9 e1003421 2013 This paper describes experiments that quantify, for the first time, the efficiency of reassortment between two nearly genetically identical strains of influenza A virus, indicating that reassortment is restricted mainly by genetic incompatibility of strains 23785286 93 Diaz-Munoz SL Electrophoretic mobility confirms reassortment bias among geographic isolates of segmented RNA phages BMC Evol Biol 13 206 2013 24059872 94 Qiao X Qiao J Onodera S Mindich L Characterization of Φ13, a bacteriophage related to Φ6 and containing three dsRNA genomic segments Virology 275 218 224 2000 11017801 95 Ramig RF Genetics of the rotaviruses Annu Rev Microbiol 51 225 255 1997 9343350 96 Wenske EA Genetic reassortment of mammalian reoviruses in mice J Virol 56 613 616 1985 4057359 97 Nibert ML Margraf RL Coombs KM Nonrandom segregation of parental alleles in reovirus reassortants J Virol 70 7295 7300 1996 This work documents the frequency of reassortment between two strains of the Reoviridae family following experimental co-infection, and provides evidence for genetic linkages among segments 8794386 98 Ramig RF Analysis of reassortment and superinfection during mixed infection of Vero cells with bluetongue virus serotypes 10 and 17 J Gen Virol 70 2595 2603 1989 2552005 99 Lu X Mechanism for coordinated RNA packaging and genome replication by rotavirus polymerase VP1 Structure 16 1678 1688 2008 This article reports the high-resolution X-ray crystal structure of the rotavirus polymerase in the presence and absence of RNA template, informing an understanding of genome segment packaging and replication 19000820 100 Ogden KM Johne R Patton JT Rotavirus RNA polymerases resolve into two phylogenetically distinct classes that differ in their mechanism of template recognition Virology 431 50 57 2012 22687427 101 Yang H Makeyev EV Bamford DH Comparison of polymerase subunits from double-stranded RNA bacteriophages J Virol 75 11088 11095 2001 11602748 102 Nelson MI Evolution of novel reassortant A/H3N2 influenza viruses in North American swine and humans, 2009–2011 J Virol 86 8872 8878 2012 22696653 103 Dugan VG The evolutionary genetics and emergence of avian influenza viruses in wild birds PLoS Pathog 4 e1000076 2008 18516303 104 Lindstrom SE Cox NJ Klimov A Genetic analysis of human H2N2 and early H3N2 influenza viruses, 1957–1972: evidence for genetic divergence and multiple reassortment events Virology 328 101 119 2004 15380362 105 Nelson MI Multiple reassortment events in the evolutionary history of H1N1 influenza A virus since 1918 PLoS Pathog 4 e1000012 2008 18463694 106 Rambaut A The genomic and epidemiological dynamics of human influenza A virus Nature 453 615 619 2008 18418375 107 Holmes EC Whole-genome analysis of human influenza A virus reveals multiple persistent lineages and reassortment among recent H3N2 viruses PLoS Biol 3 e300 2005 This first large-scale comparative genomics study of influenza A viruses shows that multiple co-circulating lineages exist and documents reassortment events 16026181 108 Ghedin E Large-scale sequencing of human influenza reveals the dynamic nature of viral genome evolution Nature 437 1162 1166 2005 16208317 109 Westgeest KB Genome-wide analysis of reassortment and evolution of human influenza A (H3N2) viruses circulating between 1968 and 2011 J Virol 88 2844 2857 2014 24371052 110 McDonald SM Evolutionary dynamics of human rotaviruses: balancing reassortment with preferred genome constellations PLoS Pathog 5 1000634 2009 This first large-scale comparative genomics study of human rotaviruses shows that multiple co-circulating lineages exist and documents reassortment events 111 McDonald SM Diversity and relationships of cocirculating modern human rotaviruses revealed using large-scale comparative genomics J Virol 86 9148 9162 2012 22696651 112 Zhang S Analysis of human rotaviruses from a single location over an 18-year time span suggests that protein coadaption influences gene constellations J Virol 88 9842 9863 2014 This comparative genomics study of human rotavirus identifies persistent lineages and suggests that co-adaptation of functionally interacting viral proteins may restrict reassortment over time 24942570 113 Dennis AF Molecular epidemiology of contemporary G2P[4] human rotaviruses cocirculating in a single U.S. community: footprints of a globally transitioning genotype J Virol 88 3789 3801 2014 24429371 114 Nomikou K Widespread reassortment shapes the evolution and epidemiology of bluetongue virus following European invasion PLoS Pathog 11 e1005056 2015 26252219 115 Nelson MI Phylogenetic analysis reveals the global migration of seasonal influenza A viruses PLoS Pathog 3 1220 1228 2007 17941707 116 Simonsen L The genesis and spread of reassortment human influenza A/H3N2 viruses conferring adamantane resistance Mol Biol Evol 24 1811 1820 2007 17522084 117 Li C Compatibility among polymerase subunit proteins is a restricting factor in reassortment between equine H7N7 and human H3N2 influenza viruses J Virol 82 11880 11888 2008 This is the first investigation to reveal how incompatibilities among polymerase subunits can restrict reassortment among divergent influenza A viruses 18815312 118 Hara K Co-incorporation of the PB2 and PA polymerase subunits from human H3N2 influenza virus is a critical determinant of the replication of reassortant ribonucleoprotein complexes J Gen Virol 94 2406 2416 2013 23939981 119 Octaviani CP Goto H Kawaoka Y Reassortment between seasonal H1N1 and pandemic (H1N1) 2009 influenza viruses is restricted by limited compatibility among polymerase subunits J Virol 85 8449 8452 2011 21680507 120 McDonald SM Shared and group-specific features of the rotavirus RNA polymerase reveal potential determinants of gene reassortment restriction J Virol 83 6135 6148 2009 This is the first report to demonstrate how incompatibilities between the rotavirus polymerase and core shell protein may restrict reassortment among divergent strains 19357162 121 McDonald SM Patton JT Rotavirus VP2 core shell regions critical for viral polymerase activation J Virol 85 3095 3105 2011 21248043 122 Taraporewala ZF Structure-function analysis of rotavirus NSP2 octamer by using a novel complementation system J Virol 80 7984 7994 2006 16873255 123 Ilyushina NA Postreassortment changes in a model system: HA–NA adjustment in an H3N2 avian–human reassortant influenza virus Arch Virol 150 1327 1338 2005 15789269 124 Kaverin NV Postreassortment changes in influenza A virus hemagglutinin restoring HA–NA functional match Virology 244 315 321 1998 This article reports that compensatory mutations can correct mismatched protein interactions that were due to reassortment for influenza A viruses in cell culture experiments 9601502 125 Kaverin NV Intergenic HA–NA interactions in influenza A virus: postreassortment substitutions of charged amino acid in the hemagglutinin of different subtypes Virus Res 66 123 129 2000 10725545 126 Rudneva IA Effect of gene constellation and postreassortment amino acid change on the phenotypic features of H5 influenza virus reassortants Arch Virol 152 1139 1145 2007 17294090 127 Neverov AD Intrasubtype reassortments cause adaptive amino acid replacements in H3N2 influenza genes PLoS Genet 10 e1004037 2014 This study shows that influenza A virus reassortment in nature causes a temporary increase in the rate of amino acid changes as the viral proteins adapt to a new genetic environment 24415946 128 Krammer F Palese P Steel J Advances in universal influenza virus vaccine design and antibody mediated therapies based on conserved regions of the hemagglutinin Curr Top Microbiol Immunol 386 301 321 2015 25007847 129 Jin H Subbarao K Live attenuated influenza vaccine Curr Top Microbiol Immunol 386 181 204 2015 25059893 130 Chandran A Santosham M RotaTeq: a three-dose oral pentavalent reassortant rotavirus vaccine Expert Rev Vaccines 7 1475 1480 2008 19053204 131 Qin XC A tick-borne segmented RNA virus contains genome segments derived from unsegmented viral ancestors Proc Natl Acad Sci USA 11 6744 6749 2014 132 Andersson DI Jerlstrom-Hultqvist J Nasvall J Evolution of new functions de novo and from preexisting genes Cold Spring Harb Perspect Biol 7 a017996 2015 26032716 133 Shirogane Y Watanabe S Yanagi Y Cooperation between different RNA virus genomes produces a new phenotype Nat Commun 3 1235 2012 23212364 134 Rager M Polyploid measles virus with hexameric genome length EMBO J 21 2364 2372 2002 12006489 135 Beniac DR The organisation of Ebola virus reveals a capacity for extensive, modular polyploidy PLoS ONE 7 e29608 2012 22247782
PMC005xxxxxx/PMC5119465.txt
LICENSE: This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. 101282906 33137 ACS Chem Biol ACS Chem. Biol. ACS chemical biology 1554-8929 1554-8937 27310134 5119465 10.1021/acschembio.6b00398 NIHMS824491 Article New Aspercryptins, Lipopeptide Natural Products, Revealed by HDAC Inhibition in Aspergillus nidulans Henke Matthew T. † Soukup Alexandra A. || Goering Anthony W. † McClure Ryan A. ‡ Thomson Regan J. ‡ Keller Nancy P. ||⊥# Kelleher Neil L. *†‡§ † Department of Molecular Biosciences, Northwestern University, Evanston, Illinois 60208, United States ‡ Department of Chemistry, Northwestern University, Evanston, Illinois 60208, United States § Feinberg School of Medicine, Northwestern University, Evanston, Illinois 60208, United States || Department of Genetics, University of Wisconsin, Madison, Wisconsin 53706, United States ⊥ Department of Bacteriology, University of Wisconsin, Madison, Wisconsin 53706, United States # Department of Medical Microbiology and Immunology, University of Wisconsin, Madison, Wisconsin 53706, United States * Corresponding Author: n-kelleher@northwestern.edu 22 10 2016 24 6 2016 19 8 2016 19 8 2017 11 8 21172123 This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. Unlocking the biochemical stores of fungi is key for developing future pharmaceuticals. Through reduced expression of a critical histone deacetylase in Aspergillus nidulans, increases of up to 100-fold were observed in the levels of 15 new aspercryptins, recently described lipopeptides with two non-canonical amino acids derived from octanoic and dodecanoic acids. In addition to two NMR-verified structures, MS/MS networking helped uncover an additional 13 aspercryptins. The aspercryptins break the conventional structural orientation of lipopeptides and appear “backward” when compared to known compounds of this class. We have also confirmed the 14-gene aspercryptin biosynthetic gene cluster, which encodes two fatty acid synthases and several enzymes to convert saturated octanoic and dodecanoic acid to α-amino acids. Graphical Abstract For decades the search for new natural products by screening for bioactivity has been hampered by rediscovering the same compounds.1 To avoid the rediscovery of natural products, some laboratories have decoupled discovery from screening for bioactivity by measuring accurate mass as the primary, high-throughput screen for the expression of new natural products.2 This new approach to molecular discovery has been applied to bacteria3,4 but less so in fungi, which offer an enormous biosynthetic potential.5 The genome of the mold Aspergillus nidulans contains more than 50 gene clusters annotated to be involved in the biosynthesis of natural products. Yet just over 20 of these biosynthetic gene clusters (BGCs) have associated natural products.6 Several strategies have been developed to better harness the biosynthetic repertoire of fungi.7 One such strategy involves the inhibition of histone deacetylase activity (HDACi) and has shown some promise.8–10 HDACi increases global histone acetylation levels and can increase transcription of otherwise repressed natural product BGCs. Our previous work used quantitative mass spectrometry-based analyses to compare the extracellular metabolomes of A. nidulans before and after both chemical and genetic HDACi.11 We found that HDACi both up-regulated and down-regulated the expression of many compounds. Among the up-regulated compounds were several not known to be produced by A. nidulans, such as the fellutamides.11 Continuing those efforts here, we have solved the structures of two new lipopeptides, aspercryptin A1 and A2, that are up-regulated by up to 90-fold using the HDACi-based strategy. The aspercryptins are six-amino-acid peptides containing two noncanonical α-amino acids derived from saturated C8- and C12-fatty acids and a C-terminal alcohol and are related to two previous aspercryptins published by Chiang et al. in 2016.12 Unlike the overwhelming majority of lipopeptides in the literature, the aspercryptins appear “backward” and have their lipid tail at the C-terminus. We also map the BGC responsible for the aspercryptins by genetic disruption and Northern blotting. It features a NRPS backbone gene encoding a terminal reductase, atypical activation domains for unusual “fatty amino acid” substrates, and enzymes putatively involved in fatty amino acid biogenesis. The aspercryptins join a small group of lipopeptide natural products where incorporation of the lipid moiety occurs at sites other than the N-terminus. Comparative Metabolomics of HDAC-Deficient A. nidulans Reveals the Aspercryptins In previous work, we generated a mutant of A. nidulans with constitutively lower levels of the HDAC RpdA (AN4493).11 Using differential metabolomics on this strain (rpdAKD, RAAS58.4) compared with wildtype fungus (Figure 1, left), we detected many signals that were up-regulated in the rpdAKD mutant (Figure 1, middle panels). Dereplication of these metabolites based on their accurate masses allowed us to cull the list to only those that have not yet been characterized (Figure 1). Several dozen of the putatively new metabolites displayed a high degree of similarity in their MS/MS fragmentation spectra, suggesting structural and therefore biosynthetic relatedness (Figure 2). For the members of this compound family, all were up-regulated over a wide range from 2- to 130-fold in rpdAKD vs wildtype (data for one compound are shown in Figure 1, third panel). The structures of two of these compounds, aspercryptin A1 (m/z 758.5386 [M + H]+, C37H71N7O9, −0.02 ppm) and aspercryptin A2 (m/z 742.5440 [M + H]+, C37H71N7O8, 0.45 ppm; Figure 1, right panel) were determined completely by MS with stable isotope feeding and extensive NMR (Supporting Information Table S1). The Aspercryptins Are “Backward” Lipopeptides The aspercryptins are linear lipopeptides built from six amino acids and appear to be the first example of peptide natural products with two lipid groups. They also seem to be the only known lipopeptides with a lipid tail at the C-terminus; thus they appear “backward” to other lipopeptides. This is despite the overwhelming literature precedent for lipopeptides having an N-terminal lipid group. Aspercryptin A1 and A2 differ from each other only at the N-terminal residue—serine for aspercryptin A1 and alanine for aspercryptin A2. The most striking feature of the aspercryptins is that of the six amino acids, two are highly unusual and nonproteogenic: 2-amino-octanoic acid and 2-amino-dodecanol. Stereochemical assignment of the aspercryptins was determined for each residue by derivatization with Marfey’s reagent and comparison with standards using HPLC-MS (Supporting Information Figure S1). For aspercryptin A1, the first two residues (serine and threonine) are epimerized to D-serine and D-allo-threonine while the remaining four residues are the L-isomers. The stereocenters of aspercryptin A2 are the same as those in aspercryptin A1; however, there is also an epimer of aspercryptin A2 such that the alanine is the L-isomer, thus we name this analogue epi-aspercryptin A2 (Supporting Information Figure S1). Several of these monomers (threonine, isoleucine, and serine) were also confirmed by metabolic feeding of stable isotope analogues (Supporting Information Figure S2). Furthermore, stable-isotope labeling shows that when fed d3-serine, labeled aspercryptin A1 only shows incorporation of two deuterons (Supporting Information Figure S2d). This further supports the epimerization of this residue by loss of the deuteron on the α carbon. MS/MS Networking Reveals a Large Family of Aspercryptins We observed that the MS/MS spectra of many other metabolites up-regulated by rpdAKD had striking similarity to those of aspercryptin A1 and A2. We then turned to MS/MS networking to visualize the relatedness of these metabolites in the data set. The ability for MS/MS networking to cluster biosynthetically related compounds is now established.13 When performing network analysis of the wildtype and rpdAKD extracts, we saw several examples of biosynthetically related natural products clustering together as expected; for example, the emericellamides group tightly together based on MS/MS spectral similarity (Figure 2a, circled). One cluster of metabolites consistently upregulated in the rpdAKD extracts (Figure 2a, boxed) contained aspercryptins A1 and A2 (Figure 2b). Using the MS/MS fragmentation patterns of aspercryptin A1 and A2 (Supporting Information Figures S3 and S4) and the recently published aspercryptins B1 and B312 as anchor points, we detected and have proposed putative structures for an additional 13 aspercryptins (Figure 2b, yellow circles; Table 1). These new aspercryptins fall into subfamilies, and we were readily able to quantify their abundance increases in the rpdAKD mutant (Supporting Information Figure S5). The putative structures for 8 of the additional 13 are shown in Figure 3. A subset was chosen for clarity in the main text (for a complete version of this chart, see Supporting Information Figure S6). The variations in the structures of the aspercryptins are standard for what is seen from NRPS pathways: incorporation of alanine instead of serine, valine for isoleucine, and a C10 fatty amino alcohol instead of the C12 version. Taking the structure of aspercryptin A1 as the “canonical” sequence of the aspercryptins, we have made a hierarchical nomenclature system, where the letter represents the status of the N-terminus, A for a free amine, B for cichorine capped, C for acetyl, and D for propionyl, and where the number represents “variants” of the base amino acid sequence, 1 for canonical, 2 for serine to alanine, etc. Isolation and full NMR structure determination for each of the aspercryptins are beyond the scope of this work. While the de novo structure elucidation of natural products from analysis of MS and MS/MS data alone is not possible, such analyses can readily be used for the detection and putative characterization of highly similar structural analogues. Though the stereochemistry of the aspercryptins proposed by MS/MS analysis is likely the same as those that have been experimentally determined, we have refrained from assuming that this is indeed the case (Figure 3). Confirmation of the Aspercryptin Biosynthetic Gene Cluster Linking natural products to their gene clusters is key to annotating the biosynthetic potential of phylogenetically diverse fungi. The genome of A. nidulans contains a 14-gene BGC12 (AN7884 to AN7872, Figure 4a and Supporting Information Table S3) that was recently shown to produce aspercryptins B1 and B3.12 This BGC contains a six-module NRPS (AN7884) and two fatty acid synthase (FAS) subunits (AN7880 and AN7873). To experimentally link all of the aspercryptins to this BGC, we deleted the NRPS gene, AN7884, and observed no detectable levels of any of the aspercryptins (Figure 4b). We also generated an overexpression mutant of the nearby transcription factor, AN7872, which led to increased transcript levels for many of the genes predicted to be in the cluster. This mirrored the overexpression of these genes in the rpdAKD strain (Supporting Information Figure S7) and confirmed the predicted cluster boundaries. Further solidifying its role as the transcription factor for the cluster, we also observed a >2-fold increase in the levels of aspercryptin A1 upon overexpression of AN7872 (Figure 4c). Additionally, deletion of the FAS gene AN7880 abolished production of the aspercryptins. Levels of the aspercryptins could be rescued partially by supplementing the media with octanoic and dodecanoic acids, which are likely the direct products of the FAS enzymes (Figure 4c). The NRPS, the transcription factor, and the intervening genes have been named atnA (NRPS) through atnN (transcription factor). Upon exploring the phylogenetic distribution of the atn BGC in the Aspergillus genome repository (http://www.aspergillusgenome.org), we found the atn BGC present in six other Aspergilli and to be most conserved in A. versicolor (NRPS genes 87% identical, Supporting Information Figure S8). The BGC borders were confirmed by transcript mapping using Northern blots of all genes in the cluster (Supporting Information Figure S7). Proposed Biosynthesis for the Aspercryptins Based on annotations of the BGC and the above deletion experiments, we propose the following for aspercryptin biosynthesis (Supporting Information Figure S9). The first step is the generation of the fatty acid precursors, octanoic and dodecanoic acids, by the FAS subunits AtnF and AtnM (AN7880 and AN7873). A. nidulans has three other pairs of FAS genes. One, fasA and fasB, is required for fatty acids involved in primary metabolism; deletion of either fasA or fasB is lethal.14 The other two pairs of FAS genes make precursor fatty acids for natural products—pkiB and pkiC for the polyketides made by the PKS pkiA (AN3386)15 and stcJ and stcK for sterigmatocystin biosynthesis.14 The fatty acid precursors are perhaps the most interesting aspect of the system and are likely transformed into the corresponding α-amino fatty acids in three steps. First, they are hydroxylated by the cytochrome P450 AtnE (AN7881), then oxidized to the corresponding α-keto acids by the NAD(P)-dependent oxidoreductase AtnD (AN11028), and finally converted to the α-amino fatty acids by the PLP-dependent aminotransferases AtnH or AtnJ (AN7878 and AN7876). Similar pathways to convert a fatty acid or polyketide precursor to the corresponding α-amino acid have been proposed for the cyclosporins and apicidins/HC-toxin, and experimentally supported to varying degrees.16–18 The only experimental evidence to support this transformation pathway from these systems comes from the deletion of a branched chain aminotransferase which eliminates HC-toxin biosynthesis.19 A recent publication by Chiang et al. also proposes this pathway for production of the fatty amino acids and shows that deletion of these genes abolished levels of aspercryptin B1 (except in the case of the aminotransferases, AtnH and AtnJ, which could reasonably compensate for each other).12 Unlike the other FAS genes in the A. nidulans genome, the aspercryptin FAS elements are “interrupted” by the amino-transferase genes that we suggest are involved in generation of the α-amino fatty acids (Supporting Information Figure S10). Perhaps this chromosomal organization evolved to decrease the likelihood that the gene cassette necessary for the fatty amino acid biosynthesis will be separated by chromosomal reorganization. If they were not disrupted by the aminotransferases, the expression of the FAS genes could conceivably result in unproductive synthesis of free medium-chain fatty acids that could disrupt membrane stability. In fact, the addition of dodecanoic acid above 10 μM for rescue experiments resulted in little to no growth. Once made, we propose that the α-amino fatty acids, 2-amino-octanoic and 2-amino-dodecanoic acids, are recognized, activated, and covalently tethered to the NRPS AtnA by its fourth and sixth adenylation domains (Supporting Information Figure S9). For typical lipopeptides, lipid moieties are added to the N-terminus by an initial terminal condensation domain of the NRPS.20 Incorporation of the lipid group as an α-amino fatty acid by an adenylation domain has been proposed for members of the apicidin/HC-toxin family and demonstrated in the biosynthesis of cyclosporin, where the NRPS has been shown to adenylate and covalently bind to the polyketide-derived α-amino acid (4R)-4-[(E)-2-butenyl]-4-methyl-L-threonine (bmt).21,22 Experiments are ongoing to directly establish the activity of adenylation domains 4 and 6 of AtnA in recognizing and activating 2-amino-octanoic and 2-amino-dodecanoic acids, respectively. To date, only a handful of α-amino fatty acids have been observed in cyclic lipopeptides (Supporting Information Figure S11). Intriguingly all of these are derived from fungi, with the exception of the piperazimycins.23 Perhaps this strategy for lipid incorporation into natural products is a fungal innovation that spread into Streptomycetes. In general, using the NRPSpredictor2 (modeled from bacterial NRPS) did not confidently predict the amino acid substrates recognized by each of the six adenylation domains of AtnA (Supporting Information Table S4). While Chiang et al. propose cichorine-serine as the monomer activated by the first adenylation domain of AtnA for the biosynthesis of aspercryptin B1,12 we believe it to be serine, and that the N-terminal amine of mature aspercryptin A1 subsequently reacts during the biosynthesis of cichorine24 to form aspercryptin B1. Additionally, despite AtnA having only one epimerase domain in the threonine module, the first two amino acids of aspercryptin A1 are D-serine and D-allo-threonine. This suggests that serine is either loaded directly as D-serine or that the epimerase domain in the threonine module epimerizes both L-serine and L-threonine. Iterative epimerase domains are not without precedent.25 Because we observed that the alanine residue of aspercryptin A2 exists as a mixture of L- and D-enantiomers, we predict that the epimerase domain acts iteratively. Chronologically, L-serine (for aspercryptin A1) or L-alanine (for aspercryptin A2) is activated by the first adenylation domain of AtnA, and while serine is fully epimerized to the D-enantiomer by the epimerase domain, alanine is only partially converted to the D-enantiomer. The complete conversion of serine and threonine and partial conversion of alanine suggests that the side chain hydroxyl of serine and threonine may aid in governing substrate recognition by the epimerase domain. The final step in the biosynthesis of the aspercryptins is the reduction of the C-terminus to an alcohol. Terminal reductase domains generally use the energy from NAD(P)H to install a reactive aldehyde that serves as a warhead26 or as an intermediate that rearranges to yield a mature natural product.25 For the aspercryptins, the removal of a charge-bearing site from dominantly hydrophobic portion of the compound is a potential reason for the installation of this alcohol at the C-termini of aspercryptins. In fact, the putatively membrane-associated nature of the aspercryptins may be relevant to their function and is consistent with our ability to isolate these compounds mainly from the cell mass and little from the extracellular medium. Many microbes use lipopeptides as a means to adhere to or move across surfaces, and to establish biofilms.27 Because we could not assign an antibacterial activity, the aspercryptins may serve a similar structural/motility function for A. nidulans. We also note that atnH and atnJ are induced by ethanol (the other atn genes were not examined), which possibly reflects a role for this metabolite during hypoxic stress.28 Conclusion Here, we uncovered over a dozen family members of the recently discovered lipopeptides, the aspercryptins, and mapped the complete gene cluster responsible for their biosynthesis. Instrumental in the discovery of the aspercryptins was the marriage of HDAC inhibition with MS-based metabolite screening. By inhibiting HDAC function, we were able to tease the production of a new family of natural products. By taking advantage of MS/MS networking, we could characterize the structural variation of the aspercryptins. Our successful use of HDACi in the discovery of the aspercryptins demonstrates its potential to survey fungal extracts for new chemical matter, even in species that have been so intensively studied, such as A. nidulans. Discovery of new natural product scaffolds from the microbial world at rates far higher than in past decades now represents a promising path for reinvigorating the pipeline of compounds flowing into pharmaceutical screening platforms. METHODS Fungal Transformations The generation of the rpdAKD strain was previously described.11 All other strains in this study are described in Table S5. For construction of overexpression strains, 1 kb of AN7884 or AN7872 5′ flanking regions and 3′ coding regions were amplified and fused to A. parasiticus pyrG (amplified from pJW24) and a 401 bp fragment of the alcA promoter using double joint PCR.29,30 The resulting overexpression construct was transformed into RJMP1.1 to create strains TAAS393.2 and TAAS394.2. For deletion constructs, 1 kb of flanking regions were amplified and fused to A. fumigatus riboB using double joint PCR. The resulting knockout construct(s) were transformed into RJMP1.1 and/or TAAS393.2 to create strains TAAS176.3, TAAS395.1, and TAAS217.1. Transformants were examined for targeted replacement of the native loci by PCR and Southern blotting, and expression levels were confirmed by northern analysis. Growth and Extraction of Fungal Strains for LC-MS/MS Analysis All strains were grown with initial inoculations of 106 spores/mL in 250 mL of GMM in 1 L unbaffled flasks, grown in the dark at 37 °C for 4 days at 200 rpm. For the initial screening of the rpdAKD, overexpression and deletant mutants, extractions, and analysis were performed as previously described.11 For induction of over-expression strains, lactose minimal medium +30 mM cyclopentanone was used. For rescue experiments, media was supplemented with 10 μM octanoic and doceanoic acids in acetone. However, for stable isotope incorporation experiments, 5 mL of GMM in 13 mL culture tubes were inoculated with 106 spores/mL and grown as described above, with the additional step of spiking with 1 mM sterile-filtered stable-isotope amino acids after 48 h of growth. After a total of 4 days of growth, whole cultures were extracted with an equal volume of ethyl acetate with sonication and vortexing for several minutes, followed by overnight incubation at 4 °C. Organic layers were then dried down and analyzed as previously described.11 Isolation and Structural Determination of Aspercryptins A1 and A2 For isolation of aspercryptin from rpdAKD mutant, large-scale growths (500 mL growths in 2 L flask, total of 4 L) were performed as described above. Mycelium was separated from the spent media with coffee filters. The spent media was extracted with dichloromethane to generate an emulsion layer. The emulsion was dried down. The cellular material was washed with excess methanol. Methanol extracts and emulsions from DCM extraction were pooled in methanol and dried onto excess silica. Silica was washed with excess ethyl acetate, and aspercryptins were eluted from silica with methanol. The methanol fraction’s pH was set to ~8.5 and run over SAX resin (Dowex 1 × 2 chloride form); flowthrough contained aspercryptins. SAX Resin washed with MeOH (pH 5) and pooled with flowthrough. This was then fractionated over preparative RPLC to afford ~4 mg of aspercryptin A1 and A2 in a ~2:1 mixture that could not be chromatographically resolved. All NMR experiments were performed in DMSO-d6 on an Agilent 600 MHz DD2 with a HCN cryoprobe, except for 13C NMR, which was acquired with an AVANCE III 500 MHz with direct cryoprobe. Stereochemistry of amino acids was determined following a standard Marfey’s Test protocol.31 Briefly, 1 mg of a ~2:1 mixture of aspercryptins A1 and A2 was hydrolyzed in 6 N HCl overnight at 110 °C. The hydrolyzed mixture was dried in vacuo, to which 100 μL of 1% Marfey’s reagent (FDAA) in acetone and 20 μL 1 M NaHCO3 were added. Amino acid standards were derivatized as described above; 2.5 μmol were used of each DL-alanine, D-serine, L-serine, DL-threonine, DL-allo-threonine, DL-isoleucine, DL-aspartic acid (for asparagine), synthetic DL-2-amino-octanoic acid, and synthetic DL-2-amino-dodecanol. MS/MS Networking to Identify Aspercryptin Molecular Family All MS/MS spectra were preprocessed by removing the 25% lowest intensity peaks, applying a nonlinear transformation to the peak intensities by taking their square root, and normalizing peak intensities to the sum of the intensities of all remaining peaks in the spectrum. Spectra with less than 10 remaining peaks, along with those where the base peak constituted more than 75% of the total scan intensity were removed from the analysis. MS/MS spectra were compared using the cosine similarity method. When comparing two spectra, if more than six matching peaks were found, the remaining unmatched peaks were aligned by shifting their m/z by the difference in precursor mass. The resulting output is a cosine score between 0 and 1 that describes the similarity between two spectra, where 1 represents a perfect match. MS/MS spectra from the same precursor were determined by a cosine similarity of >0.7 and a precursor match within 0.01 m/z. In cases where multiple spectra from the same precursor were observed, the spectrum with the higher intensity was used and the lower intensity spectrum was discarded. Using the cosine comparisons, a network containing 1590 nodes and 3396 edges was constructed and visualized in Cytoscape, where each node is a representative spectrum from a unique precursor, and each edge is a cosine comparison with a value of 0.4 or greater. Synthesis of Lipid Amino Acid Monomers DL-2-Amino-Octanoic Acid ±-2-bromo-octanoic acid (1 g, 4.5 mmol) was dissolved in 10 mL of 1:1 H2O/acetone. NaN3 (0.5 g, 7.7 mmol) was added. The solution was vigorously stirred overnight at RT (reaction mostly complete after 1 h) to yield ± –2-azido-octanoic acid. The 2-azido-octanoic acid was then hydrogenated in dry THF with 20% Pd/C under 1 atm of H2 with constant stirring at RT overnight. The mixture was filtered through Celite to remove Pd/C.32 A small aliquot was purified by RP-LC to yield 36 μg of pure DL-2-amino-octanoic acid (m/z 160.1333 [M + H]+, C8H17NOH+, 0.6 ppm). White waxy solid.1H- and 13C NMR spectra can be found in the Supporting Information. DL-2-Amino-Dodecanol ±-2-bromo-dodecanoic acid (1.25 g, 4.5 mmol) was dissolved in 10 mL of 1:1 H2O/acetone. NaN3 (0.5 g, 7.7 mmol) was added. The solution was vigorously stirred overnight at RT (reaction mostly complete after 1 h) to yield ±-2-azido-dodecanoic acid. The 2-azido-dodecanoic acid was then reduced in dry THF with LiAlH4 (0.35 g, 9.34 mmol) with constant stirring on an ice bath for 2 h.33 The reaction was quenched with 5% KHSO4 and extracted with ethyl acetate. A small aliquot was purified by RP-LC to yield 70 μg of DL-2-amino-dodecanol (m/z 202.2166 [M + H]+, C12H27NOH+, 0.2 ppm). Off-white waxy solid. 1H- and 13C NMR spectra can be found in the Supporting Information. Bioactivity Assays A total of 15 μg of purified aspercryptins A1 and A2 (~2:1) were tested in a standard disk diffusion assay against M. luteus, E. coli, P. aeruginosa, S. epidermidis, K. pneumoniae, B. subtilis, A. nidulans, and P. citrinum. Supplementary Material Supplemental Figures We would like to thank the National Institutes of Health R01 AT009143 (N.L.K.), T32 GM105538 (R.A.M.), T32 GM07133 and NRSA AI55397 (A.A.S.), and NIH 5PO1GM084077 (N.L.K.). We also thank Y. Zhang of IMSERC at Northwestern University for NMR assistance (supported by the NIH 1S10OD012016-01 and 1S10RR019071-01A1). Figure 1 Workflow to compare the metabolomes of wildtype Aspergillus nidulans and a strain where the HDAC RpdA is constitutively repressed (rpdAKD) leading to hyperacetylation in bulk chromatin. Knockdown of RpdA leads to many newly observed metabolites (second panel), from which new metabolites can be viewed selectively (third panel) and targeted for structure determination when they display unique mass signatures. Aspercryptins A1 and A2 are lipopeptides made by A. nidulans (fourth panel at far right). Full NMR data can be found in the Supporting Information. Stable isotope incorporation experiments verify much of these structures (Supporting Information Figure S2). Annotated MS/MS spectra for both aspercryptin A1 and A2 (Supporting Information Figures S3 and S4) are included for reference. Figure 2 MS/MS networking to identify and characterize a large cluster of aspercryptins. (a) MS/MS networking clusters natural products into molecular families. Here the metabolites made by wildtype A. nidulans (blue) are compared to those made by the rpdAKD mutant (red). Some metabolites are expressed equally (gray). Some molecular families are seen in only one biological state. The aspercryptins are boxed, and the emericellamides are circled. (b) Aspercryptin A1 and A2 (larger yellow circles) fall into an MS/MS cluster of metabolites mostly expressed by rpdAKD mutant. Comparing the MS/MS spectra of 5 NMR-elucidated aspercryptins allows for characterization of an additional 13 aspercryptins in this molecular family for a total of 18 structurally characterized aspercryptins, which includes aspercryptins B1 and B3 (yellow). Figure 3 Putative structures for 8 of the 13 aspercryptins based on analysis of MS spectral differences. A complete version of this chart with the 18 structurally characterized aspercryptins is shown in the Supporting Information. Heavily annotated MS/MS spectra of aspercryptins solved by NMR (blue asterisk) were used as the basis for comparison to other metabolites (Supporting Information Figures S3 and S4). Conservatively, stereochemical assignment has not been made for the MS-based structures. Figure 4 Evidence for the association of the aspercryptins to their BGC. (a) The BGC responsible for the biosynthesis of the aspercryptins contains a nonribosomal peptide synthetase encoded by atnA (AN7884), which contains six adenylation domains and a terminal reductase domain; the two fatty acid synthase subunits atnF (AN7880) and atnM (AN7873); a transcription factor atnN (AN7872); two aminotransferases atnH (AN7878) and atnJ (AN7876); a cytochrome P450 atnE (AN7881); an oxidoreductase atnD (AN11028); and three for transport atnC (AN11031) and atnG (AN7879) and resistance atnI (AN7877). (b) Deletion of the NRPS gene atnA in the background of rpdAKD showed it is necessary for biosynthesis of the aspercryptins (only aspercryptin A1 is shown here for clarity). (c) Overexpression of the transcription factor atnN (OE atnN) led to a doubling of aspercryptin A1 levels. Subsequent deletion of the FAS gene atnF (OE atnN, ΔatnF) abolished levels of aspercryptins, which could be rescued by supplementing media with the fatty acids octanoic and dodecanoic acids (OE atnN, ΔatnF + FAs). Table 1 Formulae and Expression Ratios for the 18 Aspercryptins from Figure 2, Including the Five Aspercryptins Elucidated by NMR (bold) and the 13 Additional Aspercryptins Whose Putative Structures Are Supported by Comparing MS/MS Spectra name m/z [M + H]+ molecular formula [rpdAKD]/[wildtype] name m/z [M + H]+ molecular formula [rpdAKD]/[wildtype] aspercryptin A1 a 758.539 C37H71N7O9 20 aspercryptin B1 b 934.586 C47H79N7O12 60 aspercryptin A2 a 742.544 C37H71N7O8 90c aspercryptin B2 918.591 C47H79N7O11 130 epi-aspercryptin A2 a 742.544 C37H71N7O8 90c aspercryptin B3 b 920.571 C46H77N7O12 50 aspercryptin A3 744.523 C36H69N7O9 2 aspercryptin B4 906.555 C45H75N7O12 120 aspercryptin A4 730.508 C35H67N7O9 2 aspercryptin C1 800.549 C39H73N7O10 20 aspercryptin A5 728.528 C36H69N7O8 20 aspercryptin C2 784.554 C39H73N7O9 60 aspercryptin A6 714.513 C35H67N7O8 20 aspercryptin C3 786.534 C38H71N7O10 3 aspercryptin A7 671.507 C34H66N6O7 20 aspercryptin C4 772.518 C37H69N7O10 2 aspercryptin D1 814.566 C40H75N7O10 5 aspercryptin C6 756.523 C37H69N7O9 20 a NMR structures described in this work. b NMR structures described by Chiang et al.12 c Ratio is an unresolved combination of epimers. Author Contributions M.T.H. grew strains, analyzed extracts by LC-MS, determined the structures of aspercryptins A1 and A2 by NMR and the other 13 aspercryptins by MS/MS, and prepared the manuscript. A.A.S. generated all mutants used in this study. A.W.G. performed MS/MS networking. R.A.M. performed reduction reactions and Marfey’s derivatization. N.P.K. annotated the distribution of the atn gene cluster. A.A.S., N.L.K., and N.P.K. heavily revised several versions of the manuscript. Notes The authors declare no competing financial interest. ASSOCIATED CONTENT Supporting Information The Supporting Information is available free of charge on the ACS Publications website at DOI: 10.1021/acschem-bio.6b00398. Figures largely of structural validation of the aspercryptins, including MS/MS spectra and Tables (PDF) 1 Baltz RH 2006 Marcel Faber Roundtable: is our antibiotic pipeline unproductive because of starvation, constipation or lack of inspiration? 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PMC005xxxxxx/PMC5119466.txt
LICENSE: This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. 101084138 22395 Infect Genet Evol Infect. Genet. Evol. Infection, genetics and evolution : journal of molecular epidemiology and evolutionary genetics in infectious diseases 1567-1348 1567-7257 27180895 5119466 10.1016/j.meegid.2016.05.014 NIHMS829531 Article Distinguishing the genotype 1 genes and proteins of human Wa-like rotaviruses vs. porcine rotaviruses Silva Fernanda D.F. a Gregori F. a McDonald Sarah M. bc* a Department of Preventive Veterinary Medicine and Animal Health, College of Veterinary Medicine, University of São Paulo, Brazil b Virginia Tech Carilion School of Medicine and Research Institute, Roanoke, VA, USA c Department of Biomedical Sciences and Pathobiology, Virginia-Maryland College of Veterinary Medicine, Blacksburg, VA, USA * Corresponding author at: 2 Riverside Circle, Roanoke, VA 24016, USA. mcdonaldsa@vtc.vt.edu (S.M. McDonald) 15 11 2016 12 5 2016 9 2016 22 11 2016 43 614 This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. Group A rotaviruses (RVAs) are 11-segmented, double-stranded RNA viruses and important causes of gastroenteritis in the young of many animal species. Previous studies have suggested that human Wa-like RVAs share a close evolutionary relationship with porcine RVAs. Specifically, the VP1-VP3 and NSP2-5/6 genes of these viruses are usually classified as genotype 1 with >81% nucleotide sequence identity. Yet, it remains unknown whether the genotype 1 genes and proteins of human Wa-like strains are distinguishable from those of porcine strains. To investigate this, we performed comprehensive bioinformatic analyses using all known genotype 1 gene sequences. The RVAs analyzed represent wildtype strains isolated from humans or pigs at various geographical locations during the years of 2004–2013, including 11 newly-sequenced porcine RVAs from Brazil. We also analyzed archival strains that were isolated during the years of 1977–1992 as well as atypical strains involved in inter-species transmission between humans and pigs. We found that, in general, the genotype 1 genes of typical modern human Wa-like RVAs clustered together in phylogenetic trees and were separate from those of typical modern porcine RVAs. The only exception was for the NSP5/6 gene, which showed no host-specific phylogenetic clustering. Using amino acid sequence alignments, we identified 34 positions that differentiated the VP1-VP3, NSP2, and NSP3 genotype 1 proteins of typical modern human Wa-like RVAs versus typical modern porcine RVAs and documented how these positions vary in the archival/unusual isolates. No host-specific amino acid positions were identified for NSP4, NSP5, or NSP6. Altogether, the results of this study support the notion that human Wa-like RVAs and porcine RVAs are evolutionarily related, but indicate that some of their genotype 1 genes and proteins have diverged over time possibly as a reflection of sequestered replication and protein co-adaptation in their respective hosts. Group A rotavirus Genomics Porcine Human Genotype 1 Sub-genotypic diversity Amino acid changes Host tropism 1. Introduction Group A rotaviruses (RVAs) are gastrointestinal pathogens of many animal species. In humans, RVAs are a leading cause of childhood diarrheal death, particularly in developing regions of the world (Tate et al., 2012). RVAs are also a major cause of acute viral diarrhea in suckling and weaned piglets, imparting significant financial losses to the pork industry (Chang et al., 2012). The RVA genome consists of 11 segments of double-stranded RNA, which are encapsidated within a non-enveloped, triple-layered virion particle (Estes and Kapikian, 2007). The outermost layer of the RVA virion is made up of VP4 and VP7, while the middle layer is comprised of VP6. The innermost core shell is formed of VP2, and it surrounds the viral genome and RNA processing enzymes (VP1 and VP3). Five or six viral non-structural proteins (NSP1-NSP5/6) are made within infected cells and play various roles during viral replication. RVAs are classified according to a system that designates a specific genotype for each of the 11 viral genome segments (i.e., genes) based on their nucleotide sequences and established percent identity cut-off values (Matthijnssens et al., 2008). In this system, the genotype constellation of the VP7-VP4-VP6-VP1-VP2-VP3-NSP1-NSP2-NSP3-NSP4-NSP5/6 genes is described as Gx-Px-Ix-Rx-Cx-Mx-Ax-Nx-Tx-Ex-Hx, where x is a number. The vast majority of human RVAs sequenced to date (n > 300) exhibit the genotype constellation of G1/2/3/4/9/12-P[8]-I1-R1-C1-M1-A1-N1-T1-E1-H1 (Matthijnssens and Van Ranst, 2012). Human RVAs with this genotype constellation are referred to as “Wa-like” because they are genetically similar to the archival reference strain Wa (Wyatt et al., 1980). While fewer porcine RVAs have been sequenced to date (n = 33), the available data suggests that these strains typically exhibit the genotype constellation G3/5/9/11-P[6]/[7]/[13]/[19]/[23]-I5-R1-C1-M1-A8-N1-T1/7-E1-H1 (Kim et al., 2012; Martel-Paradis et al., 2013; Matthijnssens et al., 2008; Monini et al., 2014; Nagai et al., 2015; Okitsu et al., 2013; Silva et al., 2015; Theuns et al., 2015). Thus, it seems that while human Wa-like RVAs and porcine RVAs differ in their VP7, VP4, VP6, and NSP1 gene genotypes, they tend to have similar genotype 1 VP1-VP3 and NSP2-NSP5/6 genes. This observation suggested that human Wa-like RVAs and porcine RVAs share an evolutionary relationship and perhaps a common ancestor (Matthijnssens et al., 2008). In the current study, we sought to more fully characterize the genotype 1 genes and proteins of human Wa-like RVAs and porcine RVAs and to determine whether specific genetic signatures differentiate those from each host. We constructed neighbor-joining phylogenetic trees to reveal the relationships between the genotype 1 genes of typical and atypical human Wa-like and porcine RVAs. We also employed amino acid sequence alignments to identify positions that varied in the genotype 1 viral proteins in a host-specific manner. Furthermore, we documented how several archival/unusual isolates differ at these host-specific variable positions. Altogether, these results enhance our understanding of RVA genetic diversity and elucidate putative evolutionary signatures of genotype 1 viral proteins from human versus porcine strains. 2. Materials and methods 2.1. Nucleotide sequencing of 11 Brazilian porcine RVAs Near-complete genome nucleotide sequences were determined for 11 porcine RVAs (ROTA02, ROTA03, ROTA04, ROTA05, ROTA13, ROTA16, ROTA18, ROTA25, ROTA27, ROTA30, and ROTA31) using the same approach described in Silva et al., 2015 (Silva et al., 2015). These porcine strains are considered to represent typical modern isolates as they were found in fecal specimens collected from diarrheic nursing and suckling piglets (<60 days of age) on various Brazilian farms during the years of 2012–2013. The 83 new full or partial gene sequences were genotyped using RotaC2.0 (Maes et al., 2009) and were deposited into GenBank (Table S1). Only the sequences for the genotype 1 VP1-VP3 and NSP2-NSP5/6 genes were analyzed in the current study. 2.2. Sub-genotypic neighbor-joining phylogenetic analyses During the initial stages of the analyses, we downloaded the nucleotide sequences of genotype 1 VP1-VP3 and NSP2-NSP5/6 genes of all known human Wa-like RVAs and porcine RVAs. Alignments were created for each gene using Geneious Pro v5.6.5 (Biomatters) and the ClustalW algorithm and were trimmed so that the sequences were the same length in each alignment. The following nucleotide regions were analyzed for each gene: VP1 (nts 162-1572), VP2 (nts 28-1431), VP3 (nts 52-1034), NSP2 (nts 76-907), NSP3 (nts 59-977), NSP4 (nts 48-577), and NSP5/6 (nts 43-535). Neighbor-joining phylogenetic trees were created for each gene using Geneious Pro v5.6.5 (Biomatters). The trees were out-group rooted to the genotype 2 genes of strain DS-1 and built using three different distance models (Jukes-Cantor, Tamura-Nei, and HKY) and 100 bootstrap replicates. The overall tree topologies and major groupings were identical irrespective of the distance model chosen. Based upon the clustering of sequences in the initial trees, we then selected 102 representative RVAs to include in the final trees, which were built using the Jukes-Cantor distance model (Table S2 and Figs. S1–S7). For selection of the final strains, we also considered the year, G/P-genotype, and geographical location of the strain. To prepare Fig. 1, major groupings were collapsed using FigTree v1.4 and colorized using Adobe Illustrator CS5 (Adobe Systems). 2.3. Identification of host-specific amino acid changes in genotype 1 proteins The deduced amino acid sequences of genotype 1 proteins from the 102 representative strains (Table S2) were aligned using Geneious Pro v5.6.5 and the BLOSUM-62 matrix of ClustalW. Amino acids that varied according to host species or viral isolate were identified by visual inspection of the alignments and confirmed by NCBI BLAST analysis. For VP2, which varies in length, the documented position numbers are based on those of strain RVA/Human-wt/PRY/1638SR/2008/G1P[8]. The three dimensional locations of the host-specific variable positions were determined using UCSF Chimera v1.8 and the predicted or known atomic structures of viral proteins: strain UK and SA11 VP1 and VP2 (PDB# 4F5X), strain RRV VP3 (PDB# 2IHP), strain SA11 NSP2 (PDB# 1L9V), and SA11 NSP3 (PDB# 1KNZ and PDB# 1LJ2) (Deo et al., 2002; Estrozi et al., 2013; Pettersen et al., 2004; Groft and Burley, 2002; Jayaram et al., 2002; Ogden et al., 2014). 3. Results 3.1. Genetic relationships between the genotype 1 genes of human Wa-like RVAs and porcine RVAs To investigate the genetic relationships between human Wa-like RVA and porcine RV genotype 1 genes, we constructed individual phylogenetic trees for VP1-VP3 and NSP2-NSP5/6. Initial trees were constructed using all human Wa-like RVA and porcine RVA genotype 1 nucleotide sequences available in GenBank (data not shown). In this study, we also deduced the full or partial gene sequences for 11 porcine RVAs isolated from diarrheic piglets in Brazil during the years 2012–2013. The final trees included the genotype 1 genes of these 11 new Brazilian porcine RVA sequences as well as those of 91 additional human or porcine RVAs that altogether reflected the genetic diversity seen in the initial trees (Fig. 1). The genotype constellations of the 102 representative strains are shown in Fig. 2. The human Wa-like RVAs chosen as representatives of typical modern strains (Fig. 2A) included those that were isolated during the years of 2004–2011 from diarrheic children at various geographical locations: Thailand (strains CU938-BK, CU747-KK, and CU460-KK), Africa (strains MRC-DPRU1424, MRC-DPRU1723, and MRC-DPRU1262), Belgium (strains BE00030, BE00043, BE00055, B4633, and B3458), the United States (strains 2008747100, 2008747288, 2007719720, VU08-09-20, VU06-07-21, VU06-07-32, VU05-06-2, and VU05-06-47), Australia (strains CK00100, CK00088, CK00034, and CK00005), China (strains R588 and Y128), Italy (strains JES11 and AV21), Germany (strains GER126-08 and GER172-08), India (strains 61060 and 6361), and Paraguay (strains 954SR and 1638SR) (Arora and Chitambar, 2011; Ianiro et al., 2013; Matthijnssens et al., 2008; McDonald et al., 2012; Nyaga et al., 2013; Pietsch and Liebert, 2009; Rahman et al., 2007; Shintani et al., 2012; Theamboonlers et al., 2014; Zeller et al., 2015). We also included in our phylogenetic analyses the genotype 1 gene sequences of archival/unusual human strains (Fig. 2B) that were either isolated prior to 1992 (strains RV3, 116E, YO, IAL28, DC1476, DC1600, and DC4608) or that were likely the result of pig-to-human interspecies transmission events (strains BE2001, Arg4605, Mc323, BP271, BP1227, BP1547, 1809SR, Dhaka6, Matlab36, Ryukyu-1120, and EC2184) (Banyai et al., 2009; Degiuseppe et al., 2013; Ghosh et al., 2012; Heiman et al., 2008; Komoto et al., 2013; Martinez et al., 2014; Matthijnssens et al., 2008; Matthijnssens et al., 2010; McDonald et al., 2011; McDonald et al., 2009; Papp et al., 2013; Rippinger et al., 2010; Zeller et al., 2012; Zhang et al., 2014). For the porcine RVAs, we included in the final trees typical modern strains for which complete or near-complete genome sequence information is available (Fig. 2C). These strains were considered to be wildtype porcine RVAs because they had G/P-genotypes normally associated with porcine RVAs and they were found in the feces of diarrheic or non-diarrheic piglets during the years of 2006–2014. The porcine RVAs were also from various geographical locations: Brazil (strains ROTA01-10, ROTA24-25, ROTA27, and ROTA30-31), Belgium (strains 12R022, 12R002, 12R006, 12R005, 12R041, and 12R046), Italy (strains 3BS, 2CR, and 7RE), Thailand (strains CMP45, CMP29, CMP40, and CMP48), Korea (strains PRG921, PRG9121, PRG9235, and PRG942), Canada (strains F8-4 and F7-4), and Japan (strains BU8 and BU2) (Kim et al., 2012; Martel-Paradis et al., 2013; Monini et al., 2014; Nagai et al., 2015; Okitsu et al., 2013; Silva et al., 2015; Theuns et al., 2015). We also included the gene sequences of several atypical strains (Fig. 2D) that were either archival and isolated prior to 1983 (strains RV277, OSU, YM, and Gottfried) or that were predicted to represent human-porcine RVA reassortants (strains RU172, A131, and NMTL) (Ghosh et al., 2010; Matthijnssens et al., 2008; Shi et al., 2012; Theuns et al., 2015). For VP1, we found that the genotype 1 genes of typical modern human Wa-like RVAs clustered together in the phylogenetic tree (Fig. 1A and Fig. 2A; green) and were generally separate from those of both porcine RVAs and unusual/archival strains. The genotype 1 genes of typical modern porcine RVAs, on the other hand, were found in several different phylogenetic clusters interspersed with those of archival/unusual strains (Fig. 1A and Fig. 2B–D; dark blue). Consistent with previous reports, the genotype VP1 genes of archival human strains YO, DC1476, and DC4608 clustered with those of porcine RVAs rather than with typical human strains, suggesting that they might have been acquired via gene reassortment (Fig. 1A and Fig. 2B; dark blue) (McDonald et al., 2011; Zhang et al., 2014). Moreover, as reported previously, the genotype 1 VP1 genes of several unusual human isolates (i.e., BE2001, Arg4605, Mc323, BP271, BP1227, BP1547, 1809SR, Ryukyu-1120, and EC2184) clustered with those of typical porcine RVAs, indicative of these viruses taking part in inter-species transmission events (Fig. 1A and Fig. 2B; dark blue) (Degiuseppe et al., 2013; Ghosh et al., 2012; Komoto et al., 2013; Martinez et al., 2014; Papp et al., 2013; Zeller et al., 2012). For VP2 and VP3, two major lineages were seen in each respective phylogenetic tree, which were comprised mostly of the genotype 1 genes of: (i) typical modern human Wa-like RVAs (Fig. 1B–C and Fig. 2A; green) or (ii) typical modern porcine RVAs (Fig. 1B–C and Fig. 2C; dark blue). The VP2 tree also showed several additional branches, which represented the genotype 1 genes of one modern Belgium porcine RVA (strain 12R046) and several archival/unusual RVAs found in pigs or humans (strains RV277, IAL28, BP271, BP1227, and 116E) (Fig. 1B andFig. 2B–D; cyan). Likewise, for VP3, additional branches and clusters were identified and found to be comprised of genotype 1 genes of modern porcine RVAs from Thailand (strains CMP29, CMP40, and CMP48) or Korea (strains PRG921, PRG9121, PRG9235, and PRG942), as well as genes of archival/unusual porcine or human isolates (strains RU172, NMTL, Mc323, BP271, BP1227, BP1547, Dhaka6, Matlab38, and 116E) (Fig. 1C and Fig. 2B–D; cyan). Consistent with previous reports, the VP2 and/or VP3 genotype 1 genes of several archival/unusual human RVAs (e.g., DC1476, BE2001, 1809SR, and Ryukyu-1120) clustered with those of typical porcine RVAs (Fig. 1B–C and Fig. 2B–D; dark blue), reflecting either gene reassortment events or pig-to-human transmission of the strains (Komoto et al., 2013; Martinez et al., 2014; McDonald et al., 2011; Zeller et al., 2012; Zhang et al., 2014). For NSP2, the phylogenetic tree showed the same two major lineages that were identified in the VP2 and VP3 trees, which were comprised of genotype 1 genes of: (i) typical modern human Wa-like RVAs (Fig. 1D and Fig. 2A; green) and (ii) typical modern porcine RVAs (Fig. 1D and Fig. 2C; dark blue). However, for NSP2, a third larger lineage was also identified, and it was made up of genotype 1 genes of both typical and atypical human and porcine strains (Fig. 1D and Fig. 2; cyan). Specifically, the NSP2 genes of 19 of 44 modern porcine RVAs, 5 archival/unusual porcine RVAs (strains RV277, OSU, YM, Gottfried, and A131), and 6 pig-to-human transmitted RVAs (strains BE2001 Arg4605, Mc323, BP1547, 1809SR, and EC2184) clustered in this unique grouping (Fig. 2B and 2D; cyan). Fewer modern human Wa-like RVA NSP2 genes were found in this grouping; yet, those that were are considered to be typical wildtype isolates from South Africa (strain MRC-DPRU1262), Belgium (strains BE00043, BE00055, and B3458), United States (strains 2007719720 and VU05-06-47), and Paraguay (strains 954SR and 1638SR) (Fig. 2A; cyan). The NSP3 genes of human Wa-like RVAs are almost exclusively designated as genotype 1; however, the NSP3 genes of porcine RVAs can either be genotype 1 or genotype 7 (i.e., T1 or T7, respectively). We found that 23 of the typical modern porcine RVAs and 19 of the archival/unusual porcine or human RVAs have genotype 1 NSP3 genes (Fig. 2B–D). The phylogenetic tree showed that the genotype 1 NSP3 genes of modern human Wa-like strains clustered together (Fig. 1E and Fig. 2A; green) and distinctly from those of porcine strains, which formed two separate sub-clusters (Fig. 1E and Fig. 2C; dark blue). The genotype 1 NSP3 genes of several archival/unusual human strains (i.e., IAL28, DC1600, DC4608, Mc323, BP1227, Ryukyu-1120, 116E, and EC2184) were found to be porcine RVA-like (Fig. 2B; dark blue), consistent with the reports of these strains being reassortants or the result of inter-species transmission events (Banyai et al., 2009; Ghosh et al., 2012; Komoto et al., 2013; McDonald et al., 2011; Papp et al., 2013; Rippinger et al., 2010). For NSP4, the genotype 1 genes of typical modern human Wa-like RVAs clustered together in the phylogenetic tree (Fig. 1F and Fig. 2A; green) and were largely separate from those of porcine RVAs and those of archival/unusual strains. The genotype 1 NSP4 genes of typical modern porcine RVAs, on the other hand, were found in several different phylogenetic clusters interspersed with those of archival/unusual strains (Fig. 1F and Fig. 2C; dark blue). A small grouping of genes from 8 Brazilian porcine RVAs formed a sub-cluster distinct from the genes of typical human RVAs and other porcine RVAs (Fig. 1F and Fig. 2C–D; cyan). Related to this sub-cluster were the NSP4 genes of the unusual porcine RVA from China (strain NMTL) and a single modern human Wa-like RVA from Thailand (strain CU460-KK) (Shi et al., 2012; Theamboonlers et al., 2014). For NSP5/6, we did not find any specific clustering pattern that corresponded with host or virus type (Fig. 1G and Fig. 2; cyan). Despite a few clusters in the tree, the genotype 1 genes of modern human Wa-like RVAs and porcine RVAs could not be delineated. Likewise, the genotype 1 NSP5/6/genes of modern strains were not separate from those of archival/unusual strains. 3.2. Amino acid residues distinguishing typical modern human Wa-like vs. typical modern porcine RVAs Having found that the genotype 1 VP1-VP3 and NSP2-NSP4 genes of typical modern human Wa-like RVAs generally clustered together in phylogenetic trees and were distinct from those of typical modern porcine RVAs, we next wondered whether their encoded proteins exhibited specific amino acid changes. To investigate this, we created amino acid sequence alignments and identified positions that were conserved among all typical modern human Wa-like RVAs but that varied compared to typical modern porcine RVAs and vice versa. Altogether, we found 34 host-specific variant positions for VP1-VP3, NSP2, and NSP3; no such positions were identified for NSP4, a nonstructural protein involved in virion morphogenesis and virulence. For VP1, the viral RNA-dependent RNA polymerase, we identified 2 positions (284 and 1049) that varied in a host-specific manner (Fig. 3A). Residue 284 is a buried residue located in the N-terminal domain of the polymerase, whereas residue 1049 is a surface-exposed residue in the C-terminal bracelet domain (Lu et al., 2008) (Fig. 3A and data not shown). Neither of these residues are within the catalytic motifs of VP1. For VP2, the inner core shell protein, we identified 6 positions (27, 75, 140, 258, 417, and 891) that varied in a host-specific manner (Fig. 3B). We also found that the VP2 proteins of typical modern human Wa-like strains, but not porcine strains, have an asparagine-lysine (N-K)-rich insertion at positions ~40–50 in the alignment. This insertion differs in length among human Wa-like strains and is not seen in human DS-1-like or AU-like strains with genotype 2 or 3 VP2 proteins, respectively (McDonald and Patton, 2008). Residues 140, 258, and 891 of VP2 reside in the central carapace subdomain of the core shell, whereas reside 417 is in the apical subdomain near the fivefold axis and near predicted VP1 contact sites (Fig. 3B and data not shown) (Estrozi et al., 2013). The extreme N-terminal domain of VP2 (residues ~1–100) is not resolved in any published rotavirus structure. However, this region of the core shell protein is predicted to reside within the particle interior, suggesting that host-specific variable positions 27, 40–50, and 75 may be proximal to the location of RNA, VP1, and VP3 (McClain et al., 2010). VP2 residues 258 and 891 are on the outer surface of the core shell at the VP6 interface (data not shown). For VP3, an RNA capping enzyme that has innate immune antagonist activities via a C-terminal 3′5′-phosphodiesterase domain (PDE), we identified 10 positions that varied (109, 167, 234, 275, 276, 419, 470, 517, 639, and 646) between typical modern human Wa-like RVAs and typical modern porcine RVAs (Fig. 3C) (Morelli et al., 2015). According a VP3 homology model, residues 109 and 167 are located in the N-terminal adapter domain, residues 234, 470, and 517 are in the guanine-N7-methyltransferase (N7-MTase) domain, residues 275, 276 and 419 are in the ribose 2′ O-methyltransferase (2′ O-MTase) domain, and residues 639 and 646 are located in the guanylyltransferase/RNA 5′ triphosphatase (GTase/RTPase) domain (Ogden et al., 2014) (Fig. 3C and data not shown). All of these residues are distant from the predicted catalytic motifs of VP3, with the exception of residue 470, which is located immediately adjacent to the major S-adenosyl-l-homocysteine (SAH)-binding surface in the N7-MTase domain (Ogden et al., 2014). These residues are predicted to be fully or partially surface-exposed in the context of the homology model (data not shown). No host-specific variable positions were identified in the C-terminal PDE domain of VP3. For NSP2, which is an octameric nonstructural protein that plays roles during viral genome replication and early particle assembly, we identified 9 positions (48, 97, 98, 191, 245, 256, 282, 286, and 314) that varied between typical modern human Wa-like RVAs and typical modern porcine RVAs (Fig. 3D). Based on the structure of simian rotavirus strain SA11 NSP2, residues 48, 97, and 98 are located in the N-terminal domain, residues 191, 245, 256, 282, and 286 are located in the C-terminal domain, and residue 314 is located in the extreme C-terminal alpha-helix (Jayaram et al., 2002) (Fig. 3D and data not shown). These residues are predicted to be surface-exposed in the NSP2 octamer (data not shown). For NSP3, a nonstructural protein involved in protein synthesis, we identified 6 positions (155, 235, 252, 268, 278, and 300) that varied in a host-specific manner (Fig. 3E). Residue 155 is surface-exposed and located in the N-terminal RNA-binding domain of NSP3. Residues 235, 252, 268, 278, and 300 are located within the C-terminal eIF4G-binding domain (Groft and Burley, 2002). (Fig. 3E and data not shown). Residues 235, 252, 278, and 300 are buried and contribute to NSP3 dimerization, while residue 258 is surface-exposed (Fig. 3E and data not shown) (Deo et al., 2002). 3.3. Amino acid changes associated with unusual/archival RVAs When creating the amino acid sequence alignments, we noticed that many of the 34 host-specific variable positions differed in the sequence of archival/unusual isolates (Fig. 4). Because the changes in these atypical RVAs might be influenced by the genetic context of the entire virus, we sought to document and interpret them in the context of the viral genotype constellations. Based on this analysis, we divided the archival/ unusual isolates into 3 groups: Group 1 consisted of 5 RVAs that are quite similar to typical modern porcine RVAs (Fig. 4A–B). Only one member of this group was isolated from a pig (strain YM), whereas the other 4 members (strains BE2001, Mc323, Ryukyu-1120, and BP1547) were isolated from humans following inter-species transmission events (Ghosh et al., 2012; Komoto et al., 2013; Matthijnssens et al., 2008; Papp et al., 2013; Zeller et al., 2012). In general, few changes were detected at the host-specific amino acid positions for this group. Strain YM showed a single change at position 275 in VP3, while strain BE2001 showed changes at position 470 in VP3 and position 191 in NSP2. Strains Mc323, Ryukyu-1120, and BP1547 did not show any changes at the host-specific positions, suggesting that little if any adaptation occurred during their replication in the human host. Group 2 consisted of 6 putative reassortant RVAs (strains NMTL, OSU, A131, RU172, and Gottfried, RV277) that were isolated from pigs but that have one or more genes more similar to those of human Wa-like RVAs (Fig. 4A and 4C) (Ghosh et al., 2010; Matthijnssens et al., 2008; Shi et al., 2012; Theuns et al., 2015). Four of the viruses in this group showed changes at host-specific variable positions in VP3. Additionally, the VP2 gene of the archival Belgium strain RV277, which clustered distinctly in the phylogenetic tree from the those of typical modern porcine RVAs, was found to match the cognate human Wa-like RVA residues at positions 258 and 417. Similar changes were found for the VP2 proteins of human strains IAL28, 116E, BP1227, and BP271 (see below). Group 3 consisted of 14 putative reassortant RVAs (strains RV3, YO, IAL28, DC1476, DC1600, DC4608, Dhaka6, Matlab36, 116E, BP1227, BP271, Arg4605, 1809SR, and EC2184) that were isolated from humans but that have one or more porcine RVA-like genes (Fig. 4A and 4D) (Banyai et al., 2009; Degiuseppe et al., 2013; Heiman et al., 2008; Martinez et al., 2014; Matthijnssens et al., 2008; Papp et al., 2013; Rippinger et al., 2010). We found several changes at host-specific amino acid positions in VP2, VP3, and NSP2 for many members of this group. For example, archival human strains DC1476 and DC4608 have porcine RVA-like VP1 and VP2 genes/proteins. While the NSP2 proteins of these two isolates are most similar to those of typical modern human Wa-like RVAs (with cognate amino acids at 6 of the 9 host-specific sites), they differed at positions 48, 97, and 282, showing amino acid residues typical of porcine RVAs. It is interesting to speculate that perhaps the amino acid changes seen in these human-porcine reassortant RVAs reflects ongoing adaptive evolution of the virus as a result of the new (i.e., reassortant) gene constellation. 4. Discussion Previous comparative genomic studies have reported a likely evolutionary relationship between human Wa-like RVAs and porcine RVAs (Matthijnssens et al., 2008; Matthijnssens and Van Ranst, 2012; Theuns et al., 2015). However, until now, there had not been a systematic analysis of the genes and proteins from these seemingly related RVAs strains mainly because we lacked sufficient porcine RVA genome sequences. In fact, prior to 2015, <20 complete/near-complete genome sequences had been reported for wildtype porcine RVAs (i.e., those found in the feces of symptomatic piglets), whereas >300 wildtype human Wa-like RVA genome sequences existed. Recently, we described the near-complete genome sequencing and analysis of 12 Brazilian porcine RVAs isolated in 2012–2013 (Silva et al., 2015). Here, we report an additional 11 near-complete genome sequences of porcine RVAs from this same sample collection, thereby adding significantly to the number of wildtype porcine RVA sequences available in GenBank. Importantly, the genotype and sub-genotype constellations of our Brazilian strains mirror those of RVAs isolated from pigs in Belgium, Italy, Thailand, Korea, Canada, and Japan suggesting that they are representative of porcine RVA genetic diversity (Martel-Paradis et al., 2013; Kim et al., 2012; Monini et al., 2014; Nagai et al., 2015; Okitsu et al., 2013; Theuns et al., 2015). As such, in the current study, we were well-positioned to ask the following questions: Do the genes and proteins of human Wa-like RVAs differ from those of porcine RVAs? If so, are there specific genetic signatures that distinguish human versus porcine strains? By comparing the genotype constellations of typical modern human Wa-like RVAs to those of typical modern porcine RVAs (Fig. 2), we confirmed previous reports that the most divergent genes are those encoding outer capsid proteins VP7 and VP4, the intermediate capsid protein VP6, and the nonstructural innate immune antagonist protein NSP1 (Kim et al., 2012; Martel-Paradis et al., 2013; Monini et al., 2014; Nagai et al., 2015; Okitsu et al., 2013; Silva et al., 2015; Theuns et al., 2015). Indeed, human Wa-like RVAs and porcine RVAs usually exhibit different genotypes for these four genes, which by definition share <85% nucleotide sequence identity (Matthijnssens et al., 2008). Consistent with previous reports, we also observed that the NSP3 gene can sometimes, but not always, differ in genotype between human Wa-like RVAs and porcine RVAs (Kim et al., 2012; Martel-Paradis et al., 2013; Monini et al., 2014; Nagai et al., 2015; Okitsu et al., 2013; Silva et al., 2015; Theuns et al., 2015). Thus, it is likely that the VP7, VP4, VP6, NSP1, and NSP3 genes/proteins dictate whether an RVA productively infects a human versus a pig. However, we hypothesized that host-specific changes might be found in the six other viral genes, which share the genotype 1 designation (i.e., VP1-VP3 and NSP2-5/6) and >81% nucleotide sequence identity. We posited that such host-specific changes could contribute to host tropism or could reflect evolutionary changes resulting from sequestered replication of the virus. In support of this notion, our phylogenetic analyses showed that the genotype 1 genes from typical modern human Wa-like strains generally clustered together and were separate from those of typical modern porcine RVAs (Figs. 1 and 2). We did not observe any host-specific clustering for the NSP5/6 gene, suggesting that either this gene is genetically identical in human and porcine strains, or that our current data is insufficient to resolve host-specific differences. To investigate whether the proteins encoded by the genotype 1 genes differed depending upon the host species (i.e., human vs. pig), we performed amino acid sequence alignments (Fig. 3). For this analysis, it was critical that we stratify typical modern strains away from archival/ unusual isolates because we noticed that the latter showed amino acid variations at positions in the alignment that were otherwise invariable within a host (Fig. 4). Altogether, we identified a total of 34 amino acid positions that are conserved among the typical modern human Wa-like RVAs, but that differed for typical modern porcine RVAs or vice versa. Of these 34 host-specific variable positions, 29 of them are located at surface-exposed regions of viral replication proteins VP1, VP2, VP3, NSP2, or NSP3. Given the three-dimensional locations of these host-specific residues, we hypothesize that protein co-adaptation may have been a selection pressure that influenced their emergence. Protein co-adaptation occurs when a fitness-diminishing mutation in one viral protein is compensated for by a fitness-restoring change in a second viral protein. As a consequence of protein co-adaptation, gene segments become genetically-linked and stable constellations are observed (Heiman et al. 2008; Iturriza-Gòmara et al., 2003; Miño et al., 2016; Zhang et al., 2015). This hypothesis may explain why several of the putative reassortant viruses (i.e., archival/unusual isolates) show variations at the identified host-specific positions; the viral proteins may be trying to re-adapt to a new genetic context. Indeed, strains with gene segments derived from animal rotaviruses do not appear to be major causes of infections in humans, suggesting that their overall gene/protein constellations confer decreased fitness (compared to wildtype human Wa-like strains) in the absence of compensatory changes. However, several of the archival/unusual isolates, including reassortants were grown in cell culture for many passages before sequencing, which could account for the observed changes. Moreover, the role of co-adaptive RNA-RNA or RNA-protein interactions cannot be excluded as additional possible selection pressure leading to the emergence of host-specific changes or variations following reassortment. For instance, although we observed some host-specific segregation of genotype 1 NSP4 genes, we did not find any amino acid positions that differentiated these proteins in a host-specific manner, suggesting a role for the viral RNA molecule itself. Of course, it is also possible that the host-specific amino acid (or nucleotide) residues emerged as a result of evolutionary pressure(s) from cellular factors, which would differ between humans and pigs. A fuller understanding of RVA evolution will require additional genome sequences of isolates found in humans, pigs, and other animal hosts. Nevertheless, the results of the current study provide a baseline to compare future sequences to as we continue to resolve RVA genetic diversity and identify determinants of host tropism. Supplementary Material Table S1 Table S2 We are grateful to members of the McDonald laboratory for scientific and editorial suggestions. FDFS was supported by funding from the Brazilian government/Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (Project 1079750). SMM was supported by grants from the NIH/NIAID (R01-AI116815-01, R21-AI113402-01, R21-AI119588-01). FG was supported by Foundation of Support to Research of the São Paulo State (Project 2011/00870-0). Fig. 1 Genetic relationships among the genotype 1 genes of human Wa-like RVAs and porcine RVAs. The neighbor-joining phylogenetic trees are outgroup rooted to strain DS-1, and horizontal branch lengths are drawn to scale (nucleotide substitutions per base). Bootstrap values are shown as percentages for key nodes. Monophyletic groupings were collapsed and are shown as cartooned triangles. Groupings comprised mostly of typical modern human RVA genotype 1 genes are shown in green and those of typical modern porcine RVA genes are shown in dark blue. Other groupings that contained genotype 1 genes of archival/unusual isolates or that contained genotype 1 genes from both human and porcine RVAs are shown in cyan. Fig. 2 Genotype constellations of representative human Wa-like RVAs and porcine RVAs. Strain names are listed to the left of the corresponding genotype constellation for the strains analyzed in this study. Each gene is shown as a box and is color-coded according to genotype or according to the results of Fig. 1. Specifically, genes characteristic of human Wa-like RVAs are shown in green, and those characteristic of porcine RVAs are shown in dark blue. Genes that formed distinct clusters or those that could not be resolved in Fig. 1 are shown in cyan. Black boxes represent genes for which no sequence information is available, and grey boxes represent genes with genotypes not generally found in human Wa-like or porcine strains. (A) Typical modern human Wa-like RVAs. These strains are considered to be wildtype, as they were isolated from human clinical fecal specimens during the years of 2004–2011 and have G/P-genotypes normally associated with human RVAs. (B) Archival/unusual human Wa-like RVAs. These human strains are considered atypical as they were isolated >20 years ago, are putative reassortants, and/or were involved in inter-species transmission events. (C) Typical modern porcine RVAs. These strains are considered to be wildtype, as they were isolated from porcine clinical fecal specimens during the years of 2006–2014 and have G/P-genotypes normally associated with porcine RVAs. (D) Archival/unusual porcine RVAs. These porcine strains are considered atypical as they were isolated from porcine fecal specimens >30 years ago or are putative reassortants. Fig. 3 Host-specific variable positions in genotype 1 viral proteins. The rectangles represent linear schematics of genotype 1 viral proteins (not drawn to scale) and are color-coded based on the results of Fig. 1. Typical modern human RVA genotype 1 proteins shown in green, and typical modern porcine RVA genotype 1 proteins shown in dark blue. Genotype 1 proteins of archival/unusual isolates or those from additional phylogenetic groupings containing both human and porcine RVAs are shown in cyan. Known or predicted domains/subdomains of each protein are bracketed and labeled. Positions in the amino acid sequence alignments that varied in a host-specific manner are labeled and the corresponding residues are listed below each protein schematic. Fig. 4 Amino acid differences in archival/unusual RVA strains at host-specific variable positions. Genotype constellations of RVAs are shown as in Fig. 2. For proteins VP1-VP3, NSP2, and NSP3, the host-specific variable positions identified in Fig. 3 are listed to the right of the corresponding protein. Green circles represent amino acid residues identical to those of typical modern human Wa-like RVAs. Dark blue circles represent amino acid residues identical to those of typical modern porcine RVAs. Orange circle represent amino acid residues that are unique, differing from those of human/porcine RVAs. Grey circles are shown for non-genotype 1 proteins (i.e. T7). Filled circles indicate that the residue found at that position is not what would be expected based on the evolutionary origin of the protein, indicating amino acid changes in archival/unusual isolates at host-specific amino acid positions. (A) Typical modern human Wa-like RVA and typical modern porcine RVA constellations/positions are shown as references. (B) Group 1 is comprised of porcine RVAs isolated from pigs or humans. (C) Group 2 is comprised of putative reassortant RVAs isolated from pigs but containing one or more human RVA-like genes. (D) Group 3 is comprised of putative reassortants isolated from humans but containing one or more porcine RVA-like genes. Supplementary data to this article can be found online at http://dx.doi.org/10.1016/j.meegid.2016.05.014. References Arora R Chitambar SD Full genomic analysis of Indian G1P[8] rotavirus strains Infect. Genet. Evol 2011 11 504 511 21256248 Banyai K Esona MD Kerin TK Hull JJ Mijatovic S Vasconez N Torres C de Filippis AM Foytich KR Gentsch JR Molecular characterization of a rare, human-porcine reassortant rotavirus strain, G11P[6], from Ecuador Arch. 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PMC005xxxxxx/PMC5119550.txt
LICENSE: This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. 100962779 22269 Nat Rev Genet Nat. Rev. Genet. Nature reviews. Genetics 1471-0056 1471-0064 22179717 5119550 10.1038/nrg3129 NIHMS819401 Article Experimental and analytical tools for studying the human microbiome Kuczynski Justin 1 Lauber Christian L. 2 Walters William A. 1 Parfrey Laura Wegener 3 Clemente José C. 3 Gevers Dirk 4 Knight Rob 35 1 Department of Molecular, Cellular and Developmental Biology, University of Colorado at Boulder, 347 UCB, Boulder, Colorado 80309, USA 2 Cooperative Institute for Research in Environmental Sciences, University of Colorado at Boulder, 216 UCB, Boulder, Colorado, 80309, USA 3 Department of Chemistry and Biochemistry, University of Colorado at Boulder, 215 UCB, Boulder, Colorado 80309, USA 4 Microbial Systems & Communities, Genome Sequencing and Analysis Program, The Broad Institute, 7 Cambridge Center, Cambridge, Massachusetts 02142, USA 5 Howard Hughes Medical Institute, 215 UCB, Boulder, Colorado 80309, USA Correspondence to R.K. Rob.Knight@colorado.edu 28 9 2016 16 12 2011 16 12 2011 22 11 2016 13 1 4758 This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. The human microbiome substantially affects many aspects of human physiology, including metabolism, drug interactions and numerous diseases. This realization, coupled with ever-improving nucleotide sequencing technology, has precipitated the collection of diverse data sets that profile the microbiome. In the past 2 years, studies have begun to include sufficient numbers of subjects to provide the power to associate these microbiome features with clinical states using advanced algorithms, increasing the use of microbiome studies both individually and collectively. Here we discuss tools and strategies for microbiome studies, from primer selection to bioinformatics analysis. Human-associated microbial communities are implicated in a variety of diseases. Altered microbiota (the microorganisms that are present in a community) have been linked to vaginosis1, obesity2 and inflammatory bowel disease (IBD)3,4, among other maladies5. Although the importance of the human microbiota and the human microbiome has been hypothesized for some time, recent advances in the technology used to identify and to analyse components of the microbiome have substantially improved our knowledge of the microbial communities that are associated with various habitats, including humans. The amount of variability in the microbiota and in the microbiomes both within a human subject and between different subjects is immense, and projects such as the Human Microbiome Project6,7 and MetaHIT8 have already done much to define this variability. Few microbial species are shared by most people at appreciable abundance levels9, at least among the well-sampled human skin, gut, oral and genital communities. Immense diversity is even observed between serial samples that have been taken from the same site in the same person9,10. Although human body sites and individuals do have distinct signatures, the differences in community composition across body sites are large, and within a body site, differences across individuals are, in general, much larger than differences between a single individual’s community across time11. The importance of the human microbiome is thus immense, and this emerging field is rife with opportunities for discovery. Approaches to microbiome research are increasingly diverse, so here we present an outline of the many investigations that identify microorganisms (community surveys) and genes (shotgun metagenomics, referred to hereafter simply as ‘metagenomics’) that are present in the human-associated microbial communities and relate these communities to the host phenotype. Investigations into the RNAs, proteins and metabolites that are present — processes that are referred to as metatranscriptomics, metaproteomics and metabolomics, respectively — can also provide valuable insights, especially when they are combined with community surveys and metagenomic data12,13,14. In this Review, we primarily focus on DNA-based approaches, as they have been the primary means of interrogating the microbiome in recent investigations. DNA-based microbiome studies DNA-based microbiome studies frequently fall into one of two categories. Targeted amplicon studies focus on one or a few marker genes and use these markers to reveal the composition and diversity of the microbiota. Other studies use an entire metagenomic approach. This is sometimes referred to as shotgun metagenomics owing to the randomness with which genomic sequences are obtained. FIGURE 1 provides an overview of both study types and how they may be combined. Metagenomics approaches have the advantage of providing much richer data on the functional potential present in microbial communities. However, compared to targeted amplicon studies, they sacrifice resolution into the composition (that is, the identity of the microorganisms present) of those communities. Both approaches are useful, and we consider them both in this Review. We begin by addressing how researchers can investigate various constituents of a microbial community, such as eukaryotes, viruses and various groups of bacteria. We then cover the processing of biological samples and DNA extraction, followed by DNA sequencing and the methodological options that are available. We continue by providing some discussion about the bioinformatics software used to analyse the sequencing data that emanate from both targeted amplicon and metagenomic sequencing studies, and we conclude with our outlook on the near future of this rapidly evolving field. The aim of this article is to provide a guide to the experimental designs and analytical tools used in microbiome studies and to discuss the important decisions that experimenters face when conducting investigations into the microbiome. Selecting microbial genetic targets Most microbial community studies include targeted amplicon sequencing of phylogenetically informative markers, such as the ribosomal small subunit (16S ribosomal DNA (rDNA)) gene. This allows researchers to compare the identities of the microorganisms that are present in the communities of interest. One advantage of rRNA genes is that ribosomes, and thus 16S rDNA, are present in all living organisms, whereas other commonly used markers have a limited taxonomic distribution. Furthermore, ribosomal genes contain both slowly evolving regions that can be used to design broad-spectrum PCR primers and fast-evolving regions that can be used to classify organisms at finer taxonomic levels (for example, at the family or genus levels), although species-level resolution might be unfeasible using this information alone. Another advantage that the 16S rDNA gene provides over other potential marker genes is the availability of several large databases of reference sequences and taxonomies, such as greengenes15, SILVA16 and the Ribosomal Database Project17. Although 16S rDNA is the most predominately used marker, the internal transcribed spacer region of the rRNA gene can be useful for some taxonomic groups, such as fungi, especially when resolution below the genus level is needed18. Choice of universal PCR primer There is a large choice of PCR primers (even for the widely used 16S rDNA), each of which has advantages and disadvantages. PCR primers should therefore be carefully chosen to take into account the taxonomic coverage desired, the extent of phylogenetic information generated by the fragment, the compatibility of the fragment length with the sequencing platform and the degree of specificity for amplifying microbial sequences compared to host sequences. For instance, the widely used 16S rDNA primer pair F27–R338 is highly specific for bacteria (as opposed to archaea and eukaryotes) but lacks sensitivity for taxa such as Bifidobacterium19, which is an important member of the gut microbiota. Furthermore, a complete bacterial phylum, Verrucomicrobia, is so poorly amplified by the F27–R338 primer set that this group was perceived to be a rare soil microorganism when it is, in fact, a dominant taxon that constitutes more than 20% of soil community members20. In addition to minimizing amplification bias, an optimal primer set should amplify a region that is informative both taxonomically and phylogenetically, depending on the desired analyses. One way of assessing the taxonomic usefulness of the various hypervariable regions of the 16S rDNA gene is to compare the taxonomic assignments of short fragments (for example, 100–250 bp) in these regions against those of the full 16S rDNA gene. This type of analysis demonstrated that the 16S rDNA hypervariable region V6 poorly replicates full-length taxonomic assignments compared with the V4 or V2 region21. An illustrative cartoon on the effects of primer choice is shown in FIG. 2. In addition to the taxonomic coverage of a primer set and the usefulness of its amplicon, primer selection should also take into consideration what is known about the constituents of a target community. For instance, the universal primer set F515–R806 amplifies a broad range of bacterial and archaeal phyla and would be a prudent choice for a diverse community, such as a soil sample for the purpose of mapping the entire bacterial and archaeal community. However, this primer set poorly amplifies Propionibacterium, a common skin microorganism, and another primer set such as F27–R338 could be a better choice for this particular sample type22. Amplifying eukaryotic and viral communities High-throughput analyses of eukaryotic communities and parasites in host-associated environments are currently limited23,24 and have generally been targeted to specific taxonomic groups, such as fungi25,26. Eukaryotes generally make up a small proportion of the biomass and so fully incorporating this class of organism into microbiome studies will require addressing the challenges that are presented by the low abundance of eukaryotes relative to bacteria, as well as addressing those challenges that are presented by the difficulty of avoiding amplification of host DNA. These are probably the reasons why many current studies have focused on specific taxa. One possible solution to avoid amplifying host DNA is to use universal primers together with blocking probes that are specific to the host sequence27. As more community-wide data are generated, it will be interesting to see whether the presence or absence of specific eukaryotic taxa is more or less informative than studying the overall community composition. Viruses also have a major role in shaping the human microbiome. A typical healthy human carries an abundance of viral particles (~1012 by some estimates)28, consisting mainly of bacteriophages but also of a substantial number of eukaryotic viruses29. Although an individual’s gut virome varies substantially over the first few weeks of life30, the virome of adults seems stable over time; this is remarkable in light of the strong variation between the viromes of different individuals31. This pattern may be similar to the rapid changes that are observed in the bacterial microbiota early in life32,33 followed by relative stability in adulthood9,11. The effects of these patterns in the human virome are mostly not understood, although certain bacteriophages in other animals are beneficial to the host34. The lack of a gene that is universally present in all viruses means that amplicon-based studies cannot be used to characterize the virome in its totality. Instead, clade-specific viral genes can be used to identify and resolve viral subtypes from DNA sequences28,35. In order to characterize the virome comprehensively, researchers can isolate virus-like particles before metagenomic sequencing31. Elucidating the important effects of the human virome is confounded by the fact that most human virome sequences remain ‘unknown’ when compared to public databases, such as the nr database from the US National Center for Biotechnology Information (NCBI)36. The challenges of annotating the functional roles of unknown organisms are therefore particularly acute in virome studies. Processing of biological samples and DNA Sample collection The rate-limiting step in obtaining samples of human-associated microorganisms is the approval of a human study protocol and the recruitment of subjects before the actual collection of the samples; the method of collection depends on the goals of the study and the willingness of the subjects to be sampled. Methods for collection are generally less controversial than other aspects of microbiome studies, but a few suggestions are presented in BOX 1 to make collecting samples (and, by extension, study design) more straightforward. Box 1 Recommendations for sample collection The level of invasiveness of the sampling procedure should always be minimized when designing a study of human-associated microbiota. For instance, skin-associated communities can be sampled by swabbing106,107, scraping and performing a punch biopsy108, each of which represents a different level of discomfort for the subject. Fortunately, each method produces a similar picture of the microbial community108; as sufficient amounts of bacterial DNA can be recovered for 16S rDNA analysis by the less invasive swab method, punch biopsies should only be considered in circumstances in which deeper layers of the dermis must be studied. This logic extends to sampling other body sites. Mouth- and gut-associated microorganisms can easily be collected on swabs, which pose little risk of physical discomfort to the subject. However, when the study is focused on the lining of the gastrointestinal tract, there is little choice but to collect samples by endoscopy, as faecal samples are not sufficiently similar to the intestinal mucosa109. When designing a study, we suggest erring on the side of collecting as many samples as possible, as the increased statistical power of larger samples sizes cannot be overlooked when the difficulties of gaining approval and recruiting subjects represent a substantial barrier. Longitudinal studies, in particular, can provide much needed insights into the temporal variability of the microbial communities that are associated with specific body sites by using more samples from few individuals9,11,110. DNA extraction There has been some debate about which method results in the best picture of the microbial community37. However, most extraction methods use the same basic steps (cellular lysis, removal of non-DNA macromolecules and collection of the DNA) to separate the DNA from the cellular components and the environmental matrix. In general, the lysis step receives the most scrutiny, as the intensity of the lysis can result in bias towards a particular taxonomic group38. To avoid this, many studies use a combination of chemical, physical and mechanical means to lyse cells efficiently, and we suggest that all three means should be used to lyse cells in complex microbial assemblages. Incubating samples with detergents and/or enzymes followed by bead beating is a commonly used lysis method1,39,40, but there are also modified protocols for commercially available extraction kits that use a strong base, a high temperature and bead beating9,39,41. Non-DNA macromolecules are then physically separated from the DNA, and the DNA is then concentrated into a volume that is suitable for downstream applications. However, we should add that no extraction protocol works equally well on all sample types nor produces completely unbiased results: for example, researchers studying soil microorganisms have debated the ‘best’ method of DNA extraction for decades. Minimizing contamination Regardless of the extraction protocol used, steps must be taken to minimize contamination from a ‘foreign’ source. This will involve using sensible precautions (such as operating in as sterile an environment as possible and using clean equipment) and using commercially available kits or laboratory reagents that have been thoroughly tested to be free of contaminating DNA. Likewise, care should be taken to minimize contamination during sample collection. People collecting samples should wear gloves to prevent their own microbiota from contaminating samples, and they should adhere to an overall strategy of collecting samples in order of increasing biomass (for example, skin, then mouth and then faecal) to prevent the contamination of the lower biomass samples with those that are known to contain many microorganisms. After they have been collected, samples can be stored at various temperatures for short periods without there being a noticeable impact on the bacterial community42,43. However, the long-term effects of various storage conditions on human-associated microorganisms are not well described, so it is best to extract samples as soon as possible after collection or to use consistent storage conditions within and across studies. As the field of human microbiome research is still young, we have the chance to be early adopters of emerging standards in sample preparation and to use largely homogenous methods to allow more convenient analysis of results across studies. DNA sequencing methodologies Following successful extraction of DNA from the communities of interest, there remains the important step of obtaining sequences from that DNA. Microbiome studies that use 16S rDNA-based taxonomic profiling, as well as shotgun metagenomic studies, have used several sequencing technologies, including capillary (Sanger) sequencing (such as the Applied Biosystems 3730xl DNA analyser), pyrosequencing (such as the Roche 454 Genome Sequencer GS, FLX and FLX Titanium) and Illumina’s clonal arrays (such as the Illumina GAIIx and HiSeq2000). To our knowledge, no microbial community study has been published using other sequencing technologies. As shown in TABLE 1, each technology has distinct characteristics, and getting the most out of each technology requires striking the best balance between insert size, read length, depth, sequence accuracy, usability and cost. Taxonomic profiling studies The first taxonomic profiling studies were based on the Sanger sequencing method, starting with the short 5S rRNA gene and then using increasingly long fragments of the 16S rDNA, ultimately leading up to near-full-length 16S rDNA sequences44. The study of increasing fragment lengths has been made easier by the recent use of high-throughput sequencing techniques (FIG. 3). These techniques allow more samples to be sequenced at a higher depth and lower cost, albeit at shorter read length (TABLE 1). In principle, longer sequences should yield higher resolution for applications such as classification45, defining novel taxa44 or identifying specific biomarker organisms based on a culture-independent approach46. However, changes in community composition can typically be assessed on the basis of a gene fragment that is as small as 100 bp47. The drop in the length of sequenced fragments resulted in the need to select a shorter region of the 16S rDNA as a proxy, although no consensus has been reached regarding the single best region of 16S rDNA to assay (as noted above, several regions of the 16S rDNA are almost equally effective). Within 5 years, the read lengths obtained by 454 pyrosequencing kits evolved from 100 bases (using the GS platform) to >250 bases (using the FLX platform) and then to 500 bases (using the FLX Titanium platform). Now these kits allow sequencing of almost the entire length of amplicons, which, because of the current chemistry of this technology, were thought to be limited to <600 bases (TABLE 1). This approach can span multiple hypervariable and conserved regions, increasing the performance at different phylogenetic depths. More recently, the promise of high depth at low cost introduced by the Illumina platform has resulted in the development of different strategies to compensate for the limitation posed by the shorter read lengths. Depending on the preferred region of 16S rDNA and amplification primers, fragments between ~100 and ~300 bases can be subjected to paired-end sequencing with read lengths of 76, 101 or 125 bases48–53. Some of these approaches result in overlapping reads, increasing the total fragment length and sequence quality, whereas others result in a gap in the middle of the sequence. However, all approaches potentially allow much larger-scale studies than are possible with the 454 pyrosequencing technology. The switch from Sanger sequencing to parallel pyrosequencing has resulted in a widespread increase to thousands of reads per sample and to hundreds of samples per run. An Illumina-based approach gains two to three orders of magnitude, achieving millions of reads per sample and thousands of samples per run (TABLE 1). This continued evolution in the number of reads per run leads to an increasing need for higher levels of automation in sample preparation and for improved software tools to handle the resulting massive data sets. The decreased cost per sample and per nucleotide sequence has allowed immensely deep coverage of hundreds of samples simultaneously52. It has also introduced a plethora of new hurdles to overcome, from decreased taxonomic classification sensitivity owing to short read lengths and sequencing errors54 to increased time and financial costs of sample preparation, which can be mitigated through new approaches51. Functional profiling studies Sequencing needs are somewhat different for metagenomic functional profiling approaches compared to the typical 16S-rDNA-based taxonomic-profiling approaches described in the previous section. Initial studies involved sequencing clones of large-insert libraries (for example, bacterial artificial chromosomes) that were derived from genomic DNA extracted from a microbial community55. Despite the great use of contextual data generated by these long fragments, such directed sequencing has largely been replaced by cheaper, high-throughput shotgun sequencing, both for metagenomics and for single-organism genomics. Ideally, large contiguous pieces of DNA would be generated that contain operons as well as phylogenetic markers or even that contain complete microbial genomes of previously uncultivated species. The first example of using a large-scale, random shotgun sequencing approach is the reconstruction of a simple environmental community making up an acid mine biofilm. This study involved 78 million bases of long Sanger reads and led to several near-complete genomes of the key organisms that are present56. However, metagenomics studies have also undergone substantial changes owing to the introduction of new sequencing technologies. Increasingly more complex communities have now been tackled, making it far more difficult to sample the full breadth of a population at a sufficient depth to result in large contiguous sequences, something that is possible in low-diversity environments, such as in acid mine drainage. Using next-generation sequencing to increase the amount of data up to billions of bases per sample (as was recently done in a large-scale microbiome study of the human gut8) still shows limitations in generating high-quality de novo assemblies: fewer than half of the short (75-base) reads could be assembled into contigs that were larger than 500 bases, and most of them were smaller than 2 kb. This depth issue is even more pronounced in those sample types that are not dominated by the microbial community and that contain large fractions of host DNA (for example, human mucosal sites can contain over 80% human DNA). Although terabase metagenomic data sets will be available in the near future, the challenge of metagenomic assembly is unlikely to be solely addressed by increasing the depth of coverage, and improvements will depend on both the nature and the quality of the sequence data used as input and/or on the introduction of novel sequencing technologies. Approaches that are used and/or considered for metagenomic studies currently include: increasing read lengths by creating composite reads from short, overlapping paired-end sequences57; applying a hybrid approach that combines abundant short reads patched with longer reads (for a first-generation application, see REF. 58; future applications could leverage the longer reads from the PacBio RS platform); or obtaining long-range connectivity using jumping libraries59. All of these approaches are heavily dependent on advancements in computational algorithms. Error rates An important distinction between genome sequencing — which drives the development of many sequencing methods — and microbiome sequencing is that in genome sequencing, the error rates are less important. In genome sequencing, each region of the genome is sequenced many times; by contrast, in microbiome sequencing, each fragment (derived from either amplicon or metagenomic sequencing) may be sequenced only once, and this intrinsic variation, which is conflated with the sequencing error on each read, is itself of interest. The effect of raw sequencing error rates on the observed microbial diversity is potentially great, as every sequencing error could be portrayed as arriving from a novel organism. This effect is now typically evaluated on the basis of a synthetic, or ‘mock’, community that is created by pooling genomic DNA or cloned 16S rDNA fragments of multiple isolates60,61. Ideally, near-full-length 16S rDNA gene sequences are available at reference quality for the organisms in the mock community; this allows a description of the effect of raw sequencing error rates on the number of operational taxonomic units (OTUs) and a calculation of the actual error rates and error types62. Research on reducing all types of errors — including both sequencing errors and PCR-based chimeric sequence formation63 — is an active area of study, especially with the regular introduction of novel technologies that require faster algorithms for downstream data analysis. In general, sequences that are suspected of including a high level of sequencing errors are discarded in an initial filtering step. Parameters such as the average quality score of the sequence, number and length of homopolymers, number of mismatches in the primers or total length of the sequence are tested to determine whether the sequence represents a true DNA fragment or a sequencing artefact. Chimeric sequences represent a different type of error: during PCR amplification, synthesis from a given template might be interrupted and then restarted using a different template that shares a certain degree of homology with the first template, resulting in a final DNA fragment that is formed from (at least) two different templates. Different tools exist to detect and remove chimeric sequences64–66. However, as these sequences are usually equally distributed across all samples that are subjected to the same protocol, chimaeras will primarily affect estimates of species richness (total number of OTUs in a given sample), not estimates of relative species diversity between samples. Bioinformatics data analysis tools After DNA sequences have been acquired, they must be analysed and interpreted. The large amount of data produced in modern investigations requires sophisticated analysis tools; direct manipulation of the data, such as manually aligning DNA sequences, is no longer feasible. There are many approaches for analysing such data. Here we distinguish between the analysis of targeted amplicon and metagenomic microbiome data, where the latter includes a sampling of the entire complement of the DNA that is present in the microbiome rather than relying on inference of gene content from the organisms present (FIG. 1). Analysis tools for targeted amplicon data For targeted amplicon sequencing (for example, sequencing of 16S rDNA profiles), tools such as QIIME67, mothur66 and VAMPS were developed to allow researchers to compare and analyse microbial communities using large amounts of DNA sequence data. As noted above, high-throughput sequencing technologies introduce errors, or ‘noise’, into sequence data. For 454 pyrosequencing technology, there are approaches to reduce these errors or to ‘denoise’ the sequencing results by clustering the flowgrams produced by the sequencer into a smaller number of DNA sequences that were probably present in the original biological samples. This can be done with tools such as AmpliconNoise64 and Denoiser69, which can be applied individually or used within the context of QIIME, or they can be applied using mothur-based reimplementations. One important decision to make when performing analysis is whether to use the original, published version of a tool or whether to use a tool integrator’s implementation. In QIIME, our laboratories use the original implementations; this makes installation more difficult but guarantees the use of ‘brand-name’ tools. In mothur, the algorithms are rewritten from scratch, which makes the package easier to install and, in many cases, makes it run faster, but it does not guarantee that the same results will be produced. Other tools may use either of these two strategies or a mixture of them. Assigning amplicon sequences to operational taxonomic units DNA sequences, whether or not they have been denoised, are then typically clustered into OTUs. This process is a proxy for assigning DNA sequences to microbial species and is an important step for the analysis of diversity using a variety of species-based or OTU-based ecological metrics. Because most microbial species cannot yet be cultured in the laboratory69, diversity estimates are generally based on DNA sequence data that are grouped into these OTUs. OTUs can be defined as containing as much diversity as a given taxonomic level (for example, species or genus) by changing the sequence similarity threshold. However, the sequence similarity thresholds used are imprecise measures of an imprecise concept of a microbial ‘species’, and the sequence identity of, for example, the V2 region of the 16S rDNA does not exactly reflect the sequence identity of the entire gene70. An alternative to grouping sequence data using OTU thresholds to cluster the sequences without any external information (also known as de novo OTU picking) is to analyse only those sequences that can be formally assigned to known taxa or to analyse only those sequences that are highly similar to known taxa. This alternative approach is known as reference-based OTU clustering (or picking), and it frequently yields similar patterns to de novo approaches. In reference-based OTU picking, new DNA sequences are compared to one of a variety of reference databases of typically long, high-quality DNA sequences, such as those that are maintained by greengenes15 or by SILVA16. Reference-based approaches have several key advantages over the de novo approaches that have just been described, although they lack the latter’s suitability for exploring uncharted territory in microbiome space. They can be especially useful for combining sequence data from different regions of the 16S rDNA gene by mapping disparate regions onto a database of full-length reference sequences or for combining sequence data that are generated from different sequencing technologies. In such cases, de novo OTU picking would not be appropriate, as identical microorganisms might wrongly be assigned to different OTUs based solely on differences in sequencing technology or in the DNA region chosen for amplification. The reference-based approach to OTU generation is increasingly valuable as the extent of publicly available data expands because it allows new investigations to be interpreted in the context of existing studies. Picking OTUs against a reference database can also reduce the impact of chimeric sequences and noisy data. For example, one study resequenced the microbiota of two individuals using Illumina sequencing and compared community composition over time to previous results obtained on the same individuals by pyrosequencing11. These approaches are becoming increasingly important, as databases such as VAMPS, MG-RAST71 and the QIIME database aggregate sequences that are produced by different platforms and technologies, although such comparisons can be highly effective, even using existing techniques11. As the amount of sequence data for microbial communities grows exponentially, it is becoming increasingly clear that detailed information about samples (metadata) is crucial for enabling comparison of studies in databases and for allowing meta-analyses of the sequence data. The Genomic Standards Consortium aims to make standard the collection and reporting of detailed and standardized ‘metadata’ about the sequences. Such data would include clinical information about the subjects and technical information about how the DNA extraction, sequencing and other steps were performed. Towards this goal, the Genomic Standards Consortium has recently introduced standards, such as Minimum Information about Any (x) Sequence (MIxS)72, that allow these important factors to be defined. These standards have already been adopted by large projects, such as the Human Microbiome Project73 and the Earth Microbiome Project74. Inferring phylogenetic relationships The phylogenetic relationships among DNA sequences can also be inferred, either by using an existing reference database with an associated phylogeny (such as greengenes or SILVA) or by inferring the phylogeny de novo using tools such as NAST75,76 (for sequence alignment) and FastTree77 (for phylogeny inference from aligned sequences). Phylogenies allow the use of phylogenetically aware analysis, such as UniFrac78 and Phylogenetic Diversity79, which have been extensively used. Again, such tools for phylogeny inference can be used in isolation or within the context of QIIME, mothur or other pipelines. Even after sequences have been assigned to OTUs and possibly related to one another using a phylogenetic tree, the scale of data is still extensive. Various approaches exist to interpret such data to reveal meaningful patterns in microbial diversity. Typical approaches include applying metrics of community-wide similarity and using analyses such as principal coordinates analysis (PCoA) to visualize the relationships between microbial communities. The generation of rarefaction curves to display within-community diversity (α-diversity) is also common, as are various approaches to assess informative taxa across communities and across categories of communities. VAMPS, QIIME and mothur all perform such analyses and frequently produce publication-ready figures11,80. Analytical tools for metagenomic data In addition to taxonomic analyses using marker genes, microbial community studies are increasingly using metagenomic sequencing to assess community membership in diverse environments8,10,81–83. One additional benefit of metagenomic sequencing is that it yields information on the encoded functional potential in the community DNA, and this functional profile can help to generate hypotheses on community dynamics and metabolic properties. To determine the phylogenetic membership of microbial communities based on metagenomic sequences, several freely available and popular software packages compare the metagenomic reads to a variety of full genome sequences using BLAST or interpolated Markov models. The identity of the best match then determines the likely phylogenetic origin of the sequence84,85. Another alternative is to find and extract informative phylogenetic markers from the metagenomic reads, which can be processed with similar methods to targeted gene surveys86,87. However, the taxonomic assignments from arbitrary metagenomic fragments remain a big challenge as much of the novelty in metagenomes still corresponds to organisms that lack a representative sequenced genome, and complementing metagenomic analyses with 16S rDNA analyses for which much larger reference databases exist are often useful. One advantage of metagenomic approaches is their ability to discriminate strains of common species by gene content beyond the resolution that is possible with 16S rDNA sequences8, although this approach requires high coverage and thus cannot be applied to rarer members of the community. Functional annotation of metagenomic sequences Community functional potential is almost always analysed by comparing the metagenomic sequences to large databases of metabolic annotations88–90. Depending on the sequencing strategy, coverage and community complexity, the sequences can either be used directly as short fragments, or they can be assembled into larger contigs for gene calling before annotation (for a review of metagenomic assembly, see REF. 91). Some software packages exist to tie together various components, and although no single standard exists yet, the Genomic Standards Consortium92 is currently working towards a consistent way for describing and comparing approaches. Depending on the need for customization and computational resources, annotation pipelines can be downloaded and run on a local computer cluster (for example, SmashCommunity93), or a user can upload their sequence data to a Web server and use a pre-structured pipeline, such as MG-RAST71, CAMERA94 or IMG/M95. One major benefit of online resources such as MG-RAST is the ability to compare publicly available metagenomic data sets, allowing users to perform comparative metagenomic analysis of their samples against a huge variety of environmental and host-associated metagenomic projects. As with targeted gene surveys, one of the greatest challenges for understanding metagenomic data sets is the identification of significantly different features between communities. Just like targeted gene surveys, the large number of DNA sequences and functional groups requires paying careful attention to false discovery rates and good knowledge of suitable statistical tests — simple parametric statistics are rarely appropriate. Additionally, it can be difficult to understand the biological importance of a list of gene functions that are differentially represented between two communities or between several groups of communities. An increasing number of tools and strategies are being developed that allow the identification of substantial differences in functional groups in metagenomes and, importantly, they can aggregate these gene-level differences into metabolic pathways that are differentially represented46,96,97. It should be noted that many DNA sequences from both metagenomic and targeted gene studies originate from poorly characterized genes and microorganisms, and our understanding of many of the microbial guests that are harboured in the human body is still shallow. There are thus ongoing efforts to sequence the complete genomes of a wide variety of microorganisms, in part to provide a framework from which to interpret DNA sequences from microbiome studies. These additional reference genomes that are provided by large sequencing efforts, such as the Human Microbiome Project, are allowing more insight into the nature of microorganisms that are identified in targeted gene surveys and are aiding in the functional annotation and assembly of metagenomic sequences. The availability of a larger number of reference genomes will also have a dramatic influence in our understanding of disease-associated strains and pathogenicity, as well as in providing a clearer picture of microbial evolution. Finally, the accumulation of more reference genomes will result in a faster pace at which we can reconstruct new genomes from short reads by using co-assembly methods98. Conclusions and prospectus Characterizing the taxonomic and functional characteristics of the human microbiome, despite considerable variation in methodology, is providing a much richer picture of our ‘normal’ microbial symbionts and, for several body sites, the association between microbial communities and human disease. One theme that is common to both taxonomic and functional analyses of the human microbiome is that, in order to find associations between genes, organisms and physiological or disease states, it is more informative to use larger numbers of samples than it is to sequence each sample at greater coverage. Depending on the subtlety of the patterns to be discovered, surprisingly few sequences per sample may be needed to reveal them99. However, associations that involve rare species and rare genes will require far deeper sampling than is currently typical100. For example, we know that many pathogens can be introduced with inocula consisting of only a handful of cells: the discovery of rare, persistent pathogens (either at the level of species or at the level of strains) or of rare genes, such as virulence factors, might require several additional orders of magnitude of sequencing effort and/or finer resolution of sampling sites. These deeper investigations might involve directly sampling gut mucosa rather than relying on stools as a proxy or sampling specific and anatomically defined regions of skin. Relevant to this issue is the possibility that rare ‘keystone’ genes or species that are themselves undetectable might produce widespread ripples in common members of the microbiota that are more readily detectable. For example, sampling a cubic kilometre of Yellowstone National Park would be unlikely to reveal much wolf DNA, but we know that wolves are crucial in structuring this ecosystem because their role is reflected in the distribution of common plants, animals and even fish101. In this context, it is especially important to distinguish correlations between the presence or abundance of genes and species with physiological states and causation of those states by these species. Causality has been established in a few cases: stool transplantations from one human to another can cure persistent Clostridium difficile infections102, and transfer of microbial communities together with associated physiological states has been seen between different mice103 or even between humans and mice104. However, manipulating the microbiome of humans involves overcoming substantial bureaucratic obstacles, which, in our view, are excessive, given the prevalence of unverified and largely unregulated products that aim to manipulate the microbiome and are marketed directly to non-expert consumers. Thus, we can expect much of this work to take place in animal models for the foreseeable future. Whether prospective time series studies will reveal which associations between genes or microorganisms and physiological states are causal and which are side effects remains an important unresolved question. In this Review, we have focused on 16S rDNA and metagenomic studies, which tell us about community membership and functional capacity. However, studies of gene expression at the RNA and protein level, of metabolites and of specific groups of lipids, carbohydrates and other markers will be increasingly important, as will studies of complete genomes of individual species in their natural environments. An especially exciting prospect is the ability to assemble personalized culture collections that describe the variability within an individual person105. Such investigations will allow more detailed manipulation of these communities, such as leave-one-out analyses and other perturbations, allowing us to untangle the effects of specific genes and organisms within complex communities. Manipulations of culture collections should help to determine which level of ‘multi-omics’ analysis is most useful for identifying biomarkers of human disease and also for generally increasing our understanding of the associations between microorganisms and human health. This Review covers work in the Knight laboratory that is supported by the US National Institutes of Health (NIH), the Bill and Melinda Gates Foundation, the Crohn’s and Colitis Foundation and the Howard Hughes Medical Institutes. D.G. was supported by a grant from the NIH (NIHU54HG004969), the Crohn’s and Colitis Foundation of America and the Juvenile Diabetes Research Foundation. Abbreviations Microbiota The collection of microbial organisms from a defined environment, such as a human gut. Microbiome The collection of genes that are harboured by microbiota. Metagenomics The study of the collective genome of microorganisms from an environment. Shotgun metagenomics refers to the approach of shearing DNA that have been extracted from the environment and sequencing the small fragments. Amplicon An amplified fragment of DNA from a region of a marker gene (such as 16S rDNA) that is generated by PCR. Bead beating A process used to lyse cells and to disrupt larger structures before DNA extraction. Paired-end sequencing An approach used in some sequencing platforms in which a single DNA clone is subjected to sequencing reads that originate from each of a set of primers, such that the direction of each sequencing reaction is directed to the origin of the other. Functional profiling approaches Studies in which the genomic DNA of the microbiome is assessed for functional potential. Jumping libraries Libraries that use molecular biology techniques to join together the ends of a larger DNA fragment, allowing sequencing on platforms that can only sequence a shorter fragment length. For example, 10 kb fragments might be reduced to 200 bases from each end, giving a final fragment size of 400 bp that can undergo paired-end sequencing. Operational taxonomic units (OTUs) Sequences are generally collapsed into OTUs based on sequence similarity thresholds for downstream analyses. The typical threshold is 97%, and this is taken as a proxy for species level divergence, although what constitutes a microbial species remains an open debate. Chimeric sequence An artificial sequence that juxtaposes gene regions from two or more unrelated organisms. It is produced by recombination between two or more DNA molecules during PCR amplification. Homopolymers Sequences that contain repetitions of identical bases. Metadata Information associated with sequences, including environmental conditions and the time and location of the sample collection site. Principal coordinates analysis (PCoA) A multivariate technique used in microbiome studies to visualize the relationships among communities. Each community is represented by a point in typically two- or three- dimensional space, and similar communities are located close to one another in the resulting PCoA plot. Rarefaction curves Plots of community diversity versus depth of sequencing (or, generally, observation). They are used to assess the amount of diversity and the extent to which it has been sampled at a given depth of sequencing. Interpolated Markov models A bioinformatics technique used here to classify DNA sequences using patterns of k-mer nucleotide strings that are present in a within a genome database. Leave-one-out analyses Studies of a microbial community that lacks one of its constituent microbial taxa. Figure 1 Bioinformatics analysis of microbiome sequence data Although variations exist, we show typical analysis paths for both targeted amplicon analysis (for example, analysis of 16S rDNA) and metagenomic analysis (for example, shotgun amplification). In targeted amplicon studies (left branch), raw sequences are usually passed through quality filtering and denoising algorithms to minimize the effects of sequencing artefacts. The resulting filtered sequence reads are clustered into operational taxonomic units (OTUs), representing similar organisms, and the phylogeny and taxonomic identity (when the organisms closely resemble named taxonomic groups) are inferred. At this stage, it is possible to incorporate sequence data from other relevant studies, or the data can be treated individually. The abundance of the various OTUs is then subjected to a variety of multivariate analyses and visualization procedures to elucidate the structure and patterns of the microbial communities. In metagenomic studies (right branch), the raw sequence fragments are sometimes assembled into contiguous sequences (contigs). The functional potential of those sequences is then typically assessed using a functional annotation database. The results are used to identify important metabolic pathways and are compared to the results of other metagenomic studies. The processed data are then subjected to multivariate analyses and visualizations, and they are often combined with the results of microbial profiling. Note that there are several opportunities for obtaining targeted gene data (similar to those produced in 16S rDNA gene surveys) in metagenomic studies, as indicated by the step labelled ‘identify target gene sequences’. KEGG, Kyoto Encyclopedia of Genes and Genomes; MG-RAST, Metagenomics Rapid Annotation using Subsystems Technology. Figure 2 Effects of primer choice in targeted amplicon sequencing In choosing primers, there is often a trade-off between being broadly inclusive and avoiding biases for or against specific groups, which might occur owing to variation in sequence conservation between lineages. Therefore, changes that increase the representation of one group may cause another group to drop out. This figure shows predicted taxonomic coverage for two 16S rDNA primer pairs: carefully selected universal primers (a) and commonly used primers with high bias (b). This results in variations in the observed taxonomic composition of communities owing to primer sensitivity, as shown in the pie charts for the communities in the mouth, the head and the skin and in the histograms on the right, representing the primer pairs’ sensitivity to various microbial phyla (the effect continues to finer-level taxa, such as genera (not shown)). As no primer set is without some degree of bias, it is important that a priori knowledge of the target microbiota is used along with knowledge of a primer’s performance when choosing a primer set. However, primer set 1 (which amplifies the F515–R806 fragment) is an especially good choice in terms of avoiding bias and allowing for good representation of known bacterial and archaeal groups. It has been adopted by the Earth Microbiome Project, among other projects. Data taken from REF. 9. Figure 3 How to get the most taxonomic information out of each sequencing technology Taxonomic profiling consists of generating an amplicon (in red) of the (partial) 16S ribosomal RNA (rRNA) gene (top) with selected PCR primers, followed by sequencing that amplicon with a preferred technology (grey arrows): Sanger ABI 3730xl, 454 (FLX and FLX Titanium) and Illumina 101 paired-end (PE) sequencing technologies are compared in the figure. Arrows emanating from the schematic 16S gene represent common forward (F) and reverse (R) primers, and the orange boxes denote the hypervariable regions (V1–9), which are known to be far less conserved than the surrounding sequence. Technologies differ in the maximum allowable amplicon size and read length (TABLE 1) and therefore result in a different view of the community. To increase overall length and/or quality, Sanger- and Illumina-based strategies involve sequencing amplicons in both directions; in Sanger sequencing, there is also the option of using a third read. By contrast, a preferred 454-based strategy sequences the amplicons in a single direction owing to the lack of standard paired-end sequencing and loss of pairing information. Getting the most taxonomic information requires careful selection of primers, 16S rDNA windows and technologies in order to obtain the most data27,47. The long length of Sanger reads diminishes the need for careful selection of amplicon primer pairs, which have been shown to have a large role in taxonomic assignment and community comparison results with 454 data. A variety of options exist, and studies such as the one described in REF. 47 provide suggestions on which sets to choose. Short read effects are exacerbated further in Illumina sequencing, and choosing amplicon size such that overlapping paired-end reads occur is an important consideration. Table 1 Comparison of sequencing technologies Read length Maximum insert size Run time (hours (h) or days (d)) Reads per run Relative cost factor (per Mb) Scale of reads per sample Scale of samples per run Raw error rate (%) Total Insertions Deletions Mismatches ABI 3730 800 b >1 Kb 2 h 96 100 102 101 0.001 ≪0.1 ≪0.1 ≪0.1 454 FLX Titanium 300–400 b 800 b 9 h 106 1 103 102 1 < 1 ≪ 0.1 ≪ 1 454 FLX+ 500–600 b 1200 b 23 h 106 0.7 103 102 Illumina GAIIx 76–101 b 500 b 6–9 d 4 × 108 0.1 105–106 103–104 <1 ≪1 ≪1 <1 Illumina HiSeq 2000 101–151 b 500 b 9–15 d 3 × 109 0.002 105–106 103–104 Illumina MiSeq 36–151 b 500 b 4h–27 h 107 0.06 104 102 PacBio 1100 b >1 Kb 1.5 h 3.5 × 107 1.5 103 101 15 13 1 1 IonTorrent 200 b 400 b 2–3 h 1.5 × 106–3 × 106 0.4 103 102 2 1 1 <1 The table shows a comparison of characteristics and average error rates and types of various sequencing technologies, both those that are commonly used in microbiome studies and promising but less-established technologies (MiSeq, PacBio, IonTorrent). The estimated relative cost factor presented here (relative to 454 Titanium sequencing) includes only sequencing costs and not the many other time and money costs that are involved in microbiome studies. Note that values are based on capabilities at the time of submission and that the next-generation sequencing technologies are likely to change quickly. 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This work defined a minimal set of functions that are present in all of the sampled individuals 20203603 9 Costello EK Bacterial community variation in human body habitats across space and time Science 326 1694 1697 2009 This paper was the first to establish that the microbial communities harboured across the human body are personalized but vary substantially across body sites and over time 19892944 10 Turnbaugh PJ A core gut microbiome in obese and lean twins Nature 457 480 484 2009 19043404 11 Caporaso JG Moving pictures of the human microbiome Genome Biol 12 R50 2011 This is the densest time-series analysis of variation in the human microbiota that has been carried out so far. This study also proved the usefulness of newer DNA sequencers to provide deeper insights into the microbiota by recapturing previous results in variability across body sites and time using a different sequencing technology 21624126 12 Shi Y Tyson GW DeLong EF Metatranscriptomics reveals unique microbial small RNAs in the ocean’s water column Nature 459 266 269 2009 19444216 13 Maron PA Ranjard L Mougel C Lemanceau P Metaproteomics: a new approach for studying functional microbial ecology Microb Ecol 53 486 493 2007 17431707 14 Clayton TA Baker D Lindon JC Everett JR Nicholson JK Pharmacometabonomic identification of a significant host-microbiome metabolic interaction affecting human drug metabolism Proc Natl Acad Sci USA 106 14728 14733 2009 The authors of this paper suggest a link between a person’s microbiome and their ability to metabolize a common drug, paracetamol (acetaminophen) 19667173 15 DeSantis TZ Greengenes, a chimera-checked 16S rRNA gene database and workbench compatible with ARB Appl Environ Microbiol 72 5069 5072 2006 16820507 16 Pruesse E SILVA: a comprehensive online resource for quality checked and aligned ribosomal RNA sequence data compatible with ARB Nucleic Acids Res 35 7188 7196 2007 17947321 17 Cole JR The Ribosomal Database Project: improved alignments and new tools for rRNA analysis Nucleic Acids Res 37 D141 D145 2009 19004872 18 Bellemain E ITS as an environmental DNA barcode for fungi: an in silico approach reveals potential PCR biases BMC Microbiol 10 189 2010 20618939 19 Hayashi H Sakamoto M Benno Y Evaluation of three different forward primers by terminal restriction fragment length polymorphism analysis for determination of fecal Bifidobacterium spp. in healthy subjects Microbiol Immunol 48 1 6 2004 14734852 20 Bergmann GT The under-recognized dominance of Verrucomicrobia in soil bacterial communities Soil Biol Biochem 43 1450 1455 2011 22267877 21 Liu Z DeSantis TZ Andersen GL Knight R Accurate taxonomy assignments from 16S rRNA sequences produced by highly parallel pyrosequencers Nucleic Acids Res 36 e120 2008 18723574 22 Walters WA PrimerProspector: de novo design and taxonomic analysis of barcoded polymerase chain reaction primers Bioinformatics 27 1159 1161 2011 21349862 23 Marchesi JR Prokaryotic and eukaryotic diversity of the human gut Adv Appl Microbiol 72 43 62 2010 20602987 24 Parfrey LW Walters WA Knight R Microbial eukaryotes in the human microbiome: ecology, evolution, and future directions Front Microbiol 2 153 2011 21808637 25 Ott SJ Fungi and inflammatory bowel diseases: alterations of composition and diversity Scand J Gastroenterol 43 831 841 2008 18584522 26 Ghannoum MA Characterization of the oral fungal microbiome (mycobiome) in healthy individuals PLoS Pathog 6 e1000713 2010 20072605 27 Vestheim H Jarman SN Blocking primers to enhance PCR amplification of rare sequences in mixed samples — a case study on prey DNA in Antarctic krill stomachs Front Zool 5 12 2008 18638418 28 Haynes M Rohwer F Metagenomics of the Human Body Nelson KE 63 77 Springer New York 2011 29 Virgin HW Wherry EJ Ahmed R Redefining chronic viral infection Cell 138 30 50 2009 19596234 30 Breitbart M Viral diversity and dynamics in an infant gut Res Microbiol 159 367 373 2008 18541415 31 Reyes A Viruses in the faecal microbiota of monozygotic twins and their mothers Nature 466 334 338 2010 20631792 32 Palmer C Bik EM DiGiulio DB Relman DA Brown PO Development of the human infant intestinal microbiota PLoS Biol 5 e177 2007 17594176 33 Koenig JE Succession of microbial consortia in the developing infant gut microbiome Proc Natl Acad Sci USA 108 Suppl 1 4578 4585 2011 This paper describes a two-year longitudinal study of the development of the gut microbiota in an infant. This work provides a detailed analysis of the relationship between life events and changes in microbiome composition and function 20668239 34 Oliver KM Degnan PH Hunter MS Moran NA Bacteriophages encode factors required for protection in a symbiotic mutualism Science 325 992 994 2009 19696350 35 Caporaso JG Knight R Kelley ST Host-associated and free-living phage communities differ profoundly in phylogenetic composition PLoS ONE 6 e16900 2011 21383980 36 Willner D Metagenomic analysis of respiratory tract DNA viral communities in cystic fibrosis and non-cystic fibrosis individuals PLoS ONE 4 e7370 2009 19816605 37 McOrist AL Jackson M Bird AR A comparison of five methods for extraction of bacterial DNA from human faecal samples J Microbiol Methods 50 131 139 2002 11997164 38 Wang RF Beggs ML Erickson BD Cerniglia CE DNA microarray analysis of predominant human intestinal bacteria in fecal samples Mol Cell probes 18 223 234 2004 15271382 39 Wu GD Linking long-term dietary patterns with gut microbial enterotypes Science 334 105 108 2011 21885731 40 Turnbaugh PJ Bäckhed F Fulton L Gordon JI Diet-induced obesity is linked to marked but reversible alterations in the mouse distal gut microbiome Cell Host Microbe 3 213 223 2008 18407065 41 Fierer N Hamady M Lauber CL Knight R The influence of sex, handedness, and washing on the diversity of hand surface bacteria Proc Natl Acad Sci USA 105 17994 17999 2008 19004758 42 Wu GD Sampling and pyrosequencing methods for characterizing bacterial communities in the human gut using 16S sequence tags BMC Microbiol 10 206 206 2010 This study shows that long-term dietary patterns are associated with particular enterotypes. Bacteroides spp. were associated with a Western-like diet that is rich in proteins and animal fats, whereas Prevotella spp. were linked with high-carbohydrate diets 20673359 43 Lauber CL Zhou N Gordon JI Knight R Fierer N Effect of storage conditions on the assessment of bacterial community structure in soil and human-associated samples FEMS Microbiol Lett 307 80 86 2010 20412303 44 Amann RI Ludwig W Schleifer KH Phylogenetic identification and in situ detection of individual microbial cells without cultivation Microbiol Rev 59 143 169 1995 7535888 45 Wang Q Garrity GM Tiedje JM Cole JR Naive Bayesian classifier for rapid assignment of rRNA sequences into the new bacterial taxonomy Appl Environ Microbiol 73 5261 5267 2007 17586664 46 Segata N Metagenomic biomarker discovery and explanation Genome Biol 12 R60 2011 21702898 47 Liu Z Lozupone C Hamady M Bushman FD Knight R Short pyrosequencing reads suffice for accurate microbial community analysis Nucleic Acids Res 35 e120 2007 17881377 48 Zhou HW BIPES, a cost-effective high-throughput method for assessing microbial diversity ISME J 5 741 749 2011 20962877 49 Hummelen R Deep sequencing of the vaginal microbiota of women with HIV PLoS ONE 5 e12078 2010 20711427 50 Lazarevic V Metagenomic study of the oral microbiota by Illumina high-throughput sequencing J Microbiol Methods 79 266 271 2009 19796657 51 Gloor GB Microbiome profiling by illumina sequencing of combinatorial sequence-tagged PCR products PLoS ONE 5 e15406 2010 21048977 52 Caporaso JG Global patterns of 16S rRNA diversity at a depth of millions of sequences per sample Proc Natl Acad Sci USA 108 Suppl 1 4516 4522 2011 20534432 53 Bartram AK Lynch MD Stearns JC Moreno-Hagelsieb G Neufeld JD Generation of multimillion-sequence 16S rRNA gene libraries from complex microbial communities by assembling paired-end illumina reads Appl Environ Microbiol 77 3846 3852 2011 21460107 54 Claesson MJ Comparison of two next-generation sequencing technologies for resolving highly complex microbiota composition using tandem variable 16S rRNA gene regions Nucleic Acids Res 38 e200 2010 20880993 55 Gilbert JA Dupont CL Microbial metagenomics: beyond the genome Ann Rev Mar Sci 3 347 371 2011 56 Tyson GW Community structure and metabolism through reconstruction of microbial genomes from the environment Nature 428 37 43 2004 14961025 57 Rodrigue S Unlocking short read sequencing for metagenomics PLoS ONE 5 e11840 2010 20676378 58 Goldberg SMD A Sanger/pyrosequencing hybrid approach for the generation of high-quality draft assemblies of marine microbial genomes Proc Natl Acad Sci USA 103 11240 11245 2006 16840556 59 Gnerre S High-quality draft assemblies of mammalian genomes from massively parallel sequence data Proc Natl Acad Sci USA 108 1513 1518 2011 21187386 60 Huse SM Huber JA Morrison HG Sogin ML Welch DM Accuracy and quality of massively parallel DNA pyrosequencing Genome Biol 8 R143 2007 17659080 61 Kunin V Engelbrektson A Ochman H Hugenholtz P Wrinkles in the rare biosphere: pyrosequencing errors can lead to artificial inflation of diversity estimates Environ Microbiol 12 118 123 2010 19725865 62 Schloss PD Gevers D Westcott SL Reducing the effects of PCR and sequencing artifacts on 16S rRNA-based studies PLoS ONE in the press 63 Haas BJ Chimeric 16S rRNA sequence formation and detection in Sanger and 454-pyrosequenced PCR amplicons Genome Res 21 494 504 2011 21212162 64 Quince C Lanzen A Davenport RJ Turnbaugh PJ Removing noise from pyrosequenced amplicons BMC bioinformatics 12 38 2011 21276213 65 Edgar RC Haas BJ Clemente JC Quince C Knight R UCHIME improves sensitivity and speed of chimera detection Bioinformatics 27 2194 2200 2011 21700674 66 Schloss PD Introducing mothur: open-source, platform-independent, community-supported software for describing and comparing microbial communities Appl Environ Microbiol 75 7537 7541 2009 19801464 67 Caporaso JG QIIME allows analysis of high-throughput community sequencing data Nature Methods 7 335 336 2010 This paper introduces QIIME, an open-source software tool that performs the complete analysis of microbial communities. Among other functions, QIIME implements quality filtering of the input raw reads, OTU picking, α- and β-diversity estimates and prediction of OTUs that are significantly associated with categories in the data 20383131 68 Reeder J Knight R Rapidly denoising pyrosequencing amplicon reads by exploiting rank-abundance distributions Nature Methods 7 668 669 2010 20805793 69 Rappe MS Giovannoni SJ The uncultured microbial majority Annu Rev Microbiol 57 369 394 2003 14527284 70 Schloss PD The effects of alignment quality, distance calculation method, sequence filtering, and region on the analysis of 16S rRNA gene-based studies PLoS Comput Biol 6 e1000844 2010 20628621 71 Meyer F The metagenomics RAST server — a public resource for the automatic phylogenetic and functional analysis of metagenomes BMC Bioinformatics 9 386 2008 18803844 72 Yilmaz P Minimum information about a marker gene sequence (MIMARKS) and minimum information about any (x) sequence (MIxS) specifications Nature Biotech 29 415 420 2011 73 Turnbaugh PJ The human microbiome project Nature 449 804 810 2007 17943116 74 Gilbert JA The Earth Microbiome Project: meeting report of the “1 EMP meeting on sample selection and acquisition” at Argonne National Laboratory October 6 2010 Stand Genomic Sci 3 249 253 2010 21304728 75 Caporaso JG PyNAST: a flexible tool for aligning sequences to a template alignment Bioinformatics 26 266 267 2010 19914921 76 DeSantis TZ Jr NAST: a multiple sequence alignment server for comparative analysis of 16S rRNA genes Nucleic Acids Res 34 W394 W399 2006 16845035 77 Price MN Dehal PS Arkin AP FastTree 2—approximately maximum-likelihood trees for large alignments PLoS ONE 5 e9490 2010 20224823 78 Lozupone C Knight R UniFrac: a new phylogenetic method for comparing microbial communities Appl Environ Microbiol 71 8228 8235 2005 This study introduces UniFrac, a phylogenetically aware measure of similarity, and one of the most widely used methods to establish the extent to which different microbial communities resemble each other 16332807 79 Faith DP Baker AM Phylogenetic diversity (PD) and biodiversity conservation: some bioinformatics challenges Evolutionary Bioinform Online 2 121 128 2006 80 Morowitz MJ Strain-resolved community genomic analysis of gut microbial colonization in a premature infant Proc Natl Acad Sci USA 108 1128 1133 2011 21191099 81 Tringe SG Comparative metagenomics of microbial communities Science 308 554 557 2005 15845853 82 Arumugam M Enterotypes of the human gut microbiome Nature 473 174 180 2011 In this study, faecal microbiomes were found to cluster into three distinct groups (‘enterotypes’) with minimal overlap 21508958 83 Muegge BD Diet drives convergence in gut microbiome functions across mammalian phylogeny and within humans Science 332 970 974 2011 21596990 84 Brady A Salzberg S PhymmBL expanded: confidence scores, custom databases, parallelization and more Nature Methods 8 367 2011 21527926 85 Mitra S Functional analysis of metagenomes and metatranscriptomes using SEED and KEGG BMC Bioinformatics 12 S21 2011 86 Sharpton TJ PhylOTU: a high-throughput procedure quantifies microbial community diversity and resolves novel taxa from metagenomic data PLoS Comput Biol 7 e1001061 2011 21283775 87 von Mering C Quantitative phylogenetic assessment of microbial communities in diverse environments Science 315 1126 1130 2007 17272687 88 Muller J eggNOG v2.0: extending the evolutionary genealogy of genes with enhanced non-supervised orthologous groups, species and functional annotations Nucleic Acids Res 38 D190 D195 2010 19900971 89 Kanehisa M Goto S Furumichi M Tanabe M Hirakawa M KEGG for representation and analysis of molecular networks involving diseases and drugs Nucleic Acids Res 38 D355 D360 2010 19880382 90 Finn RD The Pfam protein families database Nucleic Acids Res 36 D281 D288 2008 18039703 91 Wooley JC Godzik A Friedberg I A primer on metagenomics PLoS Comput Biol 6 e1000667 2010 20195499 92 Glass E Meeting report from the Genomic Standards Consortium (GSC) Workshop 10 Stand Genom Sci 3 225 231 2010 93 Arumugam M Harrington ED Foerstner KU Raes J Bork P SmashCommunity: a metagenomic annotation and analysis tool Bioinformatics 26 2977 2978 2010 20959381 94 Sun S Community Cyberinfrastructure for Advanced Microbial Ecology Research and Analysis: the CAMERA resource Nucleic Acids Res 39 D546 D551 2011 21045053 95 Markowitz VM IMG/M: a data management and analysis system for metagenomes Nucleic Acids Res 36 D534 D538 2008 17932063 96 Kristiansson E Hugenholtz P Dalevi D ShotgunFunctionalizeR: an R-package for functional comparison of metagenomes Bioinformatics 25 2737 2738 2009 19696045 97 Liu B Pop M MetaPath: identifying differentially abundant metabolic pathways in metagenomic datasets BMC Proc 5 S9 2011 98 Chen K Pachter L Bioinformatics for whole-genome shotgun sequencing of microbial communities PLoS Comput Biol 1 106 112 2005 16110337 99 Kuczynski J Microbial community resemblance methods differ in their ability to detect biologically relevant patterns Nature Methods 7 813 819 2010 20818378 100 Quince C Curtis TP Sloan WT The rational exploration of microbial diversity ISME J 2 997 1006 2008 18650928 101 Mcpeek MA Mcpeek MA The consequences of changing the top predator in a food web: a comparative experimental approach Ecol Monogr 68 1 23 1998 102 Khoruts A Dicksved J Jansson JK Sadowsky MJ Changes in the composition of the human fecal microbiome after bacteriotherapy for recurrent Clostridium difficile-associated diarrhea J Clin Gastroenterol 44 354 360 2010 20048681 103 West TE Toll-like receptor 4 region genetic variants are associated with susceptibility to melioidosis Genes Immun 2011 1 9 2011 104 Turnbaugh PJ The effect of diet on the human gut microbiome: a metagenomic analysis in humanized gnotobiotic mice Sci Transl Med 1 6ra14 2009 105 Goodman AL Extensive personal human gut microbiota culture collections characterized and manipulated in gnotobiotic mice Proc Natl Acad Sci USA 108 6252 6257 2011 This paper showed that a substantial proportion of an individual’s gut microbiota can be recaptured using anaerobic culturing conditions, both in vitro and in vivo 21436049 106 Paulino LC Tseng CH Strober BE Blaser MJ Molecular analysis of fungal microbiota in samples from healthy human skin and psoriatic lesions J Clin Microbiol 44 2933 2941 2006 16891514 107 Gao Z Tseng CH Pei Z Blaser MJ Molecular analysis of human forearm superficial skin bacterial biota Proc Natl Acad Sci USA 104 2927 2932 2007 17293459 108 Grice EA A diversity profile of the human skin microbiota Genome Res 18 1043 1050 2008 18502944 109 Zoetendal EG Mucosa-associated bacteria in the human gastrointestinal tract are uniformly distributed along the colon and differ from the community recovered from feces Appl Environ Microbiol 68 3401 3407 2002 12089021 110 Brotman RM Ravel J Cone RA Zenilman JM Rapid fluctuation of the vaginal microbiota measured by Gram stain analysis Sex Transm Infect 86 297 302 2010 20660593
PMC005xxxxxx/PMC5119551.txt
LICENSE: This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. 9710002 22013 Clin Liver Dis Clin Liver Dis Clinics in liver disease 1089-3261 1557-8224 27742011 5119551 10.1016/j.cld.2016.07.001 NIHMS814005 Article Towards Elimination of Hepatitis B Virus Using Novel Drugs, Approaches, and Combined Modalities Sebastien Boucle PhD Leda Bassit PhD Maryam Ehteshami PhD Schinazi Raymond F. PhD, DSc * Center for AIDS Research, Laboratory of Biochemical Pharmacology, Department of Pediatrics, Emory University School of Medicine, Atlanta, GA 30322, USA * Corresponding author. Tel.: +1-404-727-1414; fax: +1-404-727-1330, rschina@emory.edu (RF Schinazi) 10 9 2016 30 8 2016 11 2016 01 11 2017 20 4 737749 This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. Summary With nearly 30% of the world population infected, hepatitis B virus (HBV) causes significant morbidity and mortality worldwide. Although several potent antiviral agents are currently in use against HBV infection, the majority of chronically infected individuals do not achieve a functional and complete cure, as measured by the clearance of HB surface antigen (HBsAg) from blood and eradication of the covalently closed-circular DNA (cccDNA) from the nuclei of hepatocytes. In addition, even treated persons who achieve a long-term (> 10-15 years) sustained virological response (undetectable HBV DNA), are still at high risk of developing morbidity and mortality from liver complications. This review focuses upon novel, mechanistically diverse anti-HBV therapeutic strategies that are currently in development or in clinical evaluation, and highlights new combination strategies which may contribute to full elimination of HBV DNA and cccDNA from the infected liver, leading to a complete cure of chronic hepatitis B. HBV Cure siRNA CRISPR/Cas9 Anti-HBV agents cccDNA HBsAg Antiviral therapy Introduction Over the past decades research efforts have led to the development of several potent nucleosides analog inhibitors (NA) such as lamivudine (Epivir), adefovir dipivoxil (Hepsera), entecavir (Baraclude), telbivudine (Tyzeka), and tenofovir disoproxil fumarate (Viread) allowing a large decrease of HBV viremia in chronically infected persons.1 NAs in their 5’-triphosphate form are potent inhibitors of DNA polymerase/reverse transcriptase activities of the viral polymerase enzyme. They compete with natural nucleotides and act on several steps of viral DNA synthesis including initial polymerization, protein priming or the subsequent DNA strand elongation. It has been suggested that combination therapy using one of these nucleoside analogs and interferon could have better virus elimination efficacy than NA monotherapy, but such studies are difficult to perform since the current monotherapy is already very effective at controlling HBV viral load. However, current NA treatment does not lead to HBV cure as indicated by low levels of HBsAg seroconversion (Box 1).2,3 Despite the success of current available therapy, subjects who cleared the virus (HBeAg negative, HBsAg negative) can experience reactivation of HBV on treatment interruption or following the use of anti-inflammatory or immunosuppressant medications.4 This strongly suggests that current anti-HBV therapeutics are unable to eradicate the virus from infected liver cells. These limitations have led researchers to continue their drug development efforts toward finding new viral targets that could potentially lead to the discovery of a functional or absolute cure (Box 1).5 Considering that HBV covalently closed circular DNA (cccDNA) serves as the template for pregenomic RNA (pgRNA) transcription, it is thought to be responsible for virus persistence. At the same time, integration of HBV DNA is thought to be associated with increase risk of hepatocellular carcinoma (HCC) development.6 Accordingly, new therapeutic approaches that target cccDNA directly or indirectly are in development (Fig. 1). Following the recent successes with HCV drug development, the field of viral hepatitis is turning its focus to another major threat to liver health, namely HBV.7 These new therapeutic strategies will have to address the problems of cccDNA elimination, intrahepatic innate immune response stimulation, HBV specific immune response restoration and will probably have to include combination of drugs to target multiple steps of the HBV replication cycle. New antivirals currently in the pipelines include entry inhibitors, relaxed circular (rc)DNA-cccDNA conversion inhibitors and capsid assembly effectors (Fig. 1). Besides these direct acting agents, there has also been a significant development in the area of host-targeting agents (HTA). Examples include small interfering RNA-based strategies (SiRNA), RNAi silencers, CRISPR/Cas9 approaches, HBsAg inhibitors, immunomodulators, therapeutic vaccines and toll like receptor (TLR) agonists.8,9 Using these new investigational approaches, it is hoped that a functional cure for chronic HBV is achieved within the next decade. This review highlights recent progress in developing novel anti-HBV drugs and their mechanisms of action. Current treatments and limitations for a cure Nucleoside analogs are relatively potent inhibitors used for the treatment of chronic hepatitis B. These HBV reverse transcriptase inhibitors are usually well tolerated and have excellent bioavailability. They are also cost-effective in comparison to interferon treatments such as peginterferon alfa-2a (Pegasys) & interferon alfa-2b (Intron A). Nevertheless, these drugs have some limitations in terms of HBsAg clearance and cccDNA suppression. Although drug resistance can occur clinically with some of the earlier oral treatment such as Epivir, drug resistant viruses are rarely selected with the more recent drugs such as Baraclude and Viread. It has been thought that combination of NAs could have an additive and synergistic antiviral effect and could reduce the rate of drug resistance. However, combination studies involving two nucleoside analogs did not increase virologic response, since the drugs are already very potent on their own.10 As a result, because pegylated- interferon (PEG-IFN) has a different mechanism of action than NA, their combination (TDF + PEG-IFN for 48 wk) showed a greater viral suppression and higher rates of HBsAg loss.11,12 As new therapeutic strategies are being developed for the treatment of chronic hepatitis B (CHB), uncovering new inhibitory mechanisms and potential targets, it is very likely that NA will have their place in future combinations with future drug candidates. Viral entry inhibitors The HBV viral replication cycle consists of a complex multistep mechanism (Fig. 1), starting with the virus entering the hepatocyte, followed by DNA replication, nucleocapsid formation and release of virions. HBV entry represents an essential step for spreading and maintaining virus replication. The process involves two major interactions between the viral envelope protein Pre-S1 and hepatocyte cellular receptors including first, HBV binding to the glycoproteins heparin sulfate proteoglycans followed by its interaction with the sodium taurocholate co-transporting polypeptide (NTCP). Recently, Hepatera developed a synthetic lipopeptide, called Myrcludex-B, which is derived from the HBV L-protein.13 Studies have shown that the peptide competes with the viral Pre-S1 motif for NTCP binding, blocking de novo HBV infection. Because of its early effect on the HBV replication cycle, according to the authors, the drug may also efficiently block the amplification of the HBV cccDNA. With this new concept, this inhibitor, which is currently in phase II clinical trials, could have a role in the development of an HBV cure regimen (Table 1).14 Although, there are several other HBV entry inhibitors that can block the in vitro interaction of HBV with NTCP such as Cyclosporin A, Ritonavir, Ezetimibe, Vanitaracin A, Irbesartan, among others; these inhibitors alone can not lead to a complete inhibition of cccDNA synthesis as observed with Myrcludex-B. However, they might still play an important role by preventing viral entry into cccDNA free hepatocytes when combined with other antiviral therapies.15 Therapies targeting cccDNA cccDNA formation inhibitor HBV has evolved a unique replication cycle that results in the production of large viral loads during active replication without actually killing the infected cell directly. Two of the key events in the viral replication cycle of HBV involve first, the generation of cccDNA transcriptional template, either from input genomic DNA or newly replicated capsid-associated DNA and second, reverse transcription of the viral pgRNA to form progeny HBV DNA genomes.16,17 The HBV cccDNA is associated with viral persistence in HBV-infected hepatocytes.18,19 Hepatocytes have a long half-life (> 6 months or even years); therefore, elimination of cccDNA by hepatocyte turnover is not a major means of clearance. The major limitation of current treatment is the failure to eliminate the preexisting cccDNA pool and/or prevent cccDNA formation from trace-levels of wild-type or drug-resistant virus.20 As a consequence, HBV commonly rebounds after cessation of treatment with NA, leading different groups to develop assays to screen libraries of compounds in order to discover new antiviral candidates that can inhibit cccDNA formation.20 Doing so, disubstituted sulfonamides (DSS), such as CCC-0975 and CCC-0346 have been identified as inhibitors of cccDNA production.21 These molecules are believed to interfere with rcDNA conversion to cccDNA in HepDES19 cells, also inhibiting de novo cccDNA formation. Further development of these DSS in combination with other antivirals such as NA might lead to the elimination of HBV cccDNA. cccDNA targeted endonuclease New promising systems that specifically use sequence-specific endonucleases to cleave cccDNA and eradicate it from infected hepatocytes have been developed, including the programmable RNA-guided DNA endonucleases (CRISPR/Cas9), transcription activator-like effector nuclease (TALEN) or zinc-finger nuclease. Promising studies in cell and mouse models with CRIPSR/Cas9 have shown that these systems have the potential to serve as effective tools for the depletion of the cccDNA pool in chronically HBV infected subjects.22,23,24 CRIPSR/Cas9 specifically reduced total viral DNA levels by up to ~1,000-fold and HBV cccDNA levels by up to ~10-fold, in addition, it also mutationally inactivated the majority of the residual viral DNA in the stably transfected HepAD38 system. Moreover, these Spy Cas9/sgRNA systems showed additive inhibition of HBV DNA accumulation when used in combination with known pharmacological inhibitors of the HBV RT enzyme in the Hep2.2.15 cells, and in the infected HepaRG cells, reduced both viral production and up to 67% cccDNA formation.23 In a HBV hydrodynamics-mouse model, CRISPR/Cas9 system was capable of disrupting the intrahepatic HBV genome (~28%), with significant reduction but not complete elimination of HBsAg.24 siRNA approach Persistence of chronic HBV infection is markedly demonstrated by an absence of antiviral immune response against the virus. As a result, a continuous production of surface antigen (HBsAg) in the plasma of chronically infected individuals is observed.25 Three forms of HBsAg are secreted from infected hepatocytes, comprising of filaments and spherical particles, with or without virion. The empty, non-infectious particles are the most abundant in the plasma, and may play a role in preventing the immune system from building a specific immune response against HBV. One way to stop secretion of HBsAg from infected hepatocytes is to cease transcription of messenger RNA (mRNA) by using small interfering RNA (siRNA). These short sequences of nucleotides (siRNA) knock- down expression of genes of interest by promoting gene silencing at the posttranscriptional level. Several siRNA-based regimens are currently being developed and evaluated. The promising ARC-520 from Arrowhead Pharmaceuticals is in a phase II/III clinical studies (Table 1). This new molecule is comprised of two distinct siRNA sequences, which was designed to reduce all transcripts of HBV cccDNA and with wide genotype coverage of the HBV genome. To enhance delivery to hepatocytes, ARC-520 was conjugated with cholesterol and then coinjected with a hepatocyte-targeted membrane-active peptide. In chimpanzees, ARC-520 treatment resulted in a remarkable 95% decline in HBV DNA levels and, as high as 90% inhibition of secreted HBeAg and HBsAg.26,27 Similar results were demonstrated in HBeAg-positive patients, however, insignificant suppression of HBsAg was observed in HBeAg-negative chimpanzees or patients, supporting the hypothesis that HBsAg in this case was produced from integrated DNA which is not targeted by ARC-520. TKM-HBV/ARB-001467 developed by Arbutus Biopharma is another siRNA regimen in a phase II clinical trial (Table 1), which is currently being evaluated for its safety and tolerability in HBeAg-negative or –positive subjects receiving nucleoside analog therapy. This molecule targets three conserved regions within the HBV genome and appears to clear HBsAg expression from both cccDNA and integrated HBV. Lipid nanoparticles are utilized to transport it to the hepatocytes giving it more stability against nucleases. siRNA-based approaches for HBV are especially beneficial for the fact that the HBV viral RNA transcripts have their sequences overlapped. This facilitates the synthesis of one single siRNA trigger that could degrade all viral transcripts simultaneously and prevent viral proteins secretion. However, there are three main drawbacks with regard to siRNA approach for HBV therapeutics: (i) Specific delivery to hepatocytes in vivo: because of their small size and highly negatively charged hydrophilic phosphate backbone, siRNA are rapidly filtrated by the kidney and are cleared from the blood stream before achieving their target. (ii) siRNA that reach the cell membrane of hepatocytes can be easily trapped in the endosome and undergo degradation by nucleolytic enzymes. (iii) Undesirable off-target effects of siRNA and innate system stimulation are also a concern. Despite the aforementioned obstacles, novel chemical modifications seem to minimize the chance of cross-reactivity with human mRNAs to occur. These approaches can also enhance efficient delivery of siRNA to the cytoplasm where they can react with RNA-induced silencing complex (RISC) and prompt specific degradation of the HBV mRNAs.27 More recently, Benitec Biopharma developed BB-HB-331 based on a similar approach pertaining to DNA-directed RNA interfering strategy (ddRNAi).28 BB-HB-331 is a recombinant DNA construct, capable of continuously expressing short hairpin RNA (shRNA), which in turn can permanently silence the targeted viral messenger RNA expression with a single treatment. They revealed the results of an in vivo study conducted in humanized mouse PhoenixBio (PXB), showing a 98.5% elimination of circulating HBV (reduced serum HBV DNA by 1.83 logs), a 94.5% reduction of intracellular liver HBV DNA, and almost complete suppression of serum antigens HBeAg and HBsAg (92.6% and 97.6%), and reduction of HBV viral RNA and cccDNA levels. Capsid assembly and core protein effectors The HBV nucleocapsid is well recognized to have an important role in the viral replication cycle. It is believed to play an essential role in HBV genome packaging, reverse transcription, intracellular trafficking and maintenance of chronic infection.29 Several small molecules including heteroarylpyrimidines (HAP) have been shown to target the capsid protein (Cp) homo-dimers that rearrange to form the nucleocapsid. They have been identified to disrupt the capsid assembly, thus leading to inhibition of HBV replication both in vitro and in vivo.30,31 BAY 41-4109 (AiCuris) was the first HAP to be developed and reached phase I, but because of toxicity, solubility and other issues, it seems to have been abandoned.8 Despite hepatotoxicity in rats at high dosage,32 it was shown to inhibit the virus replication in HBV transgenic mouse,33 and more importantly effectiveness against lamivudine (Epivir) and adefovir dipivoxil (Hepsera) resistant viruses.34,33 Based on these results, HEC Pharm developed more recently another heteroarylpyrimidine named morphothiadine mesilate GLS4 which entered a phase II clinical trial in China.35 Early studies have demonstrated that this new HAP was more potent and significantly less toxic than analog BAY41-4109.36 GLS4 was found to misdirect capsid assembly leading to the formation of aberrant capsids without primarily affecting core protein levels.37 As these molecules may also have an impact on cccDNA stability, it is suggested that they may contribute to discovery of an HBV cure.38 Another class of small molecules known as sulfamoylbenzamides has been identified to interfere with the capsid, and potently inhibit the formation of pgRNA-containing capsids.39 NVR 3-778 is a sulfamoylbenzamide compound having a pangenotypic antiviral activity, developed by Novira (later acquired by Johnson & Johnson) that recently reached human phase IIa producing significant virus loads reduction (1.7 log reduction of serum HBV DNA and 0.86 log for HBV RNA, at 600 mg BID for 41 days). NVR 3-778 has shown encouraging pharmacokinetic properties, and was well tolerated in human volunteers.40 It has also been shown to inhibit the production of HBV DNA and RNA particles, especially in combination with PEG-IFN. As their mechanism of action is still not completely clear, this new class of small molecules represent a promising cohort of molecules with curative potential when combined with other small molecule inhibitors. Toll-like receptor (TLR-7) Toll-like receptors (TLR) agonists have antiviral effects. TLR-7 agonist activates the innate immunity by stimulating plasmacytoid dendritic cells to produce IFN-alpha and other cytokines/chemokines and induce the activation of killer cells as well as cytotoxic lymphocytes. Therefore, this new approach with agonist-induced activation of TLR7 can trigger both innate and adaptive immune responses and may represent a new strategy to treat chronic viral infections. GS-9620 (Gilead) is a small molecule, which has agonist activity. It binds to TLR7 leading to subsequent activation of several transcription factors, including nuclear factor κB (NF-κB) and interferon regulatory factors. GS-9620 has recently entered phase II clinical trials in combination with Tenofovir versus Tenofovir monotherapy.41,42 Other therapeutics with potential Caspase activators, RIG 1 activators, cyclophilin inhibitors, RNase H inhibitors and therapeutic vaccines are also being evaluated (Table 1.). Some of these strategies such as therapeutic vaccines seem very promising, but are still in development and will have to overcome any possible toxicity and problems related to immune-enhancing approaches variable in treated subjects.9 An impressive reduction of HBsAg has been demonstrated with the novel nucleic acid polymer Rep 2139-Ca (Replicor) alone or in combination with pegylated interferon alpha 2a in subjects chronically infected with HBV or co-infected with hepatitis delta virus (HDV). 43 This compound is in a phase II clinical trial and has the ability to block the formation of surface antigen protein by inhibiting the interaction of apolipoproteins with these subviral particles.44 Recently, a new in vitro approach was developed to facilitate the direct interaction of small molecules with the human HBV polymerase. With a large-scale production of this enzyme coupled with its structural and biophysical characterizations,45 Voros et al., validated their new system using a small molecule – metal-dependent and -binding modulator of HBV polymerase, calcomine orange 2R – which inhibits not only the duck HBV polymerase, but also human HBV polymerase. It remains to be determined whether this drug would interact synergistically with NAs that also target the viral polymerase. Another approach targeting microRNA could also have a role toward an HBV cure. MicroRNA-122 (miR-122) is a non-coding RNA involved in liver development and hepatic function, which has also been found to play a role in the regulation of HBV replication. It has been shown that miR-122 plays a role in viral persistence, as a decrease of miR-122 is correlated with enhancement of HBV replication through a cyclin G1-P53 dependent pathway. Based on these observations, Li et al. found that all four HBV mRNAs were harboring an miR-122 complementary site, revealing a novel mechanism by which viral mRNAs mediate host miRNA activity, contributing to the regulation of liver cancer cell proliferation, invasion and tumor growth.46 Moreover, recent studies have shown that transfection of miR-122 expression vector into HepG2.2.15 cells repressed the transcription and expression of the protein N-myc downstream-regulated gene 3 (NDRG3), contributing to HBV-related hepatocarcinogenesis.47 Thus, given the broad interactions of miR-122 in HBV chronic infection and HBV-related hepatocarcinomas, this microRNA represents a target for the development of new anti-HBV therapies. Conclusion Compared to the current available therapies that decrease and suppress the HBV viral DNA levels to undetectable levels, the new investigational drugs and approaches described herein have the potential to decrease or eliminate cccDNA and/or HBsAg. It is believed that combinations of antiviral agents targeting HBV replication and drugs restoring or increasing the host immune response could lead to a functional and perhaps an absolute cure within a decade.9 Following the recent success of HCV therapy, the viral hepatitis community has turned its focus on the discovery of novel HBV-associated biomarkers and therapeutic targets. It is hoped that the recent surge in anti-HBV drug discovery efforts will lead to the development of novel therapeutic strategies that could represent a path to cure for the more than 300 million individuals who are suffering from chronic hepatitis B infection worldwide. Fig. 1 Schematic representation of the inhibitors of Hepatitis B virus replication cycle. cccDNA, covalently closed circular DNA; ER, endoplasmic reticulum; HBV, hepatitis B virus; INF, interferon; mRNA, messenger RNA; pgRNA, pregenomic RNA; rcDNA, relaxed circular DNA; RT, reverse transcriptase. Table 1 Therapeutics in development for the treatment of hepatitis B chronic Infection. Updated information can be found on the Hepatitis B Foundation website (http://www.hepb.org/professionals/hbf_drug_watch.htm). Box 1. Definitions of cures Apparent virological cure Sustained off-drug suppression of serum HBsAg, HBeAg and viral DNA. cccDNA = undetectable or repressed Normalization of liver function (Normal levels of serum ALT and AST). *Risk of death from liver disease: to be determined once long-term survival data have been obtained. Functional cure Sustained off-drug suppression of serum HBsAg, HBeAg, viral DNA and cccDNA. Normalization of liver function (Normal levels of serum ALT and AST). *Comparable to individuals with naturally resolved infection. Absolute cure – virological cure Sustained off-drug suppression of serum HBsAg, HBeAg and viral DNA. Normalization of liver function (Normal levels of serum ALT and AST). Elimination of cccDNA. Presence of HBsAb. * Comparable to uninfected individuals. Key Points Despite current treatments available for HBV infection, the inability of the host immune system to completely clear the virus can lead to the establishment of incurable chronic infection. Identification of new targets and development of novel, curative drugs are necessary. Development of new therapeutic strategies that address the problems of cccDNA elimination, intrahepatic innate immune response stimulation, and HBV-specific immune response restoration are critical components of a path toward a possible cure. Combination of antiviral agents targeting HBV replication, and drugs restoring or increasing the host immune response could lead to a functional cure. Novel modalities such as CRISPR/Cas9 could disrupt HBV cccDNA and also target integrated viral DNA. This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final citable form. Please note that during the production process errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain. The authors have nothing to disclose. References 1 Kang L Pan J Wu J Hu J Sun Q Tang J Anti-HBV drugs: progress, unmet needs, and new hope. Viruses 2015 7 9 4960 77 26389937 2 Wei W Wu Q Zhou J Kong Y You H A better antiviral efficacy found in nucleos(t)ide analog (NA) combinations with interferon therapy than NA monotherapy for HBeAg positive chronic hepatitis B: a meta-analysis. International journal of environmental research and public health 2015 12 8 10039 55 26308024 3 Chang J Guo F Zhao X Guo JT Therapeutic strategies for a functional cure of chronic hepatitis B virus infection. Acta pharmaceutica Sinica B 2014 4 4 248 57 26579392 4 Wang YJ Yang L Zuo JP Recent developments in antivirals against hepatitis B virus. Virus Res 2016 213 205 13 26732483 5 Block TM Gish R Guo H Mehta A Cuconati A Thomas London W Chronic hepatitis B: What should be the goal for new therapies? Antiviral Research 2013 98 1 27 34 23391846 6 Hai H Tamori A Kawada N Role of hepatitis B virus DNA integration in human hepatocarcinogenesis. World journal of gastroenterology 2014 20 20 6236 43 24876744 7 Lucifora J Trepo C Hepatitis: After HCV cure, HBV cure? Nature Reviews Gastroenterology & hepatology 2015 12 7 376 8 8 Block TM Rawat S Brosgart CL Chronic hepatitis B: A wave of new therapies on the horizon. Antiviral Research 2015 121 69 81 26112647 9 Zeisel MB Lucifora J Mason WS Sureau C Beck J Levrero M Towards an HBV cure: state-of-the-art and unresolved questions--report of the ANRS workshop on HBV cure. Gut 2015 64 8 1314 26 25670809 10 Sung JJY Lai JY Zeuzem S Chow WC Heathcote E Perrillo R A randomised double-blind phase II study of lamivudine (LAM) compared to lamivudine plus adefovir dipivoxil (ADV) for treatment naïve patients with chronic hepatitis B (CHB): Week 52 analysis. J Hepatol 2003 38 Suppl 2 25 6 11 Perrillo RP Current treatment of chronic hepatitis B: benefits and limitations. Seminars in liver disease 2005 25 S1 20 8 16103978 12 Marcellin P Ahn SH Ma X Caruntu FA Tak WY Elkashab M Combination of tenofovir disoproxil fumarate and peginterferon alpha-2a increases loss of hepatitis B surface antigen in patients with chronic hepatitis B. Gastroenterology 2016 150 1 134 44 26453773 13 Urban S Schulze A Schieck A Gähler C Ni Y Meier A 10 preclinical studies on Myrcludex B, a novel entry inhibitor for hepatitis B and hepatitis delta virus (HDV) infections. J Hepatol 2010 52 Supplement 1 S5 14 Volz T Allweiss L Ben MM Warlich M Lohse AW Pollok JM The entry inhibitor Myrcludex-B efficiently blocks intrahepatic virus spreading in humanized mice previously infected with hepatitis B virus. J Hepatol 2013 58 5 861 7 23246506 15 Verrier ER Colpitts CC Sureau C Baumert TF Hepatitis B virus receptors and molecular drug targets. Hepatology International 2016 1 7 16 Locarnini S Hatzakis A Chen D-S Lok A Strategies to control hepatitis B: Public policy, epidemiology, vaccine and drugs. J Hepatol 2015 62 S76 S86 25920093 17 Schadler S Hildt E HBV life cycle: entry and morphogenesis. Viruses 2009 1 2 185 209 21994545 18 Block TM Guo H Guo JT Molecular virology of hepatitis B virus for clinicians. Clin Liver Dis 2007 11 4 685 706 17981225 19 Guo H Jiang D Zhou T Characterization of the intracellular deproteinized relaxed circular DNA of hepatitis B virus: an intermediate of covalently closed circular DNA formation. J Virol 2007 81 22 12472 84 17804499 20 Zhou T Guo H Guo JT Cuconati A Mehta A Block TM Hepatitis B virus e antigen production is dependent upon covalently closed circular (ccc) DNA in HepAD38 cell cultures and may serve as a cccDNA surrogate in antiviral screening assays. Antiviral Res 2006 72 2 116 24 16780964 21 Cai D Mills C Yu W Yan R Aldrich CE Saputelli JR Identification of disubstituted sulfonamide compounds as specific inhibitors of hepatitis B virus covalently closed circular DNA formation. Antimicrob Agents chemother 2012 56 8 4277 88 22644022 22 Kennedy EM Bassit LC Mueller H Suppression of hepatitis B virus DNA accumulation in chronically infected cells using a bacterial CRISPR/Cas RNA-guided DNA endonuclease. Virology 2015 476 196 205 25553515 23 Weber ND Stone D Sedlak RH AAV-mediated delivery of zinc finger nucleases targeting hepatitis B virus inhibits active replication. PLoS One 2014 9 5 e97579 24827459 24 Lin SR Yang HC Kuo YT The CRISPR/Cas9 system facilitates clearance of the intrahepatic HBV templates in vivo. Mol Ther Nucleic Acids 2014 3 e186 25137139 25 Marcellin P Castelnau C Martinot-Peignoux M Boyer N Natural history of hepatitis B. Minerva Gastroenterol. Dietol 2005 51 1 63 75 26 Gish RG Yuen MF Chan HL Synthetic RNAi triggers and their use in chronic hepatitis B therapies with curative intent. Antiviral Res 2015 121 97 108 26129970 27 Sebestyén MG Wong SC Trubetskoy V Targeted in vivo delivery of siRNA and an endosome-releasing agent to hepatocytes. Methods Mol Biol 2015 1218 163 86 25319651 28 Mao T Graham M Kao SC Strings V Cock TA Lindell P Roelvink P Suhy D BB-HB-331, a DNA-directed RNA interference agent (ddRNAi) for the treatment of subjects infected with hepatitis B virus (HBV), can effectively suppress HBV in a primary hepatocyte model. Global Antiviral Journal 2015 11 Suppl 3 Abstract 111 29 Alaluf MB Shlomai A New therapies for chronic hepatitis B. Liver international: official journal of the International Association for the Study of the Liver 2016 30 Bourne C Lee S Venkataiah B Lee A Korba B Finn MG Small-molecule effectors of hepatitis B virus capsid assembly give insight into virus life cycle. J Virol 2008 82 20 10262 70 18684823 31 Stray SJ Zlotnick A BAY 41-4109 has multiple effects on hepatitis B virus capsid assembly. J Mol Rec 2006 19 6 542 8 32 Shi C Wu CQ Cao AM Sheng HZ Yan XZ Liao MY NMR spectroscopy-based metabonomic approach to the analysis of Bay41-4109, a novel anti-HBV compound, induced hepatotoxicity in rats. Toxicol Lett 2007 173 161 167 17826925 33 Weber O Schlemmer KH Hartmann E Hagelschuer I Paessens A Graef E Deres K Goldmann S Niewoehner U Stoltefuss J Haebich D Ruebsamen-Waigmann H Wohlfeil S Inhibition of human hepatitis B virus (HBV) by a novel non-nucleosidic compound in a transgenic mouse model. Antiviral Res 2002 54 69 78 12062392 34 Billioud G Pichoud C Puerstinger G Neyts J Zoulim F The main hepatitis B virus (HBV) mutants resistant to nucleoside analogs are susceptible in vitro to nonnucleoside inhibitors of HBV replication. Antiviral Res 2011 92 271 276 21871497 35 Manzoor S Saalim M Imran M Resham S Ashraf J Hepatitis B virus therapy: What's the future holding for us? World j gastroenterol 2015 21 44 12558 75 26640332 36 Wu G Liu B Zhang Y Li J Arzumanyan A Clayton MM Preclinical characterization of GLS4, an inhibitor of hepatitis B virus core particle assembly. Antimicrob Agents chemother 2013 57 11 5344 54 23959305 37 Wang XY Wei ZM Wu GY Wang JH Zhang YJ Li J In vitro inhibition of HBV replication by a novel compound, GLS4, and its efficacy against adefovir-dipivoxil-resistant HBV mutations. Antiviral ther 2012 17 5 793 803 38 Belloni L Li L Palumbo GA Chirapu SR Calvo L Finn M HAPs hepatitis B virus (HBV) capsid inhibitors block core protein interaction with the viral minichromosome and host cell genes and affect cccDNA transcription and stability. AASLD Liver Meeting 2013 Abstract 138 39 Lam A Ren S Vogel R Inhibition of hepatitis B virus replication by the HBV core inhibitor NVR 3-778. AASLD Liver Meeting 2015. San Francisco November 13-17, 2015 Abstract 33 40 Gane EJ Schwabe C Walker K Flores L Hartman G Klumpp K Phase 1a safety and pharmacokinetics of NVR 3-778, a potential first-in-class HBV core inhibitor. AASLD 2014 LB 19 41 Gane EJ Lim YS Gordon SC Visvanathan K The oral toll-like receptor-7 agonist GS-9620 in patients with chronic hepatitis B virus infection. J Hepatol 2015 63 2 320 8 25733157 42 Rebbapragada I Birkus G Perry J Molecular determinants of GS-9620-dependent TLR7 activation. PLoS One 2016 11 1 e0146835 26784926 43 Al-Mahtab M Bazinet M Vaillant A Effects of nucleic acid polymer therapy alone or in combination with immunotherapy on the establishment of SVR in patients with chronic HBV infection. J Clin Virol 2015 69 228 44 REP 2139-Ca / Pegasys™ combination therapy in hepatitis B / hepatitis D co-infection 2015 U.S. National Institutes of Health ClinicalTrials.gov Available from: clinicaltrials.gov/ct2/show/NCT02233075 45 Vörös J Urbanek A Rautureau GJP Large-scale production and structural and biophysical characterizations of the human hepatitis B virus polymerase. J Virol 2014 88 5 2584 99 24352439 46 Li C Wang Y Wang S Wu B Hao J Fan H Hepatitis B virus mRNA-mediated miR-122 inhibition upregulates PTTG1-binding protein, which promotes hepatocellular carcinoma tumor growth and cell invasion. J Virol 2013 87 4 2193 205 23221562 47 Fan CG Wang CM Tian C Wang Y Li L Sun WS miR-122 inhibits viral replication and cell proliferation in hepatitis B virus-related hepatocellular carcinoma and targets NDRG3. Oncology Reports 2011 26 5 1281 6 21725618
PMC005xxxxxx/PMC5119578.txt
LICENSE: This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. 101253275 36512 Asian Med (Leiden) Asian Med (Leiden) Asian medicine (Leiden, Netherlands) 1573-420X 1573-4218 27885323 5119578 10.1163/15734218-12341360 EMS70401 Article Contested Issues of Efficacy and Safety between Transnational Formulation Regimes of Tibetan Medicines in China and Europe Schrempf Mona University of Westminster m.schrempf@westminster.ac.uk 17 11 2016 2015 22 11 2016 10 1-2 273315 This file is available to download for the purposes of text mining, consistent with the principles of UK copyright law. Tibetan medicines are key material objects for medical treatment and have become part of a global trend of ‘pharmaceuticalisation’, playing increasingly important political and socio-economic roles in an ‘alternative modernity’. As I argue in this paper, they also have become key ‘sites of contestation’ between different epistemic values and styles of practice related to efficacy and safety that are reproduced in and through specific formulation regimes. Based on my multisited ethnography of production, prescription, and use practices of Tibetan medicines in China and Europe, this paper conceptualises three distinct formulation regimes, offering a heuristic model for transnational comparison—a classical, an industrialised or reformulated, and a polyherbal regime. The first two are the major orientations while the polyherbal is a conjoint hybrid with either the classical or the industrialised formulation regime. Globalised national drug safety regulations legalise and confer legitimacy to industrialised Tibetan formulas that follow biomedically defined efficacy, safety, and disease categories, while classical formulas produced by private physicians or small-scale cottage pharmacies are increasingly marginalised as producing ‘unsafe’ and at times illegal medicines, and need to find new ways for adapting and circulating their formulas. Tibetan medicines transnational formulation regimes efficacy safety legality China Europe Introduction Tibetan medicines are key material objects for medical treatment and have become a key ‘site of contestation’ among different stakeholders in a global trend of ‘pharmaceuticalisation’.1 While Tibetan medicines have taken on ‘social lives’ of their own in various formulations,2 as patent industrialised pharmaceuticals they also play increasingly important socio-economic and political roles in a global ‘alternative modernity’.3 This development is particularly salient in China and also in Europe where growing pharmaceutical industries produce standardised, quality-controlled, industrialised Tibetan drugs based on particular ‘reformulations’ of classical multicompound formulas successfully tapping into national, increasingly globalised niche markets of ‘natural’, ‘alternative’, or ‘integrative’ medicine.4 At the same time, classical Tibetan formulas are exclusively prescribed and often still produced by private physicians trained in ‘Tibetan medicine’ (Tib. bod sman) alias Sowa Rigpa (Tib. gso ba rig pa), commonly translated as the ‘science of healing’,5 diagnosing and treating their patients according to fundamental Tibetan medical principles in relation to the disease-causing imbalance in the individual patient’s body and mind. Most physicians of Tibetan medicine (called henceforth tm physicians) practice within rural Tibetan or Himalayan communities in Tibetan populated areas of China (Tibet Autonomous Region tar, Qinghai Province, Gansu Province, Sichuan Province, Yunnan Province), in Indian exile and in the historically influenced spheres of Tibetan culture of the Himalayas (Ladakh, Nepal, Bhutan), as well as in Mongolia, and Buryatia. The globalisation of Tibetan culture and religion, more recently propelled by exile-Tibetans in or from India, has also fostered the transnational movements of physicians and medicine(s). Individual tm physicians, most of them from India (fewer directly from China), were able to establish themselves in private clinics or as teachers in Europe or America. Some are also itinerant visitors prescribing classical Tibetan formulas that are circulating within specific transnational therapeutic networks. I argue in this paper that in contrast to classical Tibetan formulations, ‘modern traditional’, industrialised medicines targeting conventional diseases and a clientele outside of the Tibetan cultural sphere, tend to become ‘independent’ of the Tibetan medical knowledge system. They are mostly prescribed by biomedically trained physicians, those of ‘complementary and alternative medicine’ (cam) or ‘traditional Chinese medicine’ (tcm), and are marketed for niche markets of ‘natural’ or ‘herbal’ medicines in China and Europe.6 In other words, symptoms and diseases are diagnosed and configured according to biomedical parameters, such as diabetes, cardio-vascular, digestive, or stress-related disorders. Testing and validating clinical efficacy and safety of branded Tibetan pharmaceuticals for such symptoms and diseases is primarily done via ‘randomised controlled trials’ (rct), while some clinical studies in both Europe and China additionally included Tibetan medical diagnostics.7 In China, however, conspicuously more heterogenous regimes are followed in such rcts, including a ‘syndrome’ or ‘pattern differentiation’ (Ch. bianzheng 辩证) modelled on tcm. Similarly, Good Manufacturing Practices (gmp) employed to produce industrialised Tibetan pharmaceuticals follow the tcm drug regime and are often perceived as incompatible with Tibetan medical values of efficacy.8 These new producers, prescribers, and markets follow the global ‘scientific evidence’ and pharmaceutical research validation regimes; they have thus reconfigured what is considered efficacious and safe, legal, and legitimate in Tibetan medicine(s) even though most of their parameters are based on biomedicine. Such industrialised Tibetan medicines are, in turn, legalised by national (globalised) drug regulations and laws. Together with national regulatory regimes and the ever-growing, global wellness market these ‘pharmacoscapes’,9 as I argue in this paper, at the same time reinforce the marginalisation and, one could add, the making dispensable of the formula-producing and/or individually prescribing physician of Tibetan medicine, known as amchi (Tib. e mchi) or menpa (Tib. sman pa) and of his personal localised knowledge. Those who still have learnt how to produce Tibetan formulas on their own from their teachers in so-called teacher-student lineages, menpa gyüpa (Tib. sman pa rgyud pa), are classically trained tm physicians and mostly senior menpa or amchi. They use their skilled sensory abilities based on the five elements—water, earth, fire, air, space—that manifest not only in the environment but specifically in plants and the human body. While I will explain the principles of the classical formulation regime later on, it is important to note that physician-cum-pharmacists are personally known and highly esteemed by colleagues and patients for producing effective medicines; in fact, their renown is often based on this.10 Institutionalised education, in contrast, tends to separate and specialise training in Tibetan medicine in either physician or pharmacist training, thereby decoupling skills that are important for a fine-grained prescription practice. In contrast to the knowledge and experience for making medicines that are located in the personal skills of the tm physician, industrialised Tibetan pharmaceuticals locate and encapsulate an objectified ‘scientific’ knowledge within the materiality of the industrialised formula per se. It seems to embody ‘the best’ of both Tibetan and bio-medicine, i.e. bioscientifically valorised efficacy and safety based on the ‘traditional’ efficacy of Tibetan formulas tested to heal internationally and biomedically defined diseases.11 The scientisation of the formulas enables and legalises the producers of Tibetan pharmaceuticals to commercialise them in larger medical fields of biomedicine, cam, or even tcm settings in China or Europe. In Europe, and increasingly so in China as well, private physicians-cumpharmacists of Tibetan medicine have to find innovative ways in order to ensure that they can continue to produce their own formulas or have access to those which they trust to be produced in such a way as to ensure their maximum efficacy and safety. In contrast to the pharmaceuticalisation of Tibetan and Asian medicines more generally, little attention has so far been paid to how these recent socio-political and economic developments have contributed to asymmetrical shifts in power, legitimacy, and legality in the diverse transnational landscapes in which Tibetan medicine is practised today.12 Little is also known on how these changes have impacted the production and prescription of classical Tibetan formulations directly or indirectly, as well as on therapeutic practices of Tibetan medicine more generally in both China and Europe. In order to better understand these shifts from the perspectives of the different stakeholders involved, I examine and compare the production, prescription, and use of Tibetan medicines in situated contexts and in relation to their respective national regulatory regimes in China (specifically Tibetan-populated areas of Qinghai Province, known among Tibetans as Amdo) and Europe (Switzerland, Germany).13 Based on my multisited ethnography, this transnational macro-perspective consists in a heuristic model of three distinct formulation regimes that exist in parallel and partly in hybridised form—a ‘classical’, a ‘reformulated’, and a ‘polyherbal’—that I developed out of my fieldwork data.14 This study is following up on the ‘materiality of drugs’ in the anthropology of pharmaceuticals focusing on Tibetan medicines.15 It has in particular profited from comprehensive academic work undertaken on transnational studies of Asian medical practices,16 the emergence of the Tibetan pharmaceutical industry in China and the ‘social ecologies’ in Tibetan medical practices, examining the multivalent practices of efficacy and safety, including issues surrounding gmp, in China, Nepal, Tibet (tar), and Qinghai Province.17 The globalisation of Tibetan medicines has been directly addressed as a topic,18 as well as the multiple perspectives and practices of Tibetan medicine related to efficacy in the broadest sense, and to science and religion.19 Before I explain in more detail the different formulation regimes and who their major stakeholders are, I briefly outline the salient regulatory frameworks in both China and Europe that have shaped the way in which these formulations are produced in various ways. The Changing Landscapes of Tibetan Medicine in China and Europe In China, from about the mid- to late 1970s onwards, Tibetan medicine was slowly ‘integrated’ or rather institutionalised and transformed into a state-supported ‘nationality medicine and pharmacy’ (Ch. minzu yiyao 民族医药)20 with the intitial aim to provide primary health care to rural Tibetan areas.21 Deng Xiaoping’s reforms opened up the possibility for physicians of Tibetan medicine who had survived the Cultural Revolution (1966–76) to be retrained as ‘barefoot doctors’ (Tib. rkang rjen sman pa) and learn some of the basics of Chinese biomedicine, such as giving injections for administering antibiotic drugs. The latter is still common practice in most Tibetan medicine clinics and hospitals.22 tm physicians initially received small township posts and were thus integrated into local government health systems in Tibetan populated areas. Producing again their own classical formulas, often with the help of a growing number of students, was usually the only medicine available. Many of these physicians stayed in government health posts, while some opened private clinics. From the early 1980s onwards, Tibetan medical hospitals with attached pharmaceutical departments were built up in Tibetan populated areas of China that started to use mechanised production techniques in order to cater to the growing demands of their patients. As Saxer argues, these were the first steps leading to industrialised Tibetan medicines in China.23 At the same time, classically trained senior physicians became the teachers for a new generation of students of Tibetan medicine. Initial training courses based mainly on the Gyüshi were later incorporated into newly established Tibetan medical departments or schools as part of university medical school curricula. From the 1990s onwards, these were increasingly based on new textbooks. Also, national pharmacopoeias were produced to comply with state efforts to integrate Tibetan medicine and drugs, at times were rather hastily incorporated into Tibetan drug standards, with monographs on common ingredients and over 200 formulas. Also a provincial Qinghai pharmacopoeia was created.24 About a decade later they were integrated into the Drugs Standards of the Ministry of Public Health of the People’s Republic of China and the Pharmacopoeia of the People’s Republic of China.25 From the late 1990s onwards, and following the privatisation of public health services and the new food and drug policies on the production of medicines in China in 2001, the pharmaceutical industry of Tibetan medicines started to boom.26 An increasing ‘scientification’ and commodification of Tibetan medicines also began to impact the curricula and medical practices as taught in governmental tm schools and at hospitals, in particular the increasing professionalisation and thus separation of a training as physician and as pharmacist, happening in parallel to, and obviously catering to, the growth of private pharmaceutical enterprises and their markets needing specialised personnel.27 Several former pharmaceutical departments of hospitals of Tibetan medicine became private enterprises in Tibetan populated areas of China. In Europe the 1960s witnessed the very beginnings of Tibetan medicine, following the first exodus of Tibetan refugees from India arriving in Switzerland, among them also some Tibetan physicians.28 While already a century earlier the physician family lineage Badmayev, originally from Buryatia, had opened up Europe’s first Tibetan medical clinic in St. Petersburg, it was the decisive encounter between Tsultrim Badma’s grand-nephew Dr Peter Badmayev and the Swiss pharmacist Karl Lutz who had a strong interest in Tibetan medicine that triggered the making of new Tibetan pharmaceuticals in Europe based on recipes from this Buryat physician lineage. After establishing an international study and research group in Zurich on Tibetan formulas using different classical Tibetan texts and sounding out their potential applications in the West including some trials with herbal pills among Swiss physicians, Karl Lutz founded the Padma ag in 1969. The first Tibetan pharmaceutical, Padma Lax, was registered with the Swiss drug regulation agency (today Swissmedic) in 1970, followed by the flagship formula Padma 28 seven years later.29 Still, Padma had to develop an elaborate network of distribution pathways between cantonal, national and international borders in order to be able to distribute their products in Switzerland and beyond. Only from about the mid-1990s onwards were exile-Tibetan physicians able to establish their first clinics or schools in Europe.30 Nevertheless, and unlike tcm, until today Tibetan medicine lacks an officially acknowledged status as an Asian medical system in Europe. This has also consequences for the practice of Tibetan medicine. An incisive regulatory law that affected the import of Asian medicines in 2001, the same year that China’s regulatory agencies employed the demand for gmp, was the European Union-directive 2001/83/ec. It was implemented by the European Parliament and the Council, requiring ‘traditional herbal medicinal products’ (thmp) to comply with globalised gmp quality standards and a scientific evaluation regarding efficacy and safety via clinical studies.31 Even though the later amendment of the eu directive 2004/24/ec has skipped these regulatory challenges, it insists on compound herbal formulas needing to be licenced by a Market Authorization (ma) or a Traditional Herbal Registration (thr). A thmp—strictly excluding metals and animal ingredients—is now required to demonstrate: bibliographical or expert evidence to the effect that the medicinal product in question, or a corresponding product has been in medicinal use throughout a period of at least 30 years preceding the date of the application, including at least 15 years within the Community.32 Schwabl and Vennos, working for and at the pharmaceutical company Padma ag, the sole producer of about 11 formulas of Tibetan medicines and dietary supplements in Europe, recommend to amend the strict rule of 15 years of documented use, since otherwise ‘European citizens will be excluded from access to high quality medical traditions with their accumulated empirical knowledge’.33 As Gerke points out, European legislation already impacts the production of Tibetan ‘dietary supplements’ and ‘health tonics’ in India, allowing for their access to the European market.34 Private physicians—if they fully want to practice Tibetan medicine in Europe—usually find Tibetan medicines as produced by Padma ag too limited and also too expensive. On the other hand, the import of Tibetan classical compound formulas into the European Union from Asia remains a difficult issue. Physicians need to be innovative in their prescription practices, and how they access medicines due to shortage of classical formulas, and having to avoid border controls. Nevertheless, in the eyes of most practising tm physicians, no matter whether in Europe or in China, these medicines are a necessity for efficacious and safe healing. Their use also keeps the costs of medicines low for their patients and allows for their own small profit margin. In Europe, tm physicians now charge for their diagnostic skills which in many rural settings in Tibetan cultural areas were not remunerated. In the past and at present, however, classical formulations of Tibetan medicines build the very basis for the economic and professional survival of tm physicians. In Europe classical Tibetan formulas circulate under the radar of eu regulations mainly within the personal therapeutic networks of some tm physicians with relation to both India (or Nepal) and Europe. The one notable exception is the certification of physicians of Tibetan Medicine under the regulations of ehtpa (European Herbal Traditional Practitioners Association) in the uk. It allows physicians trained in Asia to practise prescribing herbal formulas that, following tcm-modalities, need to be imported as quality-controlled single ingredients that are compounded at the time of consultation for each patient.35 Transnational Formulation Regimes in China and Europe Moving on from nationally specific regulatory regimes, we broaden our view to transnational and analytic domains. I distinguish between three distinct formulation regimes—a ‘classical’, a ‘reformulated’, and a ‘polyherbal’. These three formulation regimes are often hybridised and reconfigured in, as well as circulated through, distinct social networks of producers, distributors, physicians, and patients in both China and Europe and at different scales. To illustrate this, in the diagram above (Fig. 1) I have used vector-type arrows indicating both the relative coherence as well as dynamic flexibility of Tibetan medical production, prescription, and use practices that are ongoing in and between these three formulation regimes. These formulation regimes are conceptualised both as analytical tools and as major orientations for practices in which specific epistemes of efficacy and safety prevail and thus will structure this paper. They serve as primary orientations in relation to the production, prescription and use of Tibetan medicines involving different groups of actors and a range of dynamic practices that co-exist in various forms. While classical formulations are the foundation of the other regimes, the primary tension, as I argue in this paper, lies between the two major orientations—the classical and the industrialised reformulation regime. The various actors involved in these formulation regimes orient themselves primarily towards culturally distinct sources and values of authenticity, legtimation, and trust that hinge on predominant values of efficacy and safety produced and reiterated through these regimes. The third regime, the polyherbal, is a conjoint hybrid with either the classical or the industrialised reformulation as primary orientation. The classical formulation regime is neither a uniform practice nor a thing of the past. It is (and always was) dynamic and needs to be adapted to local environments, availability of formula ingredients and, in modern times, also to changing regulations. It remains the primary orientation among physicians trained in Tibetan medicine following the fundamental principles of their living tradition. The classical formulation regime also shows the strongest continuity with those premodern practice environments that we know have existed within living memory, as well as how they used to be before the Cultural Revolution in China. I agree with Blaikie that we must critically assess the ‘classical’ as a heterogenous and fluid, rather than homogenous, category and stress its dynamic character.36 Yet, as I argue, the classical formulation regime coalesces as a rather coherent practice, one based upon Tibetan medical principles with particular actors, practices, and identities attached to it and characterised by predominant sets of epistemic values of efficacy and safety that are very different from the industrialised regime. The classical formulation also builds the very basis for the professional and economic survival of physicians fully trained in Tibetan medicine and the Tibetan medical system at large, as I will demonstrate. The reformulation regime, in contrast, is employed by a very different set of actors—pharmaceutical factories, mainly physicians trained in biomedicine, cam, or tcm, and targeted consumer markets of an alternative medicine. This regime is built upon what Pordié and Gaudillière have coined a ‘reformulation’ for ayurvedic pharmaceuticals in India, defining it as being based on ‘what its actors call “reverse engineering”’.37 They describe innovative ways by which the ayurvedic herbal industry transforms ‘shastric’ (or classic) polyherbal formulas for massproduction according to gmp, and for targeting biomedical disease categories conforming to the pharmaceutical market.38 I adopt their term for the reformulation regime of industrialised Tibetan pharmaceuticals that are produced in China and in Europe because they conform pretty much to the same set of globalised regulations.39 In Europe, however, the regime is much more strictly implemented, and not only includes gmp but generally ‘good practice’ standards.40 Also, the outcomes of clinical studies, including rcts, conducted in China for validating efficacy and safety of Tibetan pharmaceuticals are often not verifiable or useful.41 More than half of the rcts carried out to test Tibetan industrialised patent medicines were conducted in China’s biomedical hospitals, while only 22.9 % were undertaken in Tibetan medical hospitals. Biomedical disease categories, such as diabetes, or simple symptoms, were mainly used as indication factors, supplemented by some ‘traditional Tibetan medicine’ (ttm), as well as tcm ‘syndromes’ or ‘pattern differentiation’.42 Also slightly opaque is the fact that, even though patent or branded Tibetan medicines fall under the category of ‘Chinese new herbal medicines’,43 this merely seems to be an official statement following the nationally adapted category of ‘traditional medicines’ influenced by the who definition.44 Moreover, in China and among physicians of Tibetan medicine, the famous ‘jewel pills’ or rinchen rilbu (Tib. rin chen ril bu) are highly esteemed as being the most effective Tibetan formulas. Despite the fact that they contain ‘purified mercury’ tsotel that is excluded as heavy metal or toxic material in the Pharmacopoeia of the People’s Republic of China, they are also produced as industrialised patent medicines. This demonstrates one of several blind spots that in this case are covered under the label ‘national heritage drugs’.45 Also, animal ingredients characteristic of the Tibetan Plateau ecology are excluded from this official Pharmacopoeia, yet in several classical Tibetan formulas they are important and used because of their special efficacy, as I will show below in the case of musk. Animal ingredients are generally maintained within both classical and reformulated formulations in China. Therefore, and in contrast to Pordié and Gaudillière’s definition, I separate the industrialised reformulation from the polyherbal regime. Thus, the third polyherbal regime primarily concerns the exclusive use of usually at least five different herbal ingredients. It is slightly different in character from the two other major regimes because it is primarily oriented towards the ingredients being only herbs and some minerals. The polyherbal regime is a hybrid per se, one that merges either with the classical multicompound formulation into formulas that are produced and prescribed by physicians of Tibetan medicine in India and in Europe,46 or that merges with the reformulation regime being produced as a multicompound pharmaceutical, such as the Tibetan medicines and supplements produced by the Padma AG in Switzerland for Europe.47 Concerning the polyherbal regime, I adapted Naraindas’ analysis of a creole formulary logic of herbal ayurvedic pharmaceuticals in India to my transnational material in a different way. He distinguishes between three forms of logic that are hybridised in specific ways—a ‘biomedical formulary’, that is based on an active ingredient (or the synthesis of several) and a specific (biomedical) cause of disease, the multicompound ‘polyherbal formulary’ of the West with an underlying biomedical nosology, and the ‘ayurvedic formulary’ based on the classical shastra literature.48 However, rather than separating the biomedical from the classical (or shastric) as a distinct form of an industrialised ayurvedic formulary logic, I understand the three formulation regimes of Tibetan medicines in the contexts of China and Europe as transnational orientations driven by particular actors, and in which different epistemic values of efficacy and safety as well as medical principles are in use. At the same time biomedical and Tibetan medical notions and practices are negotiated in each of these regimes in specific ways. In Europe, herbal medicines have a long history of traditional therapeutic use. According to the European directives following who-regulatory regimes of ‘traditional medicines’ they should only contain herbs. Furthermore, cites-regulations to protect endangered animal and plant species49 are strictly followed in Europe, reinforced by rigorous documentation of sourcing and enforced legal penalties. In India, these regulations are known and applied to classical formulations by mostly exile-Tibetan physicians and/or pharmacists within the context of the Tibetan Medical and Astro Institute (tmai) in Dharamsala, better known as the Men-Tsee-Khang. However, because Tibetan medicines are not yet produced as industrialised pharmaceuticals following gmp in India, the extent to which these regulations are actually followed and by whom remains to be researched. The two major formulation regimes, the classical and the reformulated, also have the tendency to evoke as well as reiterate what Ian Hacking has defined as a ‘style of practice’.50 I differentiate between two major styles of practice in close relation to the classical and reformulated regimes, respectively. The first is a sensory based, personalised, complex diagnostic and prescription style following the fundamental principles of Tibetan medicine as defined in the classical formulation regime, and according to the constitution and imbalance of the ‘bodily dynamics’ nyépa (Tib. nyes pa) of each individual patient. The second is a one-formula disease-centred style, centring on one particular formula produced by pharmaceutical companies with standardised biotechnologies, and tested to target and cure a specific, usually biomedically defined disease.51 Interestingly, both styles are also found with regard to the application of certain formulas in historical Tibetan medical texts. For example, specific formulas for treating wounds or particular organs, such as eye medicines, are administered beyond a specific patient’s imbalance.52 The Classical Formulation Regime The classical formulation regime is clearly characterised by the fundamental Tibetan medical principle of five elements (Tib. byung ba lnga) that make up all phenomena in the universe. As expounded in the Tibetan classical medical text, the Gyüshi, the five elements manifest in plants and other materia medica as the ‘six tastes’ (Tib. ro drug), the ‘eight potencies’ (Tib. nus pa brgyad), and the ‘three post-digestive tastes’ (Tib. zhu rjes gsum) as well as the 17 ‘attributes’ (Tib. yon tan bcu bdun).53 These criteria are used for identifying single materia medica and compounding medicines. The five elements also make up the ‘three bodily dynamics’ or ‘three faults’ nyépa sum (Tib. nyes pa gsum) in the human body.54 Together, taste, potency, and post-digestive taste constitute the ‘benefit of effect’ (Tib. phan nus)55 for the overall efficacy of a specific formula. The Fourth or Subsequent Tantra (Phyi ma’i rgyud) of the Gyüshi clearly describes taste as the central sense for evaluating the material efficacy of raw medicinals, in order to validate their maximum ‘natural potency’ (Tib. ro nus). This means learning how to utilise the senses—taste, touch, smell, hearing, and vision—for differentiating and recognising the material quality and efficacy of materia medica (Tib. rdzas gyi nus pa). This is combined with the ability to diagnose the patient’s disease and underlaying individual imbalances via pulse, urine, and visual check-up, including investigation by questioning the patient on the onset and development of the disease. The classical formulation regime therefore implies a sensory-based, personalised prescription style. The natural potency of medicinal plants that are either imported from Himalayan, Indian, and Chinese environments, or growing in the wild on the Tibetan Plateau, is dependent upon the so-called ‘seven limbs’ (Tib. yan lag bdun) used as the traditional gold standard for ensuring their efficacy and safety. Knowing when and where to collect the most potent plants, which part of the plant should be used, how to collect, clean, detoxify, and store them properly, as well as knowing how to compound them for individual patients, constitutes the art by which a medicine-producing physician personally ensures efficacy and safety. The physician-pharmacist stands in the centre of the classical formulation regime of Tibetan medicine. Efficacy and safety are primarily connected within the physician’s knowledge and experience in diagnosing and prescribing, and also compounding medicines in a personalised style. While I have so far focused on the materiality of drugs, their efficacy extends of course into the immaterial sphere as well. Additional sources of efficacy in the classical formulation can include tantric ritual empowerment of medicines mendrub (Tib. sman grub). For example, small quantities of formerly blessed medicines are used for empowering new medicine production, and these embody a physician-cum-pharmacist’s lineage.56 Even within modern medical institutions, such as Tibetan medicine hospital pharmacies, where such practices are out of place on a formal level, senior physicians ensure, if necessary through private practice, the ritual empowerment of medicines used to treat their patients more efficiently. Among physicians of Tibetan medicine and their patients, these empowered medicines are perceived of as the only ‘true’ (Tib. ngo ma) ones in the sense of them being authentic and more efficacious. They are often juxtaposed with industrialised pharmaceuticals that are—depending upon the producer57—perceived of as being ‘fake’ (Tib. rdzun ma) by comparison.58 To illustrate the classical formulation regime and its relation to these fundamental principles, I now offer three ethnographic examples from Amdo, Qinghai Province. Already back in 2005, Ani Khandroma, a petite and delicate-looking, yet very energetic and self-assured 68-year-old female physician of Tibetan medicine from Amdo, felt the deep rift widening between what she called ‘old’ and ‘new’ practices. She was a famous tantric chö (Tib. gcod) practitioner, and had learnt Tibetan medicine back in the 1950s directly within a personal master-disciple apprenticeship in her home place of Rebgong (Tib. Reb gong, Ch. Tongren 同仁),59 a local centre of Tibetan medicine in Amdo.60 After the Cultural Revolution, she was able to continue her practice again, and succeeded in building up a specialised private clinic for women’s diseases—her main field of expertise—with medicinal baths near Chabcha (Tib. Chab cha, Ch. Gonghe 共和).61 With an awe-inspiring, slightly intimidating, and matter-of-fact manner of speaking, she was determined to tell me first what she thought of contemporary Tibetan medical practice in Qinghai: ‘It’s all modern these days. Even in private clinics of Tibetan medicine, they practise the modern way.’ She elaborated: In the (old) days, medical knowledge was different—lots of seeds and leaves were dried separately in the sun. There were no students, and no hospital. The ‘modern way’ is too fast, too big,62 and not careful enough. Yet, everything is medicine—it just depends on the quality, and the amount and the sequence of mixing—like cooking, really. This is the old way; it is basically not practised anymore.63 She pointed out that these old ways of knowledge were the most effective, something many private physicians of Tibetan medicine also stressed during my enquiries. For example, in the past physicians would only administer enough medicine for three days. If the patient was not better by then they were convinced they could not treat the patient, implying that their medicines were so strong and effective that of course they should have healed the patient within that time. Ani Khandroma used to produce her own medicines until 1958. This was the most decisive year of twentieth-century history in the lives of Amdo Tibetans, the threshold that sharply divided the ‘old’ Tibetan society from the ‘new’ one that was strongly influenced by Chinese modernity. Ani Khandroma continued: It is also important to know how to clean the medicinal ingredients properly, how to dry and store them, such as knowing whether to put them into a wooden container or into an animal skin pouch—which has a different effect. All this knowledge is gone these days. She reaffirmed that she kept her ‘women’s medicines’ in special animal skin pouches, which are the best for this purpose (see also Fig. 2).64 Interrupting her explanations all of a sudden, and with a challenging look on her face, she asked me what seemed to be a leading question, ‘What do you think is the most important thing in healing, the right diagnosis or the right medicine?’ I answered diplomatically that I think both would be important, but she interjected, ‘No, no, to diagnose correctly is the most important! You can heal in so many ways, even without medicines. Yet without the right diagnosis, medicine is useless and can even be harmful’. Ani Khandroma’s statement made me think that this kind of endangered knowledge might capture the actual core of any kind of efficacy and safety in healing. Change of scene. Moving out of Xining and travelling through rural Amdo, the area of Qinghai Province where Tibetan nomadic and farming communities live on the Tibetan Plateau, I also met a locally well-known, private physician who still handcrafted his own medicines. Based on his own experience and that of his patients, he stressed the importance of ‘true’ or ‘real’ efficacy: I will give you an example. Patients come to me and claim that Tibetan medicine does not work. Of course that is not true in general. They show me the medicines they purchased and were taking, and I check them by tasting them. Factory-produced Agar 35 is never as effective as when I produce it myself—the factory owners cut corners where they can, so will not use the most potent, rare but also expensive best quality of ar nag.65 They will substitute it with another cheap ingredient or won’t even realise that they bought a ‘fake’ ingredient.66 This local physician from a nomadic area was renowned for producing very efficacious medicines for his patients at a small rural clinic, where he kept his compounded powders safe in glass bottles on shelves. Some of his pills were packaged but only to ensure that they would not dry out. The local county government had asked him to move to the county town and into a local hospital of Tibetan medicine, in order to attract patients and make the place more popular. However, he did not want to move away from his own home and clinic, yet in the end had to comply. Nevertheless, he was able to bargain for a deal that allowed him to keep his private clinic (that otherwise would have been closed down if he had not consented) and occasionally work at the county hospital. Such recruiting is a practice often used by hospitals, at times even by Peoples’ Hospitals, which shows the social importance of locally known and trusted senior physicians of Tibetan medicine for attracting patients. Another example of using the classical formulation regime was found in a large and innovative government institution, the Tibetan Medicine Hospital of Qinghai Province (Tib. Mtsho sngon zhing chen bod sman khang; Ch. Qinghai sheng zangyiyuan 青海省藏医院) in Xining City (西宁市), which below I will refer to simply as the Qinghai Tibetan Hospital. It is considered number one among ‘seven most productive study centres’ of Tibetan medicine in China.68 Founded in 1983, the Qinghai Tibetan Hospital includes biotechnological diagnostic features and a general organisation into specialised departments similar to a biomedical hospital. It maintains Good Clinical Practices (gcp) standards, being the only hospital in Qinghai with such a high status. Somewhat ironically, the Qinghai Tibetan Hospital mainly conducts clinical research and studies on biomedical and tcm drugs, rather than Tibetan pharmaceuticals.69 Only very few studies at this institution were able to examine the efficacy of classical Tibetan formula because they lacked both the interest and money of large pharmaceutical factories usually sponsoring such studies. Despite all these modern biotechnological influences, Qinghai Tibetan Hospital has a pharmaceutical department that is primarily oriented towards the classical formulation regime.70 This department prides itself on being based upon lineage knowledge. This is due to its co-founder, the 84 year-old Dr Nyima, the most famous senior physician at the Qinghai Tibetan Hospital.71 Over the years, he had built up this pharmaceutical department on the basis of his personal knowledge in materia medica and formula production. Dr Nyima still personally tastes the quality of all the medical ingredients that arrive at the hospital’s pharmaceutical department, in order to check their quality and potency. He was also recently awarded the title of a knowledge holder of an intangible cultural heritage item of Tibetan medicine known as sertel (Tib. gser thal), a specific efficacy-enhancing practice employed for making certain jewel pills. In fact, the pharmaceutical company Arura Tibetan Medicine Co. Ltd. (Ch. Qinghai Jinhe zangyao gufen youxian gongsi 青海金诃藏药股份有限公司), that had evolved out of the pharmaceutical department of the Qinghai Tibetan Hospital, and that produces reformulated Tibetan medicines, had applied for his acknowledgment.72 Pharmacists at the respective Qinghai Tibetan Hospital department proudly refer to Dr Nyima as the ultimate authority and perceive themselves as followers of his lineage. Dr Nyima still practises as a physician three days a week, diagnosing and treating on average more than 60 patients per day. He is also often addressed by younger or less experienced physicians at the hospital, as a last resort for helping to treat difficult cases. Dr Nyima’s unique knowledge is based on his immense experience of many decades treating thousands of patients. He also possesses the unique skill of adjusting formulas via kha tshar, a specially potent and efficacious practice that uses the ‘add-on’ of a single ingredient to an established base formula. Such add-ons can target a specific organ, for example, the cooling effect of gur gum (L. Crocus sativus) targets both heat and liver in ‘hot’ liver disorders. It is also used as an add-on together with the digestive base formula Sendu 4, which thus becomes Sendu Drangné, which is suitable to warm the stomach and kidneys, but at the same time does not overheat an (already ‘hot’) liver.73 If several prescribed formulas share the same ingredient(s), this can increase their specific potency, but also increase their effects too much. For these cumulative effects to be balanced properly, the physician must compound his own formula in powder form, and know the exact dosage of each single ingredient within a set formula, in order to increase or decrease the dosage of a single ingredient precisely. Only a few senior physicians of Tibetan medicine, such as Dr Nyima, still know how to do this properly. To ensure the highest efficacy of treatment in more difficult patient cases, a complex style of prescription practice is used at the in-patient ward of the Qinghai Tibetan Hospital in Xining. In those cases, at least five different formulas are usually prescribed five times a day. Adjustment of dosage and medicines, if necessary, is undertaken based upon regular daily checks of pulse and urine, the dosage or type of formula being adjusted accordingly. Patient record keeping (Tib. nad tho) is meticulously maintained, as required of a government hospital. Some of it was written in Tibetan where pulse and urine diagnosis and Tibetan formulas were concerned, while technoscientific diagnostics, including blood tests, were written in Chinese. In the out-patient ward, patients would bring small patient booklets with them into which Tibetan formula names were written in Tibetan cursive script by Dr Nyima, while an assistant would type these Tibetan formula names into a computer that automatically translated them into Chinese drug names. Clearly, there are a wide range of practices adapted to a ‘Tibetan way of doing science’,74 each incorporated into what I call the classical formulation regime which constitutes the main framework in this example. Hybrid Classical-Polyherbal Formulations The ‘classical-polyherbal’ formulation is an important hybrid formulation based on very similar classical principles of Tibetan medicine for evaluating and ensuring efficacy and safety—yet with one crucial difference to those described above in that it completely excludes all use of animal products. This hybrid type of formulation among Tibetan medicines is mainly found in Europe and India. Polyherbal formulations have come to play an important role in meeting European and Indian patients’ dietary requirements, as well as their ethical and conservationist concerns. The main actors producing it are exiled Tibetan physicians-cum-pharmacists from India, some of whom also practise in Europe or whose products circulate in transnational therapeutic networks between the two regions. Although the Gyüshi does mention polyherbal formulations, historically Tibetan formulas based exclusively upon medicinal herbs (Tib. sngo sbyor) appear to have been rather limited to specific localities and their ecologies, and limited or no access to crucial animal ingredients. Blakie reports that, mainly for pragmatic and economic reasons, until the late 1970s some Ladakhi physicians who were still trained within family lineages used simple, locally available herbal ingredients and recipes inherited from their forefathers.75 More recently among exiled Tibetans in India, these classical-polyherbal formulations have become related to ethical concerns. In 2004, the pharmaceutical department of the Tibetan Medical and Astro Institute (tmai) in Dharamsala, India, better known as Men-Tsee-Khang, officially stopped using animal products at the behest of the Dalai Lama.76 Additionally, there are quite a considerable number of vegetarians among Indian and Western patients of Tibetan medicine. Thus, for ethical reasons formulas were adapted by substituting animal with plant ingredients of similar potency based upon the classical ‘taste’ ro criteria.77 Conservationist concerns regarding cites-listed endangered species were also taken up as necessary changes to be followed. The tradition of ahimsa or ‘nonviolence’, that some Hindus and Buddhists have aligned themselves to, conveniently converges here with dietary and conservationist concerns, as well as with the who’s definition of ‘traditional medicine’. The polyherbal regime also feeds into the ‘alternative’ modern sensitivities and consumerism of a global health-conscious urban elite concerned with lifestyle and disease-prevention by consuming health promoting, and at best vegan, ‘slow foods’, and dietary supplements including Asian herbal medicines. Nevertheless, as many physicians whom I had interviewed repeatedly stressed, due to the highly effective potency of certain animal ingredients, some are impossible to substitute. Not all tm physicians agree with compromising efficacy for reasons of ethics. The formula Agar 35, for example, contains musk or latsi (Tib. gla rtsi) in its classical formulation, and it is one of the most prescribed formulas in both Asia and Europe. The most potent and efficacious musk, however, comes from the wild musk deer (Tib. gla ba). Physicians of Tibetan medicine whom I have interviewed on this topic stressed conjointly that the potency and efficacy of wild musk is unsurpassed and that there is nothing more effective for treating inflammation. Thus, the farmed musk extracted from sedated animals produced by certain pharmaceutical companies in China, and which both government-run Tibetan hospital pharmacies and pharmaceutical factories in China are officially permitted to use, is not considered an equivalent substitution.78 This is an open secret among tm physicians in both Asia and Europe, but one not freely talked about due to conservation policies and ethical concerns. When I asked a senior tm physician from Amdo about polyherbal formulas, he laughed spontaneously, and said that such formulations would only be those used among poor farmer physicians who did not have the means to buy the very potent and also expensive animal ingredients (such as musk and bear bile) for making medicines. This echoes Blakie’s findings in Ladakh cited above and those by Craig in Nepal who also found a strong consonance expressed on amchi between ‘wildness’ and high potency of plants (and animals) more generally.79 In contrast to this statement, a senior tm physician from Indian exile was very upset when I even dared to question that the polyherbal formulation regime (presently practised) had ever been different in the past, and she denied outright the fact that classical Tibetan formulas can and do include animal ingredients. Clearly, experience, regulations, and ideology all play a role in formulation regimes, and constitute aspects of a physician’s medical and cultural-cum-ethical identity. In Europe, the late Akong Rinpoche, a famous Tibetan lama-physician from Kham, who had promoted Tibetan medicine within the uk as well as in his homeland for several decades,80 had specifically ordered the production of quality-controlled, polyherbal Tibetan medicines manufactured in Xining for consumption by Western patients in his Tara Clinics in the uk.81 The formulas used for this followed a little known formulary booklet written by the famous scholar Ju Mipham Jamyang Namgyal Gyamtso (’Ju mi pham rnam rgyal rgya mtsho, 1846–1912) that lists purely herbal formulas. Before production, Ju Mipham’s formulas were also screened in order to exclude or replace endangered plant species, targeting single ingredients that were cites-listed, and the formulas had to be adapted accordingly.82 To summarise, such polyherbal formulations are not necessarily new, but they have different implications today given the scaled up and more market-based nature of the industrialisation regime and its spillover effects on all of the others which will be examined in the following. The Reformulation Regime The Jinhe or Arura Tibetan Medicine Pharmaceutical Co., Ltd. based in Xining, Qinghai Province, mainly produces Tibetan pharmaceuticals for the Chinese market.83 A short glimpse into the recent past of this company shows that it developed out of the pharmaceutical department of the Qinghai Tibetan Hospital, following the socialist market reforms that triggered the decentralisation and privatisation of the public health sector in China. Since the early 1990s, with the help of its enterprising director Dr Ao, a Tibetan biomedical physician, Tibetan medicines have been produced for the larger Chinese market under the brand name of ‘Jinhe’ (金诃; ‘golden myrobalan’) or ‘Arura’. Arura (Tib. a ru ra) is the ‘king’ of medicinal plants in Tibetan medicine, being endowed with all six tastes, and derived from the Sanskrit arura classifying a specific myrobalan fruit (L. Terminalia chebula Retz). In 1999, the so-called Arura Tibetan Medical Group was founded, comprising the hospital, pharmaceutical factory, research department, college of Tibetan medicine, and a museum of Tibetan culture and medicine in Xining.84 As stated earlier, the year 2001 was decisive for the production of tm medicines in China, because the country entered into the World Trade Organization (wto), with gmp and a new drug administration law being introduced for validating the efficacy and safety of drugs primarily based upon biomedical parameters and modelled upon those used for tcm. While this exempted Chinese single ‘crude drugs’ from strict quality controls, Tibetan multicompound formulas that are already formulated as pills came under tighter control. From 2003 to 2004, the Arura pharmaceutical factory opened new premises complying with the latest gmp standards. Another decisive event occurred in 2010, when the gmp law was revised under China’s general gmp-standard regulations. In 2013, Arura was the first company in Qinghai to have obtained a gmp certificate under the revised Specifications for Quality Management of Drug Production (2010 Revision).85 Arura medical production combines technological know-how with ‘ancient’ Tibetan medical knowledge. Its products are encapsulated in shiny blister packages produced for the Chinese market, with indications written in Chinese. These indications at times resemble a hodge-podge of biomedical and Chinese medical terms that can more easily be understood by Chinese-speaking customers. These Arura products are taken directly as ‘over the counter medicines’ (otc), or can be prescribed by physicians not fully or at all trained in Tibetan medicine, and are thus much more versatile and commodifiable than ever before. The Arura Tibetan Medicine Co. Ltd has its registered production centre in Xining, while its marketing centre is located in Shanghai. The company has nearly 800 employees, over 200 shops throughout China, and maintains a complete R&D (Research and Development), production, marketing, and industrial chain. Using effective marketing, the Arura alias Jinhe Pharmaceutical Company has developed its own pharmacoscape in China, called ‘Jinhe Culture’ (Ch. jinhe wenhua 金诃文化). The first line one encounters on their Jinhe Culture website is a mission statement that could have come from the Men-Tsee-Khang in Indian exile, and where the stated aim is ‘to enhance Tibetan medicine, for the benefit of mankind’.86 Strategic objectives are stated more plainly, ‘to engage in the business of Tibetan medicine products’; ‘to expand the field of Tibetan medicine’,87 and ‘to cultivate the Tibetan medicine culture industry’. The Buddhist altruistic goal of doing things for the benefit of all beings is a well-known and oft-cited slogan which has become part of a Tibetan medical identity that Saxer has called the ‘moral economy of Tibetanness’, and one also shared by the Men-Tsee-Khang in Dharamsala, for example.88 Furthermore, Arura publically promote their own hybrid style of practice as innovative, technologically advanced, and combining global values of efficacy and safety—according to biomedical parameters—with Tibetan cultural patterns. The company has won several honorary titles, including ‘Chinese Famous Trademark’, ‘National Geographic Indications Protection Product’, ‘The Enterprise of National List of Intangible Cultural Heritage’, ‘National Contract Compliance Enterprise’, and ‘National Innovative Technology Enterprise’.89 Their website states: The company has 1000 types of products including drugs, supplements, caterpillar fungus,90 health products, daily-life regime, and external therapy for 6 types of categories. Of the 1000, 68 are nationally approved medicines with 21 ‘exclusive drugs’, 5 exclusive dosage forms, 10 medicines approved for reimbursement under national health insurance, 1 national essential drug, and 10 otc drugs.91 Agar 35 alias Sanshiwu wei chenxiang wan (三十五味沉香丸) or ‘Eaglewood Pill of 35 Tastes’ is promoted as an otc drug by the Arura Pharmaceutical Company, for example. It is a very popular Tibetan medicine prescribed by tm physicians in both Asia and Europe as well as taken in times of stress by patients directly. It is considered to be generally effective for stress-related symptoms, such as sleeplessness and concentration problems regardless of which underlying imbalances the patient has. It contains 35 mostly herbal ingredients with the primary one being eaglewood (Ch. chenxiang 沉香; L. Aquilaria agallocha).92 It also contains two animal products, ‘yak heart’ (Ch. yeniuxin, 野牛心) and ‘artificial musk’ (Ch. rengong shexiang, 人工麝香).93 tm physicians in Europe avoided the question of how these important animal ingredients are substituted while tm physicians and pharmacists in China pointed towards animal substitutions. The Hybrid Polyherbal Reformulation in Europe In Europe, the production of Tibetan pharmaceuticals and dietary supplements has been successfully established by the company Padma ag based in Switzerland, the sole pharmaceutical company producing Tibetan medicines in Europe.94 Despite the fact that Padma have only developed some 11 different polyherbal Tibetan formulas since the start of their production in 1970, Padma’s products are now the official legal face of Tibetan medicine(s) in Europe. Except for their specific formula composition, Padma’s Tibetan medical products are akin to other industrialised herbal remedies on the European market that fall under the rubric of traditional herbal medicinal products, with a standardised dosage and quality-controlled ingredients, and production methods following the pharmaceutical gold standard of good practice rules. The efficacy and safety of their products is clinically tested, and due to rcts, some of their products even attained the (biomedical) status of a ‘Tibetan medicine’ (German ‘Tibetisches Arzneimittel’).95 However, and similar to the reformulated pharmaceuticals produced by Arura for the Chinese market, Padma’s products are mainly prescribed by physicians of biomedicine and cam, or taken directly by patients as self-medication for common symptoms or often for chronic diseases that are difficult to heal and where use of biomedical pharmaceuticals can have side effects when taken longer term. Other Padma products circulate within a growing European cam and wellness consumer market as dietary supplements with low dosages and indicated by general symptoms. A side remark by an employee from Padma, plainly stating that such low dosage standard indications, as required by law for dietary supplements, tend to fail to be effective at all, aroused my curiosity. Consequently, I was supposed to ‘forget about proving the “efficacy” of Tibetan medicines’. The remark was meant to signify that at the time, when clinical trials were still a requirement for proving (biomedically validated) efficacy and safety of Padma’s products, it was a very lengthy, difficult and costly process to conduct rcts in the proper manner. Fortunately, this hurdle was overcome by the amended European directive of 2004. Depending upon a formula’s respective regime, and its legal status—and at times on any single ingredient within a given formula which might be classified as ‘toxic’ in a particular country of the eu, and also in Switzerland—its distribution may be officially restricted to cantonal or national borders. New pathways of circulation of products are international internet orders, yet again they become increasingly tricky to use due to border control regimes between countries. Even legalisation has its limits, it seems. Padma’s Tibetan polyherbal pharmaceuticals and dietary supplements do strictly comply with European legislations and international regulations of efficacy and safety. Thus, for example, one ingredient in the so-called Padma Nerves Tonic formula (‘Nerventonikum’), alias Sogdzin 10, a slightly adapted form of the classic formula Sogdzin 11 (Srog ’dzin 11), is omitted and not substituted for obvious reasons, since it is an animal product, i.e. rabbit’s heart. Schwabl and Vennos explain that because the European diet is already high in animal protein, the missing effect of this animal ingredient in their Tibetan formula is easily compensated or additionally supporting the overall warming effect of Sogdzin 10, counterbalancing the ‘cool’ nature of the disturbed ‘wind energy’ (Tib. rlung) by eating a meat bone soup instead. They elucidate the efficacy of Sogdzin 10 in both modern scientific terms of how it addresses stress systems by improving ‘better sleep’ and a ‘focused mind’, enumerating the single ingredients, in part their biochemical make-up but also their ‘Tibetan medical’ effects, such as nutmeg (Tib. dza ti) that ‘harmonizes the Lung [Tib. rlung] energy’.96 In particular, herbal ingredients that are endangered plant species listed in cites, even those of only doubtful botanical identity, are substituted in Padma’s formulations.97 Therefore, the generally endangered cites-listed species of eaglewood, in particular Aquilaria agallocha Roxb. (Tib. a gar; Ch. chenxiang) is substituted with guaiacum (Lat. Guaiacum sanctum L.), like eaglewood, an aromatic wood known as ingredient for incense but obtained from South America.98 According to Herbert Schwabl, director of Padma AG, guaiacum was already used as a substitute for eaglewood in the earlier Buryat recipes of the Badma family physicians that serve as basis for Padma formulas.99 Nevertheless, different species of eaglewood continue to be used in other classical eaglewood formulas in Asia, such as Agar 8, Agar 15, Agar 20, Agar 35, and Sogdzin 11. These formulas are all based on the root formula of Agar 8, and are usually prescribed for what according to Tibetan medical concepts is meant by an imbalance related to the ‘wind’ (Tib. rlung). From a Tibetan medical point of view, this concerns in particular the pathological ‘heart wind’ (Tib. snying rlung) and the ‘life-sustaining wind’ (Tib. srog rlung) that flows through the ‘life-sustaining channel’ (Tib. srog rtsa).100 In contrast to this classification, Padma Nerves Tonic (Sogdzin 10) is described by Padma AG in alternative medical terms simply as an anti-stress formula, and as having astringent and warming effects that strengthen the nerves and calm the mind: ‘It is used in the treatment of nervousness, irritability, restlessness, and nervous tension, as well as in difficulty falling asleep and remaining asleep’.101 Recently, Padma Nerves Tonic was evaluated with a positive outcome for similar symptoms related to menopause by the Institute for Naturopathy, University Hospital Zurich, Switzerland.102 Using scientific explanations for the overall synergistic ‘multitarget’ effects of the polyherbal classic Tibetan formulas, researchers associated with Padma stress a Tibetan formula’s ‘signature’ effects. ‘Signature’ is a characteristic cam term that is used to explain simultaneous ‘holistic’ effects that whole—rather than extracts from—medicinal plants can have upon the body and mind. Furthermore, systems biology is consulted as an explanatory model for the ‘energetic understanding’ of diseases in Tibetan medicine, and how diseases are both conceptualised in the body and how phytotherapeutics can work on several levels simultaneously.104 Polyherbal Tibetan formulas are explained as ‘multi-target medicines with a pleiotropic effect profile’ endowed with a particularly complex structure that can address more than one chronic disease.105 Padma is clearly trying hard to make up for their small number of products by stressing their polyvalent application potential. At the same time, they deliver new explanations on complexities of chronic and multimorbid diseases that are still little understood biomedically, or difficult to treat with conventional biomedicines. However, a study undertaken by Antonio and several physicians at the Dharamsala Men-Tsee-Khang focusing on ‘neuro-psychiatric disorders’, demonstrated just how challenging it can be to explain the complexity and efficacies of different Tibetan formulas in relation to specific biomedical disease categories by deducing these via their prescription.106 Ultimately, this study found that it was not possible to make any correlation between one formula being prescribed and a particular biomedical disease category. While such explanatory models and their cultural translations between different epistemologies and systems of knowledge as used by Padma remain to be studied more closely, it is clear that Padma’s transformations and innovations of formulas do not conform to any reductionist styles of biomedical and biochemical practice that only focus upon the efficacy of active agents, and this case is similar to that of industrialised ayurvedic pharmaceuticals.107 Instead, and increasingly so, at least in the Western cam milieu, concepts of efficacy pertaining to signature medicines, synergy, quantum physics, and systems biology are used to explain the ‘holistic’ and multivalent aspects of Asian medicines. Conclusions In this paper, I have argued that the official standards of bioscientifically validated efficacy and safety—as these are embodied in globalised, nationally specific regulatory regimes, and reiterated in the production of licensed reformulated Tibetan pharmaceuticals—transform Tibetan medical practices at large in both China and Europe in both direct and indirect ways. The heuristic model of formulation regimes I have proposed allows us to compare these developments in terms of transnational production and prescription practices of a similar style and scale. The comparison encompasses two principle groups of stakeholders and their formulation regimes. One is the classical formulation regime of small-scale producers and physicians of Tibetan medicine reconfiguring classical formulas in a personalised style, while focusing on addressing the individual imbalance of the patient, which from their perspective is the underlying cause of the disease. Their personal medical identity is intimately articulated with Tibetan medicine as their living tradition. The other is the reformulation regime reproduced by large-scale pharmaceutical companies, who create their own pharmacoscapes that are reconfiguring in relation to, and are at the same time validated by, nationally legitimised, bioscientific regulatory regimes of efficacy and safety. The reformulated Tibetan pharmaceuticals they produce are mainly used by a majority of physicians oriented towards biomedical or cam-parameters for targeting specific diseases. What has also been shown is how these formulation regimes configure a direct relationship between modes of production and ways of prescribing by specific groups of physicians with distinct medical identities. Sharing the same or very similar epistemic values of efficacy and safety link actors, production, and prescription practices together in these two different professional environments. Both of their distinctive ways of sourcing, production, and registration can entail complex translation processes between classical empirical knowledge on which these formulas are based and biomedical standards of regulations. This is true not only within the reformulation regime, but also where the classical formulation is practised within governmental institutional frames, such as in the case of the Qinghai Tibetan Hospital. In China, the reformulation regime of Tibetan formulas is clearly more influenced by tcm, while in Europe it follows the herbal cam-market dynamics. In both cases, the formula-disease-centred style of practice allows Tibetan formulas to be taken directly by patients themselves, catering to ever-growing wellness and consumer markets of alternative medicine. Formulas seem to embody an objectified efficacy per se that allows them to become independent from the medical system out of which they were originally developed, opening up new markets and also possibilities for application. In any case, physicians of Tibetan medicine—no matter in which country they practice—prefer to use a wide spectrum of formulas produced by trusted pharmacists. They also prefer to find their own ways of continuing the circulation of medicines via personal therapeutic networks or transitional grey market zones through which the substances and formulas can pass. Another way of continuing circulation within the same national context, for example, is to rename a formula already produced by a pharmaceutical company so as to avoid impinging upon intellectual property rights (ipr), or to adapt a formulation (e.g. by substituting or omitting certain ingredients, and/or lowering the dosage) in order to legalise its existence. By way of such processes, Tibetan formulas then also become teas, tonics, or dietary supplements in Europe, or ‘over-the-counter’ medicines in China. Within the general field of practice I have outlined and from which ethnographic examples were given, conundrums of safety and efficacy are manifest in various ways. First of all, strict food and drug policies in Europe, as well as those implemented with increasing rigour in some Tibetan areas of China, redefine classically formulated, hand-crafted, or small-scale manufactured medicines as being neither ‘safe’ nor legal. In the wake of this, in Tibetan areas at least, some private pharmacies-cum-clinics were already temporarily closed or have been threatened with closure.108 Gerke has called the ‘moving from efficacy to safety’ a generally increasing legal concern (also in medical anthropological approaches to the subject).109 Secondly, the official legal situation in Europe clearly condemns the classical formulation regime as generally ‘unsafe’ due to its non-standardised quality and dosage controls. Consequently, the few Tibetan pharmaceuticals produced by Padma are currently the only safe and efficacious licensed Tibetan medicines in Europe. They serve, in turn, to treat a large scope of chronic ailments, much larger than their classical indications would have suggested, and are supplemented by dietary and external therapies—such as massage—of Tibetan medicine that are integrated into other nationally legalised, mainstream therapeutic practices. Tibetan medicine, extended by Tibetan forms of yoga, and a host of other mind-body-techniques, has now become part of the European cam-landscape. Yet another conundrum is the consensus among classically trained tm physicians that pharmaceutical companies are not able to ensure the gold standards of efficacy and safety according to the logic of the classical formulation regime. This critique entails several concerns, first and foremost of which is that the marketing of medicines as over-the-counter products can jeopardise patient safety and undermine the possibility of efficacious treatment. Furthermore, they say that the maximisation of profits in commercial production gives rise to many compromises being made in terms of collection and production of medicines, all of which can adversely impact the overall quality, safety, and thus efficacy of medicines. Finally, there is general concern about over-harvesting, shortages, and price rises of materia medica. One general trend this research draws attention to is that increasing pharmaceuticalisation marginalises the classic formulation regime and its non-institutionalised agents who use a personalised style of producing and prescribing Tibetan formulas. They are being increasingly relegated to a grey zone in both Europe and China by regulatory regimes that ultimately support the production style of ‘big pharma’. The unfolding dynamics of this development should be the subject of future research. Figure 1 Diagram of Transnational Formulation Regimes of Tibetan Medicines. drawn by mona schrempf, 2015. Figure 2 The compounded mixture of the common Tibetan formula Sendu Drangné (Se ’bru dvangs gnas) being blessed in the altar room of a small monastic clinic in Amdo. photo by mona schrempf, 2013. Figure 3 Deer skin leather bags of a nomadic physician of Tibetan medicine from Amdo used for storing his handcrafted medicinal powders.67 photo by mona schrempf, 2013. Figure 4 The Tibetan reformulated formula Agar 35 produced by the Arura alias Jinhe Pharmaceutical Company. photo by mona schrempf, 2014. Figure 5 The Tibetan reformulated formula Sogdzin 10 produced by Padma AG.103 1 I apply the term ‘sites of contestation’ to Tibetan medicines as core therapeutic objects of a ‘living tradition’ that Tibetan medicine in all its diversity and styles of practices represents, cf. Scheid and Lei 2014. I understand ‘pharmaceuticalisation’ as a driving global force based on ‘the technological, material, and social specificity of pharmacy as a world of practices’, cf. Pordié and Gaudillière 2014b, p. 7, based on Biehl 2007. I thank my reviewers and, in particular, Sienna Craig for fruitful feed-back on earlier versions of this article. 2 See Whyte, van der Geest, and Hardon 2002. In relation to Tibetan medicines, cf. Craig 2012 (chapter 7, pp. 215–51) focusing on the ‘birth-helping pill’ Zhi byed 11; Gerke 2013a, b on the practice of purifying mercury tsotel (Tib. btso thal); Blaikie 2015 on the ‘jewel pill’ (Tib. rin chen ril bu) Samphel Norbu; also Nianggajia on the ‘White Pill’, in this volume. 3 Petryna, Lakoff, and Kleinman (eds) 2006. On the concept of ‘alternative modernity’, see Knauft 2002; and in relation to industrialised ‘reformulated’ ayurvedic Asian pharmaceuticals, see Pordié and Gaudillière 2014a. I use the term ‘Tibetan medicines’ as well as ‘Tibetan formulas’ as umbrella terms for multicompounds produced on the basis of classical Tibetan formulas according to the three different formulation regimes outlined in this paper, and applied as therapeutic objects for medical treatment in different social, cultural, clinical, and geographical contexts. 4 On the term ‘reformulation’ in relation to the making of industrialised herbal ayurvedic medicines in India, see Pordié and Gaudillière 2014a, b; Pordié and Hardon 2015. 5 I use the English term ‘science’ as a direct translation of Tibetan rig gnas in the sense of Tibetan medicine being part of the classical ‘five major sciences’ taught in monastic curricula (Tib. rig gnas che ba lnga). Since the physicians of Tibetan medicine whom I have interviewed in Europe and China and also some pharmacists in India, were all ethnically Tibetan, I intentionally use the term ‘Tibetan medicine’ (Tib. bod sman) rather than the term Sowa Rigpa. The latter designates primarily the living tradition as it is practised in the Himalayas by non-Tibetan ethnic groups, although Sowa Rigpa has also recently become a globalised umbrella term for Tibetan medicine more generally. See Craig and Gerke (forthcoming). 6 On the use of the term ‘traditional’ medicines in the European cam regulatory context, see Schwabl 2009. On Tibetan pharmaceuticals and gmp compliance in China, see Saxer 2013. 7 For a systematic review of rcts with Tibetan medicine, here called ‘traditional Tibetan medicine (ttm) modelling the name on tcm conducted in Europe, see Reuter et al. 2013; and for China, see Luo et al. 2015. 8 See, in particular, Saxer 2012. For critical social science studies on gmp in Tibetan medicine, see Craig 2011b; Craig 2012, pp. 146–82; Saxer 2013, pp. 59–94. On challenges in undertaking cross-cultural clinical trials research with Tibetan medicines, see Adams et al. 2005. 9 Based on Appadurai’s (1990) definition of ‘(land)scapes’, I use the term ‘pharmacoscape’ describing the specific professional and social networks of sourcing, distribution, and circulation built up by pharmaceutical companies that produce Tibetan pharmaceuticals, sponsor clinical research of their products, as well as target niche alternative markets of potential clients, i.e. mainly biomedically trained physicians, cam, or tcm hospitals, patients looking for alternative ‘side-effect-free’ medicines, consumers of ‘wellness’, and so forth. 10 Cf. Schrempf 2007 on lineage physicians-cum-pharmacists in Nagchu (tar). 11 For the International Classification of Diseases-10 (icd-10) set up by the who in 1990, see url: <http://www.who.int/classifications/icd/en/>, last accessed 12 December 2015. 12 At present, Stephan Kloos’ collaborative research project funded by the European Research Council focuses on industrialised Tibetan pharmaceuticals in Asia, see url: <http://www.ratimed.net>, accessed on 15 December 2015. 13 I am grateful to The Wellcome Trust for funding my research (2012–15) as part of the collaborative project ‘Beyond Tradition—Styles of Practice and Ways of Knowing in East Asian Medicine 1000 to Present’, located at the EASTmedicine Research Group, University of Westminster, London. My monograph on the topic is forthcoming (Schrempf forthcoming). 14 I used mainly participant observation and semi-structured interviews with producers and physicians of Tibetan medicine, as well as observations during several conferences where issues of efficacy and safety were discussed. Earlier fieldwork was funded within the framework of the collaborative research centre sfb 640 by the German Research Foundation (dfg). A separate fieldtrip was undertaken to India in 2014 conducting fieldwork with some small-scale producers of Tibetan medicines whose formulas are used in Europe. I thank all my informants for sharing their knowledge and time. 15 Cf. Hsu 2010, p. 23. On Tibetan medicines, see in particular Blaikie et al. 2015 on co-producing efficacious medicines among physicians of Tibetan medicine alias Sowa Rigpa from Nepal, Ladakh, and Tibetan areas of China. See also Craig and Glover 2009; Blaikie 2011, 2013, 2014, 2015. 16 Zhan 2009. 17 Craig 2012; Saxer 2013. 18 See, in particular, Janes 2002; Craig and Adams 2008; Craig 2012, 2014; also Hofer 2014; Schwabl 2013. 19 Cf. Adams, Schrempf, and Craig 2011a, (eds) 2011b; Adams 2002a, b; Adams, Le, and Dhondup 2010, 2011; Craig 2011a, 2012; Czaja, this volume. 20 I thank Lena Springer for pointing out this literal translation of minzu yiyao. While the term connotes that a particular minority nationality has its own ethnic system of medical knowledge and practice it also clearly implies to be part of China’s culture and public health system. The present politics of China’s cultural heritage including Tibetan medicine clearly point into this direction. 21 Cf. Janes 1995, 1999. For comparison, see Hsu 2009 on previous processes of standardisation and institutionalisation leading to the making of tcm in China that already began during the late 1950s. 22 On the plurality and diversity of healing practices in Amdo, the Tibetan populated area of Qinghai Province, see Schrempf 2011. 23 Saxer 2013, p. 35. For a detailed account on the development of a Tibetan pharmaceutical industry, see Saxer 2013, chapter 2, pp. 22–58. 24 See Krung go’i sman mdzod 2000; also sqtf 1992; see also Czaja and Schrempf (forthcoming). 25 See Ministry of Health 1995; State Pharmacopoeia Commission (ed.) 2015. 26 See sfda 2001. 27 On the complex encounters of Tibetan medicine and Chinese biomedicine, see Adams, Schrempf, and Craig (eds) 2011b. 28 At about the same time, in 1961, the Men-Tsee-Khang (today called the Tibetan Medical and Astro Institute) was founded in Dharamsala. On the beginnings and the development of Tibetan medicine in Indian exile, see Kloos 2010, 2013. 29 See url: <http://www.padma.at/padma/padma-ag-schweiz/geschichte/>, last accessed on 12 December 2015. 30 See, for example, the biography of the exile-Tibetan physician Tamdin Sither Bradley, url: <http://www.aruratibetanmedicine.com/biography.asp>; and of Pasang Yontan Arya, <http://www.tibetanmedicine-edu.org/index.php/dr-pasang-y-arya/11-dr-pasang-aryas-autobiography>; both last accessed on 12 December 2015. 31 url: <http://ec.europa.eu/health/files/eudralex/vol-1/dir_2001_83_consol_2012/dir_2001_83_cons_2012_en.pdf>, last accessed on 15 December 2015. See also Schwabl 2009 who points out that the definition of traditional herbal products is most likely following tcm phytotherapy via who definitions; see also Kadetz, this volume. 32 See Chapter 2a, Specific provisions applicable to traditional herbal medicinal products, Article 16c, at url: <http://ec.europa.eu/health/files/eudralex/vol-1/dir_2001_83_consol_2012/dir_2001_83_cons_2012_en.pdf>, last accessed on 15 December 2015; cf. Schwabl and Vennos 2015. 33 Schwabl and Vennos 2015, p. 108. 34 The uk allows herbal products from the Men-Tsee-Khang in Dharamsala to be imported; see Gerke 2012. Tibetan Therapeutics is a London-based outlet of their Sorig Tibetan Health Products, see url: <http://www.tibetan-therapeutics.com>, last accessed on 15 December 2015. 35 Personal communication with Brion Sweeney, London, University of Westminster, 8 May 2015. Cf. Millard 2008; Soktsang and Millard 2013. 36 Blaikie 2015. 37 Pordié and Gaudillière 2014a, p. 59. 38 ‘[… T]his regime consists in reformulating and simplifying ayurvedic medicinal compositions in order to create new “traditional” drugs for the biomedical disorders of an international as well as Indian clientele with a holistic claim’, Ibid. 39 While Tibetan medicines in India are not part of my research focus, it is noteworthy that in India a Tibetan pharmaceutical industry is only very slowly emerging, cf. Blaikie 2015. 40 For details, see Schwabl 2009. 41 Cf. Luo et al. 2015. Cf. also Craig 2011b. 42 Ibid., p. 453. 43 Ibid., referring to Zheng 2002. 44 Cf. World Health Organization 2005; Schwabl 2009; see also Kadetz, this volume, on the confluence of who and tcm definitions. 45 Cf. State Pharmacopoeia Commission (ed.) 2015; Saxer 2013, p. 71ff. Ironically, in Europe jewel pills are perceived as being poisonous according to bioscientific standards of safety since they contain some form of mercury, cf. Gerke 2013a. 46 I have included pharmacists producing Tibetan medicines in India in this study, because their medicines play a crucial role in the treatment of Western patients in Europe. 47 I am excluding here teas and ‘vitalising dietary supplements’ produced by the Men-Tsee-Khang in India for export to Europe. 48 Naraindas defines shastra (Skt. śāstra) in the context of Ayurveda as the classical ‘science of formulating drugs’ based on the principles of the ‘five elements’ (Skt. panca mahābhūta), the three ‘humours’ (Skt. doṣa) and the seven ‘tissues’ (Skt. dhātu), as well as on their applications. See Narinadas 2014, p. 13. 49 cites or Convention on International Trade in Endangered Species of Wild Fauna and Flora is an international treaty that aims at preventing overexploitation and regulating international trade in endangered species listed in the convention. 50 The notion of ‘styles of practice’ is based on ‘styles of scientific thinking and doing’ as defined by Hacking 2010, 2012. It is applied here as a general analytical approach to understanding two major ‘styles of practice’ in Tibetan medicine, i.e. in the sense of ways of reasoning that we call ‘scientific’ and encompassing both biomedical and Tibetan medical principles and practice and understandings of the body; cf. Hacking 2010, p. 235. They are self-authenticating, emerging with new objects and truth claims. 51 The reason why I do not define the second style as always being biomedically oriented is that some classically formulated formulas, as produced, for example, by the Gartse monastery clinic in Rebgong (see Nianggajia, this volume), are labelled with indications in specifically Tibetan medical and Chinese medical disease categories, rather than biomedical ones. Such formulas are not produced according to gmp either, yet they target specific vernacular symptoms and diseases surrounding stomach and digestive disorders. It appears that in the case just cited, the disease orientation for producing an effective digestive medicine for a locally common disease was specifically oriented to the local market in order to increase the sales among a specific multiethnic clientele. 52 I thank Olaf Czaja for pointing this out, personal communication July 25, 2015. 53 ‘The six basic tastes are sweet, sour, salty, bitter, hot, and astringent, and the three postdigestive tastes are sweet, sour, and bitter. […] Each of the six basic tastes is a composite of two of the five elements (earth, water, fire, air, and space) that define the characteristics of each taste, resulting in a particular potency of each taste and its subsequent attributes’, Sonam Dolma 2013, p. 109. 54 Water and earth manifest in ‘phlegm’ (Tib. bad mkan), fire in ‘bile’ (Tib. mkhris pa), air in ‘wind’ (Tib. rlung), while space gives rise to and pervades all four elements. 55 Phan nus is a compound derived from phan tog ‘benefit’ and nus pa ‘potency’, i.e. literally the ‘benefit of potency’. In English, I think this understanding comes closest to what we can call ‘efficacy’ in the broadest sense and including various epistemic values. 56 Blaikie 2014, pp. 293ff. On empowerment rituals, see Craig 2011a, and Czaja, this volume. 57 Saxer 2013 speaks here of a moral economy of Tibetanness where ethnically Tibetan owners of pharmaceutical factories are still perceived as more legitimate than Chinese. Since Saxer’s fieldwork with producers of Tibetan pharmaceuticals in China, shareholder ownership of several of these pharmaceutical companies has changed, in particular the Arura Medicine factory in Xining, Qinghai Province, has been owned for the past three years by a Chinese majority, which was perceived as very disappointing by many Tibetans I spoke with. In contrast, Jigme Phuntsok’s pharmaceuticals were less criticised and believed to be more authentic. On the Qinghai Jiumei Tibetan Medical Co. Ltd. (Ch. Qinghai Jiumei zangyao yaoye youxian gongsi 青海久美藏藥業有限公司), see Saxer 2013. 58 On a bifurcated view of reality into ‘real’ and ‘fake’ among Tibetans living in China, see Schrempf 2008, p. 131. 59 Rebgong is both a county and a county town, as well as the prefectural capital of the Malho Tibetan Autonomous Prefecture (Tib. Rma lho bod rigs rang skyong khul; Ch. Huangnan zangzu zizhizhou 黄南藏族自治州). 60 Ani Khandroma was said to be a reincarnation of a female enlightened being, a so-called ‘sky goer’ or khandroma (Tib. mkha ’gro ma) from Labrang Monastery (Tib. Bla brang bkra shis ’khyil, Ch. Labuleng si 拉卜楞寺) in Xiahe County (Ch. 夏河县) Gansu Province, and was very respected and revered within the Tibetan community. On Rebgong as a local hub of Tibetan medicine in Amdo, see Nianggajia, this volume. 61 Located in the Tsolho Tibetan Autonomous Prefecture (Tib. Mtsho lho bod rigs rang skyong khul, Ch. Hainan 海南藏族自治州) of Qinghai Province. When I met Ani Khandroma during 2005 in a small apartment in Xining where she occasionally stayed, she was planning to build another clinic at the shore of Tsongonpo alias Lake Kokonor or Qinghai Hu. She sadly passed away in April 2010. Shortly after, her beloved project of building up a clinic at the shore of Lake Kokonor was dismissed and the initial buildings were torn down, allegedly because of a newly declared law on ‘nature preservation’ in this area; cf. the ngo report by Schweiger (url: http://www.asia-ngo.de/pdf/ReiseAmdo2010.pdf, last accessed 24 November 2015). 62 As she explained, she meant the quantity and number of college students, size of schools, and hospitals, and the sheer scale of Tibetan medicine factories in big cities, such as Xining. 63 Personal communication in Xining, 25 August 2005. I thank my interlocutor at the time, Lhamo Drolma. 64 Next to deer skin, deer blood, and musk as well as bear’s gall bladder, and in general, wild animal blood and flesh are said to be of particular importance for healing women’s diseases (Tib. mo nad) of which the Gyüshi enumerates about 60 specific kinds. 65 Ar nag is the most potent form of eaglewood, and usually identified as Aquilaria agallocha Roxb, a dark, heavy, and densely resinous and fragrant hardwood that is more costly than other forms of Aquilaria used by the pharmaceutical department in Xining, for example. 66 Agar 35 should contain a blackish and oily type of eaglewood, the most potent version of ar nag or Aquilaria agallocha Roxb. This is a common formula frequently used in both China and in Europe for general relaxation, better sleep, and less anxiety. However, as local tm physicians stated, and reconfirmed by the medical botanist Christine Leon from Kew Gardens in London, there are many adulterations of eaglewood because it is rare and expensive, as well as being listed in cites as an endangered species (personal communication with Christine Leon during a workshop on ‘Developing an Interdisciplinary and Multilingual Digital Knowledge Base on Tibetan Medical Formulas with a Focus on Stress-related (rlung) Disorders’, EASTmedicine Research Group, University of Westminster, London, May 8, 2015); url: <https://www.westminster.ac.uk/news-and-events/news/2015/eastmedicine-international-workshop-0>, last accessed 15 December 2015. 67 He kept them, however, locked away, fearing unexpected food and drug safety controls that already once before had forced him to close his clinic down in 2003. 68 Luo et al. 2015, p. 453. 69 See Craig 2012, p. 57. 70 One should point out that ultimately, it depends on the preference and personal style of a physician whether and how biotechnogical and Tibetan medical principles are hybridised in practice and on a case-to-case study. 71 On the biography of Akhe Nyima (Tib. A khu Nyi ma; ‘Uncle Nyima’) who holds the highest Tibetan medical degree of menpa bumrampa (Tib. sman pa ’bum rams pa), see url: <http://arurahp.com/tibetan/?p=341>, last accessed 15 December 2015; see also Craig 2012, pp. 66–70. Among famous teaching physicians of Tibetan medicine, their personal knowledge, lineage authority, and legitimacy is embodied within the knowledge of compounding and recipes of certain Tibetan formulas. For example, the famous scholar-physician-teacher Khyenrab Norbu (Mkhyen rab nor bu, 1883–1962) taught the practice of tsotel to many tm physicians, and is used by many physicians of Tibetan medicine refer to his knowledge having been transmitted to them personally as part of their legitimation to produce jewel pills. 72 Personal communication with Akhe Nyima via Tsering Namgyal, 20 April 2016. 73 As I was told many times by private physicians, hot liver-related problems due to an excess of ‘bile’ are very common among Tibetan patients in Amdo and China, who tend to consume, next to too much meat and diary products, also too much oily food and hot chillies from the Chinese kitchen. See also Bassini 2013; Nianggajia, this volume. 74 Adams, Le, and Dhondup 2011. 75 Blaikie 2015, p. 14. 76 Ibid. 77 Personal communication with a physician-pharmacist of Tibetan medicine from India, Dharamsala, 4 November 2014. 78 Additionally, there is much fake musk in circulation, and the ‘real’ wild substance is difficult to access and expensive, thus physicians are very secretive about where they source their musk from. 79 Cf. Craig 2012, pp. 183–214. 80 On Akong Rinpoche’s life, his training as a Tibetan medical practitioner, role as a co-founder of the first Tibetan Buddhist monastery in Europe Samye Ling, and also position as strong promoter of Tibetan medicine in Europe, see url: <http://www.khenpo.eu/tara/andtara.html>, last accessed 2 December 2015. 81 On the Tara Clinics of Traditional Tibetan Medicine, see url: <http://www.tararokpa.org/medicine/index.html>, last accessed 2 December 2015. 82 Cf. Millard 2008, p. 192f. 83 url: <http://www.arura.cn/about.aspx?classid=1>, last accessed 10 February 2016. In the following, I call this company by the shortened name Arura. 84 On the pharmaceutical factory and its development, see Adams, Le, and Dhondup 2010, 2011; Saxer 2013, pp. 45ff. 85 url: <http://eng.sfda.gov.cn/WS03/CL0768/65113.html>, last accessed 10 February 2016. 86 弘扬藏医药, 造福全人类! url: <http://www.arura.cn/about.aspx?classid=3>, last accessed 15 February 2016. According to Lena Springer, ‘enhance’ connotes here also ‘praise’ and ‘spread’. I also thank Matthias Bauer and Nianggajia for the translations of this website from Chinese into English. 87 Verbatim: ‘to expand the field of medical treatment with Tibetan medicine’. 88 Cf. Saxer 2013; Kloos 2010. 89 See url: <http://www.arura.cn/about.aspx?classid=1>, last accessed 15 February 2016. 90 Until very recently, caterpillar fungus (Tib. dbyar rtsa dgun ’bu; L. Cordyceps sinensis) used to be the main cash income-generating wild crop collected by Tibetans due to a large demand on the Chinese market. It was mainly used in guanxi transactions among business people, yet prices fell in the past two years due to policy changes, and collectors have consequently suffered large losses in income. 91 公司拥有药品、保健品、冬虫夏草、健康产品、起居养生、特色外治6大类1000 余种产品, 其中药品共有68个国药准字号产品, 独家品种 21 个, 独家剂型 5 个, 国家医保品种 10 个, 国家医保品种1个, otc 品种 10。 url: <http://www.arura.cn/about.aspx?classid=1>, last accessed 2 December 2015. 92 According to Pasang Yontan Arya, ‘There are three types of a ga ru: Aquilaria sinensis (Lour) Cuilg (ar skya) Aquilaria agallocha Roxb. (ar nag) and Cinnanomum parthenoxylon (Tack.) Nees (ar dmar).’ Ar dmar is also known under the Tibetan name of a gar go snod. ‘In general, they are beneficial for heart and life channel.’ Pasang Yontan Arya 1998, p. 299. 93 The way in which the formulation Agar 35 is culturally translated into Chinese via hybrid Tibetan, biomedical, and tcm terminologies will be expounded in a joint article by Czaja and Schrempf (forthcoming). 94 On this company, see their elaborate website url: <http://www.padma.ch/en/products/medicinal-products/>, last accessed on 17 January 2015. 95 The first Padma pharmaceutical to attain this status was Padma Lax in 1970. On in vivo, in vitro and ex vitro studies on the effects of Padma Lax, see Gschossmann et al. 2010. On the in vitro study of the effects of Padma Digestin that more recently has attained the status of a ‘Tibetan medicine’ on certain muscle tissues in rats, see Balsiger et al. 2013. On clinical studies of Padma 28, see Vennos, Melzer, and Saller 2013; for a systematic review of clinical studies on the efficacy and safety of Padma 28 written as a doctoral thesis, see Röösli 2010. 96 Schwabl and Vennos 2009, p. 11. It should be noted that the addressees of this journal publication mostly are Western therapists trained in Tibetan medicine by Nida Chenaktsang, the director of the largest European school of ttm (traditional Tibetan medicine). He is actively retranslating Tibetan medical treatments into Western contexts with an emphasis on the ‘energetic levels’ of body and mind, including Tibetan Buddhist teachings of the Yuthok Nyingthik (g.Yu thog snying thig); cf. Garrett 2009. 97 The problem with the correct botanical identification of eaglewood—despite its large use in Tibetan formulas across the Himalayas, Tibet, and China—is that there are similar yet different species that are difficult to differentiate from each other and therefore their correct identification and use is questionable. 98 Schwabl and Vennos 2009, p. 11. 99 Personal communication with Herbert Schwabl, Director of the Padma ag, Zurich, January 2014. 100 On the complex of wind disorders in Tibetan medicine, see Yoeli-Tlalim 2010. 101 Leaflet of Padma Nerve Tonic (alias Padma Nerven-Tonikum). 102 Kneip 2015. 103 Image source: the website Padma ag, url: <http://www.padma.ch/en/products/other-swiss-products/other-padma-formulas/padma-nerves-formula/>, accessed 05 December 2015. 104 In systems biology, the body is conceptualised as a whole complex system consisting of interactive parts that are organised on different hierarchical levels and systems of cells, organs, and functions, and therefore in need of being addressed simultaneously. The complexity of the body (and disease) is related to the complexity of the synergistic efficacies of a single plant, as well as to a complex formula pattern; see Verpoorte, Choi, and Kim 2005. 105 Cf. Schwabl, Vennos, Saller 2013, p. 35. On the ‘holistic’ concept of ‘signature’ medicines in European cam-medicine as entailing a combination of material and ethereal or ‘essential’ (‘wesenhafte’) efficacy that addresses both the patient’s body and mind, cf. Kalbermatten 2015. 106 Cf. Antonio et al. 2013. 107 This coincides with the studies by Pordié and Gaudillière 2014a, b on industrialised polyherbal ayurvedic reformulations. 108 As always in China, there is no uniform implementation of policies, even at the level of a single county. I have met three individual physicians in Amdo with well-established private clinics independent of one another, partly with a lineage-based background, but also with official certificates from medical schools. They were locally or even regionally well-known for the quality of their medicines. Their clinics have either been closed down temporarily or they were threatened with closure because they had no licence for their medicines. The one whose clinic was closed down was only allowed to reopen if ‘safely’ produced, licensed Tibetan and Chinese medicines were sold on the premises. I also heard of similar reports from Lhasa in central Tibet (Xizang). However, other physicians elsewhere had never even heard of such policies. 109 Gerke 2012. 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PMC005xxxxxx/PMC5119645.txt
LICENSE: This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. 101634614 42750 Microbiol Spectr Microbiol Spectr Microbiology spectrum 2165-0497 27780018 5119645 10.1128/microbiolspec.MCHD-0027-2016 NIHMS811569 Article Inflammation – a critical appreciation of the role of myeloid cells Iqbal Asif J 1 Fisher Edward A 2 Greaves David R. 1 1 Sir William Dunn School of Pathology, University of Oxford, South Parks Road, Oxford OX1 3RE, UK 2 Deaprtments of Medicine (Cardiology) and Cell Biology, NYU School of Medicine, Smilow 7, 522 First Avenue, New York, NY 10016 Contact: David R. Greaves - david.greaves@path.ox.ac.uk 20 8 2016 10 2016 01 1 2017 4 5 10.1128/microbiolspec.MCHD-0027-2016This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. “The receptor concept is to pharmacology as homeostasis is to physiology, or metabolism to biochemistry. They provide the basic framework, and are the ‘Big Ideas’ without which it is impossible to understand what the subjects are about.” H.P. Rang. The receptor concept: pharmacology’s big idea. British Journal of Pharmacology (2008) 17: S9–S1 ‘What is inflammation’s big idea?’ In this brief overview of the role of myeloid cells in inflammation we will critically discuss what drives the initiation, amplification and resolution of inflammation in different anatomical sites in response to different pathological stimuli. It can be argued that we have a good understanding of the basic principles that underlie myeloid cell activation and the mobilization of innate immune cells to sites of injury and infection in acute inflammation. The challenge now for inflammation biologists is to understand how resolution of this normal physiological response goes wrong in hyper-acute and chronic inflammation. A better understanding of how inflammation is regulated will allow us to develop new anti-inflammatory drugs that will reduce the burden of inflammatory disease without compromising the patient’s immune defenses against infectious disease. Ideally such drugs should encourage a return to homeostasis and enhance tissue repair processes. Introduction – a historical and evolutionary synthesis Multicellular organisms have had to develop a rapid response to infection and tissue injury. In all animals on our planet this involves mobilization of specialized cells to the focus of the infection or injury. This important insight was beautifully illustrated by Elie Metchnikoff whose detailed drawings of cells being recruited to the site of injury caused by a rose thorn in a starfish embryo gave us the first glimpse of cells he termed macrophages and neutrophils, which he termed ‘microphages’. If not the first person to observe phagocytosis and leukocyte diapedesis, Metchnikoff was probably the first person to fully appreciate the role of these two important cellular processes in ‘natural’ or innate immunity (1). An important question arises from Metchnikoff’s observations in model organisms and histological images of human tissues infected by pyogenic bacteria - what are the locally produced molecular signals that mediate innate immune cell mobilization? A priori, we would expect these signals and the receptors that recognize them to have arisen early in evolution of multicellular organisms and for their function to be maintained by selection pressure exerted by everyday exposure to infectious disease and physical injury. A glimpse of how local signals to both pathogens and physical injury might have arisen comes from the Atlantic horseshoe crab, Limulus polyphemus. The horseshoe crab is often described as a ‘living fossil’ due to its near identical form to species present in the Triassic period 230 million years ago. The blood (or haemolymph) of Limulus species coagulates in response to intact bacteria and bacterial endotoxin effectively walling off invading pathogens. The Limulus protein that recognizes lipopolysaccharide (LPS) and Lipid A present in the outer membrane of Gram negative bacteria is a 132kDa protein called Factor C. LPS binding to the LPS / Lipid A recognition domain of Factor C activates a serine protease domain within the same protein. Activated Factor C activates haemolymph protein, Factor B, which initiates the clotting cascade to cause local haemolymph coagulation. This observation formed the basis of the Limulus amoebocyte lysate (LAL) assay for detecting low-level endotoxin contamination of tissue culture reagents, biologicals and medical devices (2). Limulus haemolymph also contains two conserved oligomeric serum proteins, the ‘short’ pentraxins C-reactive protein (CRP) and Serum Amyloid P component (SAP) (3). These two pentraxins, together with the evolutionarily conserved ‘long’ pentraxin PTX3, play important roles in mammalian host defense (4). A recent analysis of CRP knockout mice showed a marked sensitivity to Streptococcus pneumoniae infection in animals lacking endogenous CRP production that could be rescued by infusion of purified human plasma CRP or generation of anti- Strep Pneumoniae antibodies (5). These experiments strongly suggest that CRP has evolved to protect neonatal mammals from specific virulent bacterial pathogens. Specific roles for SAP in mammalian host defence have been harder to identify (possibly due to functional redundancy) but are likely to centre around recognition of bacterial peptidoglycan, damaged host membranes and complement activation, reviewed in (6). PTX3 was originally described as a non-redundant mammalian pattern recognition receptor essential for defence against the fungal pathogen Aspergillus fumigatus and later recognised to bind the bacterial pathogens Pseudomonas aeruginosa and uropathic E. coli as well as influenza virus (7, 8). Mammalian hepatocytes synthesize a range of other host defense proteins as part of the acute phase response, most notably ~30 proteins of the complement cascade. Complement is another evolutionary ancient defense against pathogens that shares with the coagulation cascade local activation and local amplification via serine protease cleavage of inactive enzymes (zymogens). It is clear that the complement system has evolved to be much more than a simple plasma pathogen recognition system that can kill microbes through deposition of a membrane attack complex (C5b, C6–9) (9). Proteolytic cleavage of the plasma protein C3 leads to deposition of the C3b protein fragment on target cells greatly enhancing phagocytosis by professional phagocytes of the innate immune system (neutrophils and macrophages). Cleavage of the C5 complement protein by the C3 convertase complex generates a high local concentration of C5a, a potent chemoattractant for innate immune cells via the G protein coupled receptor (GPCR) C5aR1 (10). The unrelenting evolutionary pressure exerted by the twin drivers of infectious disease and tissue injury means that any germline encoded signaling molecule or cellular response system that enhances tissue defense can be rapidly fixed, duplicated and mutated within eukaryote genomes. Multiple examples are provided from comparative genomics. One striking example is the Drosophila dorsoventral regulatory gene network, spätzle/Toll/cactus, which has been ‘re-engineered’ and ‘re-purposed’ during vertebrate evolution to give the cytokine activated NF-κB signaling pathway (11). Gene duplication has generated a family of Toll-like receptors (TLRs), which act as cellular pattern recognition receptors (PRRs) for highly conserved molecules on microbial pathogens termed pathogen associated molecular patterns (PAMPs) by Charles Janeway and Ruslan Medzithov (12, 13). Another striking example of duplication and diversification of immune defense genes comes from consideration of chemokines and their receptors. Comparative genomics reveals that the chemokine-chemokine receptor system has proven a useful module for directing cell-type specific chemotaxis and activation. In addition to mediating T cell chemotaxis the CXCR4 - CXCL12 interaction is used to keep haematopoietic stem cells (HSCs) within a specific bone marrow niche (14). Indeed, a small molecule CXCR4 antagonist (AMD3100) has found clinical application in mobilizing donor HSCs from bone marrow to peripheral blood for more efficient and less painful harvesting. The chemokine-chemokine receptor system has been exploited by the adaptive immune system for dendritic cell migration to lymph nodes, homeostatic leukocyte trafficking, lymphocyte homing to different tissues (e.g. the gut) and recruitment of specific lymphocytes subsets to sites of inflammation (15). The original description of the chemokine system as a inflammatory cell recruitment system, and the impressive results obtained using chemokine receptor gene knockout animals in models of chronic inflammation e.g. Boring et al 1998 (16), suggested that small molecule drugs that inhibit chemokine receptor signaling would make potent, cell type-specific anti-inflammatory drugs. To date this initial optimism has not (yet) been converted into clinically useful drugs (17, 18). No critical discussion of the role of myeloid cells in inflammation would be complete without consideration of inflammasome activation. The seminal contribution of Jurg Tschopp to immunology and inflammation biology was the recognition that the secretion of active Interleukin-1 (and Interleukin-18) is critically dependent on the formation of a large (>=700kD), cytoplasmic, multi-subunit caspase-activating complex (19). Since Tschopp’s first description of this macromolecular structure it has been shown that inflammasome activation can be triggered by a wide range of bacterial, viral, fungal and even helminth PAMPs as well as by a range of host damage associated molecules. Inflammasome activation leads to high local concentrations of IL-1 and inflammatory cell death by pyroptosis and pyronecrosis. Recent experiments in murine models have revealed tantalizing glimpses of a link between inflammasome activation and the inflammatory component of metabolic diseases such as obesity and Type 2 diabetes. Finally, it is important to remember that the prototypic acute inflammatory response can be triggered by non-microbial stimuli. A good example of such ‘sterile inflammation’ is provided by administration of substances such as monosodium urate (MSU) crystals and calcium pyrophosphate (CPP) crystals, the pathogenic drivers of gout and pseudo-gout respectively. Sensing of these and other crystalline insults is absolutely dependent upon the presence of a functional NALP3 gene and subsequent caspase activation, showing the central role of inflammasome activation and IL-1β in this neutrophil-dominated response to tissue injury (20). Necrotic cell death releases specific intracellular molecules that can induce activation of innate immune cells in vitro and a prototypic acute inflammatory response in vivo (21). Following the intellectual lead provided by Charles Janeway, signaling molecules released by necrotic tissue have been termed Damage Associated Molecular Patterns (DAMPs) by some, ‘Alarmins’ by others (22). Such molecules include extracellular ATP, mitochondrial DNA, uric acid and chromatin associated proteins, including the chromatin high mobility group-1 protein HMG-1. In a recent study Kataoka et al (23) directly compared the role of multiple signaling pathways in two mouse models of leukocyte recruitment in response to intraperitoneal injection of necrotic cells or induction of hepatocyte necrosis with paracetamol. The authors showed that neutrophil mobilization at early time points was significantly decreased in the absence of Complement C3, natural antibodies and the protease-activated receptor PAR2. Local depletion of ATP or deletion of the P2X7 receptor gene had no effect on leukocyte mobilization in these two models of necrotic cell induced inflammation, in contrast to findings in cultured cells or other models of sterile injury. Another potential ‘danger signal’ in the context of tissue injury is damage and modification of the extracellular matrix (ECM) (24). Hyaluronan (HA) is an abundant nonsulphated glycosaminoglycan component of the ECM found in many tissues. Multiple biological functions have been ascribed to HA and pro-inflammatory functions have been assigned to low molecular weight forms of HA (LMW HA) generated by the action of a range of hyauronidase enzymes. An interesting pre-clinical study by Huang et al (25) demonstrated that commercially available LMW HA and hyaluronidase enzyme preparations are contaminated with endotoxin and other proteins. This contamination of key reagents had lead to the erroneous conclusion that LMW HA is a ligand of the TLR2 and TLR4 receptors leading to pro-inflammatory cytokine production. By using an endotoxin-free pure preparation of the human hyaluronidase enzyme PH20 (rHuPH20) in an LPS dorsal air pouch model of acute inflammation Huang et al. demonstrated a marked anti –inflammatory effect of hyaluronidase characterised by no change in pro-inflammatory cytokine production but marked reduction of neutrophils. The pro-inflammatory role of ECM damage merits further study in the context of both acute and chronic inflammation as well as in the context of tissue repair and fibrosis. Experimental Models of Inflammation Animal models of inflammation are always open to criticism of how well they mimic clinical events in human disease. For instance mouse models of atherosclerosis do not display the classical clinical sequelae of human atherosclerosis, i.e. myocardial infarction and ischaemic stroke. Another obvious concern is that drugs that work well in pre-clinical models of human disease do not always translate into successful clinical trials. An early example was the success of anti-TNF therapy in murine and primate models of endotoxic shock and the subsequent failure of anti-TNF monoclonal antibodies to impact on morbidity and mortality in human septic shock and sepsis in randomized clinical trials (RCTs). Despite these obvious limitations, our current knowledge of inflammatory mediators, inflammatory cell biology and the resolution of inflammation owes much to a wide range of well characterized pre-clinical models some of which are outlined below. Animal models of acute inflammation Peritonitis is the inflammation of the peritoneum, a thin membrane lining the abdominal cavity. Experimentally it can be triggered by infectious stimuli, which if not treated immediately can spread to the blood and lead to septic shock. Peritonitis can also be induced by injection of sterile inflammagens or implantation of necrotic cells or tissues. Rodent models of peritonitis have provided insight into the generation of local mediators that aid the resolution and return to tissue homeostasis, such as Annexin-A1, lipoxins, resolvins, protectins and maresins. A variety of inflammatory stimuli have been used to induce peritonitis including zymosan, IL-1β and Brewers thioglycollate. Zymosan induced peritonitis is a simple and reproducible model of self-resolving inflammation. It has become a ‘go to’ model to study not only the kinetics of leukocyte recruitment and pro-inflammatory mediator production, but also pro-resolving actions on processes such as macrophage efferocytosis. Zymosan is a yeast cell wall extract of Saccharomyces cerevisiae and is recognised by TLR2 and Dectin-1. Intraperioneal injection with low dose zymosan (0.1–1mg/ml) leads to an initial wave of PMN recruitment into the peritoneal cavity which peaks between 6–8 hours followed by a second wave of mononuclear cells (>16 hours) during the resolution phase(26). Carageenan (CG) induced paw oedema is a well-established model of acute inflammation used to test the effects of a variety of anti-inflammatory drugs/compounds and to understand the role of mediators during an acute inflammatory response. CG is a gelling agent consisting of sulphated galactans and three main forms have been identified; iodo-CG, kappa-CG and lambda CG. The lambda species is most widely used in mice and rats and is given as sub-plantar injection in one paw. A similar volume of saline is injected into the contralateral paw as a control and oedema is usually measured by plethysmometry (27). Upon sub-plantar injection with 1–3% CG, a biphasic inflammatory response ensues with pain, increased vascular permeability, oedema and PMN influx observed as a result of the release of range of mediators being generated locally including substance P, histamine, bradykinin, prostaglandins, complement and reactive oxygen species. Peak oedema levels in the first phase of the response is observed between 4–6 hours followed by a second more intense phase developing between 48–72 hours. A study carried out by D’Agostino et al, (2007) examined the role of peroxisome proliferator-activated receptor (PPAR)-α agonistsin modulating CG induced paw oedema in mice. The authors found that intracerebroventricular administration of an endogenous PPAR-α agonist, palmitoylethanolamide (PEA) 30 minutes before CG administration reduced oedema formation. This reduction was linked to a decrease in COX-2, iNOS synthase expression and IκB degradation. Mice lacking PPARα showed no reduction in oedema formation following pre-treatment with PEA. This study elegantly demonstrated for the first time that activation of PPAR-α in the CNS could control peripheral inflammation (28). The air-pouch model is another simple model widely used to study inflammation in vivo. Two subcutaneous injections of air (day 0 and 3) into the dorsal intrascapular region leads to the formation of a discrete pouch. Injecting inflammatory stimuli such as zymosan, MSU or cytokines into the air-pouch results in rapid influx of PMNs and the local generation of mediators, including IL-8 and C5a. Depending upon the dose and the type of inflammagen used a second wave of mononuclear cells can follow. The air-pouch offers many advantages over the peritonitis model including ease of multiple dosing and application of compounds with poor solubility profiles. It also offers users the ability to recover relatively clean exudate samples, which can be used to measure mediators with low levels of abundance(29). Animal models of chronic inflammation The collagen induced arthritis model (CIA) has been an invaluable tool in furthering our understanding of some of the key mechanisms involved in the pathogenesis of human rheumatoid arthritis (RA). CIA is an inflammatory polyarthritis that shares many of the clinical and histological manifestations associated with human RA, i.e. disease being centered on the joints and the destruction of cartilage and bone. CIA is induced following sensitization with heterologous type II collagen (CII) in complete Freund’s adjuvant (CFA) followed by a second immunization (day 21) with CII in incomplete Freund’s adjuvant (IFA). This results in the initiation of cell mediated and humoral adaptive immune responses, which are characterized by increased levels of anti-CII IgG, complement fixation in joints, leukocyte infiltration and activation into the joint space and synovium, which leads to the generation of pro-inflammatory mediators such as TNFα and IL-17/23 that continue to drive the disease. A study carried out by Notley et al in 2008 utilised the CIA model to assess the effects of TNF blockade on IL-17 production. They found that mice treated with TNFR-Fc fusion protein or anti-TNF monoclonal antibody had reduced arthritis severity and showed reduced accumulation of Th1 and Th17 cells in the joint, but expanded Th1 and Th17 cell numbers in lymph nodes. Collectively, these findings suggested two opposing roles for TNF blockade in CIA, first blocking the accumulation of Th1 and Th17 cells in joints and secondly sequestration of pathogenic T cell numbers in peripheral lymphoid organs(30). In recent years, inducing rheumatoid arthritis in mice using serum transfer has become a more widely used model of RA, in part because the CIA model only works well in selected inbred mouse strains (a common feature of several mouse models of inflammation). The K/BxN serum transfer arthritis model was first described in the mid-90s as an inadvertent byproduct of crossing KRN T-cell receptor transgenic and nonobese diabetic (NOD) mice that lead to the development of spontaneous arthritis (31). Transfer of pathogenic anti-glucose-6-phosphate isomerase (GPI) antibodies from these mice to normal recipients resulted in the development of a severe arthritis as a result of alternative complement pathway activation and continual recruitment of neutrophil and mast cells into joints. A study from the laboratory of Mathis and Benoist employed this model to delineate the role of chemokines in leukocyte recruitment during the initiation of auto-antibody mediated arthritis. The authors induced arthritis by transferring serum into several chemokine and chemokine receptor deficient mice (CCR1–7, CCR9, CXCR2, CXCR3, CXCR5, CX3CR1, CCL2, or CCL3) and found that only the absence of CXCR2, a classical neutrophil chemokine receptor, was critical for the development of autoantibody-mediated joint inflammation and arthritisin C57/Bl6 mice (32). The ability of ApoE−/− mice on a C57BL6/J background to develop atherosclerotic lesions was first reported in 1992 and a similar phenotype in Ldlr−/− mice fed a high fat-high cholesterol diet was reported a few years later. These two mouse strains have been used extensively to study the cell and molecular biology of atherosclerosis in vivo (33). Mouse models of atherosclerosis involve many of the key features of human atherosclerosis including trapping of apoB-containing lipoproteins in the sub-endothelial space of major arteries, monocyte recruitment and macrophage differentiation. Acute Inflammation is a Process Generally ascribed to the Roman physician Celsus, the cardinal signs of acute inflammation in response to infection or tissue injury have been recognized for 2,000 years i.e. redness (rubor), heat (calor), pain (dolor) and swelling (oedema). Acute inflammation, like grieving, is a process (Billy Crystal, Robert de Niro, Analyze This, movie 1999 http://www.imdb.com/title/tt0122933/). The coordinated recruitment of plasma proteins, lipid mediators and myeloid cells in the inflammatory exudate can be defined by careful examination of sterile inflammation in the experimental model systems outlined above and can be organized under three headings. Initiation The earliest event in acute inflammation is sensing of pathogens and tissue damage, typically by tissue resident macrophages and mast cells. The most important role of these sentinel cells, which are relatively few in number, is to generate signaling molecules that lead to local endothelial cell activation in post capillary venules and autocrine and paracrine activation of macrophage effector functions within tissues. Amplification Locally generated signaling molecules cause important changes in the properties of nearby endothelium, including the release of the contents of Wiebel-Palade bodies, endothelial cell contraction, up-regulation of cell adhesion molecules (e.g. ICAM-1) and synthesis and presentation of chemokines. Acting in concert, all these changes in the endothelium allow for the local elaboration of an inflammatory exudate of plasma proteins and myeloid cells, especially neutrophils. Changes in the properties of endothelial cells cause the observed clinical signs of inflammation – redness and heat via increased local blood flow, oedema through elevated oncotic pressure caused by elevated albumin in tissues and localized pain through the action of locally produced mediators including bradykinin and Prostaglandin E2. It is the recruitment of plasma proteins and their subsequent proteolytic cleavage at sites of tissue damage or suspected pathogen invasion that leads to the massive amplification phase of inflammation that is essential for the localized recruitment of myeloid cells from the blood and their subsequent activation. Local activation of serine protease cascades in response to DAMPs and PAMPs (using the same molecular mechanism adopted by the horseshoe crab 220 million years ago) generates large quantities of potent protein and peptide mediators such as complement C3a, C5a and bradykinin. Resolution This is probably the least well-understood aspect of the acute inflammatory process. Termination of further leukocyte recruitment requires catabolism of inflammatory mediators, neutrophil apoptosis, macrophage efferocytosis of apoptotic cells, lymphatic drainage and the initiation of tissue repair processes. Described by many as an ‘active’ rather than a ‘passive’ process, definitive experiments addressing the cell biology of inflammation resolution using in vivo model systems are at a premium. An under-researched area of inflammation biology is the role of the lymphatic system in clearance of the inflammatory exudate during the resolution phase. One important anatomical arena where future research seems merited is the infarcted myocardium following recent studies showing changes to the cardiac lymphatic system following injury(34). Animal models of sterile peritonitis provide some idea of the potential timescale of the key events in acute inflammation. In the widely used mouse zymosan peritonitis model resident F4/80hi macrophages leave the serosal cavity to local lymph nodes within 60 minutes of inflammagen injection and neutrophil recruitment peaks at around 4 hours. PMN recruitment is followed by a wave of inflammatory Ly6Chi monocytes, which peaks between 16 and 24 hours. In this model neutrophil and monocyte numbers in the cavity return to baseline within 96 hours but these timings and the absolute number of myeloid cells depends on the dose and nature of the inflammagen. A recent paper from the group of Derek Gilroy extended analysis of the classic zymosan peritonitis model out past this 96-hour window and showed that a true return to tissue homeostasis following clearance of zymosan particles took more than three weeks (35). After disappearance of PMNs from the peritoneum, Newson et al observed changes in monocyte derived macrophage subsets and a significant increase in the number of B and T lymphocytes in the peritoneum. The recruitment and retention of this collection of lymphoid and myeloid cells long after the disappearance of the inciting sterile stimulus is intriguing. It will be important to see exactly how the mixture of cell types present post-inflammation contribute to tissue repair and defence against infectious disease. An important myeloid cell type that we will not consider in this brief review is the dendritic cell. An important question for immunologists and pathologists is, ‘Do dendritic cells play a unique role in the initiation, amplification or resolution of inflammation that cannot be provided monocyte derived macrophages recruited to the site of inflammation?’ Perhaps the unique, non-redundant role of DCs in inflamed tissues is to engage the anti-inflammatory/ pro-repair arm of the adaptive immune response, most notably Treg cells and perhaps some lesser-studied B-lymphocyte subsets such as B1 and Breg cells. Published studies on the role of DCs and B cell subsets in animal models of atherosclerosis may lead the way in this regard. A typical time course of an acute inflammatory response is shown in Figure 1 (after Christopher Buckley, University of Birmingham, U.K.). Representing the intensity of the inflammatory response on the Y-axis (measured as leukocyte recruitment, leukocyte activation or local inflammatory cytokine concentrations) the initiation, amplification and resolution phases of a stereotypic, ‘healthy’ acute inflammatory response can be clearly demarcated. Failure to clear the initial inflammatory insult or failure of inflammation resolution leads to chronic inflammation, represented by the horizontal arrow. Hyper-acute inflammation is represented by a continuing escalation of leukocyte recruitment, leukocyte activation (locally and systemically) and unrestrained inflammatory cytokine production. A couple of important discussion points arise from consideration of this simplistic representation of the ‘classical’ acute inflammatory response. The first is whether there is ever a complete absence of inflammation in host tissues i.e. should the Y-axis be set to zero at t=0? A paper published in 2010 by Jeffrey Weiser’s laboratory showed that that low-levels of systemic peptidoglycan derived from the gut microbiota primes the host innate immune system via the Nod1 receptor leading to more efficient neutrophil killing of Streptococcus pneumonia and Stahylococcus aureus (36). A second important discussion point arising from consideration of Figure 1 is ‘What regulates the magnitude of the acute inflammation response?’ and more specifically ‘Does the magnitude of the acute inflammation to the same inciting stimulus differ between tissues in the same individual and between individuals in the same population?’ A brief consideration of the mechanisms that might drive hyper-acute inflammation as presented in Figure 1 is also warranted. One simple explanation for the continuing amplification of acute inflammatory amplification seen in say, septic shock, could simply be the continuing proliferation of the initial bacterial infection that acted as the stimulus for the initiation of inflammation at t=0. Circumstantial evidence supporting such an explanation comes from a retrospective analysis of mortality data for patients admitted to hospital with suspected sepsis. In a cohort of 17,990 patients given antibiotics upon admission to 165 intensive care units with severe sepsis or septic shock the probability of in-hospital mortality increased steadily with time to antibiotic administration (37). An alternate explanation for hyper-acute inflammation could be failure of endogenous pathways that act to limit myeloid cell responses to PAMPs, a phenomenon that has been termed endotoxin tolerance (38) or the more recently appreciation of altered myeloid cell metabolism induced by sepsis (39). In Figure 2 we represent this question in a simple diagram. We propose that the magnitude of the host response to an inflammatory insult in any given anatomical location is the net result of the action of local pro-inflammatory mediators (upward arrows) and the opposing action of endogenous anti-inflammatory mediators (downward arrows). We have termed our model the ‘Inflammatory Set point Hypothesis’ and it stands apart from a previous theoretical consideration of the acute inflammatory response, which placed more weight on the kinetics of inflammation resolution by deriving a ‘Resolution Interval’ for comparing the effects of different therapeutic interventions in experimental animal models, typically zymosan peritonitis (40). The inflammatory set point model as presented in Figure 2 immediately suggests that pharmacological interventions that lower the activity of specific pro-inflammatory mediators (e.g. anti TNF antibodies or chemokine receptor antagonists) will reduce the maximal intensity of the acute inflammatory response. Another approach to reduce the peak level of inflammation would be to augment the activity of relevant endogenous anti-inflammatory mediators. This therapeutic rationale could be particularly efficacious in treatment of human diseases where the magnitude of the initial inflammatory response overwhelms the inflammation resolution machinery i.e. chronic (‘non-resolving’) inflammation and hyper-acute inflammation (see Figure 1). Consideration of experimental evidence for the importance of the downward arrows in Figure 2 comes from the enhanced inflammatory response seen in mice carrying gene deletions for the anti-inflammatory mediator Annexin A1 and its receptor Fpr2 (41). Finding evidence in support of the model presented in Figure 2 using human rather than murine models will be challenging but use of the beetle blister model could be instructive. Derek Gilroy and colleagues performed an interesting experiment where they gave human volunteers aspirin (75mg, oral once a day for 10 days) or placebo and then induced used a fixed dose of beetle cantharidin toxin to induce an acute inflammatory response in the skin characterized by dermal oedema and localized leukocyte recruitment. Volunteers taking low dose aspirin showed no change in blister oedema volume at 24 hours compared to volunteers taking placebo but did show reduced neutrophil and monocyte numbers in the inflammatory exudate (42). In terms of our set point model of Figure 2 the effect of low dose aspirin is likely two-fold, reducing pro-inflammatory drive by reducing local PGE2 production and simultaneously enhancing endogenous anti-inflammatory 15-epi-lipoxin A4 production. Monocytes and Inflammation Macrophages have been described as the “mature forms of circulating monocytes that have left the blood and taken up residence in the tissues” (The Immune System, Peter Parham, 3rd edition, Garland Science, NY and London, 2009). We now know that the origin of tissue macrophages is not exclusively from the circulating pool of monocytes. Under homeostatic conditions, many tissue resident macrophage populations are probably of embryonic origin and capable of self-renewal (reviewed in Sieweke and Allen (43). Most relevant to this chapter, however, is that an inflammatory stimulus will significantly increase the contribution of circulating monocytes to the tissue macrophage pool. In mice, the pool of circulating monocytes has been broadly divided into Ly6Chiand Ly6C lo subsets, which are also referred to as classical and non-classical monocytes, respectively reviewed in (44). In humans, the corresponding subsets are CD14+ CD16− and CD14lo CD16+, but the proportions of classical:non-classical monocytes varies by species (1:1 in mice and 9:1 in humans). Non-classical monocytes are thought to be derived from classical monocytes, but there is some evidence also for independent origin (45). The functions of circulating monocyte subsets in inflammation have been extensively studied, particularly in mice. CCR2-mediated mobilization and chemotaxis are major drivers of classical monocyte recruitment from bone marrow to blood, and from blood to inflammatory sites. This has been borne out in multiple studies of CCR2−/− mice. CCR2 deficient mice have fewer monocyte/macrophages in models of both acute e.g., thioglycollate-induced peritonitis (46) and chronic inflammation e.g., atherosclerosis (16). Likely this reflects both the impaired release of classical monocytes from the bone marrow as well as the reduced chemokine mediated recruitment of circulating monocytes to the site of inflammation. Though non-classical monocytes are low expressors of CCR2, in contrast to the classical cells they express high levels of CX3CR1. This chemokine receptor is thought to contribute not only to the migratory behaviour of the cells, but also to enhance the survival of both the non-classical monocytes in the blood and the tissue macrophages derived from them (47). Like classical monocytes, non-classical cells are recruited to sites of inflammation, but less abundantly so in both acute and chronic models (48). Also in contrast to the classical subset, they perform “patrolling” functions in the vasculature and can be recruited to non-inflamed tissues (49). Another contrast between the two subsets is the polarization of the tissue macrophages derived from each type. It is thought to be towards the activated M1 state for those of classical, and towards the anti-inflammatory, tissue repair M2 state for those of non-classical origin (50). There are a number of exceptions, however, to this “rule” (51), suggesting that the phenotype of the macrophages derived from each subset is likely to be context dependent. Though the bone marrow is typically the major source of circulating monocytes, in certain circumstances, there can be acute and substantial contributions from extra-medullary sources. One example is reported by Swirski, Nahrendorf, and their colleagues in a series of elegant papers reviewed in (52). In a mouse myocardial infarction (MI) model, in which the myocardium experiences ischemia-reperfusion damage, they observed, not surprisingly, that the inflammatory process followed that in wound healing; namely that there was biphasic entry of monocytes into the injured tissue, the first wave being classical (Ly6Chi) cells responding to a burst of locally produced CCL2, the ligand of CCR2. These cells became activated, M1-like macrophages. The two surprises were that the second wave also consisted of Ly6Chi cells. These converted to Ly6Clo cells in the injured tissue, where they became tissue-repair, M2-like macrophages (53) in a variation to the “rule” that tissue M2 macrophages are derived from circulating non-classical monocytes. The other surprise was that the source of the circulating monocytes was not the bone marrow directly, but rather the spleen, where monocyte progenitors (HSPCs) that travelled from bone marrow to specialized niches were stimulated to proliferate and to give rise to monocytes that entered the circulation and were recruited to the injured tissue (54). These observations leave open the question of whether drugs that inhibit CCR2 activity will ever find therapeutic utility post-MI patients. The Swirski-Nahrendorf results raise the possibility that blocking CCR2+ cell recruitment post MI will interfere with tissue healing and remodeling ultimately resulting in reduced cardiac output(55). Inflammatory Mediators Our brief consideration of acute inflammation and its resolution has highlighted the importance of sequential mobilization and differentiation of innate immune cells. Could sequential recruitment and differentiation of leukocyte subsets fit the bill for Henry Dale’s ‘Big Idea’ for inflammation biology? If so, it is clear that we will need to understand how different classes of inflammatory mediators are generated, how they change leukocyte migration and activation and ultimately how these mediators work together to effect tissue repair programmes. Different classes of mediators (briefly) Vasoactive amines - Activation of mast cells leads to rapid degranulation and the release of their potent pro-inflammatory granule contents e.g. vasoactive amines histamine and serotonin. These mediators act via specific GPCRs that can lead to vasodilatation and very rapid changes in cellular behaviour, e.g. endothelial cell contraction. Systemic mast cell degranulation can be fatal, for instance binding of food allergens to specific IgEs bound to mast cells via Fcε receptors. Cytokines and chemokines Cytokine genes are transcribed within minutes of exposure of macrophages to DAMPs and PAMPs and these cytokines can act in an autocrine and paracrine manner to further amplify the transcription of pro-inflammatory cytokines. Typically cytokine production by macrophages is measured in response to a single PAMP using primary cells (often bone marrow derived macrophages) cultured ex vivo. The advent of single cell transcriptomics will allow us to follow changes in the transcription pattern of the whole genome in sentinel cells responding to pathogens in infected tissues in vivo. To take full advantage of this surge in information we will need to stop thinking about cytokines in isolation and start thinking in terms of cytokine networks. Lipid mediators- In macrophages TLR signaling increases prostaglandin synthesis by activating cytosolic phospholipase A2 (cPLA2). cPLA2 releases arachadonic acid from membrane phospholipids and up-regulates cyclooxygenase-2 and microsomal prostaglandin E synthase-1 (mPGES-1) expression. These changes in intracellular lipid pools and lipid metabolizing enzymes set the scene for generation of multiple pro-inflammatory prostaglandins and leukotrienes. Later in the acute inflammatory response there is a marked ‘eicosanoid class switching’ which is marked by a switch to production of anti-inflammatory, pro-resolution lipid mediators such as Lipoxin A4 (56, 57). Gases as mediators - Since the Nobel Prize winning discovery of nitric oxide NO as a signaling molecule we now better appreciate two other gaseous signaling molecules that can act as anti-inflammatory mediators, carbon monoxide CO and hydrogen sulfide H2S (58). Vascular endothelial cell production of NO from L-arginine is catalyzed by endothelial nitric oxide synthase (eNOS, NOS3) and this almost ephemeral, very short-lived signaling molecule strongly influences vascular tone via cGMP signaling. CO is generated by heme catabolism by the enzyme heme oxidase-1 (HO-1) and CO exerts its anti-inflammatory effects via the MAPK pathway (59). The use of multiple H2S donors and selective inhibitors of H2S synthesis has helped to define the cellular actions of this gaseous signaling molecule. The therapeutic effects of H2S releasing drugs seen in animal models of inflammation has lead to H 2S releasing drugs been taken forward into clinical trials (60). A Brief Note on Inflammasomes and Autoinflammation As alluded to above, the field of inflammation biology owes much to the seminal papers of Jürg Tschopp (1951–2011) who first identified the cytoplasmic molecular machinery for secretion of active Interleukin 1β, a structure that he termed the inflammasome (61). The majority of inflammasomes are formed with one or two Nod-like receptor proteins (NLRs). Other non-NLR proteins including absent in melanoma 2 (AIM2) and pyrin can also form inflammasomes, as reviewed in (62). The N-terminal pyrin domain (PYD) within NLRs associates with apoptosis-speck like protein containing CARD (ASC) and this permits the recruitment of pro-caspase 1 to the inflammasome. The NLRP3 inflammasome is the most extensively studied inflammasome to date. NLRP3 activation can occur is response to a wide range of stimuli including infectious agents including intracellular bacterial products e.g. Shigella shiga toxin, extracellular ATP, monosodium urate or cholesterol crystals as well as changes in osmolarity or pH (63, 64). MCC950 is a highly selective inhibitor of NLRP3 that blocks canonical (ATP, monosodium urate) and non-canonical (cytosolic LPS) NLRP3 inflammasome activation at nanomolar concentration. Administration of MCC950 to mice with EAE, a murine pre-clinical model of human multiple sclerosis, has been shown to improve clinical symptoms and attenuate IL-1β production (65). The ability to pharmacologically inhibit NLRP3 inflammasome activation in pre-clinical models will greatly aid investigation of the role of this signaling complex in the pathogenesis of inflammation and could be the starting point for development of novel small molecule anti-inflammatory drugs. Over the past 25 years rheumatologists have come to recognize that autoinflammation as a distinct disease pathology from autoimmunity. Tumour Necrosis Factor Receptor Associated Periodic Syndrome (TRAPS) is a rare, genetic disease that causes recurrent episodes of fever that are associated with chills and muscle pain. In 1999 Kastner et al showed that TRAPS did not involve T or B lymphocyte activation but rather inappropriate innate immune activation caused by germline mutations in the 55kDa TNF receptor 1 (66). Kastner et al coined the term ‘autoinflammation’ for the observed defects in the regulation of systemic inflammation. Molecular analysis of other rare genetic diseases characterized by systemic inflammation with no obvious infectious disease or autoimmune component identified a group of rare monogenic diseases with defects in IL-1β production and the NALP3 inflammasome including Cryopyrin-Associated Periodic Syndromes (CAPS), Muckle Wells syndrome and familial cold autoinflammatory syndromes (67). Detailed analysis of other rare monogenic disorders continues to provide further examples of how loss of endogenous regulatory pathways can lead to inappropriate inflammatory and innate immune responses (68). Hyper-acute Inflammation – Bacterial Septic Shock and Viral Cytokine Storm Local activation of macrophages, mast cells and endothelial cells is essential to mobilize an acute inflammatory response to sites of pathogen invasion and tissue injury. However, systemic activation of these cells by bacterial PAMPs can lead to the life-threatening septic shock. An excessive systemic host reaction to viral pathogens such as influenza, frequently termed a ‘cytokine storm’, can also have life-threatening consequences, often in young people with a robust immune system (shown diagrammatically in Figure 1). The clinical sequelae of septic shock and cytokine storm show the importance of regulating the magnitude of the initial inflammatory response (Figure 2). The recent appreciation of the need to distinguish sepsis from septic shock serves only to emphasise the importance of return to tissue homeostasis following the initial triggering of a hyper-acute inflammatory response (69). There is a substantial unmet clinical need to develop better treatments for septic shock and sepsis but a better understanding of the disease process is being held back by the lack of good experimental models and the continuing failure to translate basic science findings into effective new treatments (70). One fruitful area for future research might be to identify and augment endogenous pathways that can rapidly decrease the maximal host inflammatory response without ‘paralysing’ the innate immune system altogether. Chronic Inflammation– Pathogenesis and Current Treatments In an excellent 2010 review article Carl Nathan and Aihhao Ding wrote, “The problem with inflammation is not how often it starts, but how often it fails to subside. Non-resolving inflammation is not a primary cause of atherosclerosis, obesity, cancer, chronic obstructive pulmonary disease, asthma, inflammatory bowel disease, multiple sclerosis, or rheumatoid arthritis, but it contributes significantly to their pathogenesis.” (24). In their review the authors lay out multiple overlapping and competing models for how chronic inflammation can arise in vivo. Failure to clear a pathogen that was the original trigger for inciting acute inflammation. Classic examples would be failure to clear mycobacterial infection or chronic virus persistence in hepatitis. Response to continuing tissue injury, for instance necrotic cell damage and the release of DAMPs caused by ischaemia reperfusion injury. Continuing presence of antigen, e.g. antigens recognized by autoantibodies in rheumatoid arthritis. Non-resolving inflammation, for instance the failure to clear macrophages and macrophage derived foam cells from atherosclerotic lesions in major arteries leading to the build up of stable and unstable atherosclerotic plaques, a form of chronic inflammation that persists for decades. Consideration of the multiplicity of pathogenic mechanisms in human diseases caused by chronic inflammation reminds one of the opening lines of Leo Tolstoy’s novel Anna Karenina ‘All happy families resemble one another, each unhappy family is unhappy in its own way’. All successfully resolved bouts of inflammation resemble one another in showing a return to ‘happy’ tissue architecture and essentially normal tissue function. In contrast, each chronic inflammatory disease shows ‘unhappy’ tissue architecture caused by multiple defects in the return to homeostasis. Current treatments for chronic inflammation include steroids, non steroidal anti-inflammatory drugs (NSAIDs), disease modifying anti rheumatic drugs (DMARDs) and ‘biologicals’; i.e. recombinant monoclonal antibodies or decoy receptors that block inflammatory cytokine function. An important mode of action shared by these drugs is that they reduce inflammatory leukocyte recruitment and dampen down adaptive immune responses. Although current anti-inflammatory drugs have different targets and widely different modes of action, they all share a common side effect, namely a potentially life-threatening reduction in the host immune response to infectious disease. In a recent review Ira Tabas and Chris Glass give a good discussion of the challenges of developing new anti-inflammatory drugs and how we might achieve selective dampening of myeloid cell recruitment without compromise of ‘first responders’ to infectious disease and wound repair (71). One promising approach might be to target pro-resolving agents specifically to sites of chronic inflammation, a proof of concept of this approach using nanoparticles was recently published by Tabas and co-workers(72). Unanswered Questions and Future Directions in Inflammation Biology Following our brief overview of the role of myeloid cells in inflammation we identify seven areas where further research is needed and offer seven questions for those working in the field. (1) Macrophage differentiation and plasticity in vivo For an excellent historical overview of the macrophage M0, M1, M2 concept and a critical assessment of the current literature the authors thoroughly recommend a recent review by Fernando Martinez and Siamon Gordon (73). It is tempting to think about macrophage subsets in the same way we think about T cell subsets in disease. However, advances in flow cytometry, including single cell detection of cytokine production, have thrown up many more T cell classifications than the simplistic Th1, Th2, Th17 classifications that we previously used to explain the role of T cells in disease pathogenesis. Key questions for the field include ‘Do M1 macrophages, defined by surface expression of a handful of different markers really do something substantially different from ‘common or garden’ F4/80hi tissue resident macrophages in the context of an ongoing inflammatory response?’ Similarly, ‘Do M2 (alternatively activated) macrophages, defined in vitro by a cluster of markers, really enhance tissue repair in the context of inflammation resolution or wound repair? Put another way; ‘How plastic is macrophage differentiation within tissues? The issue of macrophage plasticity in vivo has been placed centre stage by two important papers published in 2014 (74, 75). Lavin et al. elegantly demonstrated the plasticity of tissue resident macrophage differentiation by taking F4/80hi peritoneal macrophages from CD45.1 donor mice and instilling them into the lungs of CD45.2 recipient mice (without irradiation). In parallel they transferred F4/80hi alveolar macrophages from CD45.1 donor mice and injected them into the peritoneum of CD45.2 recipient mice. CD45.1 donor cells were recovered from their new tissue microenvironments three weeks later and their transcriptomes and chromatin marks were analysed and compared to those of resident peritoneal and alveolar macrophages in the same tissue. Strikingly Lavin et al showed a complete re-programming of chromatin marks and gene expression patterns in donor macrophages so as to match the macrophages already resident in the recipient tissue. Combined with the intellectual framework provided by Chris Glass and co-workers from their studies of enhancer transcripts and transcription factor binding in myeloid cells we now have a much better understanding of how macrophage subset gene expression patterns are established and re-programmed(76). Building on these seminal studies, we need develop robust methodologies for switching specific macrophage M1 and M2 functions on or off in situ. Such an experimental approach will allow us to move from observing changes in gene expression to actually changing macrophage cellular behaviours within a site of chronic inflammation. The application of optogenetic technologies, until now largely confined to the CNS, might be one way to achieve this ambitious goal. In the future could changing macrophage behaviour in chronic inflammation be used as a novel therapeutic modality, e.g. enhancing macrophage emigration from atherosclerotic plaques, or changing the behaviour of tumour associated macrophages? (2) Functional assays for pro-resolution macrophages Over the last 30 years intense study of the molecular biology of inflammatory mediators, be they pro- or anti- inflammatory, has occurred at the expense of studying the cell biology of tissue repair and healing. Inflammation research would benefit greatly from developing useful ex vivo and in vivo models of tissue repair and fibrosis. Ideally such models should incorporate features of (patho)physiological ECM and tissue architecture, e.g. 3D cultures rather 2D tissue cultures on plastic. In recent papers Dalli and Serhan have shown that sulfido-conjugates of the pro-resolution lipid mediator maresin hasten the resolution of acute inflammatory responses. To test the ability of these mediators to promote tissue regeneration they have turned to tissue regeneration models using a Planaria flatworm model (77, 78). Tissue repair in mammals exhibits significant differences to the tissue regeneration seen in flatworms and urodeles following amputation. This important caveat emphasizes the need for developing more model systems to study the important process of tissue repair and healing. Will a better understanding of successful tissue repair processes in mammals allow us to develop treatments to prevent the irreversible effects of chronic inflammation - tissue destruction and fibrosis? (3) Time of day and time of life – circadian rhythms and Inflamm-aging Nearly all aspects of mammalian physiology have been shown to be strongly influenced by the time of day. A series of experiments from the laboratory of Ajay Chawla elegantly demonstrated that even something as critical to the host as response to Listeria monocytogenes infection is susceptible to circadian rhythm. Having demonstrated a 2–3 fold circadian oscillation in Ly6Chi monocyte numbers in blood and spleen Nguyen et al. infected two groups of C57BL/6J mice being kept on a 12 hour light / dark cycle with the same intraperitoneal dose of L. monocytogenes8 hours apart in terms of their Zeitgeber time (ZT). Mice infected at ZT8 had reduced bacterial counts in blood and tissues 2 days post infection compared to mice infected at ZT0 and this was correlated with improved recruitment of Ly6Chi monocytes to the site of infection. Mice with myeloid-specific deletion of the clock gene Bmal1 showed no rhythmic alterations in Ly6Chi monocyte numbers in blood, spleen or bone marrow and none of the circadian variation in chemokine gene expression seen in wild-type animals (79). The impact of circadian oscillation on innate immune cell numbers and myeloid cell gene expression patterns may explain the link between shift work, altered sleep patterns and increased risk of obesity, diabetes, certain cancers and cardiovascular disease (80). Aging populations, including our own, are characterized by chronic, low-grade inflammation often accompanied by elevated cortisol levels. This phenomenon merits further investigation because with few exceptions all age related diseases have a strong inflammatory component. The term ‘Inflamm-aging’ was coined by Franchesi and colleagues in 2000 and has become somewhat of a ‘poster child’ for systems biology ever since (81). In Figure 3 we have tried to represent key features of inflamm-aging in an idealized time course of inflammatory responses to a single inflammatory stimulus. The first point to note is that the inflammatory response in older subjects starts from an elevated baseline at t=0 but an important and key question is whether older experimental subjects show an elevated maximal response to the same inflammatory stimulus and whether the resolution of inflammation occurs more slowly in comparison with younger test subjects. In contrast to studying how the inflammatory response varies in inbred mouse strains over a 24-hour period, experimental investigation of how inflammatory responses are altered in older cohorts of experimental animals will be challenging but could bring novel mechanistic insights. Studies on exactly how inflammatory responses in humans change with age will be purely comparative (for instance GWAS of people living to 100 years of age), but studying the efficacy of immune responses to say influenza vaccines in different human cohorts might be a promising place to start teasing apart changes in the immune response with age. Future clinical and pre-clinical studies should take more account of the age of participants and the time of day when studies are performed. For instance does the efficacy of anti-inflammatory drugs vary with the time of delivery and/or age of the patient? Another important challenge will be to decide whether anti-inflammatory / pro-resolution agents should be given in extended versus short release formulation. The optimal drug formulation may well depend upon the ‘target’ and the specific disease. (4) Micro RNAs – Nature’s own cytokine network regulators? Micro RNAs (miRNAs) are estimated to modulate the expression of ~30% of all protein encoding genes in the mammalian genome so it is not surprising that multiple miRNAs have been shown to modulate myeloid cell inflammatory responses in a number of different settings. Silencing miRNA expression in vivo through the use of chemically modified oligonucleotides called ‘antagomirs’ has emerged as a new therapeutic modality for the development of novel anti-inflammatory drugs. The path to randomized clinical trials faces obvious problems, not least the mode of delivery and targeting antagomirs or miRNAs to the site of inflammation. However, the recent FDA approval of KYNAMRO, mipomersen sodium of a closely related therapeutic class of molecules- anti-sense oligonucleotides (ASOs)- gives rise to optimism for this approach. In a recent report Wang et al compared the efficacy of systemic delivery of an anti-miR21 compound versus the same reagent delivered via a drug eluting stent in an experimental animal model of in stent restenosis. The authors showed that an anti-miR21 oligonucleotide could prevent in stent restenosis in a balloon injured human internal mammary artery transplanted into nude rats equally well with either delivery method, but an anti-miR21 coated stent gave rise to fewer side effects(82). Will a better understanding of the roles miRNA splay in modulating inflammatory responses lead to the development of new drugs for regulating cytokine networks? (5) Metabolic inflammation and obesity -mediators and microbiota Increasing levels of obesity in the developed world have led to an alarming increase in the incidence of type 2 diabetes and cardiovascular disease. These conditions are associated with increased systemic inflammation and leukocyte infiltration into white adipose tissue (WAT). Healthy WAT in lean subjects is characterized by a population of M2 macrophages with the type 2 cytokines IL-4 and IL-13 for M2 polarisation being provided by eosinophils, which are present in reduced numbers in obese WAT. Furthermore, pro-inflammatory monocytes recruited into WAT differentiate into M1 macrophages that contribute to insulin resistance and dyslipidemia (83). It is not yet clear whether targeting leukocyte recruitment to and leukocyte activation within adipose tissue will be a viable strategy to prevent the conversion of obesity and metabolic syndrome into type 2 diabetes. Obesity is one of the more obvious manifestations of a “Western-Lifestyle” but some immunologists have postulated a link between the increased incidence of allergies, asthma and autoimmunity with changes in diet and host microbiota generated metabolites (84). Studies in pre-clinical models of inflammation have revealed the importance of a series of metabolite receptors including GPR41, GPR43, GPR109 and GPR120 expressed by innate immune cells that can have potent anti-inflammatory actions. One of the first papers to reveal a link between diet, the gut micobiota, short chain fatty acid (SCFAs) and inflammation was provided by the laboratory of Charles Mackay in 2009. Maslowski et al showed that Gpr43−/− mice had excessive inflammation in models of colitis, arthritis and asthma. Germ free mice showed a similar exacerbation of inflammatory responses consistent with bacterial fermentation of complex carbohydrate generating SCFAs for stimulation of GPR43’s anti-inflammatory actions (85). In the future will we be able to exploit our increasing knowledge of crosstalk between the microbiota, microbial metabolites and host metabolite receptors to modulate host innate and adaptive immune responses for therapeutic benefit ? (6) Towards a more molecular definition of inflammation In all pathology textbooks inflammation is defined by timing, being either short-term (acute) or long-standing (chronic). An alternative classification of inflammation could be envisaged that takes account of the inciting stimulus, e.g. metabolic inflammation, or the inflammatory cytokines that drive a specific chronic inflammatory disease process e.g. TNF versus IL-6 driven disease (86). Rapid advances in combined liquid chromatography mass spectroscopy (LC-MS) techniques for inflammatory exudates may soon allow us to draw up alternative classifications based on tissue responses to infectious diseases. A striking example is provided by two recent papers that followed the time course of lipid mediator appearance in the lungs of humans hospitalized with influenza infection and mice infected with the same titer of different strains of influenza that differed in their virulence. Morita at al and Tam et al. undertook a detailed analysis of host lipid mediators and their regulation during the course of influenza infection and correlated these changes with viral replication, host immune responses including transcriptomics and measurement of cytokine and chemokine profiles. One important result from these two extensive lipidomics studies in clinical cohorts and pre-clinical infection models was the identification of the endogenous lipid mediator protect in D1 as a potent inhibitor of influenza infection. In the longer term, advances in LC-MS technology and our ability to interpret large data sets may allow us to better assess the severity of respiratory distress and virus pathology through analysis of nasal swabs of patients hospitalized with influenza (87, 88). Ultimately, will better identification of the molecules and receptors that drive acute and chronic inflammation lead to better treatments and better patient outcomes? (7) Future anti-inflammatory drug targets and clinical trials In twenty years time when the current frontline biologics du jour such as anti TNFα, anti IL-1β, anti IL-6, anti IL-17 etc. have gone generic, we may well view these pioneering monoclonal antibodies and decoy receptors as excellent ‘test reagents’ used to identify the specific cytokine networks or specific cell types that cause chronic inflammatory responses. Currently a sub-group of RA and MS patients seem to respond better to B-lymphocyte depleting antibodies, such as the anti-CD20 monoclonal Rituximab, than they do to anti-TNFα biologics. In the future we would like to identify patients whose disease will respond better to anti B-lymphocyte therapy as soon as possible to avoid ‘hit or miss’ dosing with powerful and expensive drugs. Careful analysis of current clinical outcomes combined with biomarker analysis and pharmacogenomics studies will have the twin benefit of improved outcomes for patients and new insights in the pathogenesis of chronic inflammatory disease in human cohorts(86). Rheumatologists have long sought after biomarkers, haplotypes, environmental factors and genetic markers that can identify patients at increased risk of developing rheumatoid arthritis. Recently biomarker panels have been expanded to include serum titers of anti-citrullinated peptide antibodies (ACPA). Early reports have given rise to the idea that this class of auto-antibodies may be driving chronic inflammation in tissues other than the joints, most notably within the lungs of patients before they present with joint inflammation and are diagnosed with RA (86). If ACPA screening could identify people who will go on to develop debilitating RA up to a decade later, what will we do with this knowledge? Should we treat this pre-RA lung inflammation aggressively with systemic anti-cytokine biologics or should we use inhaled glucocorticoids? Alternatively, should we call back people with high ACPA titers for radiological assessment every year and initiate aggressive anti-inflammatory treatment as soon as we see any sign of joint disease? An analogy can perhaps be drawn with the link between elevated plasma LDL, accelerated atherosclerosis and the increased risk of cardiovascular disease where primary prevention emphasizes lifestyle changes and prescription of statins. In the future will we start prescribing anti -inflammatory drugs for people with pre-diabetes, pre-RA or even pre-dementia? DRG thanks Siamon Gordon for introducing him to macrophage biology and Thomas Schall for introducing him to chemokines and their receptors. We thank Lewis Taylor, and Sophia Valaris for constructive criticisms. Work in the laboratory of DRG is supported by the British Heart Foundation (RG/10/15/28578, RG/15/10/23915). Work in the laboratory of EAF is supported by the US National Institutes of Health (HL098055 and DK095684). We are grateful to the Royal Society for an International Exchange Grant (IE120747). Figure 1 Time course of a typical acute inflammatory response A schematic representation of the ideal outcome of an acute inflammatory response, i.e. resolution, is shown as a dashed line. Two potential outcomes leading to significant clinical sequelae are shown, hyper-acute inflammation e.g. septic shock and non-resolving, chronic inflammation e.g. rheumatoid arthritis. Figure 2 The inflammatory set point hypothesis This schematic representation highlights the balance between locally produced pro-inflammatory and endogenous anti-inflammatory / pro-resolution mediators in determining the magnitude of the inflammatory response in response to a given stimulus. Figure 3 Inflamm-aging, do inflammatory response change with age? This schematic representation compares the ‘normal’ inflammatory response (solid line) with the inflammatory response seen in aged populations (dashed line). Aged populations show increased basal levels of systemic inflammation and may show differences in the magnitude of the response to inflammatory stimuli and/or altered resolution. 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PMC005xxxxxx/PMC5119647.txt
LICENSE: This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. 8006349 6600 Placenta Placenta Placenta 0143-4004 1532-3102 27697215 5119647 10.1016/j.placenta.2016.07.005 NIHMS808656 Article Differential expression of Toll-like receptors in the human placenta across early gestation Pudney Jeffrey 2 He Xianbao 1 Masheeb Zahrah 2 Kindelberger David W. 3 Kuohung Wendy 2* Ingalls Robin R. 1* 1 Section of Infectious Disease, Department of Medicine, Boston Medical Center and Boston University School of Medicine, Boston, MA, USA 2 Division of Reproductive Immunology, Department of Obstetrics and Gynecology, Boston Medical Center and Boston University School of Medicine, Boston, MA, USA 3 Department of Pathology and Laboratory Medicine, Boston Medical Center and Boston University School of Medicine, Boston, MA, USA * To whom correspondence should be addressed: Dr. Robin R. Ingalls, EBRC Room 610, 650 Albany St., Boston, MA 02118 USA, ringalls@bu.edu. Dr. Wendy Kuohung. 85 East Concord St., 6th floor, Boston, MA 02118 USA, wkuohung@bu.edu * Contributed equally to this work. 6 8 2016 26 7 2016 10 2016 01 10 2017 46 110 This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. Toll-like receptors (TLRs) are an essential component of the innate immune system. While a number of studies have described TLR expression in the female reproductive tract, few have examined the temporal expression of TLRs within the human placenta. We hypothesized that the pattern of TLR expression in the placenta changes throughout the first and second trimester, coincident with physiological changes in placental function and the demands of innate immunity. We collected first and second trimester placental tissue and conducted quantitative PCR analysis for TLRs 1-10, followed by immunohistochemistry to define the cell specific expression pattern of a subset of these receptors. Except for the very earliest time points, RNA expression for TLRs 1-10 was stable out to 20 weeks gestation. However, the pattern of protein expression evolved over time. Early first trimester placenta demonstrated a strong, uniform pattern predominantly in the inner villous cytotrophoblast layer. As the placenta matured through the second trimester, both the villous cytotrophoblasts and the pattern of TLR expression within them became disorganized and patchy, with Hofbauer cells now identifiable in the tissue also staining positive. We conclude from this data that placental TLR expression changes over the course of gestation, with a tight barrier of TLRs forming a wall of defense along the cytotrophoblast layer in the early first trimester that breaks down as pregnancy progresses. These data are relevant to understanding placental immunity against pathogen exposure throughout pregnancy and may aid in our understanding of the vulnerable period for fetal exposure to pathogens. innate immunity reproductive immunology pregnancy Toll-like receptors placenta INTRODUCTION The mammalian placenta is a highly specialized organ composed of both maternal and fetal cells that performs vital functions for the developing fetus during gestation. In addition to transfer of nutrients, gas exchange, elimination of waste, and hormone production, the placenta is an important site of immune defense for the fetus against maternal rejection as well as exogenous microbial insults. During pregnancy, the maternal immune system adapts to permit tolerance of the fetal allograft while maintaining defenses against harmful pathogens [reviewed in (1, 2)]. Any disturbance in this tightly regulated balance may lead to a breach in immune defenses, intrauterine infection by bacteria or viruses, and obstetrical complications such as miscarriage, preterm labor, intrauterine growth restriction, and preeclampsia. Elucidating the etiology of intrapartum infection requires identifying not only the infectious agent but also the route of entry into the amniotic cavity. In contrast to the formerly held belief that the amniotic tissues are sterile, a number of studies over the past two years suggest the placenta harbors a unique, low-level microbiome that may be linked to birth outcome (3–7). Surprisingly, these studies demonstrate that the taxonomic profile of the gravid vaginal microbiome was quite dissimilar to that of the placental microbiome, favoring hematogenous dissemination over intrauterine ascension as the more common route of entry of infectious agents. It is therefore likely that immune defenses contained within the placenta, the barrier between maternal and fetal circulation, are critical in preventing the transmission of both commensals and pathogens. Toll-like receptors (TLRs) are a fundamental component of the innate immune system (8) and constitute an important host defense in the placenta against intrapartum infection. This family of transmembrane receptors plays a pivotal role in the recognition of microbial ligands by the innate immune system (9, 10). Toll, initially identified as a receptor involved in embryonic development in Drosophila (11), was found to regulate important antimicrobial responses against fungi in the adult fly (12), an observation that set off an explosion of research to identify similar receptors in humans and mice. At least ten mammalian orthologues of Toll have been identified, and most have been implicated in cellular responses to microbial pathogens [reviewed in (13–17). For example, TLR4 and the secreted protein myeloid differentiation factor 2 (MD-2; also known as lymphocyte antigen 96 or Ly96) are required for recognition of lipopolysaccharide (LPS); TLR2, paired with TLR1 or TLR6, recognizes bacterial lipoproteins and lipoteichoic acid; TLR5 recognizes bacterial flagellin; TLR9 recognizes CpG enriched double-stranded DNA; TLR7 and TLR8 recognize single-stranded RNA (ssRNA); and TLR3 recognizes double stranded RNA (dsRNA) [reviewed (14)]. The TLRs can be sub-divided into surface expressed TLRs (TLR1, -2, -4 and -5) and endosomal expressed TLRs (TLR3, -7, -8, and -9). Upon recognition of pathogen-associated ligands, the TLRs dimerize, initiating a signaling cascade that leads to the secretion of proinflammatory cytokines and antimicrobial peptides, induction of interferon stimulated genes (primarily from the endosomal TLRs and TLR4), as well as activation of the adaptive immune response. In contrast to the abundant data on TLR function, the temporal expression of toll-like receptors (TLRs) throughout pregnancy has not been as well studied. It is known that TLRs 1-10 are expressed in term human placenta, and that TLR2 and TLR5 transcripts appear to rise in association with labor (18). A recent survey of expression and function of TLRs in first trimester cytotrophoblasts suggests that TLRs are broadly expressed at 6–12 weeks gestation (19), although a comparison to second and third trimester placental tissue was not done. Knowledge of temporal shifts in TLR expression at the maternal-fetal interface may be important clinically to establish periods of increased maternal susceptibility to transmit infections such as CMV and Zika virus or optimal windows for treatment of infections that could impact the fetus. In this report, we describe the expression of TLRs in the human placenta at the level of gene expression and protein, reviewing the relevant details of placental histology over the first and second trimester. MATERIALS AND METHODS Study samples First and second trimester placentas were obtained from elective termination of pregnancies under a protocol approved by the Institutional Review Board (IRB) for the Boston University Medical Campus and in accordance with the principles expressed in the Declaration of Helsinki. Criteria for exclusion of placental samples included known current maternal viral or pelvic infection, preexisting fetal demise, and known abnormal fetal karyotype. Termination of pregnancy was performed by suction dilation and evacuation. Samples were divided according to trimester of collection as follows: first trimester, up to 12 weeks; and second trimester, 12–24 weeks gestation. Gestational age was dated according to the subject’s last reported menstrual period and/or ultrasound dating as well as foot measurement when possible. At least 2 placental specimens representing each week of gestation were obtained during the first trimester of pregnancy from 6–12 weeks and during the second trimester from 13–22 weeks. More specific numbers of samples per analysis are provided below. Placental tissue utilized for RNA analysis was stored in RNAlater (Qiagen) for later processing for RNA extraction. The remaining samples for histology were fixed in 10% unbuffered methanol-free formaldehyde and processed for embedding in wax; 5 μm thick sections were cut from each sample and placed on glass slides for histological analysis. RNA isolation Placental tissue was homogenized by using a Tissue Homogenizer LT (Qiagen) and TRIzol (Life Technologies). After pelleting tissue debris, tissue homogenates were transferred to a fresh tube and chloroform was added. After precipitation of protein, the RNA-rich upper aqueous phase was transferred, mixed with an equal volume of 70% ethanol, and then loaded onto RNeasy Mini Kit columns (Qiagen). All RNA was treated with RNase-free DNase (Qiagen) prior to cDNA synthesis. Quantitative reverse transcriptase PCR analysis A total of 11 samples were available for PCR analysis (first trimester, n=6 samples; second trimester, n=5 samples). Quantitative reverse transcription PCR analysis (qRT-PCR) for TLR expression was performed with the TaqMan Expression Assay system (Life Technologies), which utilizes FAM-MGB probes for each target. Primer IDs for the target genes [TLRs 1-10, MD-2, GAPDH, and N-myc downstream-regulated gene 1 (NDRG1)] are shown in Table 1. cDNA preparation was carried out using High Capacity RNA-to-cDNA kit (Life Technologies). The final 20 μl PCR reaction mixture consisted of 10 μl of 2x TaqMan Gene Expression Master mix, 1 μl of cDNA, 8 μl of RNase-free water, and 1 μl of TaqMan Gene Expression Assay mixture containing the target primer. Reactions were performed in a 96-well plate and the housekeeping gene GAPDH was used as internal control. Real-Time PCR was run on an Applied Biosystems StepOnePlus™ Real-Time PCR System using a standard program (50°C for 2 min, 95°C for 10 min, followed by 40 cycles of 95°C for 15s and 60°C for 1 min). PCR data was analyzed using StepOne Software v2.3, and the comparative Ct method to calculate relative quantitation. The Ct from the target genes of each sample was normalized to the Ct of the reference gene GAPDH, to generate the sample delta Ct (ΔCt sample = Ct reference gene GAPDH − Ct target). To compare the gene expression levels between samples of different gestational age, the target genes were normalized to sample 1, which we defined as the earliest gestational age (sample ΔΔCt = sample ΔCt − sample 1ΔCt). To compare the different TLR gene expression levels, the TLR genes were normalized to the expression of TLR10 sample 1, which was the lowest expressed gene by both semi-quantitative PCR and real-time PCR. The Relative Quantitation (RQ) was calculated as: RQ = log2(−ΔΔCt). Graphpad Prism software 6.0 was used for statistical analysis of the data. For statistical comparison of a given target between the first and second trimester, a student’s t-test was used. A p value < 0.05 was considered statistically significant. The R-squared (R2) value for RQ vs. gestational age was calculated using a simple linear regression model. Histology and immunohistochemistry Two placental samples per gestational week studied were analyzed for TLR expression except as noted here: week 7 utilized 4 samples, and weeks 18 and 19 utilized 3 samples. For general histological analysis, sections from each gestational week studied were stained with routine hematoxylin and eosin (H&E). A trained pathologist in Obstetrics and Gynecology routinely screened these slides for the presence of inflammation, infection or abnormal placental development. No morphological evidence for any pathological conditions or changes were detected in any of the placental tissues examined. All placental samples that were studied for expression of the TLRs were therefor judged to be normal. The immunohistochemical analysis of TLR expression in placental tissue was carried out as previously described (20). Briefly, an antigen retrieval step was carried out by immersing the sections in a citrate buffer (pH 6.0), and heating them to 125°C for 30 seconds in a pressure cooker (Biocare Medical, Concord, CA, USA). The sections were rinsed thoroughly in distilled water and incubated with a blocking reagent (Background Sniper, Biocare Medical) prior to the application of primary antibodies directed against TLR2 (Novus Biologicals, Littleton, CO, USA) at 1:100 dilution; TLR3 (Santa Cruz Biotechnology Inc., Santa Cruz, CA, USA) at 1:100 dilution; TLR4 (Novus Biologicals) at 1:120 dilution; TLR5 (Santa Cruz Biotechnology) at 1:80 dilution; and TLR9 (Santa Cruz Biotechnology) at 1:110 dilution for 60 minutes at room temperature. This was followed by washing in Tris buffer containing 0.1% Tween 20 (TBST). The antibodies were detected with a proprietary secondary reagent (MACH 4 Universal Alkaline Phosphatase, Biocare Medical) that detects both mouse and rabbit primary antibodies. The sections were then washed in TBST, and the antibodies visualized by incubating with a substrate for alkaline phosphatase (Vulcan Fast Red Chromogen, Biocare Medical) that stains positive cells a bright red. Development of the staining was monitored by light microscopy. Following a final wash, the sections were counterstained in aqueous hematoxylin mounted in a glycerin-based medium and mounted on a coverslip. Sections were analyzed under an Olympus microscope (Olympus America Inc., Center Valley, PA, USA) and images captured with a DP70 digital camera. Negative controls for the immunohistochemistry were processed in the absence of the primary antibodies. These were replaced with either the antibody diluent or a mouse or rabbit control antibody (Vector Laboratories, Burlingame, CA, USA) at the same concentration. RESULTS Expression of TLR genes across the first and second trimester is stable In order to quantify the changes in TLR gene expression in the placenta during the first and second trimester of pregnancy, we conducted a quantitative analysis for placental expression of the genes for TLRs 1-10 and the TLR4-associated protein, MD2. Comparisons were made to the housekeeping gene GAPDH, as well as the placental gene NDRG1, which has been shown to be expressed throughout the placenta in a relatively stable manner (21). We found mRNA for all 10 TLRs and MD2 could be detected, and for the majority of the TLRs, expression increased with gestational age. This is illustrated in Table 2, where raw Ct values are shown for each of the TLR targets tested, and Fig. 1, where relative gene expression (RQ) is graphed against trimester and gestational age. We found expression of TLR3 was the highest compared to the other TLRs in both the first and second trimester without a significant change in expression over time. We found a statistically significant increase in the RQ value in the second trimester compared to the first trimester samples for TLR1, TLR4, TLR7 and TLR8, with a non-significant trend towards increased RQ for TLR2 and TLR10 (Fig. 1A). For some of the TLRs (TLR1, TLR4, TLR7, TLR8), the increase in gene expression could be predicted by the gestational age, as shown by the calculated R squared value (Fig. 1B). In comparison, expression of the placental gene NDRG1 is stable across gestation. The limitation of this data is that it reflects gene expression not protein expression within a tissue of mixed cellular composition. To further examine cell specific expression in polarized cells within a tissue, we turned to immunohistochemistry. Histological changes within the placental villi during the first and second trimester We began by characterizing the histological changes that occur within the chorionic villi of the placenta over the first and second trimester using routine H&E staining of tissues, analyzing at least two tissues obtained at each time point. As shown in Fig. 2, there was considerable variation in the morphological composition of the placental villi with progression of gestation. As has been described, during the earliest weeks of gestation that we could evaluate (6–8 weeks), the inner villous cytotrophoblast layer was essentially continuous, consisting of small, regularly shaped cuboidal cells with round to oval nuclei (Fig. 2A). With further progression (9–12 weeks), the villous cytotrophoblast layer of some villi was noted to be more disorganized, whereas in some others it appeared as an attenuated layer of cells that were more flattened (Fig. 2B, 2C). Towards the end of the first trimester, a number of villi could be seen with scattered, large, cells within the cytotrophoblast layer (Fig. 2D). As gestation proceeded into the second trimester, the morphological changes observed to be taking place in the first trimester progressed such that few villi now possessed an intact layer of villous cytotrophoblasts. Although an attenuated cytotrophoblast layer could still be detected in some villi, in the majority of cases, cell-cell contact between cytotrophoblasts was lost leaving a loosely organized cellular layer beneath the outer syncytiotrophoblast (Fig. 2E). This resulted in a greater level of structural diversity between the individual villi for each placental sample compared to that observed in the first trimester. Moreover, it appeared that the few identifiable cytotrophoblasts were now increased in size and irregular in shape when compared to those present in the first trimester, perhaps suggesting increased differentiation towards a syncytiotrophoblast phenotype (Fig. 2F). With further maturation of the placenta during the last weeks of the second trimester, it was observed that many villi still possessed small but varying numbers of large villous cytotrophoblast cells scattered at the periphery. For many other villi, however, it was difficult to precisely identify the presence of any villous cytotrophoblast layer, and the villi instead appeared to be surrounded by a single layer of syncytiotrophoblast cells (Fig. 2G). Expression of TLRs within the placental villi during the first trimester of pregnancy Using immunohistochemistry protocols developed by our laboratory we examined the expression of TLR2, TLR3, TLR4, TLR5, and TLR9 in the available placental tissues. Negative controls of placental tissue samples observed at any stage of gestation showed no to little evidence of background or non-specific staining when the primary antibody was replaced with the antibody diluent (Fig. 3A). There was however a slight increase in background staining in placental tissues when incubated with either the rabbit IgG or mouse IgG negative controls (Fig. 3B). We found that in the early first trimester, at 6–7 weeks of gestation, the inner villous cytotrophoblast layer expresses all the TLRs that were studied (Fig. 4). Staining for TLR2 appeared especially intense on the cell membrane of the villous cytotrophoblast adjacent to the syncytiotrophoblast layer (Fig. 4A). This often gave the appearance of an apparent solid band of TLR2-positive staining dividing these two layers of cells (Fig. 4B). Staining for TLR4 and TLR5 was also membrane associated, but in contrast to TLR2, expression was not polarized (Fig. 4D and 4E). As expected for the endosomal TLRs, expression of TLR3 and TLR9 was observed as positive cytoplasmic staining within cytotrophoblasts (Figs. 4C and 4F), although unlike the surface expressed TLRs, the positive cells were discontinuous in some areas. The expression of TLR2, TLR3, TLR4, and TLR5, as evidenced by the intensity and pattern of positive staining in the cytotrophoblasts for all these TLRs, appeared to be fairly consistent, not only between the different placental samples studied at this stage, but also between the individual villi present within the same sample. The exception was TLR9, for which some villi, even from the same placenta, demonstrated abundant positive cytoplasmic granules throughout the sample, while others showed few or no cytoplasmic granules within the cells of the cytotrophoblast layer. Later in the first trimester (8–12 weeks), there was more variability in the intensity and distribution of the staining (Fig. 5). Villi that still possessed an intact cytotrophoblast layer consisting of conspicuous, well-developed, round cells were found to stain positive for the TLRs 2, 3, 4, 5 and 9 in a manner resembling that observed at 6–7 weeks gestation. The flattened, discontinuous cytotrophoblasts present in other villi also expressed TLR2 in a similar fashion to the earlier stages of gestation, with what appeared to be a continuous band of intense staining along the outer membrane bordering the syncytiotrophoblast (Fig. 5A). However, staining for TLR3 in many areas was more intense on the outer villous cytotrophoblast cell membrane adjacent to the syncytiotrophoblast layer, similar to what we had observed with TLR2, with some cytosolic staining as well (Fig. 5B). In contrast, the staining for both TLR4 and TLR5 appeared to be more uniform on the cell membrane of these cells, with some staining visible in the cytosol (Fig. 5C and 5D). The villous cytotrophoblasts, either as a discontinuous or flattened layer of cells, also stained positive for TLR9 with some variability in the expression similar to what we had observed earlier in gestation (Fig. 5E and 5F). Expression of TLRs within the placental villi during the second trimester of pregnancy During the early stages of the second trimester (13–17 weeks), the villous cytotrophoblasts in most villi were present as a loosely organized layer of large, often irregularly shaped cells (Fig. 6). It was observed that only a small number of these isolated cells were now expressing TLR2, although the pattern still resembled that observed in the first trimester, with intense expression on the membrane adjacent to the syncytiotrophoblasts (Fig. 6A). Other cytotrophoblast cells showed no TLR2 staining (Fig. 6B). TLR3 also appeared to be expressed by the villous cytotrophoblasts at this stage with both cytosolic and membrane staining detected (Fig. 6C). Intense staining was detected for TLR4 in the villous cytotrophoblasts, whether they were present as a disorganized layer or as individual cells scattered around the villi (Figs. 6D and 6E). Strong expression of TLR5 was also observed (Fig. 6F). As in the earlier time points, there appeared to be variability in the expression of TLR9 by the villous cytotrophoblasts. Whereas in some villi only a few cells stained positive for TLR9, in others it was apparent that most if not all of the cells contained intensely TLR9 positive granules (Fig. 6G). As the placenta developed during the last weeks of the second trimester (18–22 weeks), it was observed that some of the disorganized and often isolated cells of the villous cytotrophoblast layer still maintained the polarized staining for TLR2 with greater expression present on the cell membrane adjacent to the syncytiotrophoblast (Fig. 7A). Interestingly, the staining for TLR3 by the villous cytotrophoblasts was found to vary. For many villi, the remnant villous cytotrophoblast layer of large cells displayed uniform cytoplasmic expression of TLR3 (Fig. 7B), while in other villi, cells displayed TLR3 expression in a polarized fashion, similar to TLR2, with more intense staining of the cell membrane adjacent to the syncytiotrophoblast (Fig. 7C). Expression of TLR4 was consistently detected on all villous cytotrophoblast cells (Fig. 7D), while expression of TLR5 and TLR9 was not regularly detected (Fig. 7E and 7F). Hofbauer cells Cells that morphologically resembled Hofbauer cells were detected in villi during the early weeks (6–7) of gestation. As pregnancy proceeded however increasing numbers of putative Hofbauer cells appeared to be present in placental villi. These cells occurred in varying numbers in villi and many were found to stain positive for TLR2, 3, 4, 5 and 9. Examples of this are TLR2 (Fig. 6B arrow), TLR3 (Fig. 5B arrow) and TLR5 (Fig. 6F arrow). DISCUSSION Pregnancy is often perceived as an immune suppressed state that is necessary for the mother to tolerate the developing fetus. However, this over-simplified view underestimates the complex immunological exchange that occurs at the maternal-fetal interface within the placenta, particularly when microbial pathogens or commensals could be encountered. An inadequate immune response would allow the infection to spread to the fetus, while an excessive inflammatory response could lead to miscarriage, preterm labor, or other consequences of placental dysfunction. The innate immune system plays an essential role in balancing these often conflicting priorities with the goal of maintaining an appropriate environment for the developing fetus while protecting the health of the mother. The temporal regulation of TLRs in the placenta has not been widely studied. Ours is the first study to examine placental expression of the TLRs across the first and second trimester by both mRNA and protein. TLR gene expression was surprisingly consistent between individuals in the second trimester, although there was some variability within the first trimester for a subset of the TLRs. For example, placental TLR2 expression in the latter half of the first trimester was variable between individuals, as was TLR7 and TLR8. This coincides with the histological changes we observed in the first trimester, where the villous cytotrophoblast layer becomes more disorganized, suggesting a very dynamic tissue at this early stage. Of the TLRs studied, TLR3 was most highly expressed at the level of mRNA. In contrast, TLR9 and TLR10 mRNA expression was the lowest among the TLRs studied. Because our gene expression studies reflect mRNA levels throughout a tissue of mixed cellularity, it is impossible to determine the relative contribution of the individual cell types, such as villous cytotrophoblasts vs. Hofbauer cells. Clarification comes from the immunohistochemistry studies, where protein expression can be determined in situ. The most striking expression pattern was the band of TLR2 staining at the outer plasma membrane of the intact villous cytotrophoblast layer in the very early first trimester placenta. In fact, all the surface-expressed TLRs we examined (TLR2, TLR4, TLR5) demonstrated a similarly contiguous pattern of staining in this early stage placenta. TLR3 was generally detected in the cytosol; however, there were situations where TLR3 appeared to be expressed at the plasma membrane. While TLR3 is commonly considered an endosomal TLR, its expression has been described outside this compartment. For example, fibroblasts (but not dendritic cells) were shown to express TLR3 at the cell surface (22, 23), and it has been hypothesized that cell surface TLR3 binds dsRNA and becomes activated upon internalization (24). TLR9 staining was also localized to the cytosol, although by RT-PCR its expression was relatively lower than that seen for the other TLRs. The strong TLR3 expression by both RT-PCR and IHC is worth noting as TLR3 is a receptor for dsRNA and particularly important for danger signals. In addition to dsRNA viruses, dsRNA is formed as an intermediate during replication of some ssRNA viruses (such as respiratory syncytial virus, West Nile, influenza A, coxsackievirus, etc.) as well as DNA viruses (25). Cellular dsRNA can also be released during necrotic cell death [reviewed in (26)]. TLR3 activation is a strong inducer of type I IFNs and an antiviral immune response through the activation of IRF3 and NF-κB [reviewed in (27, 28)], and mouse models suggest that TLR3 activation can lead to preterm birth (29, 30). It was recently reported that placental IFN-β regulates inflammation by inhibiting responses to LPS, suggesting that inhibition of type I IFNs could remove the brake from inflammation induced by bacterial commensals and pathogens and lead to placental dysfunction and pregnancy loss (31). Thus, the presence of TLR3 could play a regulatory role in modulating inflammation through the induction of type I IFN. Our data is consistent with what others have reported. For example, Abrahams et al. demonstrated that TLR2 and TLR4 are expressed by villous cytotrophoblasts and extravillous trophoblasts, but not by syncytiotrophoblasts in first trimester placenta (32). Tangerås et al reported expression of functional TLRs 2–5 and TLR9 in isolated first trimester cytotrophoblasts (19). Ours is the first study to correlate expression of TLRs with histological changes in the placenta. It is interesting to speculate on the evolutionary adaptations that would shape the temporal and spatial patterns of TLR gene expression in the placenta. Early in the first trimester when the fetus is most vulnerable, the villous cytotrophoblasts appear to provide a firm line of defense, demonstrating the active role played by these cells as an arm of the innate immune system and countering the argument that pregnancy is a state of immune suppression. The presence of the full complement of TLRs in this tissue reflects the pressure to protect the fetus against invading pathogens as it weathers the first-trimester tests of chromosomal fitness, maternal antibody attack, endocrine imbalances, and defective implantation. As pregnancy progresses, however, breaches in this line of defense appear, perhaps reflecting improved fetal resilience as well as the need to temper an excessive inflammatory response that can be both harmful and beneficial to mother and fetus, leading to consequences such as miscarriage or preeclampsia. An improved understanding of the temporal and spatial regulation of TLRs in the placenta and the role they play in maintaining homeostasis could be exploited clinically. Much to the disappointment of clinicians, treatment of infections such as vaginitis (33, 34) or periodontal disease (35–38) during pregnancy has not reduced the incidence of preterm birth. Selective use of TLR antagonists in conjunction with more traditional antimicrobial treatments could prove useful as an approach to managing pregnancy-associated infections. The authors would like to thank the patients and clinical staff of the Obstetrics and Gynecology Department at Boston Medical Center for their support of this project. We thank Dr. Joe Politch for assistance with formatting figures, Dr. Deborah J. Anderson for insightful discussions, and the BUMC Analytical Instrumentation Core (AIC) for access to core instruments. This work was supported by funding from the NIH/NIAID through grant number AI101088. Fig. 1 Real time PCR analysis of TLR expression in placental tissue is shown. RNA isolated from first and second trimester placental tissue was subjected to RT-qPCR and normalized as described in the Methods section. Each data point represents an individual placenta, with n = 6 samples analyzed for first trimester, and n = 5 samples analyzed for second trimester except as follows: n = 5 for TLR5, TLR8 and TLR10 in the first trimester as no product was detected for TLR8 and TLR10 in a 6 week sample and TLR5 in a 7 week sample. (A) RQ is graphed on the y-axis according to trimester, and data shown is the mean with the SEM. PCR for each sample was repeated twice. Statistical significance (p-value) was calculated using a t-test: *, p < 0.05; **, p < 0.01; ***, p < 0.001. (B) Scatter plot analysis of TLR expression over 6–19 weeks gestation is depicted. RNA isolated from placentas of 6–19 weeks of gestation was subjected to Real-Time PCR for TLRs 1-10, MD2 and the control gene NDRG1, as described in the Methods. Each data point represents an individual placenta. Data shown above is the relative quantitation (RQ) of each gene vs. gestational age in the first and second trimester. The R2 values were calculated using a simple linear regression model. Fig. 2 Variations in the morphological appearance of the cytotrophoblast in villi during gestation. Cytotrophoblasts are seen as (A) a competent layer of small cells at 6 weeks; (B) a disorganized layer of cells at 12 weeks; (C) an attenuated layer of cells at 12 weeks; (D) large cells present in some villi at 12 weeks; (E) a loosely organized layer of cells at 13 weeks; (F) very large and irregular shaped cells now present in many villi at 13 weeks; and (G) mostly absent from villi that appear now to be surrounded by only the syncytiotrophoblast at 22 weeks. Original magnification: A, 10x; B–E, 20x; F, 40x; G 20x. Fig 3 Representative examples of negative controls. (A) Primary antibody was replaced with the antibody diluent (9 week sample). (B) Primary antibody was replaced with a negative control rabbit IgG (7 week sample). Original magnification: A–B, 10x. Fig 4 TLR expression by the villous cytotrophoblasts during early (6–7 weeks) first trimester of pregnancy is depicted. (A) Intense staining for TLR2 at 6 weeks with (B) polarized expression of TLR2 at the outer (apical) plasma membrane adjacent the syncytiotrophoblast layer (7 weeks). (C) Cytoplasmic staining of TLR3 (7 weeks). Membrane staining of (D) TLR4 (7 weeks) and (E) TLR5 (7 weeks). (F) Cytoplasmic staining of TLR9 (7 weeks). Original magnification: A, 10x; B, 40x; C–E, 20x; F, 10x. Fig 5 TLR expression by the villous cytotrophoblasts during late (8–12 weeks) first trimester of pregnancy is depicted. Attenuated layer of cells expressing (A) TLR2 (9 weeks) and (B) TLR3 (8 weeks) on the apical cell membrane adjacent the syncytiotrophoblast layer. Putative Hofbauer cell with positive staining for TLR3 (arrow). Expression of (C) TLR4 (12 weeks) and (D) TLR5 (12 weeks) by disorganized round cells. Expression of TLR9 by either (E) disorganized (12 weeks) or (F) attenuated cells (9 weeks). Original magnification: A, 10x; B–F, 20x. Fig 6 TLR expression by the villous cytotrophoblasts during early (13–17 weeks) second trimester of pregnancy is depicted. At this stage the cytotrophoblasts appear as a disorganized layer of large irregularly shaped cells. (A) TLR2 is expressed by a small number of cells (13 weeks), and some villi (B) stain negative for TLR2 (15 weeks; small arrow). Note adjacent putative Hofbauer cell that stained positive for TLR2 (large arrow). Expression of (C) TLR3 (13 weeks); TLR4 (D, 13 weeks; E, 15 weeks); (F) TLR5 (13 weeks); and (G) TLR9 (15 weeks). Original magnification: A–B, 40x; C–D, 20x; E, 10x; F–G, 20x. Fig. 7 TLR expression by the villous cytotrophoblasts during late (18–22 weeks) second trimester of pregnancy is depicted. (A) Remnant cells still expressed TLR2 with often intense staining of the cell membrane adjacent the syncytiotrophoblast (18 weeks). (B) TLR3 was expressed either as distinct positive cytoplasmic staining (22 weeks) or (C) as polarized staining with higher expression by the cell membrane next to the syncytiotrophoblast (21 weeks). Isolated cytotrophoblast cells expressing (D) TLR4 (20 weeks) and (E) TLR5 (22 weeks) and (F) TLR9 (18 weeks). Original magnification: A–F, 20x. Table 1 RT-qPCR primer ID, TaqMan® Gene Expression Assay Target Assay ID TLR1 Hs00413978_m1 TLR2 Hs01014511_m1 TLR3 Hs00152933_m1 TLR4 Hs00152939_m1 TLR5 Hs01019558_m1 TLR6 Hs01039989_s1 TLR7 Hs00152971_m1 TLR8 Hs00152972_m1 TLR9 Hs00152973_m1 TLR10 Hs01675179_m1 NDRG1 Hs00608387_m1 GAPDH Hs99999905_m1 Table 2 Raw Ct values First Trimester Second Trimester p-value Raw Ct (Mean ± SEM) n Raw Ct (Mean ± SEM) n TLR1 30.96 ± 0.6694 6 27.21 ± 0.5113** 5 0.0020 TLR2 32.56 ± 0.9181 6 28.13 ± 0.7483** 5 0.0055 TLR3 26.07 ± 0.3476 6 25.27 ± 0.2160 5 0.0947 TLR4 29.91 ± 0.4826 6 26.44 ± 0.2186*** 5 0.0002 TLR5 30.26 ± 0.5319 5 28.60 ± 0.1483* 5 0.0168 TLR6 30.62 ± 0.4225 6 28.24 ± 0.3195** 5 0.0019 TLR7 30.48 ± 0.7499 6 27.13 ± 0.2657** 5 0.0037 TLR8 35.47 ± 0.5801 5 31.89 ± 0.5597** 5 0.0022 TLR9 35.79 ± 0.1746 6 35.02 ± 1.045 5 0.445 TLR10 37.64 ± 0.2855 5 35.44 ± 0.6617* 5 0.0157 MD2 28.36 ± 0.3990 6 25.86 ± 0.1996*** 5 0.0005 NDRG1 24.70 ± 0.2163 6 24.63 ± 0.5569 5 0.9056 GAPDH 20.63 ± 0.5354 6 20.05 ± 0.3347 5 0.4127 * p<0.05; ** p<0.005; *** p<0.001 compared to first trimester. Highlights Cytotrophoblasts express multiple TLRs. TLR expression across early gestation is dynamic, especially in the first trimester. The villous cytotrophoblast layer becomes more disorganized as the placenta matures. This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final citable form. 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PMC005xxxxxx/PMC5119654.txt
LICENSE: This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. 2985117R 4816 J Immunol J. Immunol. Journal of immunology (Baltimore, Md. : 1950) 0022-1767 1550-6606 27864551 5119654 10.4049/jimmunol.1600872 NIHMS810515 Article Immunological Outcomes of Antibody Binding to Glycans Shared Between Microorganisms and Mammals1 Patel Preeyam * Kearney John F. * * Department of Microbiology, University of Alabama at Birmingham, Birmingham, AL 35294 USA Corresponding Author: John F. Kearney, Office: (205) 934-6557, Fax: (205) 996-9908, jfk@uab.edu 16 8 2016 1 12 2016 01 12 2017 197 11 42014209 This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. Glycans constitute basic cellular components of living organisms across biological kingdoms (Table 1), and glycan-binding antibodies participate in many cellular interactions during immune defense against pathogenic organisms (Figure 1). Glycan epitopes are expressed as carbohydrate-only entities or as oligomers or polymers on proteins and lipids. Such epitopes on glycoproteins may be formed by post-translational modifications or neoepitopes resulting from metabolic/catabolic processes, and can be altered during inflammation. Pathogenic organisms can display host-like glycans to evade the host immune response. However, antibodies to glycans, shared between microorganisms and the host, exist naturally. These antibodies are able to not only protect against infectious disease, but are also involved in host housekeeping functions and can suppress allergic disease. Despite the reactivity of these antibodies to glycans shared between microorganisms and host, diverse tolerance-inducing mechanisms permit the B cell precursors of these antibody-secreting cells to exist within the normal B cell repertoire. Introduction Glycans, polymers of glycosidically linked sugars, are one of the most basic cellular components, and exist as carbohydrate-only entities as well as covalently attached modifications of proteins (glycoproteins) or lipids (glycolipids). Here, we use “glycan” to indicate both oligosaccharides and polysaccharides. In mammals, glycans have diverse functions, such as marking apoptotic cells for clearance, immune self/non-self discrimination, cell-cell communication, and intracellular signaling (1, 2). Glycosylation defects in humans are linked to disease (3), and the expressed glycome can be altered during inflammation, cellular stress, as well as cancer (4). Although the combinatorial composition of a saccharide array can generate an immense number of structures, the composition of mammalian glycans is well-conserved (5). Some microbial pathogens including bacteria, fungi, and protozoans display mammalian-associated glycans on their surfaces as an evolutionary adaptation to evade detection by the host’s immune system (6). This property can also directly contribute to pathogenicity of these organisms (7, 8). Additionally, expression of host-similar glycans by allergens may promote their engagement of innate receptors expressed by antigen-presenting cells (APCs) and epithelial cells in the lung (9, 10). In mammals, B cells and antibodies that react with self glycans exist naturally and function to promote homeostasis (11) by facilitating the clearance of dangerous and potentially inflammatory components, such as apoptotic cells (12), senescent red blood cells (13), and metabolic products such as oxidized lipids (14). Aside from these homeostatic functions, naturally occurring antibodies specific for mammalian glycoproteins or glycolipids recognize these structures when displayed by microorganisms as well as allergens, and can facilitate their clearance (10, 12, 15, 16). Many cellular processes such as engagement of SiglecG/CD22 (17), sequestration of autoreactive antigens (12), and induction of cellular anergy (18) exist to regulate and maintain autoreactive B cells within the B cell repertoire. In this review, we discuss the expression and interactions of B cells with selected glycan epitopes that are expressed on host cells, microbes, and allergens. These epitopes include N-acetylglucosamine (GlcNAc), sialyl-lacto-N-tetraose, and α-1,3-glucan. We then give some examples of how antibodies to these glycans mediate housekeeping functions and provide protection against pathogens and allergens (Figure 1, Table 1). Antibodies to Glycans, Implications for Polyreactivity, and Infection-Induced Autoimmunity Much has been written regarding antibodies with extensive “polyreactivity” (19–21). The term polyreactive has generally been used to describe antibody reactivity with seemingly structurally unrelated antigen targets and has been attributed to both germline and somatically mutated gene-encoded contributions to their antigen-binding sites (22, 23). The polyreactive nature of some antibodies has often been characterized by antibody binding to recombinant antigens or mimotopes in solid-phase ELISA-type assays or by western blotting of denatured complexes from microbes, mammalian tissues, or cell extracts. These assays may also detect low-avidity binding of antibodies against neoepitopes generated through processing of the antigen-containing material that may not normally be exposed on the native non-denatured molecules. By contrast, the representative antibodies discussed in this review exhibit exquisite specificity for defined oligosaccharide moieties expressed as glycan epitopes. These structures are themselves similar among bacterial, fungal, and parasitic components as well as allergens and multiple mammalian cell types. We, and others, have demonstrated that anti-GlcNAc antibody binding to bacterial cell wall peptidoglycan complexes is inhibited by soluble monomeric GlcNAc monosaccharide, but not its enantiomer GalNAc (24, 25). Thus, these antibodies are “polyreactive” only in the sense that they bind an identical or a very similar associated glycan epitope present in various molecular entities expressed by a wide range of living organisms. Host-resembling epitope expression by microorganisms has been referred to as molecular mimicry, and infections caused by some of these organisms, especially viruses and bacteria, have been implicated as the precipitating event for development of autoimmunity (26–29). Most of the studies in this field imply that the immune response to these infectious organisms drives the development of autoreactive T or B cells. However, evidence for most of these claims are sparse, and some of the suggested immune mechanisms by which this occurs are debatable. The association between Streptococcus pyogenes infection and rheumatic heart disease (RHD) is commonly discussed, and although 30–40% of humans that recover from rheumatic fever develop RHD (30), the cellular mechanism driving this disease remains controversial. Some prominent studies have implicated anti-GlcNAc antibody activity in mice immunized with myosin or GlcNAc-BSA conjugates as being a causative agent of RHD (31, 32). However, the specificity of antibody binding to GlcNAc-protein conjugates was not demonstrated by inhibition with free monosaccharide. Additionally, these T-dependent hybridoma antibodies reactive with myosin and GlcNAc-BSA did not express the canonical VHJ606 gene segment characterizing the highly conserved antibody repertoire of GlcNAc-specific monoclonal antibodies raised by immunizing mice with S. pyogenes (33). Further, other studies have clearly demonstrated that serum antibodies from rabbits immunized with S. pyogenes cell wall that bound to heart muscle were only inhibitable with the insoluble, but not soluble (GlcNAc-containing), portion of the bacterial cell wall (34). Instead, many studies have showed that streptococcal M protein and cardiac myosin express similar epitopes and peptides (35–37). Therefore, T and B cells with specificity for streptococcal M protein that also react with myosin are most likely the initiating factor in S. pyogenes-induced RHD. Although pathogenic antibodies against M protein are involved in RHD pathology, they are not likely to be directed towards defined GlcNAc epitopes as some studies suggest (31). Instead, these antibodies may be cross-reactive with neoepitopes possibly formed artificially by conjugating GlcNAc to BSA (31). In contrast, the GlcNAc residues on Group A streptococcal (GAS) carbohydrate are structurally ordered (38) and monoclonal antibodies against GlcNAc peptide conjugates do not bind native S. pyogenes bacteria or the purified GAS polysaccharide (unpublished observations). Therefore, studies demonstrating that antibodies generated against bacterial glycan epitopes cause autoimmunity should be interpreted cautiously. Bacterial infections may drive the development of other autoimmune conditions such as Guillain-Barré syndrome (GBS) (39). GBS is characterized by neuromuscular paralysis caused by T and B cells with specificity for peripheral nerve myelin gangliosides (40). Gangliosides are sialylated glycolipids that are widely distributed in mammalian neuronal membranes, where they are sequestered in islands in the lipid bilayer (41, 42). In some rare cases, GBS can be preceded by an infection with ganglioside-bearing organisms (39) such as Streptococcus agalactiae (Group B Streptococci) (43, 44), Mycoplasma pneumoniae (45), or Campylobacter jejuni (46–48), the most common organism implicated in this disease. Many C. jejuni strains have cell wall lipopolysaccharides containing sialylated gangliosides such as GM1, GT1a, GD1b, or GD3 that are identical to human gangliosides (47). It has been proposed that infection with C. jejuni can induce ganglioside-reactive antibodies that cause host nervous system damage (46–49). C. jejuni-induced autoreactive antibodies are specific for the oligosaccharide sequences attached to the polar groups in membranes, but sequence similarities and their membrane distribution may yield cross reactivities with different gangliosides such as GM1, GT1a, GD1b, or GD3 (46, 48). Due to the sequestration of gangliosides in membrane islands (41), the reactivity of these autoantibodies with gangliosides would most likely depend on their density, distribution, and clustering patterns in host membranes. Although the similarity of these ganglioside-like epitopes on the C. jejuni lipopolysaccharide may explain some GBS-inducing pathology, development of GBS among individuals infected with C. jejuni (50) and other ganglioside-expressing organisms, such as cytomegalovirus (CMV) (51), varicella zoster virus (VZV) and Epstein Barr virus (HBV) is low (52), making this cause and effect controversial (39). Therefore, in addition to antibodies to gangliosides, there may be other unknown immune factors contributing to incidence of disease. In addition to C. jejuni, it has long been known that the type-specific capsular polysaccharides of Group B streptococci (which will be discussed in detail later in this review) share structural similarities with epitopes on human glycoproteins (43) and the oligosaccharide head groups of mammalian membrane sphingolipids (43). The repeating units of the sialylated Group B streptococci type III polysaccharide are identical to gangliosides GD3 and GT3 (43). Similarly, the Group B streptococci type Ib repeating unit (53) is identical to the oligosaccharide sialyl-lactoneotetraosyl-ceramide (44), and has the potential to share epitopes with other gangliosides, including GD1a, expressed on mouse TH2 cells and GD1α expressed preferentially on mouse TH1 cells (54). Anti-Group B streptococcal antibodies raised by immunization of mice with the Group B streptococci type III or type Ib does not appear to cause neuromuscular paralysis or affect T cell functions (55). Another striking characteristic of these antibodies is that their binding to target acidic polysaccharides is calcium dependent (44) such that these antibodies may not bind to oligosaccharides expressed as gangliosides on host cells. The sialyllactose oligosaccharide epitope of the ganglioside GM3 is found on the plasma membrane of many mammalian cell types (56) and is highly expressed in melanoma, and has been extensively studied as a potential anti-tumor target (57, 58). Conventional wisdom suggests that antibodies against GM3 and other gangliosides may target and damage many GM3-bearing cells. However, binding of certain induced anti-GM3 monoclonal antibodies occurs in an all-or-none fashion depending on the threshold density of GM3 exposed at the cell surface (59). These observations suggest that bacteria could possibly induce antibodies that would bind to the target bacterial epitope without affecting functions of normal cells. Therefore, antibody recognition of cell-surface GM3 may depend on the density and spatial distribution of oligosaccharides on complex membrane bound structures and thus be a general characteristic regulating the relative binding of antibodies to similar epitopes on bacteria and host cells. Although bacteria display epitopes that can also be expressed on mammalian cells, the implications that antibodies to self glycan epitopes cause autoimmunity should be interpreted carefully. Naturally Occurring Antibodies In this review, we discuss the immunological activities of antibodies with specificity for GlcNAc, sialyl-lacto-N-tetraose, and α-1,3-glucan. Such antibodies are detectable in the serum of mice as well as humans and are referred to as natural antibodies (24). This terminology is often used to imply that these antibodies are detectable in the absence of deliberate immunization or vaccination. Glycan epitopes inducing natural antibodies may include those expressed by bacterial organisms comprising the microbiome, whereas others represent neoepitopes that are normally sequestered, but can be exposed by altered glycosylation related to cell apoptosis or death. The B cell repertoire encoding natural antibodies is generated early in life, and its individual clonal components can fluctuate throughout the lifetime of the host depending on exposure to self, microbiota, or environmental antigens expressing these epitopes (24). Mechanisms that both limit and maintain these autoreactive B cells within the B cell repertoire are discussed later in this review. Anti-GlcNAc-Based Therapeutics For Prevention of Bacterial and Protozoan Infections and Aspergillus-Induced Allergic Airway Disease Diverse groups of bacteria, protozoans, and fungi utilize N-acetylglucosamine (GlcNAc) as a building block in glycan-based structures (60). Helminths such as Heligmosomoides polygyrus and Strongyloides stercoralis express GlcNAc-containing cellular and structural components (24, 61), and helminth exposure can drive the production of high-titer serum antibodies against GlcNAc (24). Additionally, the biochemical composition of bacterial cell walls is highly conserved (62). Gram-positive bacteria incorporate alternating units of GlcNAc and N-acetylmuramic acid (MurNAc) connected by a β-1,4-glycosidic bond to assemble peptidoglycan for their cell walls (63). In addition to peptidoglycan, gram-negative bacteria possess an outer membrane containing a unique lipopolysaccharide that promotes immune evasion by shielding peptidoglycan GlcNAc moieties from serum antibodies and lectins (64). Certain gram-positive organisms such as Streptococcus pneumoniae evade the host immune system by generating a serotype-specific cell wall-linked polysaccharide capsule that prevents complement-mediated opsonophagocytosis (65). Regardless of serotype, S. pyogenes (Group A streptococcus, GAS) expresses a cell wall polysaccharide with a helical rhamnose backbone decorated with repetitive terminal GlcNAc residues (38) that is highly immunogenic in mice and humans. Infection with GAS induces antibodies against GlcNAc (25), and these antibodies are somewhat protective in mouse models of GAS infection (66–68). The development of a GlcNAc-based vaccine for GAS infection has been proposed for many years. However, the likelihood of pathogenic self reactivity of such antibodies and relatively poor protection in mouse models may have disfavored efforts to develop such a vaccine (38, 69). Because multiple bacterial species express variable levels of GlcNAc-containing molecules, efforts have also been made to design a GlcNAc-based vaccine that could protect against a broad array of organisms, including antibiotic-resistant Staphlococcus aureus (70). Recently, Genentech developed a novel anti-GlcNAc-based therapeutic agent in which human IgG1 anti-GlcNAc antibodies were linked to the antibiotic, rifalogue. In vivo, these modified antibodies bound to S. aureus, and upon phagocytosis, endosomal activation of the antibiotic agent mediated killing of intracellular S. aureus (71). The conserved microbial expression of molecules containing GlcNAc epitopes suggests that these approaches may have wider implications for drug delivery to intracellular compartments for killing other GlcNAc-expressing pathogenic organisms, such as Mycobacterium tuberculosis. GlcNAc is the basic subunit in the form of β-1,4 GlcNAc linked residues constituting the homopolymer chitin (72), which is the second most abundant biopolymer on earth. Chitin is present in the cell walls of various fungi, including yeast (73, 74), and is a major component of crustacean and insect exoskeletons (75) as well as protozoan and insect gut walls (76, 77). The physicochemical properties of different chitins may vary, and chitin particles purified from crab shells or different fungal species elicit significantly varied pro-inflammatory cytokine responses (78). Chitin is also expressed by a wide variety of respiratory allergens such as house dust mite (HDM), cockroach, and many fungal species including Aspergillus fumigatus (9, 79). Chitinous particles derived from these organisms may be considered as carriers associated with protein allergens that act as cargo (9, 10). For example, the hyphal cell wall of A. fumigatus contains chitin as a structural element and bears the major allergens Asp f 1 and Asp f 2. Engagement of innate receptors by chitin-bearing particles can promote the cellular entry to promote the processing of these allergenic proteins. Targeting the chitinous portion of these particles to prevent engagement of these innate receptors would also prevent entry of many different types of inflammatory elements associated with allergens, such as LPS, β-glucan, and proteases aside from allergenic proteins (80). Our laboratory has demonstrated that anti-GlcNAc antibodies bind chitin particles and germinated A. fumigatus and significantly decrease their uptake by alveolar macrophages and APCs in the lung. Additionally, neonatal exposure of mice to S. pyogenes results in increased levels of serum anti-GlcNAc antibody and an attenuation of A. fumigatus-induced allergic disease. These studies further demonstrated that intravenously (i.v.) delivered anti-GlcNAc antibodies suppressed A. fumigatus-induced airway disease development (9). Serum antibodies against GlcNAc occur naturally, and may vary depending on the microbiome, blood type, as well as the history of infection (12). Accordingly, therapeutic manipulation of anti-GlcNAc antibody levels may protect against bacterial and protozoan infection as well as respiratory and food allergies associated with chitin-bearing organisms. Anti-Sialyl-Lacto-N-Tetraose Antibodies are Protective Against Invasive Aspergillosis and Decrease Carriage of and Infection with Streptococcus agalactiae Aside from GlcNAc expression in its cell wall, germinated A. fumigatus also expresses sialyl-lacto-N-tetraose and α-1,3-glucan (9), an epitope described later in this review. Sialyl-lacto-N-tetraose is also expressed by Group B streptococci type 1b (44) and is a component of human milk oligosaccharides (HMOs) (81). Apart from causing allergic airway disease, A. fumigatus is the leading cause of invasive aspergillosis (I.A.) (82). I.A. results from an opportunistic infection, and is common among immunocompromised individuals (82) and Aspergillus is commonly isolated from deep tissue wounds of soldiers wounded in combat (83, 84). Current I.A. treatments have a limited success rate (85), and an efficacious vaccine for preventing I.A. has not yet been developed (86). Although some fungal polysaccharides can induce protective antibodies, they do so very poorly. This could be a result of multiple factors, including: suppression of T and B cell activity (87), variation in epitopes expressed between hyphal and yeast states, as well as fungus-induced proteosomal degradation of antibodies (88). Since the generation of antibodies to fungal epitopes is difficult, we hypothesized that generating antibodies to a bacterial epitope that is also expressed by fungi would stimulate the production of immunoprotective antibodies. Mice vaccinated with a Group B Streptococci 1b strain containing sialyl-lacto-N-tetraose were protected in a model of disseminated aspergillosis (55). Additionally, i.v., infusion of antibodies against sialyl-lacto-N-tetraose (clone SMB19) or use of SMB19 B cell transgenic mice expressing high levels of endogenous antibodies against sialyl-lacto-N-tetraose without deliberate bacterial immunization resulted in protection. Interestingly, J558 B cell transgenic mice with a high frequency of B cells specific for α-1,3-glucan and increased levels of antibody against α-1,3-glucan, which is also a major component of the A. fumigatus hyphal cell wall, were not protected against disseminated aspergillosis (55). Compared with antibodies against α-1,3-glucan, the SMB19 antibody is unique because it preferentially binds the tip of the germinating hyphae (24, 55). Calcium pumps and channels regulate the growing tip of the hyphae, and dysregulation of these calcium gradients may inhibit hyphal growth (89). The hyphal tip of many other yeast and fungal species such as Candida albicans also contains sialyl-lacto-N-tetraose (Figure 2). Therefore, targeting the hyphal tip may be an effective therapeutic for preventing many different types of invasive fungal diseases. Group B Streptococci 1b polysaccharide conjugate vaccine, provides protection against Group B Streptococci 1b infection (90). Group B Streptococci can cause severe infection among newborns, pregnant women, and the elderly (91). Currently, women testing positive for Group B Streptococci during pregnancy receive antibiotics during labor to prevent maternal and neonatal Group B Streptococcal infections. To generate long-lasting immunity and to circumvent antibiotic use, glycoconjugated Group B streptococcal vaccines have been developed (90). Group B Streptococcal vaccine generation was predated by the observation that maternal antibodies against the Group B streptococcus capsular polysaccharide correlated with lower neonatal susceptibility to Group B Streptococcal disease (92). In clinical trials, pregnant women immunized with the glycoconjugate Group B Streptococcus vaccine produced type-specific antibodies that were also detectable in the newborn cord blood and in the infants for up to 2 months of age. In these studies, Group B Streptococcus carriage rates were also lower among adult females receiving the vaccine (90). Collectively, the effectiveness of the Group B Streptococcal polysaccharide conjugate vaccine for inducing human antibodies that both protect against Group B Streptococci infections and also react with multiple fungi have motivated our efforts to repurpose Group B Streptococcus-conjugate vaccines for protection against IA development in immunocompromised individuals. In addition to being expressed on bacteria and fungi, lacto-N-tetraose and sialyl-lacto-N-tetraose are highly abundant oligosaccharide found in breast milk (81, 93–96). These HMOs can be advantageous by promoting growth of many beneficial Bifidobacterium species (97, 98) or as decoys for pathogenic diarrhea-causing organisms that use glycan-mediated attachment mechanisms for accessing the host immune system (95). However, HMOs may also promote pathogenicity as suggested by their ability to increase Staphylococcus epidermidis and S. aureus growth in vitro (99). Both of these staphylococcal organisms cause mastitis (100, 101), contaminate breast milk, and cause infections among infants (102–104). The exact mechanism by which the HMOs modulate the host immune system, apart from benefiting the gut microbiome (105), has not yet been determined. The presence of lacto-N-tetraose in breast milk and the infant digestive system is of interest because Group B Streptococcus 1b-vaccinated women and their children had antibodies against sialyl-lacto-N-tetraose (90). Although these antibodies can potentially react with an HMO epitope that is highly expressed in the mammary glands of pregnant females and digestive tracts of neonates, the vaccine did not have related adverse effects, and was shown to be safe for use in women of childbearing age, including those who were pregnant (106, 107). This further supports observations that antibodies against shared epitopes can reside in the body naturally without causing autoimmune manifestation. α-1,3-Glucan Expressing Organisms, Non-Canonical T cell-Independent B cell Responses, and Protection Against Cockroach Allergy α-1,3-glucan is a linear α-1,3-linked homopolymer of glucose, and antibodies against α-1,3-glucan are naturally occurring (24). In mice, B cells specific for α-1,3-glucan are enriched within the marginal zone and B1b cell populations (108). Anti-α-1,3-glucan antibodies are detectable in human plasma (unpublished observations); however, unlike the other antibodies discussed in this review, our understanding of the levels and characteristics of human antibodies against α-1,3-glucan is poor. Fungi, including yeast, are among the best documented expressers of the α-1,3-glucan epitope (74). Molecules expressing these epitopes can function as virulence factors when expressed by yeast (109) and fungal cell walls (74), or oral plaque-forming bacteria (110). However, commensal enteric organisms from mice can also express this molecule without any known pathogenic consequence (111). In fungi, such as Aspergillus nidulans, α-1,3-glucan accumulates during vegetative cell growth, and is used as an endogenous carbon source during sexual development (112). Whereas in yeast such as Cryptococcus neoformans, α-1,3-glucan is involved in anchoring the capsule to the cell wall (109). In some Histoplasma capsulatum strains, the α-1,3-glucan cell wall polymer may act as a shield for β-glucan, thereby evading immune clearance via recognition by Dectin-1, a mammalian β-glucan receptor (113), however a receptor for α-1,3-glucan has not yet been identified. Although antibodies against α-1,3-glucan were not protective in a mouse model of invasive aspergillosis (55), it is possible that they could protect against non-invasive fungal and yeast infections similarly to antibodies against β-1,3-glucan, which have been shown to inhibit growth of multiple fungi species (114). Bacterial species expressing α-1,3-glucan include oral streptococci (110, 115), cyst-forming bacteria (116), and some enteric organisms isolated from mice (111). Planktonic Streptococcus mutans do not express α-1,3-glucan; however, when these organisms begin producing biofilms, a series of glucosyltransferases (GTFs) synthesize α-1,3-glucan from sucrose (117). α-1,3-glucan provides structural stability for these biofilms, and is critical for S. mutans attachment, aggregation, as well as accumulation on tooth surfaces (118). It has yet to be determined whether oral antibodies against α-1,3-glucan could specifically prevent cariogenic biofilm formation. Additionally, biofilms formed by other bacterial organisms or yeasts may also contain α-1,3-glucan. Aside from S. mutans, cyst-forming bacteria such as Azotobacter vinelandii and some commensal enteric organisms such as Enterobacter cloacae and Serratia liquefaciens can also express α-1,3-glucan under non biofilm-forming conditions (111, 116). We and others have used α-1,3-glucan to study the immune response to T cell-independent antigens (108, 119–123). Textbook descriptions of T-independent responses state that these immune reactions do not result in the formation of memory; however, using the α-1,3-glucan epitope-bearing strain of Enterobacter (MK7), we demonstrated that α-1,3-glucan-specific IgM-secreting cells contribute to polysaccharide-specific memory antibody responses, which are maintained long-term (108, 124). Aside from bacteria and fungi, German cockroach (Blattella germanica) allergen also contains detectable α-1,3-glucan epitopes. These epitopes are expressed in the insect’s muscle and exoskeleton, and binding of anti-α-1,3-glucan is not exclusively due to microorganism contamination. Cockroach fecal pellets contain both allergenic protein Bla g 2 as well as α-1,3-glucan, and we suggest that particles bearing α-1,3-glucan epitopes can act as carriers of allergenic Bla g 2 proteins (Patel and Kearney manuscript submitted). Natural antibody based therapeutics for treating cockroach allergy are attractive because children that are skin-prick test positive for cockroach allergens are more likely to have difficult-to-control asthma (125, 126) and visit the emergency room due to an asthmatic event (127) than children that are not allergic to cockroaches. Treatment of neonatal, but not adult, mice with purified α-1,3-glucan or an α-1,3-glucan-expressing MK7 Enterobacter strain resulted in suppressed development of cockroach allergy during adult life. α-1,3-glucan-specific IgA-secreting cells were identified in the lungs of mice immunized with MK7 as neonates, but not as adults. By generating mice that are unable to make IgA responses to α-1,3-glucan, we confirmed that these B cells are responsible for protection against cockroach allergy (Patel and Kearney manuscript submitted). It has been shown that neutralization of bacteria and viral particles by antigen-specific IgA at mucosal sites is critical for preventing some diseases (128, 129). Additionally, this mechanism may also be important for suppressing allergic disease and selection of B cell clones capable of producing IgA during neonatal life may also be crucial in this process. Considering these, and other observations, we suggest that early exposure to α-1,3-glucan, in the form of a probiotic or natural colonization, may be sufficient to protect against mycosis and suppress fungal or cockroach allergy development for the lifetime of the individual. Autoreactive B Cell Stimulation and Maintenance As we have described in this review, B cells and their antibody products with the potential to react with self glycans exist naturally and there are multiple mechanisms that maintain self-reactive B cells within the repertoire. These antibodies against self antigens are not limited to those mentioned in this review, and also include antibodies against major and minor blood group antigens as well as antibodies against the phospholipid epitope phosphorylcholine (PC). One major unanswered question is: what mechanisms govern the maintenance of these potentially autoreactive B cell within the adult B cell repertoire? The levels of antibodies in human serum that react with self glycans, such as GlcNAc, are much lower compared to those that react with non-self ligands such as Gal-(α-1,3)-Gal (130) or anti-Neu5Gc (131). A possible explanation for this is that a tolerance mechanism may be involved in maintaining self-reactive B cells within the B cell repertoire. For example, engagement of CD22 or SiglecG by sialic acid-bearing glycans dampens B cell signaling and can even cause B cell apoptosis (17). However, glycan engagement by the BCR along with additional signals through TLR or NOD receptors, such as following encounter with a pathogenic organism, could break these tolerance-inducing mechanisms, allowing for autoreactive antibody production (132). Retention of B cells with reactivity for both self and microbial antigens may be evolutionarily advantageous such it drives the development and maintenance of a complete B cell repertoire (unpublished observations). In another suggested mechanism, epitopes similar among microorganisms and host may be sequestered in the host such that they are not normally exposed to B cell receptors at a level sufficient to initiate B cell activation. For example, GlcNAc subunits of mammalian glycans are usually capped by mannose or highly charged sialic acids, which prevent BCR receptor engagement (12). These antigens, which are normally sequestered intracellularly, may be exposed only as part of the apoptotic program or released during necrotic cell death. Normally, immune disposal mechanisms clear these antigens rapidly and limit their ability to drive immune reactions. (133). However, chronic inflammation and cancer induce states of glycan remodeling (4), during which these epitopes could possibly be exposed. Our last suggested mechanism for the maintenance of autoreactive B cells in the repertoire involves B cell clonal anergy. Many self-reactive B cells are found in innate-like B1 and marginal zone B cell subsets in an activated state (134). Their heightened activation state most likely results from BCR engagement by self antigen. Studies of the regulatory mechanism controlling B cell responses following exposure to self antigen revealed that a proportion of B cells, but not T cells, exist in a state of anergy instead of being deleted. In this particular study, B cell unresponsiveness was manifest as a continuum with the highest indication of BCR engagement apparent in MZ B cells (18), consistent with our previous findings that the MZ B cell population is one of the main reservoirs of B cells that can respond to self- and microbe-associated epitopes (134). Much of the dogma related to the tolerant and anergic state of B cells was originally generated with B cell receptor transgenic or knock-in mice (135). The BCRs in many, but not all, of these models were derived from B cells initially isolated from mice that were repeatedly immunized with T cell-dependent antigens or from autoimmune mice that made somatically hypermutated and isotype-switched pathogenic antibodies. Therefore, forced expression of transgenes among B cells in these models involves the expression of highly mutated high-affinity receptors that may not be reflective of those that would exist in a normal primary repertoire, where B cells would express mostly germline immunoglobulin genes. Thus, B cells expressing self-reactive BCRs may normally co-exist peacefully in a system with self-reactive antigens due to various mechanisms such as SiglecG/CD22 engagement, self-antigen sequestration, anergy, or even receptor editing (136). However, these tolerance mechanisms can be breeched upon engagement of microorganism-associated epitopes that co-engage TLRs, enabling B cells to respond rapidly to the corresponding environmental organisms. Most likely, frequencies of these autoreactive B cell clones fluctuate throughout the lifetime of an individual depending on acquisition of and alterations in the microbiome, bacterial infection, and tissue injury. Conclusions Glycans can exist in different states, such as attached to lipids or proteins, and can be reshaped by post-translational modification or metabolic or catabolic processes. Glycan epitopes are extensively distributed over various organisms across kingdoms (Table 1, Figure 1). Some of these glycans mediate primary biological functions such as self/non-self distinction and apoptotic cell removal. It is clear that some bacteria and allergens can display epitopes that are also expressed on host glycans. The bacterial expression may serve as an effort to evade host immune responses. However, antibodies reactive with these shared glycans are common in mammals, where they mediate both homeostasis within the host and provide defense against pathogenic organisms and allergens. Production of antibodies against these glycans can vary with age, and antibody reactivity against glycans expressed commonly by both the host and these environmental organisms can be involved not only in protection against infectious diseases but also allergic diseases. Despite the association of some of these glycans with host molecules, anti-self antibodies exist naturally, and self-reactive B cells exist in equilibrium within the normal B cell repertoire as the result of highly regulatory and complex dynamics. Figure 1 Overlapping expression of conserved glycan epitopes shared among mammalian cells, bacteria, fungi, and allergens and mechanisms by which autoreactive B cells are maintained in the B cell repertoire (A) Streptococcus pyogenes (Group A streptococcus) expresses GlcNAc, which is also expressed by Aspergillus fumigatus in the form of chitin. (B) Sialyl-lacto-N-tetraose is found on A. fumigatus, Streptococcus agalactiae (Group B streptococcus), and in breast milk, which promotes the growth of commensal gut organisms. (C) Some commensal enteric organisms express α-1,3-glucan, which is also expressed by German cockroach (Blattella germanica) allergen. (D) Autoreactive B cells can be maintained within the normal B cell repertoire by a variety of mechanisms including: signaling through CD22 or Siglec G, obtaining an anergic state, sequestration away from antigen, and receptor editing. Figure 2 Candida albicans (CA) hyphae express β-1,3-glucan and sialyl-lacto-N-tetraose epitopes The yeast form of CA was grown at 37°C on glass slides in RPMI 1640 medium for 2.5 hrs. (A) Cells were washed, fixed in ethanol at −20°C, then stained with monoclonal antibodies against β-1,3-glucan (green) or sialyl-lacto-N-tetraose (red) along with DAPI (blue). (B) Phase-contrast view of the same field; Scale bar= 20µm Table 1 Glycans Shared Between Microorganisms and Mammals Epitope Expression Immunological Outcomes of Glycan-Binding Antibodies N-acetyl-D-Glucosamine (GlcNAc) Mammalian: Apoptotic cells Post-translational modification Bacterial: Staphlococcus aureus Streptococcus pneumoniae Streptococcus pyogenes Mycobacterium tuberculosis Fungal/Yeast: Aspergillus fumigatus Helminth: Heligmosomoides polygyrus Strongyloides stercoralis Allergens: Aspergillus fumigatus Dermatophagoides pteronyssinus (dust mite) Blattella germanica (cockroach) Other chitin-containing organisms (e.g., shellfish) Protection against: Bacterial infections Allergic disease Promote apoptotic cell clearance May modulate fungal infections Sialyl-lacto-N-tetraose Mammalian: Human breast milk Bacterial: Streptococcus agalactiae type 1b Fungal/Yeast: Aspergillus fumigatus Candida albicans Protection against: Bacterial infections Invasive fungal infections May modulate: Allergic disease α-1,3-glucan Mammalian: None to date Bacterial: Streptococcus mutans biofilms Select Enterobacter cloacae Select Serratia liquefaciens Azotobacter vinelandii Fungal/Yeast: Aspergillus fumigatus Aspergillus nidulans Cryptococcus neoformans Histoplasma capsulatum Allergens: Blattella germanica (German cockroach) Protection against: Some invasive fungal diseases Allergic disease May modulate: Biofilm formation 1 This work was supported by the National Institutes of Health (NIH) Grants AI14782-37 and AI100005-05 and T32 AI00705 as well as the American Asthma Foundation. 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PMC005xxxxxx/PMC5119655.txt
LICENSE: This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. 101631050 42499 EcoSal Plus EcoSal Plus EcoSal Plus 2324-6200 27735785 5119655 10.1128/ecosalplus.ESP-0020-2015 NIHMS787922 Article The Mosaic Type IV Secretion Systems Christie Peter J. Department of Microbiology and Molecular Genetics, The University of Texas Medical School at Houston, Houston, TX 77030 Correspondence: Peter J. Christie,: Peter.J. Christie@uth.tmc.edu 6 8 2016 10 2016 22 11 2016 7 1 10.1128/ecosalplus.ESP-0020-2015This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. Escherichia coli and other Gram-negative and -positive bacteria employ type IV secretion systems (T4SSs) to translocate DNA and protein substrates, generally by contact-dependent mechanisms, to other cells. The T4SSs functionally encompass two major subfamilies, the conjugation systems and the effector translocators. The conjugation systems are responsible for interbacterial transfer of antibiotic resistance genes, virulence determinants, and genes encoding other traits of potential benefit to the bacterial host. The effector translocators are used by many Gram-negative pathogens for delivery of potentially hundreds of virulence proteins termed effectors to eukaryotic cells during infection. In E. coli and other species of Enterobacteriaceae, T4SSs identified to date function exclusively in conjugative DNA transfer. In these species, the plasmid-encoded systems can be classified as the P, F, and I types. The P-type systems are the simplest in terms of subunit composition and architecture, and members of this subfamily share features in common with the paradigmatic Agrobacterium tumefaciens VirB/VirD4 T4SS. This review will summarize our current knowledge of the E. coli systems and the A. tumefaciens P-type system, with emphasis on the structural diversity of the T4SSs. Ancestral P-, F-, and I-type systems were adapted throughout evolution to yield the extant effector translocators, and information about well-characterized effector translocators also is included to further illustrate the adaptive and mosaic nature of these highly versatile machines. INTRODUCTION Secretion of DNA and protein macromolecules across the Gram-negative cell envelope requires elaboration of dedicated translocation systems and the coupling in space and time of substrate recruitment, processing, and translocation reactions. Translocation of substrates to another cell by contact-dependent mechanisms adds more complexity through the requisite establishment of productive cell-cell junctions. The type IV secretion systems (T4SSs) deliver various macromolecular substrates, including DNA and monomeric and multimeric proteins, to a diversity of bacterial, fungal, plant, and human cell types (1, 2). Some T4SSs also function as contact-independent exporters or importers of substrates to or from the extracellular milieu. This functional versatility makes the T4SSs unique among the known bacterial translocation systems. In Escherichia coli, the known T4SSs are restricted in their substrate repertoires to mobile genetic elements (MGEs), although these systems also are capable of translocating certain proteins associated with the DNA transfer process. Detailed investigations of conjugation machines have established the importance of T4SSs over evolutionary time in the shaping of bacterial genomes and, on a more immediate time scale, for dissemination of virulence and antibiotic resistance genes in clinical settings (3, 4). These studies also have contributed greatly to our current understanding of T4SS machine architecture, mechanism of action, and evolution (3, 5, 6, 7). The T4SSs are functionally grouped as (i) conjugation systems, (ii) effector translocators, or (iii) contact-independent DNA/protein exchange systems (1). The conjugation systems are the largest subfamily, present in nearly all bacterial species and some archaeal species (5). These systems are specifically employed for dissemination of the mobile elements that encode them, and they also can mediate transfer of some genetically unlinked, non-self-transmissible mobile elements. The effector translocators, so far shown to function only in Gram-negative pathogens or symbionts, deliver effector proteins to eukaryotic cells (8, 9, 10). The translocated substrates disrupt host cell physiological processes, enabling bacterial colonization and spread. The contact-independent exchange systems, consisting of only a few members, function in release of DNA or protein substrates to the milieu or, alternatively, uptake of exogenous DNA (11, 12, 13). In E. coli, several conjugation systems have been characterized in detail (see Fig. 1). These systems elaborate two surface structures, a cell-envelope-spanning translocation channel and an extracellular pilus (6, 7). A classification scheme that will be used in this review groups the E. coli conjugation systems by the type of conjugative pilus produced. Accordingly, F-type systems elaborate long, flexible pili that dynamically extend and retract (14, 15, 16). These pili support equally efficient mating in liquid or solid surfaces. The P-type systems, by contrast, elaborate short, rigid pili for which no evidence exists of dynamic extension and retraction. Well-characterized conjugation systems encoded by E. coli plasmids RP4, R388, and pKM101, as well as the Agrobacterium tumefaciens VirB/VirD4 system, are P-type systems (17). A third group of plasmids represented by R64 and ColIb-P9 encode two types of pilus structures: a thick, rigid conjugative pilus and a long, flexible type IV pilus. Despite their name, type IV pili are ancestrally unrelated to conjugative pili produced by T4SSs and instead are phylogenetically and functionally related to type II secretion systems (T2SSs) (18). Nevertheless, type IV pili do play a role in enhancing conjugative transfer of these plasmids, especially in liquid media, by virtue of their ability to extend and retract, reminiscent of F pili. The T4SSs encoded by this group of plasmids are designated as I type, and they have a number of physical and functional features that distinguish them from the F- and P-type systems (19, 20). A major aim of this review is to summarize structure-function relationships of paradigmatic F-, P-, and I-type conjugation systems of E. coli and the VirB/VirD4 system of A. tumefaciens. On the basis of detailed phylogenetic studies, it is postulated that the present-day effector translocators evolved from P-, F-, and I-type conjugation systems (5). In general, this process involved the appropriation by ancestral conjugation systems of structural motifs from unknown ancestries that enabled diversification of substrate repertoires and the capacity to deliver substrates to eukaryotic host cells. A second goal of this review is to compare well-characterized conjugation and effector translocator systems to shed light on this evolutionary process and to illustrate the striking structural diversity and functional versatility of this fascinating translocator superfamily. OVERVIEW OF T4SS ARCHITECTURE AND TRANSLOCATION PATHWAY The paradigmatic A. tumefaciens VirB/VirD4 T4SS provides a unifying genetic nomenclature for a discussion of the T4SSs (Fig. 1) (21). The T4SSs of Gram-negative bacteria can be viewed as compilations of four distinct proteins or subassemblies: (i) the VirD4 type IV coupling protein (T4CP); (ii) the inner membrane complex (IMC) composed of VirB4 ATPase, VirB11 ATPase (when present), polytopic VirB3 and VirB6, and bitopic VirB8; (iii) the outer membrane complex (OMC) composed of outer membrane-associated VirB7 and VirB9, and a cell-envelope-spanning subunit VirB10; (iv) the conjugative pilus composed of VirB2 pilin, a proteolytic fragment of the VirB1 transglycosylase (VirB1*) and the pilus-tip protein VirB5 (Fig. 2A) (6, 7). The VirB/VirD4 T4SS and related P-type systems in E. coli are among the simplest T4SSs functioning in Gram-negative species in terms of subunit composition and machine architecture. Other P-type systems as well as the F- and I-type systems encode homologs or orthologs of most or all of the VirB subunits, but also possess additional domains, subunits, or protein subcomplexes that endow these systems with specialized functions and confer greater structural complexity (9, 14, 22). Two recent lines of investigation have shaped our current view of T4SS architecture and the substrate translocation pathway (Fig. 2). Although investigations commencing in the 1940s established the importance of so-called mating pair formation (Mpf) proteins for conjugative DNA transfer, it was not until the early 2000s that the first definitive evidence was obtained that these proteins assemble as a mating channel. By use of a ChIP-based, formaldehyde (FA)-crosslinking assay termed transfer DNA immunoprecipitation (TrIP), a translocation pathway was described for the A. tumefaciens transfer-DNA (T-DNA) substrate through the VirB/ VirD4 T4SS (23). With the TrIP assay, FA-cross-linkable substrate contacts were detected with the VirD4 T4CP, VirB11 ATPase, inner membrane proteins VirB6 and VirB8, and periplasmic/outer membrane subunits VirB2 and VirB9 (Fig. 2B). These subunits were thus postulated to constitute the cell-envelope-spanning “mating” channel. Other components of the T4SS that did not form FA cross-links with the T-DNA substrates were proposed to function as structural scaffolds or stabilizing elements for the channel (23). Second, structures of T4SS subunits or soluble domains and of larger subassemblies have been solved by X-ray crystallography or electron microscopy. Most notably, structures recently were presented for the OMC and the IMC/OMC subassemblies of P-type systems encoded by E. coli plasmids pKM101 and R388 (24, 25, 26). The R388-encoded IMC/OMC subassembly is the largest T4SS structure solved to date and is composed of homologs of the A. tumefaciens VirB3 through VirB10 subunits, lacking only homologs of VirD4, VirB11, VirB1, and VirB2 (26). This structure, here referred to as R388 T4SS3–10, is the current architectural blueprint for the T4SSs (Fig. 2C) and is described in more detail below. By integrating results of the in vivo TrIP and ultrastructural studies, a current model for translocation of substrates through a P-type T4SS postulates that substrates first dock with the VirD4 T4CP and then are transferred to VirB11 for further processing. All three ATPases, VirD4, VirB11, and VirB4, then coordinate substrate transfer across the inner membrane via a channel composed minimally of VirB6 and VirB8. The substrate is then delivered into a channel, composed of VirB2 and VirB9, that is housed within the OMC for translocation across the periplasm and outer membrane (Fig. 2) (7, 23, 27). The following sections describe this P-type translocation pathway and interesting structural or mechanistic variations among the F- and I-type systems. SUBSTRATES AND SUBSTRATE RECOGNITION In the initiating steps of type IV secretion, DNA and protein substrates are processed and recruited to cognate T4SSs for translocation. The early DNA substrate-processing reactions have been extensively reviewed elsewhere (3, 28). In brief, these are conserved reactions in most bacteria, carried out by proteins termed DNA transfer and replication (Dtr) factors. Dtr proteins bind specific origin-of-transfer (oriT) sequences associated with mobile elements, resulting in formation of the catalytically active relaxosome. One Dtr protein, the relaxase, cleaves the DNA strand destined for transfer (the T strand) at the nic site through a DNA phosphodiesterase reaction that results in covalent linkage of a catalytic Tyr residue with the 5′ end of the cleaved DNA. Accessory Dtr factors play critical roles in guiding the relaxase to the oriT sequence and facilitating the nicking reaction on supercoiled DNA substrates. Upon nicking, the relaxase serves to pilot the covalently associated T strand through the conjugation or “mating” channel. The early DNA-processing reactions are spatially positioned at or near the entrance to the conjugation channel, specifically mediated by contacts formed between relaxosome components and the VirD4-like T4CP (28, 29, 30). Accordingly, the T4CP functions as the receptor and docking site for cognate DNA substrates. This receptor activity, however, is not restricted to DNA substrates. T4CPs are associated with nearly all effector translocator systems, where they also function as receptors for protein substrates (2, 31). DNA Substrate Recognition Signals The nature of DNA substrate-T4CP contacts is not yet fully defined, but studies have identified motifs associated with relaxases that are required for DNA transfer. These motifs are postulated to specify the docking of DNA substrates with cognate T4CPs and are designated as translocation signals (TSs). Among the relaxases characterized to date, two types of TSs have been identified. The F plasmid-encoded TraI relaxase, for example, is a large protein with relaxase and helicase domains in its two halves. TSs termed TSA and TSB were mapped, respectively, in the two halves of the protein (32). Both TSs have a consensus sequence (G[E/D]R[L/M]R[V/F]T), and a structure of the TSA region of TraI was solved recently by X-ray crystallography (33). It consists of three domains, each structurally similar to SF1B helicase family domains. A putative T4CP interaction surface was mapped to one of the helicase domains through mutational analysis. Other relaxases, including R388-encoded TrwC and RSF1010-encoded MobA, carry TSs similar to those identified in TraI, suggestive of a common mode of relaxase binding to cognate T4CPs (34, 35, 36). Relaxases alternatively have C-terminal signals that can contribute to DNA substrate-T4CP docking. In A. tumefaciens, for example, the VirD2 relaxase carries such a TS, which is composed of a high proportion of positively charged residues. This motif is critical for the VirD2-VirD4 T4CP interaction and for transfer of the T-DNA substrate through the VirB/VirD4 T4SS to plant cells (see below). Interestingly, the VirB/VirD4 T4SS also translocates several protein substrates to plant cells, and these substrates also carry C-terminal, positively charged TSs (37, 38). Finally, relaxases can carry a combination of internal and C-terminal TSs for docking with cognate receptors. In some cases, such relaxases have been shown to employ these signals to mediate transfer of DNA substrates through distinct T4SSs. RSF1010 plasmids, for example, are promiscuous in the sense that they can translocate through many different T4SSs. RSF1010’s MobA relaxase carries internal TSs required for RSF1010 transfer through P-type T4SSs in E. coli. However, the relaxase also carries a C-terminal, positively charged TS that promotes RSF1010 transfer through the A. tumefaciens VirB/VirD4 T4SS (34, 36, 38). Similarly, the TrwC relaxase employs internal TSs for substrate transfer through the R388-encoded T4SS, and a C-terminal motif for substrate passage through a Bartonella henselae VirB/ VirD4 T4SS (35). Relaxases are only partly responsible for specifying the docking of DNA substrates with cognate T4CPs. Other Dtr accessory factors can confer substrate specificity, as best documented for the F-type systems. For F plasmids, substrate docking relies on the formation of highly specific contacts between the accessory factor TraM and the TraD receptor. In fact, the TraM-TraD interaction is the only structural interface solved to date by X-ray crystallography, as described in further detail in the next section. T4CPs and the DNA Substrate-Docking Reaction The T4CPs are so named because they link secretion substrates with cognate T4SS channels (23, 39, 40, 41). They typically are composed of an N-terminal transmembrane domain (NTD) joined to a large cytoplasmic moiety that consists of a nucleotide binding domain (NBD) and an α-helical bundle termed the all-alpha-domain (AAD) (Fig. 3A, B). An X-ray structure showed that a soluble fragment of the TrwB T4CP assembles as a globular homohexamer of ~110 Å in diameter and 90 Å in height, with a ~20-Å-wide channel in the center. This channel forms an 8-Å-wide constriction at the cytoplasmic pole of the molecule. The NTD extends from the opposite end of the globular assembly, as shown by electron microscopy, giving rise to an overall F1-F0-like ball-stem structure (Fig. 3A) (41, 42). These findings, coupled with evidence that T4CPs exhibit sequence and structural similarities with the FtsK and SpoIIIE DNA translocases, prompted a model in which the T4CP serves as the translocase for delivery of DNA substrates across the inner membrane (See Fig. 2, route 1) (43). Two features of the TrwB structure point to a role for the AAD in DNA substrate docking: (i) the AAD is positioned at the cytoplasmic pole of the TrwB homohexamer (Fig. 3A) and (ii) the AAD structurally resembles the DNA binding domain of XerD recombinase (41). Mutational analyses confirmed the functional importance of AADs associated with TrwB as well as a homolog encoded by plasmid RP4 (44, 45). A recent study further showed that the AADs of the A. tumefaciens VirD4 T4CP and of a T4CP encoded by Enterococcus faecalis pCF10 are essential for translocation of cognate DNA substrates in vivo (46). Purified forms of these domains bind DNA substrates and, more importantly, display specificity for cognate relaxases and other Dtr factors (46). As mentioned above, the A. tumefaciens VirD2 relaxase possesses a C-terminal TS required for T-DNA transfer to plants (38, 47, 48, 49). A VirD2 mutant deleted of this TS fails to bind VirD4’s AAD in vitro, suggesting that a VirD2 TS-VirD4 AAD interaction constitutes a basis for docking of the T-DNA substrate with the VirB/VirD4 channel in A. tumefaciens (49). T4CPs also can carry C-terminal domains (CTDs) of variable lengths and sequence compositions (Fig. 3B) (2). Contributions of these CTDs to substrate transfer are unspecified, with one notable exception. For F-type systems, the CTD of the TraD receptor plays a critical role in docking of the F plasmid substrate (Fig. 3C) (50). An acidic motif at the extreme C terminus of the CTD was shown by X-ray crystallography to mediate specific contacts with the Dtr accessory factor TraM (51, 52). Mutational analyses further confirmed that the TraD hexamer-TraM interaction forms the basis of a highly specific relaxosome-T4CP interaction in vivo (52, 53). This interaction both mediates highly efficient F plasmid transfer and blocks access of the RSF1010 plasmid substrate to the T4CP, resulting in strong inhibition of RSF1010 plasmid transfer (50). TraD’s CTD thus functions as a specificity checkpoint by ensuring efficient docking of the cognate F plasmid substrate at the exclusion of alternative substrates. At this juncture, therefore, the available data suggest that T4CPs recruit cognate DNA substrates through interactions mediated by AADs and, when present, CTDs. Further work is needed to define substrate-T4CP interactions at higher resolutions and identify factors controlling the dynamics of these contacts. The “coupling” function of T4CPs is only partly defined by its receptor activities. T4CPs also interact with cognate T4SS channel subunits to mediate delivery of docked substrates through the channel. The NTDs of T4CPs are required for these contacts, as shown by two-hybrid screens and mutational analyses (54, 55). These domains are implicated in formation of contacts with VirB10-like subunits (54, 55, 56), and it has been proposed that such contacts are responsible for the coupling of T4CPs with cognate channels. On purely stoichiometric grounds, however, it is difficult to envision how a T4CP hexamer (s) forms specific contacts with VirB10 subunits, which, according to the R388 T4SS3–10 structure, exist in 14 copies in the translocation channel (Fig. 2) (26, 41). Another complicating aspect of this interaction is that T4CPs have been shown to undergo profound changes both in conformation and oligomeric state in response to substrate docking and ATP binding signals (57, 58; see below). Accordingly, it seems more reasonable that, rather than forming stable, high-affinity contacts with T4SS channel subunits, T4CPs associate dynamically with T4SSs, possibly in response to activation by intracellular signals. That the T4CP is not a fixed, structural component of the T4SS is further supported by the fact that, in its absence, the T4SS is fully functional in its ability to elaborate conjugative pili (2, 22). STRUCTURE AND FUNCTION OF TYPE IV MACHINES The T4CPs deliver secretion substrates to the translocation channel composed of the VirB homologs. As mentioned above, the R388 T4SS3–10 structure currently represents the architectural blueprint for the T4SS superfamily (Fig. 2C). It is dominated by two large subassemblies, the IMC and OMC, which are connected by a narrow stalk. The following sections summarize current structure-function information about these subassemblies and the respective components, with emphasis on their contributions to the dynamics of substrate transfer across the inner and outer membranes. Contributions of ATPases to Substrate Trafficking In the R388 T4SS3–10 structure, two hexamers of the VirB4-like ATPase form the “legs” of the IMC substructure, but the VirD4- and VirB11-like ATPases were absent (Fig. 2). The ATPase interaction network is thus not yet described in molecular detail, nor is the specific contribution(s) of ATP energy to the overall process of substrate transfer. There is, however, compelling evidence for the P-type systems that all three ATPases coordinate their activities to drive substrate transfer across the inner membrane (54, 59). Interestingly, while the P- and I-type conjugation systems employ homologs of the VirD4, VirB4, and VirB11 ATPases (19, 20, 60, 61), in striking contrast, the F-type systems as well as conjugation systems functioning in Gram-positive species employ only homologs VirD4 and VirB4 (8, 22). The role of the T4CP as a substrate receptor is described above. Importantly, receptor activity does not require the ATP hydrolysis by the T4CP, suggesting that this catalytic activity is required for subsequent steps of the transfer process. One such postulated function is that the T4CP itself catalyzes the delivery of secretion substrates across the inner membrane (Fig. 2, route 1). According to this model, the DNA substrate binds the T4CP via its AAD and then enters the central lumen of the hexamer. The substrate is then pumped through the lumen by rounds of ATP hydrolysis across the membrane (3). At this time, the only support for this model is that the T4CP is phylogenetically and structurally similar to the DNA translocases SpoIIIE and FtsK (43). It is also difficult to reconcile this model with results of the TrIP studies showing that all three ATPases, VirD4, VirB4, and VirB11, are required for delivery of the DNA substrate to the inner membrane subunits VirB6 and VirB8 (23). Thus, alternative models have postulated that the three ATPases form an energy center that coordinates early-stage DNA-processing reactions as well as delivery of the DNA transfer intermediate across the membrane (Fig. 2, routes 2 and 3). Specific contributions of the VirB-like ATPases to substrate transfer have not been defined, but results of mutational analyses as well as structural information about these subunits have supplied important clues regarding their functions. For the VirB11-like ATPases, results of the TrIP studies showed that VirB11 interacts with the DNA substrate only in cells producing the VirD4 receptor, implying that VirD4 delivers the substrate to VirB11 (23). Mutational studies further supplied evidence that VirB11 also engages with effector protein substrates (62). Structural studies of VirB11 homologs revealed that these proteins belong to a secretion ATPase superfamily, whose other members include GspE subunits associated with T2SSs and type IV pilus assembly systems and InvC associated with a Salmonella enterica type III secretion system (T3SS) (63–65). These ATPases undergo large nucleotide-dependent conformational changes thought to be important for providing the mechanical leverage necessary for driving machine assembly processes or substrate unfolding. Indeed, studies confirmed that InvC catalyzes both the release of bound secretion chaperones and unfolding of effector proteins in an ATP-dependent manner (66). By analogy, VirB11 subunits might catalyze the unfolding of relaxases and effector proteins prior to translocation through the T4SS. The VirB4 ATPases are large (>70 kDa) proteins that bind tightly or integrally with the cytoplasmic membrane. Interestingly, these proteins are phylogenetically related to and exhibit structural similarities with T4CPs (5, 67). VirB4-like subunits have been shown to form multiple contacts with other IMC subunits, as well as with the VirB10 subunit (54, 59, 68). In A. tumefaciens, cross-linking of the T-DNA substrate with VirB4 was not detected by TrIP, but production of VirB4 was necessary for detectable substrate cross-linking with the VirB6 and VirB8 channel components (23). In more recent studies, evidence was presented for DNA substrate binding in vivo by a VirB4 homolog associated with a E. faecalis T4SS (69) and for DNA binding in vitro by VirB4 homologs associated with the E. coli pKM101- and R388-encoded T4SSs (70, 71). These findings raise the possibility that VirB4 plays a more direct role in mediating the transfer of DNA substrates across the inner membrane than originally envisioned (23). Accordingly, it can be proposed that, upon docking of the DNA substrate with the VirD4-like receptor, the substrate is delivered to the VirB11 ATPase for further processing. In turn, VirB11 might deliver the substrate to the VirB4 ATPase for transfer to or across the inner membrane (Fig. 2, routes 2 and 3). The Inner Membrane Complex and Its Contribution to Substrate Transfer across the Inner Membrane In early studies, the IMC was envisioned as a subassembly consisting of the ATPases and one or a few copies each of the membrane proteins VirB3, VirB6, and VirB8 (17). Structural definition of the R388 T4SS3–10 subassembly, however, now establishes that the IMC is considerably larger than previously thought (Fig. 2C) (26). This substructure presents as an arch of 255 Å in width sitting on top of the two VirB4 hexamer barrel structures each with dimensions of 105 Å in width and 135 Å in length. The arch, composed of 12 copies each of VirB8 and VirB3, and 24 copies of VirB6, sits in the inner membrane. Intriguingly, the arch also is composed of 12 copies of VirB5, which also localizes at the tip of the conjugative pilus (26). Finally, the IMC is composed of 14 copies of VirB10, which also is a major structural component of the OMC (see below). In view of known topologies of these subunits, the IMCs of P-type systems can be estimated to consist of at least 200 transmembrane helices. VirB6 channel activity? Results of the TrIP studies in A. tumefaciens favored a translocation pathway whereby the three ATPases coordinate delivery of DNA substrates to a membrane channel composed of VirB6 and VirB8 (Fig. 2, route 3) (23, 54). Various VirB6 mutations also were found to selectively block formation of T-DNA contacts with VirB8, suggesting that VirB6 and VirB8 act sequentially in the substrate transfer pathway (Fig. 2B) (72). Other mutations in VirB6 selectively inhibited formation of substrate contacts with the VirB2 and VirB9 subunits, further indicating that VirB6 also might form contacts with OMC components necessary for passage of the DNA substrate through the distal portion of the channel (see below) (72). VirB6 subunits minimally are ~300 residues with 5 or more membrane-spanning domains and a large central, periplasmic domain (2, 72). In view of the recent T4SS3–10 structure, it is intriguing to consider how 24 copies of VirB6 might be configured as part of the translocation channel. One possibility warranting further investigation is that VirB6 oligomerizes to form more than one functional channel across the inner membrane. This could, for example, enable the simultaneous passage of multiple substrates through a given T4SS in response to environmental cues. For conjugation machines mediating the transfer of a mobile genetic element to a bacterial recipient, such redundancy of function might not seem necessary. However, as noted earlier, conjugation systems translocate not only DNA substrates but also certain proteins, e.g., primases, single-stranded DNA binding proteins (SSBs), that function in establishment of the mobile element upon transfer to recipient cells (73, 74). Successful transfer of a DNA substrate therefore could rely on the coordinated and simultaneous transfer of DNA-metabolizing proteins, sometimes in many copies as in the case of SSBs, through a given T4SS. It is also noteworthy that effector translocator systems typically deliver multiple substrates to eukaryotic target cells. While this could be achieved through reiterative rounds of transfer through a single channel or different T4SS machines, a potentially more efficient mechanism would employ multiple channels within the framework of a single T4SS machine for the simultaneous export of multiple substrates. This could explain how, in Legionella pneumophila, the Dot/Icm system is able to rapidly deliver as many as several hundred effectors to eukaryotic cells during an infection (75, 76). With these considerations in mind, the various translocation routes depicted in Fig. 2 might not be mutually exclusive. For example, the T4CP or VirB4-like ATPase might suffice to translocate DNA substrates (routes 1 and 2), while the VirB6/VirB8 channel mediates protein trafficking (route 3). Even for DNA transfer, a model was proposed that the T4CP functions as the translocase for the DNA component of a DNA substrate and the VirB6/ 8 subunits mediate transfer of the relaxase bound to the 5′ end of the DNA substrate (3). Such a model is intriguing as it invokes two distinct translocation pathways for the delivery of a single DNA substrate, the relaxase-T-strand transfer intermediate, across the inner membrane. It also has been envisioned that large periplasmic loops of VirB6 monomers might assemble to form an entry portal for DNA substrates delivered to the periplasm by the T4CP ATPase. This proposal was based on findings in A. tumefaciens that mutations in a central periplasmic loop of VirB6 blocked formation of formaldehyde crosslinks with the DNA substrate (72). In fact, the existence of an entry portal in the periplasm for feeding substrates into the channel housed by the OMC is appealing in view of evidence that some effector translocator systems recruit and export substrates that are first delivered to the periplasm via the general secretory pathway (GSP; see below). VirB8, an IMC-OMC connector? The VirB8 subunits are bitopic proteins with a short cytoplasmic N-terminal domain, a membrane-spanning domain, and a large C-terminal periplasmic domain (77). VirB8 subunits are signatures of T4SSs carried by Gram-negative and -positive species (8), and recent work has established that their periplasmic domains adopt a common structural fold (78, 79, 80, 81, 82). This fold presents as large extended β-sheets with five α-helices, giving rise to an overall globular fold. VirB8 subunits pack as dimers or trimers in the crystal structures, and results of mutational analyses suggest that oligomerization is physiologically relevant. Indeed, the dimer interface has served as a target for a high-throughput screen that resulted in the identification of small-molecule inhibitors of T4SSs (83). Recently, crystal structures were solved for the periplasmic domains of VirB8-like DotI and TraM associated with the I-type L. pneumophila Dot/Icm and plasmid R64 T4SSs (82). Interestingly, the VirB8-like domain of DotI forms a stack of two octameric rings in the crystal structure, and results of mutational analyses suggest that the contacts between the two octameric rings are biologically important in vivo. The octameric structure distinguishes DotI of the I-type systems from P-type homologs, which are predicted to assemble as a dodecameric ring in the IMC (26, 82). Nevertheless, in view of the earlier TrIP data generated with the A. tumefaciens system, it is reasonable to propose that these subunits assemble as ring-like structures at the IMC/OMC junction for conveyance of substrates from the IMC into the channel housed by the OMC. The Outer Membrane Complex and Its Contribution to Substrate Transfer across the Outer Membrane In A. tumefaciens, the outer membrane lipoprotein VirB7 and VirB9 interact with bitopic inner membrane protein VirB10, forming a subassembly originally termed the core complex (see Fig. 2A) (17, 21). This complex, renamed the OMC, is intrinsically stable and stabilizing for most of the other VirB subunits (17). A. tumefaciens ring-shaped OMC complexes were visualized by transmission electron microscopy (TEM) (84), and corresponding OMCs associated with P-type T4SSs encoded by E. coli plasmids pKM101 and R388 have been structurally solved by X-ray crystallography, cryoelectron microscopy, and TEM (24, 25, 26). The pKM101-encoded OMC is composed of 14 copies each of the VirB7, VirB9, and VirB10 homologs (24, 25). This is a large, 1.05 MDa barrel-shaped structure of 185 Å in width and length. It is composed of two layers (I and O layers) forming a double-walled structure. The I layer, composed of the N-terminal domains of VirB9 and VirB10, is anchored in the inner membrane via the N-terminal transmembrane domain of VirB10. The N-terminal domains of VirB10 form a ring of 55 Å in diameter when the OMC is produced in the absence of the IMC. The O layer, composed of VirB7 and domains of VirB9 and VirB10, has a main body and cap that is thought to span the outer membrane. The cap, with a narrow hole of 10 Å in diameter, consists of 14 copies of a domain of VirB10 termed the antennae projection (AP). The OMC thus forms a large barrel with openings at both ends (24, 25). VirB10-like proteins are highly unusual bacterial membrane proteins in extending across the entire cell envelope (24, 85). This feature lends itself well to roles for these subunits not only as structural scaffolds for the T4SS (27) but also as transducers of activating signals from within or outside the cell across the T4SS (see below). In the R388 T4SS3–10 structure, the OMC is linked to the IMC by a thin structure termed the stalk (Fig. 2B) (26). The composition of the stalk is not defined but must consist in part of the 14 copies of VirB10’s N-proximal region since the N terminus of VirB10 extends across the inner membrane. The biological importance of the stalk, or even its existence in the context of the T4SS when embedded in the cell envelope of an intact cell, is not yet established. However, a gap between the IMC and OMC junction may enable access of substrates delivered into the periplasm via the GSP to the OMC for translocation across the outer membrane. The interior chamber of the OMC is sufficiently large to house a translocation channel consisting of VirB2 and VirB9, which were shown by TrIP to cross-link with the translocating T-DNA substrate (24, 25, 86). Interestingly, VirB10 did not detectably interact with the DNA substrate (23), even though VirB10’s AP presumably forms the outer membrane-spanning pore (24, 25). OMC structures solved to date lack VirB2 pilin homologs, and it is conceivable that VirB2-like subunits assemble as part of the channel at the distal end of the OMC to add structural complexity to the outer membrane pore (Fig. 2A) (27). The Translocation Route With an emerging knowledge of T4SS architecture, it is interesting to return to the question of how substrates are routed through the T4SS across the cell envelope. Translocation systems of Gram-negative bacteria deliver their cargoes either in one or in two steps. One-step pathways employ a single channel that spans the entire cell envelope, and two-step pathways employ an inner membrane translocase and a second system that recruits the substrate from the periplasm for delivery across the outer membrane (see reference 18). Most T4SSs are thought to employ a one-step route, as depicted in Fig. 2, routes 2 and 3. For conjugation systems, such a pathway is highly likely given the prevalence of nucleases in the periplasm. Indeed, in uninterrupted matings over periods of many minutes, E. coli Hfr strains can translocate single-stranded forms of nearly entire chromosomes through F-type T4SSs without apparent degradation. A one-step pathway does not exclude the use of a T4CP for delivery of DNA cargoes across the inner membrane (Fig. 2, route 1), however, because the physical disposition of the T4CP relative to the T4SS3–10 subassembly is not known presently. Thus, the T4CP could fit within the body of the IMC, possibly even substituting for one or both of the VirB4 “legs,” to enable DNA delivery through a T4CP-channel contact without substrate exposure to the periplasm (see Fig. 2). It is simplest to envision that a one-step pathway also is employed for translocation of protein substrates, but this is not invariably the case, because at least two systems lack a T4CP and instead rely on the GSP or another inner membrane translocase for delivery of the protein substrate to the periplasm. The Bordetella pertussis Ptl system was the first described T4SS utilizing a two-step pathway. The sole substrate of the Ptl system is the pertussis toxin (PT) of the A/B family of toxins. The A and B subunits of PT carry canonical sec signal sequences for secretion to the periplasm by the GSP. Once in the periplasm, the PT subunits assemble as the holotoxin, which is then recruited and exported by the Ptl system to the extracellular milieu (11). The Ptl system resembles other P-type systems in subunit composition and most likely in overall architecture (see Fig. 1 and Fig. 2) (87). With the R388 T4SS3–10 subassembly as a structural reference (Fig. 2C), it is enticing to suggest that the holotoxin enters the Ptl T4SS through a portal positioned at the IMC/OMC junction. The VirB T4SSs elaborated by Brucella spp., also likely employ a two-step translocation route for delivery of effectors into eukaryotic host cells. Interestingly, the Brucella T4SSs also lack associated T4CPs, yet only some effectors carry canonical sec signal sequences, while others do not. Precisely how the latter are translocated across the inner membrane remains an intriguing question for further study (88, 89, 90). Signal-Mediated Activation of T4SSs The T4SSs generally translocate substrates only upon establishment of direct contact with target cells. This indicates that the channels are gated and activated by propagation of a signal from recipient to donor cells. Studies in the 1970s of the F transfer system supplied strong experimental support for such a signal, generated upon contact of the F pilus with a recipient cell (91). This signal is transduced to the interior of the donor cell where it stimulates early F plasmid-processing reactions. More recent work supplied further evidence for signal communication from the F pilus to the cell interior (92). The F-like R1-encoded pilus is the receptor for bacteriophage R17, which enters cells through undefined mechanisms involving pilus retraction or penetration of the pilus lumen. It was discovered that R17 binds and enters only cells in which the TraD T4CP has already engaged with the F relaxosome. Phage R17 binding appears to supply a requisite extracellular signal, possibly by mimicking recipient cell contact, which together with the DNA substrate-T4CP docking signal activates the channel to allow phage uptake. Studies in A. tumefaciens also have provided evidence for signal transduction along the VirB/VirD4 T4SS. In this system, VirB10 was shown to undergo a conformational switch in response to sensing of two intracellular signals mediated through the VirD4 T4CP. The first signal is conveyed through a two-step reaction involving the docking of the T-DNA substrate with VirD4 and its subsequent transfer to the VirB11 ATPase (49). The second signal corresponds to the ATP hydrolysis activities of VirD4 and VirB11 (93). Integration of these signals results in a conformational change in the structural scaffold VirB10, as shown by a change in protease susceptibility. This conformational change is necessary for passage of the DNA substrate through the distal portion of the VirB channel composed of the VirB2 pilin and VirB9 subunits, as shown with the TrIP assay (49, 93). The nature of the conformational change is not yet known, but a role for VirB10 in the coupling of intra-cellular signals to gating of an outer membrane pore is suggested by isolation of a mutation near the VirB10 AP pore that “locks” VirB10 in the energized conformation and allows for release of secretion substrates to the cell surface independently of target cell contact (94). Therefore, as shown for a number of small-molecule and macromolecular transport systems, the VirB/VirD4 T4SS appears to be activated by a combination of ligand and energy signals. It is tempting to suggest that intra- and extracellular signals generally activate T4SS channels through the envelope-spanning VirD4-VirB10 transduction network. For type IV secretion, signal activation would open channels enabling substrate passage to target cells. In a reverse reaction, exogenous DNA or phage binding to pilus or other T4SS receptors might activate channels for uptake of nucleic acids across the cell envelope. MODULATION OF DONOR-TARGET CELL INTERACTIONS BY ADAPTED FORMS OF CHANNEL SUBUNITS Besides their functions as structural components of the translocation channel, several T4SS subunits have been adapted for novel purposes through acquisition of novel domains or motifs. Most notably, the IMC component VirB6 and the OMC subunits VirB7 and VirB10 of several T4SSs carry domains of demonstrated or postulated importance for modulation of donor cell contacts with bacterial or eukaryotic target cells. The next sections describe some of these specialized functions. Extended VirB6s VirB6 subunits are minimally ~300 kDa and have at least 5 or 6 membrane-spanning helices (2, 72). A subset additionally carries a large hydrophilic domain of functional importance. These subunits were designated “extended VirB6,” and they are found in conjugation systems and many effector translocator systems (2). For the F-type T4SSs, the polytopic motif of VirB6-like TraG subunits is followed by a large ~600 residue C-terminal domain (Fig. 4) (22). This domain is extensively α-helical in its predicted secondary structure, and has been suggested to functionally substitute for VirB8, on the basis of its periplasmic location and the absence of a VirB8 ortholog in the F-type systems (14, 22). Interestingly, TraG also is involved in entry exclusion, a process that blocks redundant DNA transfer between identical donor cells. When a donor cell contacts another donor cell, the C-terminal domain of TraG is thought to extend across the outer membranes of the paired cells to form a specific contact with TraS, a protein also encoded by F-carrying donor cells (Fig. 4) (95, 96). This contact signals a nonproductive donor-donor cell junction, and blocks DNA transfer. Similar findings were reported for homologs of TraG and TraS encoded by the SXT ICE (integrative and conjugative element) of Vibrio cholera (97). Precisely how the TraG-TraS interaction blocks DNA transfer is not yet known, but might involve transduction of a signal across the donor-donor cell junction resulting in a conformational change in the T4SS that blocks channel function (Fig. 4). The Rickettsia spp. P-type T4SSs have multiple copies of variant forms of “extended-VirB6” subunits (98, 99). They range in size between ~600 and 1,400 residues and the polytopic VirB6 motif can be located in one or both terminal regions or centrally. There is evidence for surface display of VirB6 domains in Wolbachia, supporting the notion that such exported domains are involved in establishment of endosymbiotic relationships (Fig. 4) (100). Whether these domains protrude through the OMC chamber as depicted in Fig. 4, or are proteolytically cleaved from the rest of the protein prior to export to the cell surface is presently not known. I-type systems also code for “extended-VirB6” subunits. E. coli plasmid R64 encodes TraY, a 745-residue protein with an unusual hydropathy profile (19). The N- and C-terminal thirds of the protein are highly hydrophobic with between 4 and 6 TM motifs, and the central third is hydrophilic and predicted to reside in the periplasm. In the related L. pneumophila Dot/Icm system, the TraY ortholog is DotA. DotA is ~300 residues larger than TraY, and possesses the same general hydropathy profile with multiple N- and C-terminal TM domains flanking a central hydrophilic domain. Strikingly, DotA is released in a Dot/Icm-dependent manner to the extracellular milieu where it forms ring-shaped complexes (Fig. 4) (101). In contrast to R64-encoded TraY, DotA has an N-terminal signal sequence, leading to a proposal that it is secreted across the membrane by the GSP (101). If true, DotA would be delivered to the cell surface in two steps: first, across the inner membrane by the GSP and, second, across the outer membrane by the Dot/Icm T4SS (Fig. 4). No function has been ascribed to the extracellular form of DotA, and no follow-up studies have defined its export route in further detail. VirB7 Adaptations VirB7 subunits are typically small lipoproteins that play an important role in stabilizing the OMC at the outer membrane. However, larger forms of VirB7-like lipoproteins functioning in P- and I-type systems have novel features, including surface variable regions, as shown for Helicobacter pylori CagT (102, 103), or N0 domains as shown for Xanthomonas citri VirB7 and L. pneumophila DotD (Fig. 5) (104, 105). Studies have shown that surface-variable CagT is required for CagA translocation and pilus biogenesis (106, 107), and also might contribute to immune evasion by H. pylori (102). By contrast, No domains are structural modules thought to serve a variety of functions relating to transport processes. They are features of transport-associated proteins, including TonB, secretins of the types II and III secretion systems and related type IV pilus systems, bacteriophages, and type VI secretion systems (see reference 104). The N0 domains of X. citri VirB7 and L. pneumophila DotD are envisioned to form additional rings at the base of the OMC that contribute to channel gating or contacts with the IMC (104, 105). VirB10 Adaptations The VirB10-like subunits are among the most sequence-and structurally variable subunits of the T4SSs. In the Cag T4SS of H. pylori, only a small C-terminal region of CagY is similar to VirB10, whereas a large central region is composed of multiple repeats (Fig. 5) (108). This central region is surface displayed and associates with a pilus structure (109, 110). Furthermore, during infection this region undergoes extensive genetic rearrangements that disrupt or activate the Cag T4SS (108, 110). Through host immunedriven recombination, CagY is postulated to function as a sensor of the host immune response and, in turn, regulate Cag T4SS function to maximize persistent infection (110). A second example of an interesting but as yet unexplored OMC adaptation is found in the I-type systems. In E. coli, plasmid R64 codes for TraO, which closely resembles VirB10 in size and predicted overall structure (19). In striking contrast, in the related L. pneumophila Dot/Icm system, “VirB10-like” DotG is over 1,000 residues and only the extreme C-terminal region resembles VirB10 (111, 112). DotG possesses central variable domains consisting in part of multiple sets of pentapeptide repeats (111). Although this region of DotG has been postulated to reside in the periplasm, it is noteworthy that DotG homologs from various Legionella species carry structural motifs of known bacterial effector proteins, as shown by Phyre 2 modeling (Fig. 5) (113). Most strikingly, L. pneumophila DotG (accession no. AF026534.1) has structural folds highly similar to PipB2, a T3SS effector of Salmonella enterica serovar Typhimurium (Phyre2 modeling: c2leza; 99.2% confidence; 18% sequence identity) During Salmonella infection, secreted PipB2 participates in reorganization of late endosome/lysosome compartments by linking kinesin-1 onto the Salmonella-containing vacuole (SCV) membrane. The pentapeptide motif is required to efficiently recruit kinesin-1, whereas the N-terminal domain suffices for type III translocation and association with SCVs (114, 115). A C-proximal pentapeptide motif of DotG (accession no. AF026534.1) also has a structural fold similar to the Salmonella T3SS effector SopA (Phyre2 modeling: c2qzaA, 99.7% confidence; 12% sequence identity), which structurally mimics eukaryotic ubiquitin ligase (Fig. 5) (116). The central regions of DotG subunits from different L. pneumophila species are highly variable, and a search among 11 other DotG/IcmE subunits identified structural folds similar to other effector domains that were mainly embedded within pentapeptide motifs (P. J. Christie, unpublished findings). Thus, it can be proposed that DotG subunits of Dot/Icm T4SSs might elaborate effector domains that, reminiscent of passenger domains of type V autotransporters (117), are either tethered to the L. pneumophila cell surface or released by proteolysis for delivery into eukaryotic cells. CONJUGATIVE PILI AND PILUS BIOGENESIS All conjugation systems and probably most effector translocator systems of Gram-negative bacteria elaborate pili or other surface appendages. Although there is compelling evidence that these structures promote attachment of donor cells to potential bacterial or eukaryotic target cells, the contributions of these organelles to the process of substrate transfer is somewhat controversial. On the one hand, studies of E. coli F-type pili showed that donor cells can inefficiently deliver the F plasmid to distantly located recipient cells, suggestive of a role for extended F pili as conduits for the DNA substrate (118, 119). On the other hand, E. coli and A. tumefaciens mutants lacking detectable pili can still efficiently transfer DNA substrates, establishing that extended pili are not obligatory features of T4SS channels (61, 62, 120, 121). In natural settings, it is likely these surface organelles enhance DNA transfer efficiencies, not as conduits for substrates, but rather through their ability to promote aggregation of donor and recipient cells and development of robust biofilms on biotic and abiotic surfaces. Through these adhesive activities, conjugative pili promote cellular contacts favoring formation of mating junctions that resist shear forces and other environmental perturbations. E. coli F pili are presently the best characterized group of conjugative pili. These pili are typically long, ranging from 1 to 20 µm in length, and flexible (14). Among their most noteworthy properties, they stochastically and dynamically extend and retract. This is thought to enable donor cells to scan the local environment for viable recipient cells as a means of enhancing F plasmid transfer efficiencies, particularly in low-cell-density, aqueous environments (14, 15, 16). In contrast to the F pili, the P pili are thicker, more rigid, and typically much shorter, although length measurements are complicated by the fact that isolated pili are often broken (122, 123, 124). These pili do not appear to undergo cycles of extension and retraction, but instead accumulate in the milieu, either through breakage or an active sloughing mechanism. They tend to aggregate as a mesh of polymers, which might promote nonspecific clumping of donor and recipient cells resulting in formation of productive mating pairs. The biogenesis of pili elaborated by E. coli conjugation systems has been a subject of study for over 50 years. The general requirements for pilus assembly are the same as those for elaboration of the translocation channel, with two exceptions. First, the T4CP is not required for pilus production (14). Second, the VirB1 transglycosylase is important for pilus assembly but not a functional translocation channel (60, 125). In fact, the contribution of VirB1 to pilus assembly appears not to be associated with its cell wall hydrolase activity but rather with the export of a proteolytic fragment termed VirB1* to the cell surface. At this location, VirB1* interacts with VirB2 pilin and VirB5 and, by an undefined mechanism, promotes pilus polymerization (126). The biogenesis of conjugative pili can be divided into early- and later-stage reactions, as summarized below. Early-Stage Pilus Assembly Reactions F and P pili are synthesized as pro-proteins with unusually long (~30 to 50 residues) leader peptides that are cleaved upon insertion into the inner membrane (127). The F plasmid-encoded TraA pro-pilin inserts into the membrane by a mechanism dependent on the proton motive force, but not the GSP (128). The F plasmidencoded membrane protein TraQ also is required for correct orientation and stabilization of TraA pro-pilin in the membrane (129). Membrane-embedded pro-pilins are processed further by proteases and other posttranslational modifications. Following signal sequence cleavage by LepB, F pili are acetylated at their N termini, although this modification is not required for F pilus assembly (14). Pilin subunits of P pili undergo a novel head-to-tail cyclization required for stabilization of the pilin in the membrane and for pilus assembly (130, 131). Processed forms of the conjugative pilins typically are composed of alternating stretches of hydrophilic and hydrophobic residues along the length of the protein, giving a characteristic membrane topology such that the N and C termini are in the periplasm and a small hydrophilic domain of only a few residues is in the cytoplasm (128, 132, 133, 134). Approximately ~100,000 monomers of F pilin assemble in the membrane for use in building the pilus upon receipt of an unknown signal (135). F pili assemble by sequential addition of pilin monomers to the base of the growing pilus (15). These pili are composed of a single type of pilin, although the composition and nature of the pilus tip is currently unknown. F pili are hollow cylinders of ~9 nm in diameter with an axial lumen of ~3 nm. Recent studies showed that a single F pilus is composed of distinct 1-start and 4-start helical symmetries, a property thought to enable these pili to withstand considerable extension and contraction forces as might be encountered upon engagement of the pilus with recipient cells (136). E. coli cells typically possess 1 to 5 F pili per cell, although variant F systems can encode up to 20 pili per cell. The pili are randomly distributed around the cell, and it is thought that there are more pilus assembly sites on the cell surface than extended pili (14). The structures of P pili have not yet been solved. They are difficult to visualize when attached to the cell surface, but indirect detection through decoration with pilus-specific phage or green fluorescent protein labeling of pilus assembly proteins yielded estimates as high as 20 pilus assembly sites per cell (14, 137). The mechanism by which pilins are extracted from the hydrophobic membrane environment was evaluated by monitoring accessibility of Cys residues engineered along the length of A. tumefaciens VirB2 to a membrane-impermeable thiol-reactive reagent. This study defined the inner membrane topology of VirB2 and also presented evidence that the VirB4 ATPase, with a contribution by the VirB11 ATPase, catalyzes extraction of the pilin from the membrane (134). Consistent with these findings, VirB4 also stabilizes subunits required for pilus assembly and is essential for interaction of VirB2 with another pilus-associated protein, VirB5 (68). VirB5 associates with the tip of pili elaborated by the A. tumefaciens VirB/VirD4 system, and the VirB2-VirB5 interaction is thought to be essential for pilus nucleation (138). VirB4 thus is postulated to function in dislocation of mature pilins from the inner membrane to mediate formation of the VirB2-VirB5 nucleation complex for subsequent pilus polymerization (134). F-type systems encode VirB5-like TraE subunits, but no evidence exists for a pilus tip association. Rather, these subunits are thought to form part of the T4SS in the periplasm, which, interestingly, agrees with recent evidence for association of VirB5-like TrwJ with the IMC of the R388 T4SS3–10 structure (22, 26). VirB5 subunits might have multiple functions in relation to assembly of the IMC as well as the conjugative pilus. Later-Stage Pilus Assembly and F Pilus Dynamics The membrane pool of pilin monomers is recruited upon receipt of an unknown signal(s) to build the pilus, presumably within or on top of the T4SS. In view of the R388 T4SS3–10 structure showing that two VirB4 hexamers are located at the base of the IMC (Fig. 2) (26), it is reasonable to suggest that VirB4 subunits catalyze extraction of pilin monomers from the membrane and then feed them into the chamber of the OMC. Once in the OMC chamber, pilins would undergo polymerization to build the conjugative pilus. The central chamber of the pKM101-encoded OMC is approximately 100 Å in diameter, sufficiently large to house the conjugative pilus, but the diameter of the outer membrane cap is at most only 32 Å and clearly not large enough to accommodate the pilus. These observations suggest at least two alternative models for pilus assembly. First, the pilus assembles from an IMC platform, and, as it extends through the OMC chamber, it induces profound structural changes in the distal portion of OMC. Second, pilin monomers are delivered through the OMC chamber where polymerization initiates on an outer membrane platform formed by VirB10’s AP (cap) domain (see Fig. 2C). At this time, it is not possible to discriminate between these models. As mentioned above, the F pili are so far the only group of conjugative pili for which a dynamic mode of extension and retraction has been unequivocally established. F pilus assembly requires a putative TraV/TraK/TraB OMC, as well as IMC subunits VirB3-like TraL, VirB4-like ATPase TraC, and VirB6-like TraG (14). These systems code for a unique set of proteins, TraF, -H, -U, -W and TrbB, -I (Fig. 5) (16, 139, 140). These proteins form an interaction network distinct from the presumptive TraV/K/B OMC (141). The TraF/H/U/W-TrbB/I complex is thought to regulate the dynamics of F pilus extension/retraction, although the underlying mechanism is not yet defined. TraF, -H, -U, and -W localize at the outer membrane (14). TrbI is of special interest as a bitopic inner membrane protein that contributes specifically to the process of pilus retraction through contacts with the outer membrane-associated TraF/H/U/W protein complex (Fig. 5) (142). F pilus extension and retraction has been visualized by use of fluorescently labeled phage R17, which binds along the sides of F pili. Intriguingly, F pili were shown to stochastically extend and retract regardless of the presence of recipient cells in the vicinity (15). Pilus polymerization and retraction requires ~5 min for completion, and new pili are elaborated prior to retraction of older pili, suggesting that initiation and retraction events are randomly timed and not coordinated. These studies also presented evidence supporting earlier work showing that F pili rotate along their longitudinal axis during retraction, causing a bound recipient cell to spin as it is drawn closer to the donor cell (15). Such a rotary motion of flexible pili during extension and retraction is thought to allow pili to “sweep” a large volume around the donor cell in order to enhance the probability of a productive encounter with a recipient cell, which would be of particular benefit for cells growing in liquid environments (16). MATING PAIR FORMATION AND THE MATING JUNCTION In E. coli, conjugative pili first form loose contacts with potential recipients. At this stage, mating by F- and P-type plasmids can be disrupted by physical means or treatment with 0.01% SDS. Donor-recipient cell contacts soon stabilize and become difficult to break apart (143, 144, 145, 146). F-type systems encode two proteins, TraN and TraG, that specify this function (Fig. 5). These proteins, termed mating pair stabilization proteins, are unique to the F-type systems and promote formation of tight mating junctions (145). TraN family proteins are large (~600 to 1200 residues) cysteine-rich proteins thought to function as adhesins for formation of stable donor-recipient cell-mating pairs. TraN also was shown to coordinate its functions through interactions with the TraV subunit of the putative TraV/ K/B OMC (145). TraN binds both OmpA and LPS on recipient cells, which likely explains the basis for F-specific mating-pair stabilization. This was evidenced by the identification of mutations in recipients that disrupt formation of tight mating junctions in genes encoding OmpA and constituents of the lipopolysaccharide (LPS) biosynthesis pathway (145, 147). The second mating-pair stabilization protein, TraG, was discussed above as a VirB6-like protein with an α-helical C terminus that can extend or be delivered into recipient cells where it binds the inner membrane protein TraS to block DNA transfer in nonproductive donor-donor pairs (96). In matings with F-minus recipients, however, the C-terminal domain of TraG is thought to alternatively form contacts with another, unidentified inner membrane protein to stabilize the mating junction (96). TraG also has been implicated as a binding partner of TraN (148) and, through this interaction, promote formation of mating pairs (Fig. 5). The architecture of conjugative mating junctions is presently not defined in E. coli or any other species. E. coli donor cells carrying plasmid RP4 form mating junctions at poles and along the lengths of cells, as shown by electron microscopy. Junctions at cell poles were estimated to be ~150 to 200 nm in length, whereas those along the cell body extended up to 1,500 nm in length or up to half the lengths of the cells (143). Intriguingly, no structures resembling the R388 T4SS3–10 or the OMC or IMC subassemblies, or any other structures, have been detected at the mating junction (149). This suggests the intriguing possibility that intact channels form only transiently upon channel activation by substrate-docking signals and establishment of donor-recipient cell contacts. Discerning the assembly mechanism and architecture of the mating junction is further complicated by evidence that E. coli conjugation systems are exceedingly promiscuous in their capacity to deliver cargos to a wide range of Gram-negative and -positive bacteria. In fact, this promiscuity extends to eukaryotic cells, as both F-and P-type systems have been shown to deliver substrates to yeast and even human cells (150, 151, 152, 153). CONCLUSIONS AND FUTURE DIRECTIONS In recent years, mechanistic and structural features of E. coli conjugation systems have been described in unprecedented detail. Most noteworthy, the recent ultrastructural studies have generated an architectural blueprint of a nearly entire T4SS that, when combined with results of the earlier TrIP studies, enhances our understanding of the substrate transfer route. Despite this exciting progress, long-term studies of E. coli conjugation systems have described many features of the F-, P-, and I-type systems whose underlying mechanisms remain poorly understood. Answers to the following “big picture” questions surrounding type IV secretion will require sustained efforts and implementation of creative state-of-the-art technologies and approaches. What is the architecture of the translocation channel and the pathway(s) by which substrates are delivered through the channel? In this review, three possible routes across the inner membrane were described involving the T4CP, VirB ATPases, and integral membrane components of the IMC. Refined studies are needed to discriminate between these possibilities and to define specific contributions of the ATPases and ATP energy consumption to the early-stage translocation reactions. We also now have an OMC structure in atomic detail and, based on this structure and results of the TrIP studies, it is proposed that the translocation channel responsible for conveying substrates to the cell surface is located within the OMC. Visualization of this channel and the nature of its interaction with the IMC channel is critical for answering the larger question of whether T4SSs employ one- or two-step translocation pathways. Donor and recipient cells are known to form tight mating junctions, but the architecture of this junction remains poorly defined. Indeed, the mechanisms by which T4SSs establish productive target cell contacts and then presumably dissociate after mating are perhaps the greatest mysteries surrounding type IV secretion. What are the physical and functional relationships of the conjugative pilus, the translocation channel, and the mating junction? With recent advances in superresolution and cryoelectron microscopy, it should be feasible using the highly efficient F- and P-type systems in E. coli to visualize mating junction formation in real time and the junction itself at near atomic resolution. Equally important is the goal of visualizing the T4SS within the mating junction and specific T4SS machine contacts with the recipient cell envelope. Of broader biological interest, since E. coli also can deliver DNA substrates to yeast and human cells, we should be able to use this model bacterium to define the architecture of junctions formed during interkingdom mating. Intracellular and extracellular signals are known to activate T4SSs, but what are the molecular and structural details of signal activation? Also of interest, conjugative DNA transfer must be coordinated with DNA replication and cell division to avoid replication of a mobile element from occurring at the same time as transfer. A stabilization system (Stb) has been identified as one mechanism functioning to reconcile the maintenance mode with the propagation mode a mobile element (154). What other types of molecular signals and pathways coordinate these potentially conflicting processes? Finally, while there is clear evidence for the structural diversification of P-, F-, and I-type systems during evolution, what novel functions do these structural acquisitions specify? An especially interesting avenue of research for the coming years is to decipher how T4SS machine adaptations and host-derived or other environmental signals confer spatiotemporal control over substrate translocation. The E. coli conjugation systems remain the best subjects for refined structurefunction studies of T4SSs. Yet, a full understanding of T4SS diversity also will require detailed investigations of effector translocators with particular attention to specialized features acquired during the evolution of these machines. I thank members of the Christie laboratory for helpful discussions. This work was supported by NIH R01GM48476 and R21AI105454. Figure 1 Conservation of type IV secretion genes among P-, F-, and I-type T4SSs (P type) The A. tumefaciens VirB/VirD4 reference system with subunit enzymatic functions and associations with inner membrane complex (IMC), outer membrane complex (OMC), or pilus. PG Hydrolase, peptidoglycan hydrolase; T4CP, type IV coupling protein. (F type) Genes related to the virB/virD4 genes are color coded. Genes encoding functions required for F pilus/retraction are shaded in dark gray, and for mating pair stabilization (Mps) or surface exclusion in light gray (VirB6-like TraG also functions in mating pair stabilization). Uppercase letters are tra genes, lowercase letters are trb genes. (I type) virB/virD4-like genes are color coded. Genes unique to the I-type systems encoding inner membrane proteins are in beige; genes encoding subunits that functionally interact with the DotL T4CP are in light-shaded purple. P- and I-type systems employ three ATPases related to VirD4, VirB4, and VirB11; F-type systems employ only homologs of VirD4 and VirB4. Unless otherwise indicated, the systems shown are functional in E. coli. Figure 2 Architecture of a prototypical P-type T4SS The E. coli R388 T4SS3–10 structure (26), presented schematically using the A. tumefaciens VirB/VirD4 reference nomenclature and as visualized by transmission electron microscopy. (A) The T4SS is composed of an extracellular pilus, an outer membrane complex (OMC), and inner membrane complex (IMC), the VirD4-like T4CP (substrate receptor) and, for most systems, a VirB11 ATPase. Substructures of the T4SS: The conjugative pilus was not part of the solved T4SS3–10 structure, but is postulated to associate with the structure as depicted. In the A. tumefaciens VirB/VirD4 T4SS, the pilus is composed of a fragment of the VirB1 transglycosylase (VirB1*), VirB2 pilin, and VirB5 tip protein (126, 138). The OMC is composed of the VirB7, VirB9, and VirB10 subunits in copy numbers listed in parentheses (26). The VirB1 transglycosylase is required for pilus assembly but not for elaboration of the translocation channel. The IMC is composed of the VirB5, VirB8, VirB6, VirB3, and VirB4 subunits with copy numbers listed in parentheses (26). Other ATPases, including VirD4 and VirB11, were not part of the solved T4SS3–10 structure, but are postulated to associate with the IMC as depicted. Color-coding of the subunits matches that for the corresponding virB/virD4 genes in Fig. 1. (B) The A. tumefaciens subunits shown to form formaldehyde cross-links with the T-DNA substrate during transfer through the VirB/VirD4 T4SS with the TrIP assay. Red arrows denote the proposed translocation pathway (23). (C) The R3883–10 structure solved by transmission electron microscopy, reproduced with permission by reference 26. The OMC is postulated to house the translocation channel that extends through the periplasm and across the outer membrane. The OMC is connected to the IMC by a narrow stalk. Two hexamers of VirB4 extend into the cytoplasm and are postulated to establish contacts with the VirD4 T4CP and the VirB11 ATPase. (A and C) For both the schematic and solved T4SS3–10 structure, three possible routes of substrate translocation across the inner membrane are depicted in red dashed lines. A single route is postulated, in a red dashed line, through the OMC for substrate passage to the cell exterior (see text for details). IM, inner membrane; P, periplasm; OM, outer membrane. Figure 3 Domain architecture of type IV coupling proteins (T4CPs) (A) The structural prototype of the T4CPs, R388-encoded TrwB, is a hexamer with a stem composed of the N-terminal transmembrane domains (NTDs) of the 6 protomers and a ball composed of the nucleotide binding domains (NBDs) and all-alpha-domains (AADs). (Left) A space-filling model of the TrwB hexamer showing the Connolly surface (red, negatively charged; blue, positively charged) and central channel connecting the cytoplasm to the periplasm. IM, inner membrane. (Right) A ribbon diagram of the NBD (multicolored) and AAD (green). In the assembled hexamer, the AAD sits at the entrance of the hexamer lumen. Images reproduced with permission by reference 43. (B) Schematics display the domain architectures of P-types TrwB and A. tumefaciens VirD4 and F-type TraD; numbers represent domain junctions with residue numbers relative to the start codon. The AAD is boxed. Known or predicted properties are listed above each domain. TrwB lacks a C-terminal domain (CTD), but such domains are carried by other VirD4 homologs including F-type TraD. (C) The TraD T4CP in the inner membrane with the various domains listed. The extreme C terminus of the CTD (residues in parentheses) is negatively charged and forms specific contacts with C-terminal α-helical domains (purple cylinders) of the TraM Dtr accessory protein. TraM’s N-terminal ribbon-helix-helix domain (RHH; purple dots) mediates binding to sbmA sites located within the F plasmid oriT sequence. The TraD-TraM interaction specifies F plasmid transfer through the F-encoded T4SS. IM, inner membrane. Figure 4 Adaptations of the IMC: VirB6-like subunits Polytopic VirB6 subunits with lengths of ~300 residues are components of the IMC. Many T4SSs have larger forms of these subunits, designated extended-VirB6. These forms of VirB6 are composed of a polytopic VirB6-like domain and a hydrophilic domain as large as ~1,000 residues. (Left) F-type F plasmids of E. coli encode large VirB6-like TraG subunits. These subunits participate in entry exclusion, which prevents nonproductive plasmid transfer between donor cells. TraG’s C-terminal domain extends or is delivered via the T4SS across the donor-donor cell junction, where it binds the entry exclusion protein TraS located in the inner membrane of the paired donor. This interaction might transduce a signal resulting in a conformational change in the T4SS that blocks nonproductive F plasmid transfer to other F-carrying cells (96). (Middle) Rickettsial P-type T4SSs are composed of 4 or more large VirB6 subunits whose hydrophilic domains are unrelated in sequence and which might be surface-displayed for target cell binding or immune evasion (98, 99, 100). (Right) The I-type Dot/Icm system of L. pneumophila secretes the highly hydrophobic DotA (~1,000 residues) to the milieu where it assembles as large ring-shaped complexes. DotA has a canonical signal sequence, which is thought to mediate DotA delivery through the General Secretory Pathway (GSP) across the inner membrane. In the periplasm, DotA is then recruited to the Dot/Icm T4SS for delivery across the outer membrane to the cell exterior (101). Figure 5 Adaptations of the OMC: VirB7- and VirB10-like subunits The outer membrane complexes (OMCs) of paradigmatic T4SSs are composed of the small (~5-kDa) lipoprotein VirB7, outer membrane-associated VirB9, and envelope-spanning VirB10 (~50-kDa). Many T4SSs have larger forms of the VirB7- and VirB10-like subunits that carry surface-displayed domains of functional importance. (Left) H. pylori P-type T4SSs carry larger forms of VirB7-like CagT and VirB10-like CagY with repeat domains that are exposed on the cell surface. TM, transmembrane domain. (Middle) L. pneumophila I-type T4SSs also carry larger forms of the VirB7- and VirB10-like proteins. VirB7-like DotD has an N0 domain that is thought to form an extra ring of structural importance for the OMC. DotG has an N-terminal transmembrane domain (TM), a C-terminal VirB10 structural fold (20), and internal structural folds similar to that of Salmonella T3SS effector PipB2 and the Salmonella effector SopA (114, 116), as determined by Phyre2 structural modeling (113). It is proposed that these domains of DotG protrude through the OMC or are proteolytically released from the VirB10 scaffold domain for delivery into the eukaryotic cell where they exert effector activities. (Right) E. coli F-type T4SSs carry novel subcomplexes that may or may not be physically associated with the T4SS at the cell surface. The TraW/U/F/B/F/TrbI subunits mediate F pilus extension and retraction, TraN and VirB10-like TraG stabilize mating pairs and the TraT lipoprotein prevents redundant F plasmid transfer among donor cells through surface exclusion (see reference 22). Conflicts of interest: The author declares no conflicts. 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LICENSE: This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. 8804207 1862 Schizophr Res Schizophr. Res. Schizophrenia research 0920-9964 1573-2509 26260078 5119750 10.1016/j.schres.2015.07.026 NIHMS714436 Article Molecular evidence for decreased synaptic efficacy in the postmortem olfactory bulb of individuals with schizophrenia Egbujo Chijioke a Sinclair Duncan a Borgmann-Winter Karin ab Arnold Steven E a Turetsky Bruce a Hahn Chang-Gyu a# a Department of Psychiatry, University of Pennsylvania, Philadelphia, PA b Children's Hospital of Philadelphia, Philadelphia, PA # Corresponding author: Chang-Gyu Hahn, Neuropsychiatric Signaling Program, Center for Neurobiology and Behavior, University of Pennsylvania, 125 S 31st St, Philadelphia, PA, 19104 USA; phone 610 520 9131, fax 215-573-2041 7 10 2016 07 8 2015 10 2015 22 11 2016 168 1-2 554562 This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. Multiple lines of evidence suggest altered synaptic plasticity/connectivity as a pathophysiologic mechanism for various symptom domains of schizophrenia. Olfactory dysfunction, an endophenotype of schizophrenia, reflects altered activity of the olfactory circuitry, which conveys signals from olfactory receptor neurons to the olfactory cortex via synaptic connections in the glomeruli of the olfactory bulb. The olfactory system begins with intranasal olfactory receptor neuron axons synapsing with mitral and tufted cells in the glomeruli of the olfactory bulb, which then convey signals directly to the olfactory cortex. We hypothesized that olfactory dysfunction in schizophrenia is associated with dysregulation of synaptic efficacy in the glomeruli of the olfactory bulb. To test this, we employed semi-quantitative immunohistochemistry to examine the olfactory bulbs of 13 postmortem samples from schizophrenia and their matched control pairs for glomerular expression of 5 pre- and postsynaptic proteins that are involved in the integrity and function of synapses. In the glomeruli of schizophrenia cases compared to their matched controls, we found significant decreases in three presynaptic proteins which play crucial roles in vesicular glutamate transport- synapsin IIa (−18.05%, p= 0.019), synaptophysin (−24.08% p=0.0016) and SNAP-25 (−23.9%, p=0.046). Two postsynaptic proteins important for spine formation and glutamatergic signaling were also decreased- spinophilin (−17.40%, p=0.042) and PSD-95 (−34.06%, p=0.015). These findings provide molecular evidence for decreased efficacy of synapses within the olfactory bulb, which may represent a synaptic mechanism underlying olfactory dysfunction in schizophrenia. schizophrenia synapse olfactory bulb synaptophysin SNAP-25 PSD-95 1. Introduction Multiple lines of evidence implicate synaptic alterations in schizophrenia. A number of genes and pathways critical for synaptic function have been associated with schizophrenia in genetic studies (Fromer et al., 2014; Kirov et al., 2012; Schizophrenia Working Group of the Psychiatric Genomics, 2014). In postmortem studies, altered expression of genes and proteins involved in synaptic structure or function, such as synaptophysin, synapsin II, GAP-43, SNAP-25, Cdc42 and Duo, have been observed in the dorsolateral prefrontal cortex (DLPFC), temporal lobe, hippocampus and amygdala in schizophrenia (Eastwood et al., 1995; Eastwood et al., 2000; Eastwood and Harrison, 1995; Glantz and Lewis, 1997; Hill et al., 2006; Ide and Lewis, 2010; Karson et al., 1999; Sawada et al., 2002; Tan et al., 2014; Tcherepanov and Sokolov, 1997; Thompson et al., 1998; Varea et al., 2012; Webster et al., 2001). Furthermore, brain imaging studies indicate altered structural and functional connectivity in cortico-limbic and meso-limbic circuitry in schizophrenia (Allen et al., 2012; Alonso-Solis et al., 2014; Amad et al., 2014; Genzel et al., 2014; Whitfield-Gabrieli et al., 2009; Woodward et al., 2012), some of which may be modifiable by antipsychotic medications (Sarpal et al., 2014). As ultra-structural correlates of synaptic connectivity, decreased dendritic spine density observed in the layer 3 of DLPFC (Glantz and Lewis, 2000; Rosoklija et al., 2000) and auditory cortex (Sweet et al., 2009) further supports impaired synaptic connectivity in schizophrenia. The neural circuitry underlying olfaction may serve as a useful system for studying synaptic efficacy and connectivity in schizophrenia. The essential circuitry consists of the olfactory epithelium (OE) – olfactory bulb (OB) – pyriform cortex. In the OE, odorants bind to odorant receptors generating action potentials in glutamatergic olfactory receptor neurons (ORNs), which synapse with mitral and tufted cells in the glomeruli of the OB (Gottfried, 2010). Within the glomeruli, OB neurons are modulated by relay cells, and axons of OB neurons then travel to the forebrain via the olfactory nerve. Some of these neurons project to the olfactory tubercle, while most of the fibers terminate at the pyriform cortex, where they form synapses with pyramidal neurons that in turn terminate in other parts of the forebrain and limbic system. Neural transmission between the OE and olfactory cortex therefore relies on the relatively simple OE – OB synaptic connection, which is highly concentrated in the olfactory glomeruli. As such, the connectivity/strength in glomerular synapses can affect sensitivity and cognition of olfactory signals (Gottfried, 2010), which can offer clues to synaptic dysregulations in patients with schizophrenia. Increasing evidence suggests that olfactory dysfunction is an endophenotype of schizophrenia (Turetsky et al., 2008; Turetsky et al., 2003a). Individuals with schizophrenia and those at high risk exhibit deficits in multiple domains of olfactory function including deficits in odor identification (Moberg et al., 1997), odor detection threshold sensitivity (Rupp et al., 2005), odor discrimination (Rupp et al., 2005) and odor memory and odor hedonic judgments (Moberg et al., 2014; Moberg and Turetsky, 2003; Nguyen et al., 2011; Turetsky et al., 2009; Turetsky et al., 2003b). Interestingly, a lesser degree of olfactory dysfunction also may be found among patients’ family members (Moberg et al., 2014) but see (Compton and Chien, 2008; Kamath et al., 2013), suggesting a heritability of this phenotype. Together, olfactory dysfunction may be a heritable trait that co-segregates with the illness and thus meets the criteria for an endophenotype. Structural and functional alterations in the olfactory circuitry have been reported in schizophrenia (Arnold et al., 2001; Kamath et al., 2011; Nguyen et al., 2011; Rioux et al., 2004). Olfactory event related potentials that are measured in response to odorant stimulation were found to be decreased in patients with schizophrenia compared to controls (Turetsky, 2003a) which indicates an overall decrease in odorant induced neural transmission. Such changes could be in part due to structural changes in key regions of the circuit, as evidenced by decreased size of the OB (Turetsky et al., 2003a; Turetsky et al., 2000) and olfactory sulci (Nguyen et al., 2011; Takahashi et al., 2013a; Takahashi et al., 2013b; Takahashi et al., 2014) in schizophrenia patients and individuals at high risk. In addition, histologic examination of the postmortem OE showed increased ratios of immature vs. mature (GAP-43 immunoreactive vs. OMP immunoreactive) neurons (Arnold et al., 2001), suggesting that altered neuronal maturation may impact olfactory neuron function in schizophrenia patients. The olfactory glomerulus is a specialized structure in the OB where the axons of the olfactory receptor neurons and dendrites of the olfactory nerves synapse. As such, it permits an opportunity to examine synaptic efficacy with relative ease compared to other regions of the brain. We hypothesized that there would be a decrease in key synaptic proteins in the OB of subjects with schizophrenia, which could mirror similar alterations in other areas of the brain. The results of our study indicate that key presynaptic and postsynaptic proteins are strikingly decreased in the OB of schizophrenia cases compared to their matched controls. 2. Method 2.1 Postmortem samples Olfactory bulbs were removed at autopsy from 13 prospectively assessed elderly subjects with schizophrenia and 13 non-psychiatric control subjects carefully matched for age, postmortem interval (PMI), gender and fixative. No significant differences in age at death or PMI were found between schizophrenia and control groups. Subjects with schizophrenia had been diagnosed prospectively according to DSM-III-R/DSM-IV criteria based on medical history, interview with caregivers and clinical examination of the patient. Subjects with schizophrenia had been elderly participants in a prospective clinicopathological studies program with post mortem tissues stored with the University of Pennsylvania brain bank. Written informed consent for antemortem evaluation and autopsy in the event of death were obtained from next of kin according to approved institutional review board protocols. The antipsychotic exposures of individuals with schizophrenia were converted to chlorpromazine equivalent doses using established methods (Davis, 1974; Woods, 2003). Brain tissues from non-neuropsychiatric elderly controls were obtained through the University of Pennsylvania's Center for Neurodegenerative Disease Research. While none of these control subjects had undergone antemortem assessments, a review of their clinical histories found no evidence of any neurological or psychiatric illness. 2.2 Immunohistochemistry Olfactory bulbs were fixed in formalin (3.7% formaldehyde in 100 mM Tris) or 70% ethanol for 24 h, paraffin embedded, and cut into 10 um thick sections, and then mounted on poly-l-lysine coated slides. Immunohistochemistry experiments were conducted according to previously described procedures (Talbot et al., 2012), to assess the expression of the synaptic proteins. Briefly, sections were deparaffinized, rehydrated and then incubated for 20 min in 3% H2O2 in methanol at room temperature to remove endogenous peroxidase activity. Antigen retrieval was performed, involving boiling for 10 min in 1 mM EDTA, 0.1 M Tris, pH 8.0. After two washes in TTB (0.1M Tris Buffer with 0.01% Triton X-100 pH 7.6) sections were incubated in TTB containing 10% normal horse serum (NS) for 60 min at room temperature. The sections were then incubated overnight at 4°C in primary antibodies diluted in TTB containing 10% NS. Primary antibodies used were a mouse monoclonal anti synapsin-IIa antibody (1:2000, cat #610667, BD Biosciences, San Jose, CA, USA), a rabbit polyclonal anti–synaptophysin antibody (1:2000, cat # 180130, Invitrogen, Waltham, MA, USA), a mouse monoclonal anti-SNAP-25 antibody (1:400, H-1 [sc-376713], Santa Cruz, Santa Cruz, CA, USA), a rabbit polyclonal anti-spinophilin antibody (1:1200, ABA5669, Millipore, Billerica, MA, USA), a mouse monoclonal anti-PSD-95 antibody (1:200, clone K28/43, UC Davis/NIH NeuroMab Facility, Davis, CA, USA), a mouse monoclonal anti- GFAP antibody (1:100,000, MAB360 Millipore, Billerica, MA, USA) and a mouse monoclonal anti-β-actin antibody (1:1000, cat # A2228 Sigma-Aldrich, St. Louis, MO, USA). Slides were then rinsed three times with TTB and incubated in secondary antibody (1:500, Vector Labs, Burlingame, CA, USA) in 10% NS for 1h. After being rinsed two times with TTB, they were incubated for 1 h in Vectastain ABC reagent (1:500, Vector Labs) in TBS at room temperature. The slides were rinsed, and then incubated with the chromogen diaminobenzidine (DAB in 0.1 M Tris) and 0.03% H2O2 for 10 min. Sections were then rinsed, dehydrated and coverslipped with Cytoseal (Thermo-Fisher Scientific, Waltham, MA, USA). For PSD-95 quantification, only formaldehyde fixed samples (pairs 1-11) could be used. One section per subject was used in each run. For each protein including actin and GFAP, all cases were processed in a single, precisely timed run. Sections incubated without primary antibody or with an IgG of the same species than the primary antibody were run in parallel and served as negative controls. The concentration of the primary antibodies was based on manufacturers’ recommendations and our titration studies. 2.3 Quantification and analysis To determine the optical density (OD) of the DAB/AB reaction product in the glomeruli of the olfactory bulbs, we used customized Image pro 7.2 software (Media Cybernetics, Rockville, MD, USA) run on a desktop computer attached to a Leitz DMRB microscope (Leica, Wetzlar, Germany) and an Evolution OE camera (Media Cybernetics, Rockville, MD, USA). All the images were captured at the same scope, with the same illumination and settings for each antibody. For each subject a randomly selected slide section of the olfactory bulb was used, the entire section of the bulb was captured and all glomeruli contained in it were delineated. For fifteen subjects (6 cases, 9 controls), both left and right olfactory bulbs were sectioned and analyzed, while for eleven subjects (7 cases, 4 controls) a single bulb was sectioned and analyzed. Glomeruli were readily identified as areas of increased density of pre- and post-synaptic protein immunostaining within the glomerular layer of the bulb. The gray value for each glomerulus within each section was recorded and converted to an OD value, from which was subtracted the background OD (obtained from non-stained portion of the bulb), yielding the mean OD of each protein across all glomeruli in the section (Balu et al., 2012; Rioux et al., 2005; Talbot et al., 2004). All background-corrected mean glomerular OD data were approximately normally distributed (skewness between −1 and 1). Diagnostic groups were compared using paired two-tailed T-tests, and the relationship between continuous variables and glomerular OD was determined by Pearson's correlations. 3. Results 3.1 Presynaptic protein expression in OB glomeruli In schizophrenia cases and controls, we investigated the expression levels of three important markers of presynaptic function. Synapsin-IIa is a synaptic vesicle phosphoprotein that is abundantly expressed within the glomeruli, but found much less elsewhere in the olfactory bulb (Figure 1A). There was a significant decrease in the mean expression levels of synapsin-IIa within glomeruli in schizophrenia cases compared to matched control subjects. (−18.1%, p= 0.019; Figure 1B). Synaptophysin is a presynaptic protein localized to synaptic vesicle membranes (Wiedenmann and Franke, 1985). Synaptophysin was strongly expressed in the glomeruli of the bulbs, but much less expressed in the peri-glomerular area (Figure 1C). There was a significant decrease in the glomerular levels of synaptophysin in schizophrenia cases compared to normal controls (−24.1% p=0.0016; Figure 1D). SNAP-25 (Soluble NSF Attachment Protein) is a SNARE protein which plays a major role in the fusion of synaptic vesicles with the presynaptic membrane for neurotransmitter release (Washbourne et al., 2002). We observed that SNAP-25 is highly expressed in the olfactory bulb glomeruli (Figure 1E). There was a significant decrease in mean glomerular SNAP-25 expression levels in schizophrenia cases compared to matched controls. (−23.9%, p=0.046; Figure 1F). 3.2 Postsynaptic protein expression in OB glomeruli The glomerular expression of two postsynaptic proteins was also quantified. Firstly, spinophilin is a postsynaptic marker which is highly expressed in dendritic spines (Muly et al., 2004). Spinophilin immunostaining was evident in various regions of the bulb but more so in the glomeruli (Figure 2A). There was a significant decrease in spinophilin expression within the glomeruli in schizophrenia cases compared to matched controls. (−17.4%, p=0.042; Figure 2B). PSD-95 is a core scaffolding protein located within the postsynaptic density of excitatory synapses (Kim and Sheng, 2004). PSD-95 was highly expressed in the olfactory bulb glomeruli, but sparsely expressed in the peri-glomerular area (Figure 2C). We observed a significant decrease in the expression levels of PSD-95 in the glomeruli of schizophrenia subjects when compared to matched controls (−34.1%, p=0.015; Figure 2D). To determine whether non-specific or possibly artifactual differences between groups may account for group differences in synaptic proteins, β-actin and GFAP were quantified as internal controls. Both GFAP and β-actin was not highly concentrated in glomeruli (Figure 3E), so glomerular and peri-glomerular areas were quantified together. There were no differences between schizophrenia and matched control subjects in glomerular and peri-glomerular GFAP and β-actin expression ([GFAP] p=0.41, β-actin [p=0.64]; Figure 3F for not shown and for). Overall, the glomerular expression of each synaptic protein investigated in this study was significantly decreased in subjects with schizophrenia when compared to controls (Figure 3). We found no significant correlations between expression levels of the synaptic proteins studied with age or PMI within control and schizophrenia groups individually, or both groups combined. Expression levels also were not correlated with age of onset, duration of illness or antipsychotic dosage within the schizophrenia group. 4. Discussion Given multiple reports of abnormal synaptic density and protein expression in various cortical and limbic brain regions in schizophrenia (Glantz and Lewis, 1997, 2000; Hill et al., 2006; Karson et al., 1999; Rosoklija et al., 2000; Sweet et al., 2009; Thompson et al., 1998), we hypothesized that altered synaptic connectivity in schizophrenia would be reflected in dysregulation of key synaptic proteins in the olfactory glomeruli of schizophrenia cases. Consistent with this hypothesis, we observed a significant decrease in the expression levels of pre- and post-synaptic proteins synapsin-IIa, synaptophysin, SNAP-25, spinophilin and PSD-95 in the glomeruli of the olfactory bulb in schizophrenia, but no decrease in GFAP or β-actin. These findings may reflect a decrease in synaptic connectivity within the glomeruli, which could contribute to the olfactory dysfunction observed in schizophrenia. In this study, levels of three presynaptic proteins (synapsin-IIa, synaptophysin and SNAP-25) and two postsynaptic proteins (spinophilin and PSD-95) were decreased in the glomeruli of individuals with schizophrenia. In presynaptic terminals, these three proteins are involved in multiple stages of vesicular neurotransmitter release, including reserve pool regulation [synapsin-IIa; (Gitler et al., 2008)], vesicle fusion [SNAP-25; (Washbourne et al., 2002)] and endocytosis [synaptophysin; (Kwon and Chapman, 2011)]. Postsynaptically, PSD-95 stabilizes the synapse and modulates synaptic long-term potentiation (Nagura et al., 2012) while spinophilin regulates spine morphology and plasticity (Feng et al., 2000; Sarrouilhe et al., 2006). While deficits in a subset of these proteins may have suggested dysregulation of specific genes or pathways, the concurrent decreases of all five proteins are likely to reflect overall changes in synaptic integrity, such as decreased number of synapses or diminished synaptic strength throughout olfactory glomeruli in schizophrenia. The spatial resolution of our methods did not allow us to distinguish between these two possibilities. The origin of such overall changes in the olfactory synapses is unclear at present. It is possible that dysregulations either in the presynaptic or postsynaptic segments are primary, and the other segment is affected via trans-synaptic communication. It is also possible that fundamental neurobiological changes affect each segment separately and together disrupt the synaptic ultrastructure. In this regard, our previous observations of altered neuronal lineage in the postmortem OE may suggest a role of presynaptic alterations. In the OE of schizophrenia cases, we found decreased ratios of OMP immunoreactive (IR) cells with respect to GAP-43 IR cells, each representing mature and immature olfactory sensory neurons (OSNs) respectively (Arnold et al., 2001). Given that presynaptic molecules in the OB arise from OSNs, decreased proportions of mature neurons could account for decreased expression of presynaptic molecules in the OB, which in turn may compromise the integrity of postsynaptic segment. Two previous studies have investigated synaptic protein expression in the OB in schizophrenia. One study reported decreased MAP2 expression in OB glomeruli in schizophrenia (Rioux et al., 2004), suggesting a possible decrease in glomerular dendritic arborization which would be consistent with our findings. However, in a follow-up study, the same group did not identify differences in pre- and post-synaptic glomerular proteins OMP, GAP-43, NCAM, calbindin, NFM/HP, β-tubulin III or TrkB, and although synaptophysin was decreased by about 13% it was not statistically significant (Rioux et al., 2005). Further work is required to determine to what extent pre- and postsynaptic deficits in OB glomeruli are a consistent feature of schizophrenia, and to clarify whether deficits are specific to key cellular processes such as vesicular transport, which was the predominant focus of this study. Our observations of decreased expression of synaptic proteins are consistent with similar findings in various postmortem brain regions in schizophrenia, many of which demonstrated brain region- or cell layer-specificity. Decreased levels of synapsin I and pan synapsin proteins in the hippocampus (Browning et al., 1993; Vawter et al., 2002), and synapsin III in the DLPFC (Porton and Wetsel, 2007), have been reported in schizophrenia. Decreased SNAP-25 protein has also been described in the PFC (BA10) (Karson et al., 1999; Thompson et al., 2003) and hippocampus (Fatemi et al., 2001; Young et al., 1998), while fewer spinophilin-positive puncta have been described in the auditory cortex in schizophrenia (Sweet et al., 2009). Decreased PSD-95 in the anterior cingulate cortex in schizophrenia (Funk et al., 2009), but increased PSD-95 in the dorsomedial thalamus (Clinton et al., 2006), have been described. Finally, decreased synaptophysin has been reported in the PFC (BA9, 10, 46) (Glantz and Lewis, 1997; Karson et al., 1999; Rao et al., 2013), thalamus (Landen et al., 1999), hippocampus (Davidsson et al., 1999; Vawter et al., 1999) and cingulate cortex (Davidsson et al., 1999). These broad array of findings, which reveal decreases in the same proteins quantified in our study, support that altered synaptic connectivity in multiple brain regions may be a hallmark of schizophrenia. Although many of these findings have been replicated, other studies have failed to find differences in other brain regions in implicated in schizophrenia (Barksdale et al., 2014; Gray et al., 2010; Halim et al., 2003; Vawter et al., 2002; Young et al., 1998). One reason for the divergence of these findings may be that, while widespread, synaptic deficits may still be localized to discrete brain regions and cell types within them. The glomerulus of the OB represents a subcellular domain which has a concentration of synaptic inputs and can be extremely accurately demarcated, suggesting that it may be a useful brain region for further exploration of synaptic abnormalities in schizophrenia. Given that all the individuals with schizophrenia had been on varying doses of antipsychotics for several years, it is important to consider the impact of antipsychotics on our findings. Consistent with previous findings with spinophilin in schizophrenia (Sweet et al., 2009), we did not observe a correlation of antipsychotic dosage with levels of pre- or post-synaptic molecules. This analysis, however, has inherent limitations because although coefficients used in converting different antipsychotics to their chlorpromazine equivalents have been empirically derived and are based on expert consensus, they do not the take into account the distinct effects of individual drugs or the effects of polypharmacy. In addition, the doses used for conversion were the dosages that the patients were on at the time of death, and may not accurately reflect cumulative lifetime exposure. This however remains an area for further study to evaluate the long term effects of antipsychotics on the olfactory circuit given that significant neurogenesis takes place in this circuit as OSNs are constantly regenerated in adult life. An additional possible confound in this study is smoking, which is more common among individuals with schizophrenia than normal controls (Dickerson et al., 2013). Smoking may impair olfaction [(Katotomichelakis et al., 2007; Schriever et al., 2013)] and could lead to decreased olfactory bulb volume (Schriever et al., 2013). In previous studies, olfactory bulb volume decreases in schizophrenia cases and first degree relatives were significant when covarying for smoking status and volume (Moberg et al., 2014; Turetsky et al., 2003a; Turetsky et al., 2000), suggesting deficits in schizophrenia independent of any effects of smoking. 5. Conclusion We report decreased levels of pre- and postsynaptic proteins in the OB glomeruli of individuals with schizophrenia which is consistent with the hypothesis that abnormal synaptic efficacy is a feature of the illness. Future studies will need to integrate findings from the OB, OE and olfactory cortex to shed further light on the origins of synaptic and circuit abnormalities that underlie schizophrenia. Acknowledgements We thank Konrad Talbot for providing technical expertise and advice in the design and execution of the project, Hala Kazi for technical assistance, and John Robinson, Theresa Schuck and the PENN Brain Bank for assistance with tissues and demographic data. Role of Funding Source CE is supported by an ITMAT CTSA KL2 Grant, DS by an NHMRC (Australia) CJ Martin Fellowship (APP1072878), and CGH by NIH grants MH890140 and MH10028395. Figure 1 Cytoarchitecture and connections of the olfactory bulb. Figure 2 Expression of presynaptic proteins in the glomeruli of the olfactory bulb from individuals with schizophrenia and controls. A, C, E) Immunostaining in the entire olfactory bulb and in glomeruli (inset) of a representative matched pair (pair 9) for (A) synapsin IIa, (C) synaptophysin and (E) SNAP-25; B, D, F) comparison of protein expression between individuals with schizophrenia and controls within each matched pair for (B) synapsin IIa, (D) synaptophysin and (F) SNAP-25. SCZ- schizophrenia. Inset scale bars indicate 150μm. Figure 3 Expression of postsynaptic proteins and GFAP in olfactory bulb glomeruli from individuals with schizophrenia and controls. A, C, E) Immunostaining in the entire olfactory bulb and in glomeruli (inset) of a representative matched pair (pair 9) for (A) spinophilin, (C) PSD-95 and (E) GFAP; B, D, F) comparison of protein expression between individuals with schizophrenia and controls within each matched pair for (B) spinophilin, (D) PSD-95 and (F) GFAP. SCZ- schizophrenia. Inset scale bars indicate 150μm. Figure 4 Differences in glomerular expression of pre- and post-synaptic proteins in the olfactory bulb between individuals with schizophrenia and controls. For GFAP and β-actin, mean ODs included glomerular and peri-glomerular areas. SCZ- schizophrenia. * p<0.05, ** p<0.005, N.S.- non-significant. Error bars represent standard error of the mean. Table 1 Demographic and clinical information for individuals whose olfactory bulbs were used in this study. Pair # Diagnosis Age (years) Age at diagnosis (years) Sex Race PMI (hr) Tissue age (years) Antipsychotic dose / day Chlopromazine dose equivalance Cause of death 1 Schizophrenia 90 35 Female African American 7.5 10 Risperidone 4mg 400 Hypertensive vasculopathy 2 Schizophrenia 86 24 Female Caucasian 7.5 12 Unknown Unknown Resp failure 2nd to MRSA 3 Schizophrenia 83 19 Female Caucasian 7.5 11 Risperidone 3mg 300 Pneumonia complications 4 Schizophrenia 90 20 Female Caucasian 16 18 Thioridazine dose unknown Unknown Resp failure 5 Schizophrenia 82 42 Female Caucasian 12 12 Clozapine 250mg 250 Resp failure 2nd to anemia, DM2, COPD, CVD 6 Schizophrenia 81 19 Male Caucasian 9 9 Olanzapine 7.5mg 225 Resp failure 2nd to vasculopathy and CVA 7 Schizophrenia 84 Unknown Male Caucasian 20 3 Risperidone 6mg 600 Resp failure 2nd to COPD, cardiomyopathy, anemia 8 Schizophrenia 81 19 Male Caucasian 5 11 Thioridazine 450mg 400 Post fall & head injury 9 Schizophrenia 88 24 Female Caucasian 7 14 Thioridazine 25mg 25 Chronic Renal Failure 10 Schizophrenia 39 16 Female African American 17.5 15 Risperidone 8mg 800 Complications of HTN, cardiomyopathy, CHF, 11 Schizophrenia 72 Unknown Male Caucasian 26 1 Unknown Unknown Unknown 12 Schizophrenia 76 21 Female Caucasian 10 15 Thiothixene 10mg 200 Metastatic cecal CA, anemia 13 Schizophrenia 70 17 Female Caucasian 17.5 12 Unknown Unknown Resp failure 2nd to COPD 1 Control 92 - Female Caucasian 5 11 - Endometrial CA 2 Control 84 - Female Caucasian 3 3 - CAD/HTN, Leukemia, breast CA, DM 3 Control 75 - Female Caucasian 15 3 - Cardiac arrest 2nd to aortic stenosis 4 Control 97 - Female Caucasian 15 3 - CAD, HTN, heart block 5 Control 78 - Female Caucasian 19 2 - Post-op complications following GI bleed. 6 Control 72 - Female Caucasian 13.5 2 - Acute renal failure 2nd to AA dissection 7 Control 82 - Male Caucasian 18 6 - Cardiac arrest 8 Control 80 - Male Caucasian 10.5 7 - Myocardial Infarction 9 Control 82 - Female Caucasian 5 3 - Unknown 10 Control 46 - Female Multiracial 12 2 - Fulminant hepatic & multi organ failure 11 Control 70 - Male Caucasian 36 1 - Complications of DM & HTN 12 Control 72 - Female Caucasian 4 23 - Unknown 13 Control 71 - Female Caucasian 10.5 8 - Abdominal aortic aneurysm PMI- postmortem interval, Resp- respiratory, 2nd- secondary, MRSA- multidrug resistant staphylococcus aureus, PNA- pneumonia, COPD- chronic obstructive pulmonary disease, CVD- cardiovascular disease, HTN- hypertension, CHF- congestive heart failure, CA- cancer, CAD- coronary artery disease, DM- diabetes mellitus, GI- gastrointestinal, AA- aortic arch. Table 2 Summary of demographic information. Schizophrenia Control Age 78.6 (± 13.4) 77.5 (± 12.3) PMI 12.5 (± 6.3) 12.4 (± 9.0) Tissue age 11 (± 4.7) 5.7 (± 6.0) Data represented as group mean (± standard deviation). PMI- postmortem interval. This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final citable form. Please note that during the production process errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain. Contributions CE, KBW, SEA, BT, and CGH designed the study together. CE, DS and KBW together conducted the experiments, analyzed and interpreted the data. CE, DS, SEA, BT and CGH wrote the manuscript. Conflict of Interest The authors declare no conflict of interest. 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LICENSE: This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. 8805635 27439 Immunol Allergy Clin North Am Immunol Allergy Clin North Am Immunology and allergy clinics of North America 0889-8561 1557-8607 27712762 5119761 10.1016/j.iac.2016.06.004 NIHMS795547 Article AERD as an Endotype of Chronic Rhinosinusitis Stevens Whitney W. MD, PhD 1 Schleimer Robert P. PhD 12 1 Division of Allergy-Immunology, Department of Medicine, Northwestern University Feinberg School of Medicine, Chicago, IL USA 2 Department of Otolaryngology, Northwestern University Feinberg School of Medicine, Chicago, IL, USA Corresponding author: Dr. Robert P. Schleimer, Division of Allergy-Immunology, Northwestern University Feinberg School of Medicine, 240 E. Huron St., McGaw Room M-318, Chicago, IL, 60611, USA, Tel.: 312-503-0076, Fax: 312-503-0078, rpschleimer@northwestern.edu 22 6 2016 13 9 2016 11 2016 01 11 2017 36 4 669680 This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. Synopsis Aspirin-Exacerbated Respiratory Disease (AERD) and Chronic Rhinosinusitis with Nasal Polyps (CRSwNP) are both diseases characterized by the presence of chronic sinonasal inflammation and nasal polyps. Both diseases are associated with asthma; AERD by definition and CRSwNP by common comorbidity (~50%). Therefore, the most prominent clinical feature distinguishing patients with AERD from those with CRSwNP remains the development of an upper or lower respiratory tract reaction following the ingestion of a COX-1 inhibitor. However, even in the absence of COX-1 inhibitors, there are other notable clinical and pathophysiological differences between AERD and CRSwNP patients. Patients with AERD on average have worse upper respiratory disease with increased sinonasal symptoms, mucosal inflammation and requirements for revision sinus surgery when compared to patients with CRSwNP. While no single genetic factor has been identified in either CRSwNP or AERD pathogenesis to date, many studies have evaluated whether there are differences in the underlying cellular and molecular mechanisms that account for the observed clinical variations. Studies from several laboratories have discovered important differences in the metabolism of arachidonic acid, including increased activity of the 5-lipoxygenase pathway and decreased levels of the anti-inflammatory prostanoid PGE2. Clear evidence for activation of platelets in AERD also distinguishes it from CRSwNP. Nasal polyp tissues from both AERD and CRSwNP are characterized by type-2 inflammation but there are significantly increased levels of eosinophil and mast cell degranulation products in AERD sinonasal tissue, and recent evidence suggesting that spontaneous activation of eosinophils, basophils and mast cells occurs. Chronic Rhinosinusitis Chronic Rhinosinusitis with Nasal Polyps CRSwNP Aspirin-Exacerbated Respiratory Disease AERD Samter’s Disease Samter’s Triad Introduction Chronic Rhinosinusitis with Nasal Polyps (CRSwNP) and Aspirin-Exacerbated Respiratory Disease (AERD) are both conditions characterized by the presence of chronic sinonasal inflammation and nasal polyps. Numerous groups have labored to describe the clinical features of these diseases as well as investigate the underlying mechanisms that could be driving their overlapping but distinct pathophysiologic mechanisms. However, there are few head-to-head studies directly comparing the sinonasal inflammatory environment of CRSwNP with that of AERD. As a result, the relationship between CRSwNP and AERD remains incompletely defined. Classification To further understand the relationship between CRSwNP and AERD, it is important to review the clinical criteria needed to make the diagnosis of each condition. Per the consensus guidelines, patients with CRSwNP must present with greater than 12 weeks of rhinorrhea, facial pressure or pain, nasal congestion, and/or a reduction in sense of smell 1, 2. Additionally, there must be objective evidence of nasal polyps and mucosal disease visualized upon sinus CT imaging or nasal endoscopy. CRSwNP can exist without medical comorbidities but more often is observed with other chronic conditions such as asthma, hay fever, cystic fibrosis, or eosinophilic granulomatosis with polyangiitis. The clinical diagnosis of AERD is based upon evolving criteria. In 1922, Widal published the first study describing a patent with asthma, nasal polyps, and sensitivity to aspirin. Later, Samter and Beers described a cohort of aspirin-sensitive patients of whom 85% had only respiratory symptoms and 51% had nasal polyps 3. In this report, it was noted “that every patient does not necessarily present with every potential component of the syndrome”. Furthermore, later studies suggested that AERD patients first developed upper respiratory tract symptoms which progressed to involve the lower respiratory tract and then lastly acquired the aspirin intolerance 4. In 2001, the term “aspirin-exacerbated respiratory disease” was termed by Stevenson and colleagues to emphasize that these patients had underlying respiratory disease that was worsened but not induced by aspirin 5. Additionally, over the course of time, it was also discovered that all medications that inhibit the cyclooxygenase-1 (COX-1) enzyme, not just aspirin, could elicit upper and lower respiratory tract symptoms in AERD patients. Given this history, it is not surprising that different terminologies are still used to define the same or related clinical phenotypes (e.g. Samter’s Disease, Samter’s Triad, AERD, NSAID-exacerbated respiratory disease (NERD), aspirin-intolerant asthma). However, even when the same terminology is used, there can be variations in the clinical features of the study cohort. For example, AERD has been investigated in patients with asthma and aspirin intolerance as well as in patients with asthma, aspirin intolerance, and CRSwNP. How the presence (or absence) of sinonasal inflammation might influence the overall disease pathology is not known. As a result, it is not clear whether these two groups are distinct subsets or rather part of a disease continuum. Unless otherwise specified, this review will define AERD as the presence of the triad of CRSwNP, asthma, and worsening of upper and lower respiratory tract symptoms following the ingestion of COX-1 inhibitors. Epidemiology By definition, all patients with AERD have CRSwNP. However, not all patients with CRSwNP have AERD. It is estimated that only ~10% of patients with nasal polyps and ~9% of patients with chronic rhinosinusitis have AERD 6. However, the true prevalence of AERD in the general population or among patients with both chronic rhinosinusitis and nasal polyps (CRSwNP) is still unknown. This is partly due to the lack of epidemiological studies evaluating patients with CRSwNP in large primary care populations. As an additional layer of complexity, both AERD and CRSwNP are associated with asthma. Nearly all AERD patients and ~26–63% of CRSwNP patients have asthma 1, 7, 8. In contrast, only ~7–10% of asthmatics have AERD but as many as 90% of asthmatics may have radiographic evidence of sinonasal inflammation, with or without nasal polyps 1, 6, 9, 10. Interestingly, the prevalence of AERD can increase to ~15% among severe asthmatics 6, 9 and a significant association between severe asthma and enhanced sinonasal inflammation has been reported 11. However, the true prevalence of AERD among patients with both CRSwNP and asthma is not known and, as a result, further investigation is needed. Clinical Features The respiratory reaction following ingestion of a COX-1 inhibitor is the most prominent and definitive clinical feature distinguishing patients with AERD from those with CRSwNP. In AERD patients, this reaction is associated with distinct pathophysiological changes within the sinonasal mucosa. Consequently, most AERD patients typically avoid taking COX-1 inhibitors of their own accord. This results in the presence of a population of patients with CRSwNP and asthma who have aspirin sensitivity that does not appear in their health records. Thus, diagnosis of AERD by examination of medical record charts can overlook a significant number of AERD patients. It has been reported that as many as 15% of asthmatic patients previously unaware of having a COX-1 inhibitor hypersensitivity had a positive reaction to aspirin during an oral challenge 4. Additionally, in separate smaller studies of patients with both CRSwNP and asthma, 20–42% had positive aspirin challenges despite being previously unaware of any COX-1 hypersensitivity 12, 13. In contrast, it has been estimated that as many as 15% of patients with a clinical history consistent with the triad of AERD actually do not react to aspirin upon clinical challenge and instead have only CRSwNP with asthma 4, 13, 14. Taken together, these studies illustrate the limitations in distinguishing CRSwNP and AERD by clinical history alone and highlight the importance of confirming the diagnosis by oral aspirin challenge. There are other less definitive clinical features that can help to distinguish between AERD and CRSwNP. Both CRSwNP and AERD develop in adulthood, with the average age of onset being approximately 42 and 34 years respectively 1, 14. CRSwNP is more common in men while AERD is more common in women 1, 4, 14. Interestingly, a more recent study examining patients who had undergone sinus surgery at a tertiary care hospital suggests that among patients with CRSwNP, women had more severe disease than men as determined by radiographic evidence of enhanced sinus inflammation, need for revision surgery, and use of oral corticosteroids at the time of surgery 15. This is consistent with a large European cohort study that found that women with aspirin-induced asthma have more progressive upper and lower respiratory tract disease than men 4. Clinically, patients with CRSwNP or with AERD both present with symptoms of nasal congestion, rhinorrhea, sinus pressure/pain, and/or hyposmia. Patients with AERD were shown to subjectively report more severe sinus symptoms than patients with CRSwNP 16. Additionally, AERD patients typically have significantly worse endoscopic sinus scores as well as radiographic evidence of sinonasal inflammation compared to CRSwNP patients 16–18. Finally, AERD patients have greater risk of symptom recurrence following surgery and are more likely to undergo revision surgeries sooner and more frequently than those without AERD 19–21. The average number of revision surgeries in AERD patients has been reported to range from 2.6 to 10 4, 14, 21. In contrast, one study reported that patients with CRS on average underwent 1.8 total sinus surgeries but the number of revision surgeries in CRSwNP patients specifically is not well-established 22. In regards to lower respiratory tract disease, CRSwNP and AERD are both associated with asthma that is more severe than that in patients with asthma alone. Conversely, in patients with chronic rhinosinusitis undergoing surgery at a tertiary care facility, asthmatic patients had worse sinus scores than non-asthmatic patients 23. Additionally, as mentioned previously, asthma severity increased with enhanced radiologic evidence of sinus severity 11. In a separate study of 201 AERD patients, 45% had uncontrolled asthma 24. Additionally, Morales and colleagues observed that AERD patients had a 60% increase in risk of severe asthma and 80% increase in emergency room visits compared to patients with aspirin-tolerant asthma 9. AERD patients had lower mean bronchodilator FEV1, more severe asthma by physician assessment, and higher intubation rates than patients without AERD 25. More recently, studies have begun to further define asthma characteristics, as there are variations within the population in regards to clinical features and overall disease severity. For example, the Severe Asthma Research Program performed a cluster analysis of over 700 patients with persistent asthma and identified 5 distinct asthma subsets 26. In particular, one of these cohorts (group 5) was characterized by having the most severe asthma, lowest baseline lung function, and frequent systemic corticosteroid use 26. Additionally, almost half of these patients reported a history of sinus surgery, 26 again suggesting an association between asthma severity and chronic sinus disease. A similar cluster analysis was recently performed in a cohort of AERD patients, albeit only ~81% reported a history of having nasal polyps. In this analysis, 4 distinct subgroups of AERD were defined predominantly based upon levels of asthma severity ranging from mild to severe 27. Interestingly, those patients with significant upper respiratory symptoms (group 1) had the highest levels of peripheral blood eosinophils and urinary leukotrienes among all the subsets examined 27. It is thus clear that patients with NP and AERD have worse asthma than patients with asthma and no NP, and that patients with NP and asthma have worse NP than patients with NP and no asthma. These two diseases each appear to worsen the other. A causal relationship between atopy and either CRSwNP or AERD is still not established and appears unlikely. It has been estimated that 51–86% of patients with CRSwNP 8, 22 and 33–66% with AERD 4, 14 are sensitized to at least one aeroallergen. However, it remains unclear whether allergic sensitization is associated with increased sinus disease severity 8, 22, 23, 28, 29. In summary, AERD, on average, is characterized by more severe upper airway disease than CRSwNP and more significant lower airway disease than asthma. As a result of the severity of their disease, patients with AERD place a disproportionate financial burden on the healthcare system compared to patients with either CRSwNP or asthma alone 30. Given the heterogeneity in past AERD study populations, future investigations are needed to more extensively characterize patients with the clinical triad of AERD and directly compare them to patients with CRSwNP alone as well as with CRSwNP and asthma together. Such studies would also allow for a better understanding of the roles that gender, atopy, asthma, and intolerance to COX-1 inhibitors play in AERD versus CRSwNP. Genetics Since both CRSwNP and AERD develop in adulthood, neither a simple Mendelian pattern of inheritance nor a single genetic defect has been associated with either disease to date 31, 32. In support of this, cohort studies found that only 1% of American and 6% of European AERD patients reported a family member also having AERD 4, 14. Additionally, there have been several studies evaluating whether various specific gene polymorphisms are linked to AERD, although not all AERD patients evaluated in these analyses had CRSwNP (see discussion about definitions above) 32–35. Taken together, present data do not suggest a strong genetic component to CRSwNP or AERD but additional studies are clearly needed to definitively evaluate the role of genetic inheritance in CRSwNP and AERD. As another means to search for potential gene expression differences between AERD and CRSwNP, Stankovic and colleagues examined and compared transcriptional gene profiles of nasal polyps extracted from patients with CRSwNP, AERD, and healthy controls through a microarray analysis 36. While specific gene signatures could distinguish AERD as well as CRSwNP nasal polyps from healthy sinonasal tissue, there were no significant differences in gene expression profiles between AERD and CRSwNP nasal polyps themselves. Interestingly, when compared to healthy controls, CRSwNP nasal polyps were specifically characterized by the up-regulation of met proto-oncogene and protein phosphatase 1 regulatory subunit 9B as well as by the down-regulation of prolactin-induced protein (PIP) and zinc alpha2-glycoprotein. In contrast, up-regulation of periostin gene expression was most characteristic of AERD polyps compared to healthy controls 36. The role these genes play in disease pathogenesis is uncertain but work from our laboratory has also confirmed a significant overlap between gene signature profiles of AERD and CRSwNP polyps (Stevens et al., unpublished data). It is also possible that epigenetic changes and/or differential levels of various proteins or non-protein inflammatory mediators could account for the clinical differences between the two conditions 37. Alterations in gene expression could also be occurring in the bone marrow, in primary or secondary lymphoid tissues or in other sites in AERD such that they are not detectable in NP tissue. Alternatively, unspecified external factors might be needed to induce the enhanced AERD phenotype observed in certain genetically susceptible patients with nasal polyps. As such, chronic viral infections, active smoking, and exposure to environmental tobacco smoke during childhood have all been hypothesized to play a role in the development of AERD 38, 39. Disease Pathophysiology Epithelial barrier dysfunction, exposures to pathogenic and non-pathogenic bacteria, and dysregulation of the host innate and adaptive immune responses are all thought to be important in CRSwNP pathophysiology. Unfortunately, less is known about the specific cellular and molecular mechanisms contributing to AERD pathogenesis in particular, especially at baseline when COX-1 inhibitors are not present. For example, the role of epithelial cells and the microbiome in AERD has not been as extensively characterized as it has in CRSwNP 40–42. As a result, it is possible that specific functional and physical defects in sinonasal epithelial cells as well as alterations in the microbiome of the sinonasal cavity could distinguish AERD and CRSwNP clinical phenotypes. Clearly, further investigations are warranted. Host Immune Response There has been an increasing focus on exploring how the host immune response could contribute to the chronic sinonasal inflammation seen in CRSwNP and AERD. One of the hallmarks of CRSwNP and AERD nasal polyps is an enhanced tissue eosinophilia compared to healthy sinonasal tissue 43. Additionally, levels of the eosinophil granule protein, eosinophil cationic protein (ECP), were also significantly elevated in both subsets of nasal polyps compared to controls as well as in AERD nasal polyps compared to CRSwNP 43–45. In contrast, recent studies found no significant difference in the number of eosinophils counted in hematoxylin and eosin stained slides within nasal polyp sections from AERD and CRSwNP nasal polyps 45, 46. Taken together, these observations lead to the hypothesis that eosinophils are more highly activated in AERD compared to CRSwNP, thus releasing their granule contents (causing more ECP to be detected in AERD) but in the process losing their ability to be detected by traditional histologic staining. It should be noted that not all patients with CRSwNP have enhanced tissue eosinophilia. In particular, Asian patients either living in Asia or in the United States were found to have significantly less eosinophils in their nasal polyps when compared to CRSwNP patients of European descent 44, 47. These observations would in turn suggest that Asian patients, given their relative paucity of tissue eosinophils, might be less likely to have AERD. This is supported by one small study from China that found the prevalence of AERD to be 0.57% among patients evaluated with CRSwNP 48, which is must lower than the 9–10% estimated in a meta-analysis of patients predominantly of European descent 6. Second generation Asians with CRSwNP in the US also had less atopy and less comorbidity with asthma than non Asian Americans. One interpretation of these findings is that the new generation of type 2 targeting biologicals may have reduced efficacy in patients of Asian descent. In addition to eosinophils, CRSwNP nasal polyps are also traditionally characterized as having an increased number of innate type-2 lymphoid cells (ILC2), mast cells, basophils, and neutrophils when compared to healthy sinonasal tissue 46, 49–51. Walford and colleagues reported an overall correlation between the number of eosinophils and ILC2s in nasal polyps but they did not specifically compare ILC2 numbers in AERD versus CRSwNP nasal polyps 50. Similar to eosinophils, mast cell numbers did not significantly differ between CRSwNP and AERD nasal polyps 41, 52. However, mast cells are a major source of prostaglandin D2 (PGD2) and this inflammatory mediator has been shown to be significantly elevated in AERD compared to CRSwNP patients, especially after aspirin challenge 52, 53. Finally, basophil numbers were significantly reduced in AERD versus CRSwNP nasal polyps 46. It remains unclear exactly how eosinophils, basophils, mast cells, and ILC2s each contribute to sinonasal inflammation and the clinical symptoms of either CRSwNP or AERD. Furthermore, given the elevated levels of PGD2 and ECP despite a lack of significant elevation in number of mast cells or eosinophils, it is tempting to speculate that these innate immune cells are more activated in AERD than CRSwNP. However, additional studies are needed to further evaluate this hypothesis. Even less is known regarding adaptive immune cells in AERD. T cells are elevated in nasal polyps of CRSwNP patients compared to healthy controls 43, 54. Additionally, B cells and plasma cells are also elevated in CRSwNP nasal polyps and thought to be locally activated within this tissue to produce increased amounts of IgG, IgA, IgM and IgE 43, 55–57. Some of the antibodies found in CRSwNP nasal polyps are against self-proteins (e.g. nuclear antigens and cytokines) but it is unclear if similar levels of autoantibodies exist in AERD patients 58, 59. It has been estimated that as many as 64% of CRSwNP and 87% of AERD patients are colonized with Staphylococcus aureus with a subset of these patients producing IgE against staphylococcal superantigens 60. Some studies report significantly increased levels of IgE to staphylococcal superantigens in AERD nasal polyps compared to CRSwNP 61, 62 while a more recent study found no difference 63. Taken together, additional studies are needed to further define the relationship between IgE to staphylococcal superantigens in AERD and CRSwNP nasal polyps. However, these specific antibodies may still contribute by an unknown mechanism to the chronic sinonasal inflammation observed in both diseases. In addition, Staphylococcus aureus enterotoxins can activate large numbers of T cells, and there is a body of literature suggesting that T cell activation mediated by these toxins plays a role in CRSwNP 64–66. Arachidonic Acid Metabolites AERD is classically characterized by a systemic dysregulation in arachidonic acid metabolism but a full description of this pathway is beyond the scope of this review. There have been some studies that have specifically focused on examination of prostaglandin and leukotriene mediators in the sinonasal tissue of AERD compared to CRSwNP patients. For example, levels of Prostaglandin E2 (PGE2), along with its receptor EP2, are decreased in AERD versus CRSwNP nasal polyps 67–70. Given the anti-inflammatory properties of PGE2, its reduction in AERD could in turn contribute to the enhanced sinonasal inflammation observed. Laidlaw and colleagues recently reported that the number of platelet-adherent leukocytes was significantly increased in AERD compared to CRSwNP nasal polyps 71. Furthermore, these platelets could convert leukocyte-derived Leukotriene (LT) A4 into LTC4 and thus contribute to the elevated levels of cysteinyl leukotrienes that are classically seen in AERD nasal polyps compared to CRSwNP or healthy controls 67, 71. Furthermore, the cysteinyl leukotriene receptor, CysLT1, is also elevated in AERD versus CRSwNP 68, 72, 73. Interestingly, in CRSwNP, cysteinyl leukotrienes (LTC4, LTD4, and LTE4) were also significantly elevated in sinonasal tissue when compared to healthy mucosae 69, 74. How these mediators all contribute to different clinical phenotypes in AERD versus CRSwNP is still not entirely understood. Other Inflammatory Mediators In addition to arachidonic acid metabolites, there have been numerous studies characterizing the baseline inflammatory milieu of nasal polyps from CRSwNP and AERD patients. Given the association with type-2 innate immune cells (e.g. mast cells, eosinophils, and basophils), it is not surprising that there are elevations in levels of traditional type-2 inflammatory mediators in AERD and also in CRSwNP nasal polyps when compared to healthy sinonasal tissue (e.g. IL-5, IL-4, IL-13, Eotaxin-1 Eotaxin-2) 43, 4448, 45, 75, 76. However, when directly comparing AERD nasal polyps with CRSwNP nasal polyps, there have been conflicting results. Some reports suggest that protein levels of IL-5 and the type-1 cytokine, IFNγ, are elevated in AERD compared to CRSwNP polyps 67, 77. More recently, a separate study evaluated the expression of 19 different inflammatory mediators in AERD and CRSwNP polyps. Surprisingly, there were no differences in levels of type-2 cytokines (IL-4, IL-5, IL-13, Eotaxin-1, Eotaxin-2, and MCP-4) or type-1 cytokines (IL-6, IFNγ) between these diseases 45, although levels of GM-CSF and MCP-1 were significantly elevated in AERD nasal polyps 45. It is unclear why there are discrepancies among studies but possible explanations could include differences in the tissues collected, techniques utilized to measure protein levels, the use of corticosteroids or other drugs within the study populations etc. In summary, it appears that both CRSwNP and AERD are characterized by a type-2 inflammatory milieu with increased levels of both type-2 cytokines and eosinophils when compared to healthy sinonasal tissue but not necessarily when compared to each other. There is a marked increase in levels of certain mediators released by activated innate immune cells (e.g. ECP and PGD2) in AERD compared to CRSwNP. While the underlying mechanisms that contribute to the increase in inflammatory cell degranulation products is unknown, it is worth exploring whether the abnormalities in arachidonic acid metabolism or other factors mediate the exaggerated activation of these cells in AERD. Summary CRSwNP and AERD are both important clinical diseases associated with increased socioeconomic burden and decreased quality of life. The most prominent clinical feature distinguishing patients with AERD from those with CRSwNP remains the development of an upper or lower respiratory tract reaction following the ingestion of a COX-1 inhibitor. However, even in the absence of COX-1 inhibitors, there are other clinical and pathophysiological differences observed between AERD and CRSwNP patients. Those with AERD on average have worse upper respiratory disease with increased sinonasal symptoms, mucosal inflammation and requirements for revision sinus surgery when compared to patients with CRSwNP. While no single genetic factor has been identified in either CRSwNP or AERD pathogenesis to date, studies characterizing differences in the underlying cellular and molecular mechanisms that could account for the observed clinical variations are progressing. Both AERD and CRSwNP nasal polyps are now known to be characterized by a type-2 inflammatory environment but there appear to be significantly increased levels of eosinophil and mast cell degranulation occurring in AERD sinonasal tissue. In addition, AERD, unlike CRSwNP, is also characterized by the systemic dysregulation of arachidonic acid metabolism and activation of platelet function. The underlying mechanisms that contribute to these observations are still not fully known and additional studies are needed to further define both CRSwNP and AERD pathogenesis. Funding: This work was supported by Chronic Rhinosinusitis Integrative Studies Program (U19-AI106683) and by the National Institutes of Health grants T32 AI083216, R37 HLO68546, RO1 HL0788860 and R01 AI104733. Key Points Clinically, patients with AERD can be distinguished from those with CRSwNP and asthma by the development of respiratory symptoms following the ingestion of a COX-1 inhibitor. However, clinical history alone may not always be sufficient to confirm the diagnosis of AERD. In the absence of COX-1 inhibitors, AERD patients on average still have worse upper and lower respiratory tract disease than those patients with CRSwNP with or without asthma. Nasal polyps from AERD and CRSwNP patients are both defined by a predominant type-2 inflammatory environment but there appears to be significantly increased levels of eosinophil and mast cell degranulation occurring in AERD. Mechanistically, AERD, unlike CRSwNP, is characterized by platelet activation as well as a dysregulation in arachidonic acid metabolism. Disclosures: Whitney Stevens has no financial conflicts of interest. Robert Schleimer has served as a consultant with several pharmaceutical companies with interest in CRS, including Astra-Zeneca, Genentech, GSK, Intersect ENT, Merck, Regeneron and Sanofi. Dr. Schleimer is a founder, shareholder and advisor for Allakos. This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final citable form. Please note that during the production process errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain. 1 Fokkens WJ Lund VJ Mullol J Bachert C Alobid I Baroody F European Position Paper on Rhinosinusitis and Nasal Polyps 2012 Rhinol Suppl 2012 3 p preceding table of contents 1 298 2 Peters AT Spector S Hsu J Hamilos DL Baroody FM Chandra RK Diagnosis and management of rhinosinusitis: a practice parameter update Ann Allergy Asthma Immunol 2014 113 347 85 25256029 3 Samter M Beers RF Jr Intolerance to aspirin. Clinical studies and consideration of its pathogenesis Ann Intern Med 1968 68 975 83 5646829 4 Szczeklik A Nizankowska E Duplaga M Natural history of aspirin-induced asthma. AIANE Investigators. European Network on Aspirin-Induced Asthma Eur Respir J 2000 16 432 6 11028656 5 Stevenson DD Sanchez-Borges M Szczeklik A Classification of allergic and pseudoallergic reactions to drugs that inhibit cyclooxygenase enzymes Ann Allergy Asthma Immunol 2001 87 177 80 11570612 6 Rajan JP Wineinger NE Stevenson DD White AA Prevalence of aspirin-exacerbated respiratory disease among asthmatic patients: A meta-analysis of the literature J Allergy Clin Immunol 2015 135 676 81 e1 25282015 7 Promsopa C Kansara S Citardi MJ Fakhri S Porter P Luong A Prevalence of confirmed asthma varies in chronic rhinosinusitis subtypes Int Forum Allergy Rhinol 2015 8 Tan BK Zirkle W Chandra RK Lin D Conley DB Peters AT Atopic profile of patients failing medical therapy for chronic rhinosinusitis Int Forum Allergy Rhinol 2011 1 88 94 21731824 9 Morales DR Guthrie B Lipworth BJ Jackson C Donnan PT Santiago VH NSAID-exacerbated respiratory disease: a meta-analysis evaluating prevalence, mean provocative dose of aspirin and increased asthma morbidity Allergy 2015 70 828 35 25855099 10 Joe SA Thakkar K Chronic rhinosinusitis and asthma Otolaryngol Clin North Am 2008 41 297 309 vi 18328369 11 Lin DC Chandra RK Tan BK Zirkle W Conley DB Grammer LC Association between severity of asthma and degree of chronic rhinosinusitis Am J Rhinol Allergy 2011 25 205 8 21819754 12 Delaney JC The diagnosis of aspirin idiosyncrasy by analgesic challenge Clin Allergy 1976 6 177 81 1277441 13 Dursun AB Woessner KA Simon RA Karasoy D Stevenson DD Predicting outcomes of oral aspirin challenges in patients with asthma, nasal polyps, and chronic sinusitis Ann Allergy Asthma Immunol 2008 100 420 5 18517072 14 Berges-Gimeno MP Simon RA Stevenson DD The natural history and clinical characteristics of aspirin-exacerbated respiratory disease Ann Allergy Asthma Immunol 2002 89 474 8 12452205 15 Stevens WW Peters AT Suh L Norton JE Kern RC Conley DB A retrospective, cross-sectional study reveals that women with CRSwNP have more severe disease than men Immun Inflamm Dis 2015 3 14 22 25866636 16 Jang DW Comer BT Lachanas VA Kountakis SE Aspirin sensitivity does not compromise quality-of-life outcomes in patients with Samter’s triad Laryngoscope 2014 124 34 7 23712910 17 Awad OG Lee JH Fasano MB Graham SM Sinonasal outcomes after endoscopic sinus surgery in asthmatic patients with nasal polyps: a difference between aspirin-tolerant and aspirin-induced asthma? Laryngoscope 2008 118 1282 6 18475212 18 Robinson JL Griest S James KE Smith TL Impact of aspirin intolerance on outcomes of sinus surgery Laryngoscope 2007 117 825 30 17473677 19 Young J Frenkiel S Tewfik MA Mouadeb DA Long-term outcome analysis of endoscopic sinus surgery for chronic sinusitis Am J Rhinol 2007 21 743 7 18201458 20 Yip J Yao CM Lee JM State of the art: a systematic review of the surgical management of aspirin exacerbated respiratory disease Am J Rhinol Allergy 2014 28 493 501 25514486 21 Kim JE Kountakis SE The prevalence of Samter’s triad in patients undergoing functional endoscopic sinus surgery Ear Nose Throat J 2007 86 396 9 17702319 22 Batra PS Tong L Citardi MJ Analysis of comorbidities and objective parameters in refractory chronic rhinosinusitis Laryngoscope 2013 123 Suppl 7 S1 11 23 Pearlman AN Chandra RK Chang D Conley DB Tripathi-Peters A Grammer LC Relationships between severity of chronic rhinosinusitis and nasal polyposis, asthma, and atopy Am J Rhinol Allergy 2009 23 145 8 19401038 24 Bochenek G Szafraniec K Kuschill-Dziurda J Nizankowska-Mogilnicka E Factors associated with asthma control in patients with aspirin-exacerbated respiratory disease Respir Med 2015 109 588 95 25820158 25 Lee JH Haselkorn T Borish L Rasouliyan L Chipps BE Wenzel SE Risk factors associated with persistent airflow limitation in severe or difficult-to-treat asthma: insights from the TENOR study Chest 2007 132 1882 9 18079222 26 Moore WC Meyers DA Wenzel SE Teague WG Li H Li X Identification of asthma phenotypes using cluster analysis in the Severe Asthma Research Program Am J Respir Crit Care Med 2010 181 315 23 19892860 27 Bochenek G Kuschill-Dziurda J Szafraniec K Plutecka H Szczeklik A Nizankowska-Mogilnicka E Certain subphenotypes of aspirin-exacerbated respiratory disease distinguished by latent class analysis J Allergy Clin Immunol 2014 133 98 103 e1 6 23993879 28 Robinson S Douglas R Wormald PJ The relationship between atopy and chronic rhinosinusitis Am J Rhinol 2006 20 625 8 17181106 29 Ramadan HH Fornelli R Ortiz AO Rodman S Correlation of allergy and severity of sinus disease Am J Rhinol 1999 13 345 7 10582111 30 Chang JE White A Simon RA Stevenson DD Aspirin-exacerbated respiratory disease: burden of disease Allergy Asthma Proc 2012 33 117 21 22525387 31 Hsu J Avila PC Kern RC Hayes MG Schleimer RP Pinto JM Genetics of chronic rhinosinusitis: state of the field and directions forward J Allergy Clin Immunol 2013 131 977 93 93 e1 5 23540616 32 Park SM Park JS Park HS Park CS Unraveling the genetic basis of aspirin hypersensitivity in asthma beyond arachidonate pathways Allergy Asthma Immunol Res 2013 5 258 76 24003382 33 Kurosawa M Yukawa T Hozawa S Mochizuki H Recent advance in investigation of gene polymorphisms in Japanese patients with aspirin-exacerbated respiratory disease Allergol Immunopathol (Madr) 2015 43 92 100 25224359 34 Kim SH Choi H Yoon MG Ye YM Park HS Dipeptidyl-peptidase 10 as a genetic biomarker for the aspirin-exacerbated respiratory disease phenotype Ann Allergy Asthma Immunol 2015 114 208 13 25592153 35 Chang HS Park JS Shin HR Park BL Shin HD Park CS Association analysis of FABP1 gene polymorphisms with aspirin-exacerbated respiratory disease in asthma Exp Lung Res 2014 40 485 94 25338211 36 Stankovic KM Goldsztein H Reh DD Platt MP Metson R Gene expression profiling of nasal polyps associated with chronic sinusitis and aspirin-sensitive asthma Laryngoscope 2008 118 881 9 18391768 37 Cheong HS Park SM Kim MO Park JS Lee JY Byun JY Genome-wide methylation profile of nasal polyps: relation to aspirin hypersensitivity in asthmatics Allergy 2011 66 637 44 21121930 38 Szczeklik A Aspirin-induced asthma as a viral disease Clin Allergy 1988 18 15 20 3127083 39 Chang JE Ding D Martin-Lazaro J White A Stevenson DD Smoking, environmental tobacco smoke, and aspirin-exacerbated respiratory disease Ann Allergy Asthma Immunol 2012 108 14 9 22192959 40 Mahdavinia M Keshavarzian A Tobin MC Landay AL Schleimer RP A comprehensive review of the nasal microbiome in chronic rhinosinusitis (CRS) Clin Exp Allergy 2016 46 21 41 26510171 41 Stevens WW Lee RJ Schleimer RP Cohen NA Chronic rhinosinusitis pathogenesis J Allergy Clin Immunol 2015 136 1442 53 26654193 42 Lou H Meng Y Piao Y Zhang N Bachert C Wang C Cellular phenotyping of chronic rhinosinusitis with nasal polyps Rhinology 2016 43 Van Zele T Claeys S Gevaert P Van Maele G Holtappels G Van Cauwenberge P Differentiation of chronic sinus diseases by measurement of inflammatory mediators Allergy 2006 61 1280 9 17002703 44 Zhang N Van Zele T Perez-Novo C Van Bruaene N Holtappels G DeRuyck N Different types of T-effector cells orchestrate mucosal inflammation in chronic sinus disease J Allergy Clin Immunol 2008 122 961 8 18804271 45 Stevens WW Ocampo CJ Berdnikovs S Sakashita M Mahdavinia M Suh L Cytokines in Chronic Rhinosinusitis: Role in Eosinophilia and Aspirin Exacerbated Respiratory Disease Am J Respir Crit Care Med 2015 46 Mahdavinia M Carter RG Ocampo CJ Stevens W Kato A Tan BK Basophils are elevated in nasal polyps of patients with chronic rhinosinusitis without aspirin sensitivity J Allergy Clin Immunol 2014 133 1759 63 24636088 47 Mahdavinia M Suh LA Carter RG Stevens WW Norton JE Kato A Increased noneosinophilic nasal polyps in chronic rhinosinusitis in US second-generation Asians suggest genetic regulation of eosinophilia J Allergy Clin Immunol 2015 135 576 9 25312761 48 Fan Y Feng S Xia W Qu L Li X Chen S Aspirin-exacerbated respiratory disease in China: a cohort investigation and literature review Am J Rhinol Allergy 2012 26 e20 2 22391072 49 Ho J Bailey M Zaunders J Mrad N Sacks R Sewell W Group 2 innate lymphoid cells (ILC2s) are increased in chronic rhinosinusitis with nasal polyps or eosinophilia Clin Exp Allergy 2015 45 394 403 25429730 50 Walford HH Lund SJ Baum RE White AA Bergeron CM Husseman J Increased ILC2s in the eosinophilic nasal polyp endotype are associated with corticosteroid responsiveness Clin Immunol 2014 155 126 35 25236785 51 Takabayashi T Kato A Peters AT Suh LA Carter R Norton J Glandular mast cells with distinct phenotype are highly elevated in chronic rhinosinusitis with nasal polyps J Allergy Clin Immunol 2012 130 410 20 e5 22534535 52 Buchheit KM Cahill KN Katz HR Murphy KC Feng C Lee-Sarwar K Thymic stromal lymphopoietin controls prostaglandin D generation in patients with aspirin-exacerbated respiratory disease J Allergy Clin Immunol 2015 53 Cahill KN Bensko JC Boyce JA Laidlaw TM Prostaglandin D(2): a dominant mediator of aspirin-exacerbated respiratory disease J Allergy Clin Immunol 2015 135 245 52 25218285 54 Derycke L Eyerich S Van Crombruggen K Perez-Novo C Holtappels G Deruyck N Mixed T helper cell signatures in chronic rhinosinusitis with and without polyps PLoS One 2014 9 e97581 24911279 55 Van Zele T Gevaert P Holtappels G van Cauwenberge P Bachert C Local immunoglobulin production in nasal polyposis is modulated by superantigens Clin Exp Allergy 2007 37 1840 7 17941912 56 Hulse KE Norton JE Suh L Zhong Q Mahdavinia M Simon P Chronic rhinosinusitis with nasal polyps is characterized by B-cell inflammation and EBV-induced protein 2 expression J Allergy Clin Immunol 2013 131 1075 83 83 e1 7 23473835 57 Kato A Peters A Suh L Carter R Harris KE Chandra R Evidence of a role for B cell-activating factor of the TNF family in the pathogenesis of chronic rhinosinusitis with nasal polyps J Allergy Clin Immunol 2008 121 1385 92 92 e1 2 18410958 58 Tan BK Li QZ Suh L Kato A Conley DB Chandra RK Evidence for intranasal antinuclear autoantibodies in patients with chronic rhinosinusitis with nasal polyps J Allergy Clin Immunol 2011 128 1198 206 e1 21996343 59 Tsybikov NN Egorova EV Kuznik BI Fefelova EV Magen E Anticytokine autoantibodies in chronic rhinosinusitis Allergy Asthma Proc 2015 36 473 80 26534753 60 Van Zele T Gevaert P Watelet JB Claeys G Holtappels G Claeys C Staphylococcus aureus colonization and IgE antibody formation to enterotoxins is increased in nasal polyposis J Allergy Clin Immunol 2004 114 981 3 15480349 61 Perez-Novo CA Kowalski ML Kuna P Ptasinska A Holtappels G van Cauwenberge P Aspirin sensitivity and IgE antibodies to Staphylococcus aureus enterotoxins in nasal polyposis: studies on the relationship Int Arch Allergy Immunol 2004 133 255 60 14976394 62 Suh YJ Yoon SH Sampson AP Kim HJ Kim SH Nahm DH Specific immunoglobulin E for staphylococcal enterotoxins in nasal polyps from patients with aspirin-intolerant asthma Clin Exp Allergy 2004 34 1270 5 15298569 63 Yoo HS Shin YS Liu JN Kim MA Park HS Clinical significance of immunoglobulin E responses to staphylococcal superantigens in patients with aspirin-exacerbated respiratory disease Int Arch Allergy Immunol 2013 162 340 5 24193355 64 Conley DB Tripathi A Seiberling KA Schleimer RP Suh LA Harris K Superantigens and chronic rhinosinusitis: skewing of T-cell receptor V beta-distributions in polyp-derived CD4+ and CD8+ T cells Am J Rhinol 2006 20 534 9 17063750 65 Huvenne W Hellings PW Bachert C Role of staphylococcal superantigens in airway disease Int Arch Allergy Immunol 2013 161 304 14 23689556 66 Bachert C Zhang N Patou J van Zele T Gevaert P Role of staphylococcal superantigens in upper airway disease Curr Opin Allergy Clin Immunol 2008 8 34 8 18188015 67 Perez-Novo CA Watelet JB Claeys C Van Cauwenberge P Bachert C Prostaglandin, leukotriene, and lipoxin balance in chronic rhinosinusitis with and without nasal polyposis J Allergy Clin Immunol 2005 115 1189 96 15940133 68 Adamusiak AM Stasikowska-Kanicka O Lewandowska-Polak A Danilewicz M Wagrowska-Danilewicz M Jankowski A Expression of arachidonate metabolism enzymes and receptors in nasal polyps of aspirin-hypersensitive asthmatics Int Arch Allergy Immunol 2012 157 354 62 22123288 69 Yoshimura T Yoshikawa M Otori N Haruna S Moriyama H Correlation between the prostaglandin D(2)/E(2) ratio in nasal polyps and the recalcitrant pathophysiology of chronic rhinosinusitis associated with bronchial asthma Allergol Int 2008 57 429 36 18797183 70 Machado-Carvalho L Torres R Perez-Gonzalez M Alobid I Mullol J Pujols L Altered expression and signalling of EP2 receptor in nasal polyps of AERD patients: role in inflammation and remodelling Rhinology 2016 71 Laidlaw TM Kidder MS Bhattacharyya N Xing W Shen S Milne GL Cysteinyl leukotriene overproduction in aspirin-exacerbated respiratory disease is driven by platelet-adherent leukocytes Blood 2012 119 3790 8 22262771 72 Sousa AR Parikh A Scadding G Corrigan CJ Lee TH Leukotriene-receptor expression on nasal mucosal inflammatory cells in aspirin-sensitive rhinosinusitis N Engl J Med 2002 347 1493 9 12421891 73 Corrigan C Mallett K Ying S Roberts D Parikh A Scadding G Expression of the cysteinyl leukotriene receptors cysLT(1) and cysLT(2) in aspirin-sensitive and aspirin-tolerant chronic rhinosinusitis J Allergy Clin Immunol 2005 115 316 22 15696087 74 Perez-Novo CA Claeys C Van Cauwenberge P Bachert C Expression of eicosanoid receptors subtypes and eosinophilic inflammation: implication on chronic rhinosinusitis Respir Res 2006 7 75 16689996 75 Van Bruaene N Perez-Novo CA Basinski TM Van Zele T Holtappels G De Ruyck N T-cell regulation in chronic paranasal sinus disease J Allergy Clin Immunol 2008 121 1435 41 41 e1 3 18423831 76 Steinke JW Payne SC Borish L Interleukin-4 in the Generation of the AERD Phenotype: Implications for Molecular Mechanisms Driving Therapeutic Benefit of Aspirin Desensitization J Allergy (Cairo) 2012 2012 182090 22262978 77 Steinke JW Liu L Huyett P Negri J Payne SC Borish L Prominent role of IFN-gamma in patients with aspirin-exacerbated respiratory disease J Allergy Clin Immunol 2013 132 856 65 e1 3 23806637
PMC005xxxxxx/PMC5119898.txt
LICENSE: This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. 8704771 1572 Alzheimer Dis Assoc Disord Alzheimer Dis Assoc Disord Alzheimer disease and associated disorders 0893-0341 1546-4156 27819841 5119898 10.1097/WAD.0000000000000162 NIHMS798771 Article Recruiting U.S. Chinese Elders into Clinical Research for Dementia Li Clara Ph.D. 1 Neugroschl Judith M.D. 1 Umpierre Mari Ph.D., LCSW. 1 Martin Jane Ph.D. 1 Huang QiYing MSW. 1 Zeng Xiaoyi B.A. 1 Cai Dongming M.D., Ph.D. 1 Sano Mary Ph.D. 12 1 Icahn School of Medicine at Mount Sinai, New York, NY 2 James J. Peters VA Medical Center, Bronx, NY Corresponding Author: Clara Li, Ph.D., Department of Psychiatry Alzheimer’s Disease Research Center, Icahn School of Medicine at Mount Sinai, One Gustave L. Levy Place, Box 1230, New York, NY 10029-6574, Tel: 212.241.6500 ext. 88786, Fax: 212.996.0987, clara.li@mssm.edu 7 7 2016 Oct-Dec 2016 01 10 2017 30 4 345347 This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. Purpose This study described and evaluated the rapid recruitment of elderly Chinese into clinical research at the Mount Sinai Alzheimer’s Disease Research Center (MSADRC). Design and Methods Methods of publicizing the study included lectures to local senior centers/churches and publications in local Chinese newspapers. The amount of time and success of these methods were evaluated. A “go to them” model of evaluation was employed to enable participants to complete the study visit at locations where they were comfortable. Results From January to December 2015, we recruited 98 participants aged ≥ 65 who primarily speak Mandarin/Cantonese and reside in New York. The mean age and years of education was 73.93±6.34 and 12.79±4.58, respectively. The majority of participants were female (65.3%) and primarily Mandarin speaking (53.1%). Of all enrollees, 54.1% were recruited from community lectures, 29.6% through newspapers, 10.2% through word of mouth, and 6.1% from our clinical services. 40.8% of participants underwent evaluations at the MSADRC, 44.9% at local senior centers/churches, and 14.3% at home. Implications Given that the majority of our participants had low English proficiency, the use of bilingual recruiters probably allowed us to overcome the language barrier, facilitating recruitment. Our “go to them” model of evaluation is another important factor contributing to our successful recruitment. elderly Chinese Americans clinical study dementia aging recruitment minority Chinese Americans are one of the fastest growing populations among the elders in the United States (U.S.).1 Many elderly Chinese are at a high risk for developing cognitive loss and dementia, probably due to the high prevalence of vascular risk factors,2 low level of education,3 and limited access to healthcare services.4 However, recruitment of elderly Chinese Americans into research remains to be a challenge for a variety of reasons, such as misconceptions that memory loss is an inevitable part of aging, lack of trust in research and/or researchers, and social stigma associated with dementia.5 Additionally, many elderly Chinese Americans are fearful of going to a medical center and/or reluctant to leave their neighborhood for healthcare. This manuscript describes the experience with recruitment of U.S. Chinese elders into aging and dementia research at the Mount Sinai Alzheimer’s Disease Research Center (MSADRC) in New York City. Design and Methods Chinese Outreach Program Our Chinese Outreach Program was staffed by a bilingual Ph.D. level neuropsychologist (CL) at 70% effort and a bilingual research coordinator (QH) at 50% effort. The bilingual staff translated recruitment flyers, brochures, and consent forms from English into Simplified and Traditional Chinese. The Chinese recruitment flyers and brochures were distributed in local senior centers and churches following community talks. All study materials were approved by the local Intuitional Review Board (IRB). PowerPoint lectures on dementia and cognitive aging were given at four local churches and six senior centers frequented by elderly Chinese. The lectures were conducted in Cantonese and simultaneously translated into Mandarin. These lectures varied in length from 30 minutes to one hour and ended with information about research opportunities at the MSADRC. At the end of the lectures, audiences were given the opportunity to sign up to participate in the aging and dementia study at the MSADRC. A newspaper announcement about the lecture was printed in a local Chinese newspaper and paid for by the church where the lecture took place. The contexts of the lecture and research opportunities at the MSADRC were published as a column in a local Chinese newspaper at no cost following an interview with the newspaper journalist who attended the announced lecture. Subjects Our outreach effort targeted individuals who were 65 years of age or older, primarily Chinese speaking, New York residents, and able to complete cognitive assessments. Study Procedures An IRB approved Chinese version of the MSADRC consent form was signed by participants or study partners as appropriate prior to study participation. The study involved a 3-hour in-person clinical evaluation modeled by the MSADRC, which includes medical, functional, and cognitive assessments. An optional blood draw for DNA banking and genetic analysis was included as part of the standard dementia evaluation. The “go to them” model of evaluation was used, which allows participants to complete the study procedures in locations that were comfortable and convenient for them, such as participants’ own home, local senior centers/churches, and the MSADRC. Upon completion of the evaluation, all participants were assigned a research diagnosis of normal cognition, Mild Cognitive Impairment (MCI), and dementia using the diagnostic criteria used by the MSADRC. A brief report, written in both Chinese and English, was mailed to each research participant detailing results of the cognitive testing along with research diagnosis and clinical recommendations. Results Through our Chinese outreach program, we successfully enrolled 98 participants between January and December 2015. In the one-year period, community lectures generated 65 potential interests and 54 enrollees. Newspaper exposures, on the other hand, produced 66 potential interests and 29 enrollees. Table 1 shows details in recruitment efforts and outcomes from the two recruitment methods. Figure 1 shows the lag time between outreach and recruitment. Of all the enrollees, 54.1% were recruited from community talks; 29.6% from newspapers; 10.2% through word of mouth; and 6.1% from our clinical services (e.g. social workers and physician referrals). The average age at initial interviews was 73.93±6.34 years. The sample cohort has a relatively high level of education (12.79± 4.58 years). Many of the research subjects have been living in the U.S. for over three decades. Most were right-hand predominant (92.9%), married (65.3%), females (65.3%), and Mandarin speaking (53.1%). 40.8% of participants were evaluated at MSADRC, 44.9% at their senior centers/church, and 14.3% at home. 87.5% of the participants and 59.3% of the informants reported concerns about memory functioning and/or thinking abilities of the research participants. The informants were spouses (43.9%), children (33.7%), other family member (6.1%), friends (9.2%), and health aides (4.1%). 81.6% of participants agreed to have their blood drawn. Discussion Our Chinese outreach program, established to engage elderly Chinese Americans into research, demonstrates that direct face to face outreach with bilingual staff members is the most successful recruitment technique. A majority of our elderly Chinese Americans enrolled in that year were a result of this face to face approach. While newspaper exposures generated a greater number of potential interests than community lectures, the lectures (a face to face methodology) produced greater enrollment. In addition, community talks appeared to be less time consuming and yielded a higher success rate in recruiting the targeted population compared to newspaper announcements, suggesting that direct face to face outreach with bilingual staff members was a more successful form of recruitment. Overall, our experience provides a template for successful recruitment of elderly Chinese Americans, and perhaps recruitment of other immigrant elderly populations, into aging and dementia research. First, we find that U.S. elderly Chinese participants, like many older adults, have concerns about their memory functions, and are willing to participate in clinical research. Most participants agreed to DNA banking and genetic analysis, suggesting that other biomarker studies may be of interest. A factor that appears to increase willingness to participate is participants’ desires to understand their levels of cognitive health. Most of our participants reported experiencing a decline in their memory and were motivated to learn more about their cognitive functions. Most of our participants do not speak English well, and the use of bilingual recruiters allowed us to overcome the language barrier that would prevent access to cognitive assessment. In addition, our graph illustrates that recruitment efforts takes time to show effect. It took several talks before enrollments occurred and there was a sharp increase in enrollment following each outreach event but then recruitment reached a plateau and needed another outreach to boost enrollment. Further, nearly 60% of our evaluations were conducted at the participants’ homes and senior centers/churches, indicating our “go to them” model of evaluation was another essential element to our successful recruitments. Data from the current study indicates that our participants were largely in their 70s, high school graduates, residents in the U.S. for over three decades, females, married, right-handed, born in China, and Mandarin speaking. The results help to identify specific sub-groups of participants who are more likely to participate in research and those who may require more attention for improving future recruitments in clinical research for elderly Chinese Americans. While our data showed that it is possible to recruit the minority population into aging and dementia research, our cohort may not represent the average population of elderly Chinese Americans in New York. In addition, our sample has a relatively high level of education. Previous studies have reported that low education may threaten the validity of diagnostic testing.6 Systematic collection of clinical data will help to establish better norms. Future studies focusing on recruitment of participants with low levels of education are needed. Source of Support: NIH National Institute on Aging grant (P50AG05138) Figure 1 Graph 1: Lag Time between Outreach and Recruitment Community talks and newspaper announcements were successful in recruiting participants but their effectiveness began to fade towards the end of the year. Table 1 Outreach Recruitment Efforts and Outcomes Community talks provided an opportunity for information sharing pertaining to study project and resulted in less one-on-one calls to explain study proceudre and yielded more eligible participants compared to newspaper annoucements. Recruitment Methods Community Lectures Newspaper Announcements Total exposures 249 38,000 Total potential interests 65 66 Total enrollments 54 29 Bilingual staff efforts Giving community lectures (11 hours) Speaking with potential participants (6 hours) Scheduling participants for study visits (5 hours) Creating power point slides (5 hours) Translating brochures/flyers (6 hours) Contacting local senior centers/churches (3 hours) An interview with a newspaper journalist (1 hour) Speaking with potential participants (36 hours) Scheduling participants for study visits (4 hours) Total staff hours 36 hours 41 hours Staff hour(s) spent to enroll one participant 0.67 hour 1.41 hours Total costs $600 $0 References 1 Asian/Pacific American Heritage Month EaSAW USDoC Facts for Features U.S. Census Bureau 2011 5 Washington, DC USA 2011 2 He J Iosif AM Lee DY Brain structure and cerebrovascular risk in cognitively impaired patients: Shanghai Community Brain Health Initiative-pilot phase Archives of neurology 2010 10 67 10 1231 1237 20937951 3 Salmon DP Jin H Zhang M Grant I Yu E Neuropsychological assessment of Chinese elderly in the Shanghai Dementia Survey The Clinical Neuropsychologist 1995 9 159 168 4 Nguyen D Bornheimer LA Mental health service use types among Asian Americans with a psychiatric disorder: considerations of culture and need The journal of behavioral health services & research 2014 10 41 4 520 528 24402440 5 Chao SZ Lai NB Tse MM Recruitment of Chinese American elders into dementia research: the UCSF ADRC experience The Gerontologist 2011 6 51 Suppl 1 S125 S133 21565814 6 Lezak M Neuropsychological assessment 1995 New York Oxford University Press
PMC005xxxxxx/PMC5119922.txt
LICENSE: This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. 8303331 22425 Nutr Res Nutr Res Nutrition research (New York, N.Y.) 0271-5317 1879-0739 27865347 5119922 10.1016/j.nutres.2016.08.001 NIHMS808774 Article Gestational food restriction decreases placental IL10 expression and markers of autophagy and ER stress in murine intrauterine growth restriction Chu Alison a1 Thamotharan Shanthie a2 Ganguly Amit a3 Wadehra Madhuri mwadehra@mednet.ucla.edu b Pellegrini Matteo matteop@mcdb.ucla.edu c Devaskar Sherin U. a4* a David Geffen School of Medicine at UCLA, Department of Pediatrics, Division of Neonatology & Developmental Biology, Neonatal Research Center of the UCLA Children's Discovery and Innovation Institute. 10833 Le Conte Avenue, MDCC 22-402, Los Angeles, CA, 90095, USA b David Geffen School of Medicine at UCLA, Department of Pathology, 4525 MacDonald Research Laboratories, Los Angeles, CA 90095, USA c David Geffen School of Medicine at UCLA, Department of Molecular, Cell, and Developmental Biology, 3000 Terasaki Life Sciences Building, 610 Charles Young Drive East, Los Angeles, California 90095, USA Corresponding author: Sherin U. Devaskar, David Geffen School of Medicine at UCLA, Department of Pediatrics, Division of Neonatology, 10833 Le Conte Avenue, MDCC 22-402, Los Angeles, CA 90095; (t) 310.825.9357, (f) 310.267.0154 1 alisonchu@mednet.ucla.edu 2 sthamotharan@mednet.ucla.edu 3 aganguly@mednet.ucla.edu 4 sdevaskar@mednet.ucla.edu 11 8 2016 5 8 2016 10 2016 01 10 2017 36 10 10551067 This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. Intrauterine growth restriction (IUGR) affects up to 10% of pregnancies and often results in short- and long- term sequelae for offspring. The mechanisms underlying IUGR are poorly understood, but it is known that healthy placentation is essential for nutrient provision to fuel fetal growth, and is regulated by immunologic inputs. We hypothesized that in pregnancy, maternal food restriction (FR) resulting in IUGR would decrease the overall immunotolerant milieu in the placenta, leading to increased cellular stress and death. Our specific objectives were to evaluate: (1) key cytokines (e.g. IL10) that regulate maternal-fetal tolerance, (2) cellular processes (autophagy and ER stress) that are immunologically-mediated and important for cellular survival and functioning, and (3) evaluate the resulting IUGR phenotype and placental histopathology. After subjecting pregnant mice to mild and moderate FR from gestational day (GD) 10 to 19, we collected placentas and embryos at GD19. We examined RNA sequencing data to identify immunologic pathways affected in IUGR-associated placentas and validated mRNA expression changes of genes important in cellular integrity. We also evaluated histopathologic changes in vascular and trophoblastic structures as well as protein expression changes in autophagy, ER stress, and apoptosis in the mouse placentas. Several differentially expressed genes were identified in FR compared to control mice, including a considerable subset that regulates immune tolerance, inflammation and cellular integrity. In summary, maternal food restriction decreases anti-inflammatory effect of IL10 and suppresses placental autophagic and ER stress responses, despite evidence of dysregulated vascular and trophoblast structures leading to IUGR. mouse placenta vasculature intrauterine growth restriction autophagy ER stress Interleukin-10 1. Introduction Intrauterine growth restriction (IUGR) is a poorly understood complication of pregnancy, affecting up to 10% of pregnancies. As the causes of IUGR are myriad, IUGR is thought to encompass a broad spectrum of diseases that results from poor nutrient provision to the fetus. This adverse intrauterine environment may, in some cases, result from disordered placentation or poor maternal health and nutrition [1,2]. It is critical to understand the contribution of maternal diet towards the pathophysiology of IUGR, as IUGR not only places offspring of these pregnancies at increased risk of short-term morbidity, but also at increased risk for adult-onset cardiovascular and metabolic diseases [3-6]. The placenta plays an important role in IUGR as it is the essential organ for transportation of nutrients from maternal blood to the fetus. Studies of placental gene expression have shown that the placenta is able to sense and respond to changes in the immediate environment (e.g. maternal diet) in ways that directly alter the transport of nutrients to the fetus [7-9]. The transfer of nutrients is largely mediated by blood flow and transcellular transport, via placental vasculature and across trophoblast cells. The reported placental changes seen in human IUGR include a degenerated syncytiotrophoblastic lining, fibrin deposition, hypovascular/avascular villi and large areas of infarction [10]. These findings likely represent changes that occur in response to longstanding nutrient and oxygen insufficiency in IUGR. These changes further exacerbate poor blood flow to the fetus, resulting in poor in-utero growth of the fetus. The development and maintenance of placental structure and cellular function are dependent upon immune modulation with several pathways communicating to allow immune tolerance at the maternal-fetal interface. A growing body of evidence suggests that pathology in pregnancy disorders such as preeclampsia, recurrent miscarriage and IUGR can be related to altered immune tolerance. Interleukin-10 (IL10), an anti-inflammatory cytokine, is a key immunologic signal that is altered in these pregnancy states. It normally acts as an anti-inflammatory pleiotropic regulator in pregnancy via suppression of inflammatory cytokines, inhibition of antigen expression via major histocompatibility complex (MHC) class II expression, protection against vascular dysfunction and inflammation, and modulation of endoplasmic reticulum (ER) stress and autophagy [11] (Figure 1). Our specific research objectives were to ascertain the effect of maternal food restriction resulting in placental insufficiency and IUGR on key cytokines in pregnancy affecting immune tolerance, e.g. IL10, and on downstream immunologic pathways regulating cellular maintenance, e.g. autophagy and ER stress. As autophagy and ER stress are processes that are essential for cellular functioning in the face of pathologic stimuli such as nutrient deprivation and hypoxia, we hypothesized that maternal food restriction during pregnancy would result in IUGR and concomitantly decrease “anti-inflammatory” signaling in the placenta and increase cellular stress and death via alterations in autophagy and ER stress. To do this, we exposed pregnant mice to varying degrees (25% and 50% restriction of daily food intake, by weight) of maternal food restriction (FR) during the second half of gestation, and assessed the effect of maternal FR on placenta and embryo weight. FR during gestational days (GD) 10-19 was chosen to mimic the chronicity of human IUGR, which more commonly manifests in the second half of pregnancy. This time period was also chosen because placental function and gene expression dramatically affect fetal growth patterns during this portion of pregnancy. To initially undertake a global approach, we analyzed RNA sequencing data generated from whole placental samples to identify key genes involved in immunomodulatory pathways that were affected in our animal model of IUGR. We identified candidate genes not previously characterized in placental pathology per se, but known to be important in autophagy, ER stress, and vascular inflammation in other human diseases. We then validated altered mRNA expression of these specific genes by real time PCR. We employed a combination of western immunoblotting as well as immunohistochemistry to evaluate whether tissue-level and/or protein expression of IL10 and markers of autophagy and ER stress pathways reflected the same directional changes as seen in the transcriptomic changes in these placentas. We also examined the placentas for histopathologic findings consistent with IUGR, and to localize associated degenerative changes that we would expect to see with altered autophagy and ER stress pathways. Taken together, these experiments further our understanding of how maternal diet specifically affects the immunologic milieu at the maternal-fetal interface and the cellular health of key placental structures for nutrient provision to the fetus. 2. Methods and materials This study was conducted in accordance with established guidelines and all protocols [12] were approved by the Animal Research Committee of the University of California Los Angeles in accordance with the guidelines set by the National Institutes of Health. C57/BL6 mice were housed in 12:12 hour light-dark cycles with ad libitum access to a standard rodent chow diet (Pico Lab Rodent Diet 20, cat# 5053, Lab Diet, St. Louis, MO; major ingredients included: ground corn, soybean meal, wheat middlings, whole wheat, fish meal, dried beet pulp, wheat germ, cane molasses, brewers dried yeast, ground oats, dehydrated alfalfa meal, soybean oil, whey, and calcium carbonate), and the vitamin and mineral premixes. The macronutrient content of the diet was comprised of the following: carbohydrate (62.3% energy), protein (24.5% energy), and fat (13.1 % energy). 2.1. Placental samples At 8 weeks of age, male and female mice were mated overnight, and pregnant mice were identified by the presence of a vaginal plug (designed as gestational day 1). Pregnant females were transferred to individual cages and reared on the same chow diet ad libitum until gestational day 10, at which point they were randomly assigned to three groups: 1) control group - ad libitum access to the standard rodent diet, 2) mild restriction group – restricted by 25% of their daily intake from gestational day 10 to 19, and 3) moderate restriction group – restricted by 50% of their daily intake from gestational day 10 to 19, as previously described (n=4-5 pregnant mothers/group) [7]. On GD 19, animals were euthanized by intraperitoneal injection of 100 mg/kg of phenobarbital. The placentas were separated from the respective fetuses and collected (n=20-25/group). The placentas and fetuses were weighed in a Mettler AB104 precision balance (0.01 mg sensitivity), and then immediately snap-frozen and stored at -80°C until further analysis. In some cases, placentas were fixed in paraffin and then processed for immunohistochemical staining, as described below (section 2.6). 2.2. RNA sequencing For this analysis, only two groups were considered. Whole placental samples were obtained from control and 50% FR groups (n=5/group). Briefly, tissue from single placentas was homogenized and RNA extracted as previously described [7]. Total RNA was quantified using the Qubit RNA assay (Thermofisher Scientific, Waltham, MA). 1,000ng of total RNA was used as starting material for each sample. Library preparation was performed using the Illumina TruSeq RNA Sample Preparation kit, according to the manufacturer's instructions. Libraries were run using 50-bp single-end reads on the HiSeq2000 System (Illumina), and reads were mapped with TopHat, which keeps unique alignments and those with up to two mismatches [13]. The quality of alignments was checked with FastQC and the resulting file was processed through the HTSeq program to create a gene matrix as input for downstream analysis. DESeq [14] was used to calculate differential expression, generating Reads Per Kilobase per Million mapped reads (RPKM) per gene [7]. 2.3. Library analysis Genes were considered differentially expressed between control and the 50% FR group if differentially methylated regions (DMR) located close to those genes had significantly different mean expression levels as determined by Student's t-test, p<0.05. Details on determination of mean methylation levels are included in section 2.3.1 below. Pathway analysis was then conducted to identify genes that were involved in functional immunomodulatory pathways. Specifically, genes previously identified as important in inflammatory, immunologic, vascular, autophagy, or ER stress pathways in human disease were selected for further validation. 2.3.1. Statistical analysis methods used in RNA sequencing and library analysis For each CG site, a t-score was calculated from the t-test of mean difference between the two groups of comparison. Sites with an absolute t-score greater than or equal to 1.5 (approximately top 10%) were deemed candidate DMRs. For each candidate DMR, z-score of average t-score from all CG sites within the region was calculated. If the absolute z-score was greater than threshold, as calculated based upon the false discovery rate of <5% [7], and mean methylation levels in the two groups differed by at least 15%, the region was considered a DMR. Genes that overlapped or had transcription start sites within 5Kbp of the DMR were considered associated genes to the DMR of interest. Genes were considered differentially expressed between control and the 50% FR group if differentially methylated regions (DMR) associated with those genes had mean expression levels that were significantly different between the two groups, by Student's t-test, with unadjusted p-value<0.05. Log2 ratios and adjusted p-values using Bonferroni correction were also calculated. False discovery rate for p value cutoffs was <5% [7]. 2.4. qRT-PCR Total cellular RNA was isolated using the RNeasy mini kit (Qiagen, Valencia, CA. USA). cDNA was generated from 1 μg of total RNA from placental tissue (n=6/group) by reverse transcription (RT) using a Superscript III Reverse Transcriptase kit (Invitrogen, San Diego, CA). Amplification was performed in triplicate using Taqman-based detection on a Step One real-time quantitative PCR thermocycler (Applied Biosystems), as previously described [12]. For IL-10, the IL-10 Taqman Gene expression Assay Mm01288386_m1 was used according to the manufacturer's instructions (Applied Biosystems). For all other genes of interest, a Fam/Tamra probe was used (Eurofins, MWG Operon). Relative gene expression was calculated using the comparative CT method [15] with 18S (Applied Biosystems, #4319413E) expression used as the internal control for normalization. The amplification cycles consisted of: 50°C for 2 minutes, 95°C for 20 seconds, then 45 cycles of 95°C for 1 second (denaturation) and 56-59°C for 20 seconds (annealing), followed by 72°C for 5 minutes (extension). Specific annealing temperatures, exon-spanning primers for amplification, and probe sequences for detection are provided in Table 1. 2.5. Western blotting BAX (Bcl-2 associated X protein) and BCL2 (B-cell lymphoma 2) protein detection was undertaken to evaluate for changes in apoptosis in whole placental samples. BIP (Binding immunoglobulin protein) detection was undertaken by Western blot analysis to evaluate overall ER stress in whole placental samples. Briefly, tissue homogenates from whole placental samples were solubilized in 50mM Tris, pH 6.8, containing 2% SDS. Protein concentration was determined by using the Bio-Rad dye-binding assay. Western blotting was performed as described previously (n=9/group) [16]. Briefly, the solubilized protein homogenates (20 μg) were subjected to electrophoresis on 10% SDS-polyacrylamide gels and transferred to nitrocellulose membranes (Transblot; Bio-Rad, Hercules, CA). The following primary antibodies were used for signal detection: BAX antibody (Cell Signaling Technology, 1:750 dilution), BCL2 antibody (Cell Signaling Technology, 1:750 dilution), and BIP antibody (Cell Signaling Technology, 1:1000 dilution). Anti-vinculin antibody (Sigma-Aldrich, St. Louis, MO, 1:7000) was used to detect endogenous vinculin, which served as an internal control for inter-lane loading variability [17]. For all bands, resultant optical density was ensured as linear to the loading protein concentrations, and the intensity of the protein bands was assessed by densitometry using the Scion Image software program [16]. 2.6. Immunohistochemistry Immunohistochemistry for detection of IL10, markers of autophagy (LC3B, a ubiquitin-like protein involved in the ATG-8-conjugation system, necessary for the formation of the autophagosome), vasculature (CD34+ endothelial cells), and trophoblast cells (cytokeratin staining) was performed. All tissues were rinsed in PBS, fixed in cold 10% neutral buffered formalin for 24 hours and then transferred to cold 70% ethanol. Samples were embedded in paraffin and sectioned at 5 μm thickness. A single section from each placenta was stained with hematoxylin and eosin by the Tissue Procurement Core Laboratory (TPCL) at UCLA. Samples were deparaffinized and dehydrated in alcohol. Antigen retrieval was performed using 0.1 M citrate, pH 6.0, at 95°C for 20 min. The slides were then incubated with antibody or control rabbit pre-immune serum at the same dilution overnight. The antibody signal was visualized using the Vectastain ABC kit (Vector, PK6101). Negative controls (no incubation with primary antibody) were included for each experiment. Anti-IL10 (Abcam, ab33471) was used at a dilution of 1:100; anti-CD34 (Abcam, ab81289) was used at a dilution of 1:100; pan cytokeratin (DAKO, Z0622) was used at a dilution of 1:50; LC3B (Abcam, ab168831) was used at a dilution of 1:50. Antibody staining was detected using the appropriate species Vector ABC kit (Vector Laboratories, PK6106) followed by the DAB substrate [18]. Image Calibration: Staining was captured using a 4×, 10×, 20× or 40× objective (×40 or ×100 or ×200 or ×400 magnification) from at least four non-overlapping microscopic fields by an AxioCam CCD digital camera (Carl Zeiss). Files were saved in a 12-bit tagged image file format (.tif). To perform area analysis, unmodified, uncompressed. tif image files of staining were accessed in Photoshop as previously described [19]. 2.6.1. Statistical analysis of immunohistochemistry data We conducted quantitative analysis of vasculature using ImageJ software. The observer was blinded to experimental group, and using systematic random sampling, at least three non-overlapping regions within the labyrinthine layer from each placental section (40× magnification images) were analyzed. Control, 25% FR, and 50% placentas (n=8/group) were evaluated and standardized for equal pixel size. For vascular quantification, CD34 positively stained cells were identified and contiguous positively stained cells were marked to create an outline of the vascular area. Region of interest analysis was conducted to calculate the summative area of positively outlined areas per region. Because of the pattern of distribution of positive staining, semi-quantitative analysis of IL10 (n=4-7/group) and trophoblast staining (n=8/group) was conducted by a pathologist blinded to phenotypic information. Staining was quantified by grading the overall positive staining of cells with intensities of 0 to 4 akin to a Likert scale (0=below the level of detection, 1=weak, 2=mild, 3=moderate, 4=strong) [20]. Quantitative analysis of LC3B staining was performed by counting the number of positively- and non-staining spongiotrophoblast cells per region of interest, located in the junctional zone. All cell counts were completed in triplicate on randomly selected fields (taken at 40×) per placental section and average cell counts calculated for each mouse placenta (n=3-4/group). 2.7. Statistical Analyses All statistical analyses were conducted in GraphPad Prism software (version 5, GraphPad Software Inc., La Jolla, CA) and data are presented as means ± SEM. Significant differences between three groups were analyzed using one-way analysis of variance (ANOVA) with Fisher's LSD, unless otherwise indicated (for qRT-PCR and western blotting studies). Post-hoc Tukey's multiple comparison testing was used to determine significant differences in pairwise comparisons. When comparisons were made between two groups only, Student's t-test was performed. All p-values are reported as 2-tailed with statistical significance set at <0.05 for all comparisons. Sample sizes were based upon previously published data evaluating placental gene expression using this murine model of maternal FR resulting in IUGR [7]. Power analyses conducted using gene expression data (by qRT-PCR) from that study, which showed mean relative expression=1.0 with SD=0.1, indicate that 5-8 animals per experimental group was sufficient to detect a 25-35% change in gene expression from the control group. These sample sizes achieve 89% power to detect a difference of at least 25-35% using the Hsu (with Best) multiple comparison test at a 0.05 overall significance level. 3. Results 3.1 Placenta and embryo weight Compared to controls (n=20), 25% FR mice (n=25) did not demonstrate a decrease in placental weight. However, 50% FR mice (n=21) demonstrated a significant (p<0.01) decrease in placental weight compared to control and 25% FR mice (control: 0.08±0.002g versus 25% FR: 0.08±0.002g versus 50% FR: 0.06±0.002g). The 50% FR mice displayed a 29% decrease in placental weight compared to the control and a 31% reduction compared to the 25% FR mice. Both the 25% FR mice and 50% FR mice showed a significant (p<0.01) decrease in embryo weight compared to controls (25% FR: 42% decrease; 50% FR: 48% decrease) (control: 1.16±0.02g versus 25% FR: 0.67±0.01g versus 50% FR: 0.61±0.03g). There was no significant difference in embryo weight between 25% and 50% FR mice. 3.2 RNA sequencing pathway analysis in placental tissue There were almost 700 genes that were differentially expressed between 50% FR and control groups, as previously reported [7]. Approximately 15% of these genes have unknown clinical significance in human physiology or disease. Of the remainder, approximately 7% of the genes that had differential RNA expression in the 50% FR group compared to controls have been associated with immunologic function, vascular and endothelial maintenance, inflammation, autophagy, or ER stress (Table 2). 3.3 qRT-PCR In order to extend the results found by RNA sequencing to the 25% FR group, we utilized qRT-PCR to determine gene expression in all groups, with a focus on genes involved in autophagy, ER stress and inflammation in human disease. We validated differences in expression between control, 25% FR and 50% FR groups (n=6/group) for three genes involved in autophagy, Dram1 (control: 1.009±0.059 versus 25% FR: 0.816±0.094 versus 50% FR: 0.301±0.062; p<0.001), Fbxo32 (control: 1.010±0.062 versus 25% FR: 0.708±0.046 versus 50% FR: 0.305±0.046; p<0.001), and Scd1 (control: 1.012±0.067 versus 25%FR: 0.851÷0.114 versus 50% FR: 0.581±0.048; p<0.006). Three genes which are known to be functionally important in the endoplasmic reticulum (ER) stress response, Pdia4, Creld2, and Derl3 were also significantly differentially expressed between groups (control: 1.014±0.075 versus 25% FR: 0.955±0.038 versus 50% FR: 0.493±0.038; p<0.0001), (control: 1.009±0.057 versus 25% FR: 0.885±0.054 versus 50% FR: 0.738±0.089; p<0.04), (control: 1.007±0.073 versus 25% FR: 0.746±0.078 versus 50% FR: 0.479±0.091; p<0.001), respectively. Lastly, two genes involved in vascular inflammation were found to be differentially expressed, Map3k6 (control: 1.030±0.084 versus 25% FR: 1.697±0.120 versus 50% FR: 2.000±0.305; p<0.02) and C1qa (control: 1.022±0.088 versus 25% FR: 0.804±0.096 versus 50% FR: 0.459±0.059; p<0.0008) (Fig 2). In addition, given the key anti-inflammatory role of IL10 in pregnancy, we quantitated its expression and found that Il10 levels in whole placenta decreased in FR compared to control groups (control: 1.113±0.214 versus 25% FR: 0.328±0.058 versus 50% FR: 0.320±0.072; p<0.001). 3.4 Western immunoblotting Our results above suggested that FR results in alterations to autophagy and ER stress pathways. To translate these differences, BAX, BCL2, and BIP protein expression were assessed by Western blot analysis. There was no significant difference in BAX (p=0.19) or BCL2 (p=0.46) protein expression among groups (Fig 3A,3B). However, BIP expression was down regulated in FR groups (control: 97.62±5.94 versus 25% FR: 77.46±4.71 versus 50% FR: 69.21±4.60; p=0.0016) (Fig 3C). As a marker of generalized ER stress, this observation is consistent with our qPCR findings of decreasing ER stress with increasing severity of food restriction. 3.5 Placental histopathology Histopathology was undertaken to evaluate for differences in placental structures among groups. No appreciable differences were seen between groups in the overall architectural organization of the placenta as visualized by H&E staining (Fig 4). IL10 and LC3B immunostaining was performed to evaluate for protein-level expression of inflammatory markers and bulk autophagy. Positive staining for IL10 was seen predominantly within the junctional zone of the placenta (Fig 5A), and overall positive staining for IL10 was decreased with increasing degrees of food restriction (control: 3.60±0.24 versus 25%FR: 1.75±0.25 versus 50% FR: 1.25±0.25; p<0.0001) (Fig 5B). Similarly, positive staining for LC3B was seen predominantly within the junctional zone, and detected in mostly spongiotrophoblast cells, though occasionally seen in giant trophoblast cells (Fig 5C). Overall numbers of spongiotrophoblasts and giant cell trophoblasts (determined by morphology) were not different between groups (p=0.38 and p=0.81, respectively). Average number of LC3B-positively staining spongiotrophoblast cells per section (using region of interest analysis) was significantly different between groups (control: 13.44±2.39 versus 25% FR: 4.89±0.29 versus 50% FR: 5.17±1.18, p=0.0087) (Fig 3D). Evaluation of vascular and trophoblast structures was specifically undertaken, as these structures are essential for nutrient provision from the mother to the fetus. Within the labyrinthine area, FR mice showed a graded decrease in vasculature with increasing severity of FR, as analyzed by CD34 immunohistochemical analysis (Fig 6A). When summative area of vasculature per region of interest was compared, there was a significant decrease in both FR groups compared to controls (control: 35264±3530 versus 25% FR: 23224±1623 versus 50% FR: 20156±2193; p<0.01) (Fig 6B). Overall trophoblast integrity was altered in the FR mice, as demonstrated by pan cytokeratin immunohistochemistry staining (Fig 6C). Sections were graded 0 to 4+ on overall positivity of staining, and there was a significant difference between groups (control: 3.125±0.125 versus 25% FR: 2.000±0.267 versus 50% FR: 1.500±0.267; p<0.01) (Fig 6D). Qualitative review revealed degenerative changes of the cytokeratin-positively staining structures with a decreased percentage of positively stained cells overall in FR groups compared to control. 4. Discussion Our animal study demonstrates that maternal nutrient deprivation during pregnancy affects the immunologic milieu in the placenta, specifically affecting both gene and protein expression of IL10 and associated cellular stress responses to nutrient deprivation via autophagy and ER stress. Our findings are consistent with our hypothesis that IL10 expression is decreased in maternal food-restricted placentas. These findings are in line with human data showing that placental insufficiency uniformly seen in various disorders of pregnancy such as recurrent miscarriages, preeclampsia, and/or intrauterine growth restriction may be due to disordered immune tolerance and/or dysregulation of IL10 [11,21-23]. IL10 is a known key anti-inflammatory cytokine in pregnancy, but has been shown in other inflammatory human disease to also regulate autophagic and ER stress responses. In our model, we provide evidence that bulk measures of autophagy and ER stress are suppressed at the junctional zone of the murine placenta in conditions of maternal food restriction. These findings are contradictory to our hypothesis that IL10 reduction leads to increased cellular death via autophagy and ER stress. Instead, these findings suggest that placental cell populations adapt to chronic nutrient restriction by decreasing cellular autophagic and ER stress responses in order to continue to function and survive to provide nutrients and blood flow to the growing fetus. We identified, by RNA sequencing and pathway analysis, novel genes important in these cell homeostasis regulatory pathways that are differentially affected by maternal food restriction. However, the suppression of autophagy, ER stress, and anti-inflammatory signals localized largely to the junctional zone in maternal FR-associated placentas does not adequately compensate for dysregulation of vascular and trophoblast structures within the murine labyrinth. Autophagy is the process by which damaged organelles and protein aggregates are engulfed into autophagosomes, fused with lysosomes and degraded by hydrolases. This process is essential for cell survival and regulation of energy and nutrient homeostasis. Therefore, we had hypothesized that in our model of maternal food restriction and intrauterine growth restriction, markers of autophagy would be increased. However, we found the opposite – that bulk measures of autophagy are decreased. These contradictory findings are in line with the existing debate on whether placental insufficiency leads to induction or suppression of autophagy as some groups have shown that up-regulation of autophagy is associated with fetal growth restriction and preeclampsia [24-26]. It is generally accepted that both in vivo and in vitro, starvation conditions activate autophagy. However, these responses are highly tissue-specific, and modulated by multiple and complex input signals. The placenta is a unique organ that is responsible for sustenance of the growing fetus, often at the expense of maternal well-being, and therefore, may regulate autophagic processes differently in response to nutrient deprivation. Our results in placentas associated with FR overall suggest that bulk autophagy is decreased, especially in the junctional zone of the murine placenta. We believe that this seemingly contradictory finding may reflect the function of certain autophagy genes to inhibit inflammation, as seen in tissue-specific knock-out animal models of autophagy genes resulting in wide spread tissue over-inflammation [27,28]. In fact, in in vivo cancer models, autophagy inhibition has been demonstrated to favor immunosuppression, leading to increased tumor aggressiveness [29]. If this is also true in pregnancy at the maternal-fetal interface, our results suggests that the autophagic suppression seen in the FR-associated placentas may represent a compensatory mechanism to maintain pregnancy in the face of a pro-inflammatory environment. By RNA sequencing, we identified a number of autophagic genes that may be suppressed in IUGR induced by maternal food restriction. For example, Dram1, or DNA-damage regulated autophagy modulator 1, is a gene regulated as part of the p53 tumor suppressor pathway that encodes a lysosomal membrane protein required for the induction of autophagy via this pathway. In our murine FR-associated placentas, Dram1 expression was significantly decreased compared to controls implying suppressed autophagy via this pathway. This is in contrast to reports by Hung et al, who found increased levels of DRAM in human IUGR placentas [24]. Fbxo32, or F box protein 32 (also known as atrogin-1), deficiency in a knock-out animal model has been associated with premature death of cardiomyocytes via impaired autophagy [30]. In our model, FR led to decreased production of Fbxo32, perhaps affecting autophagy-induced cell death. Scd1, stearoyl-CoA desaturase 1, is a key player in fatty acid biosynthesis. Therefore, its reduction in our FR groups may simply represent poor maternal nutrient supply. However, inhibition of Scd1 has been shown to reduce starvation-induced autophagy [31]. Therefore, the reduced levels of Scd1 seen in FR groups may reflect compensation in these placentas to reduce the induction of autophagy by starvation. ER stress is the disruption of protein folding in the endoplasmic reticulum, resulting in the accumulation of misfolded proteins within the ER. This pathologic process results from disturbances such as ER calcium depletion, nutrient deprivation, oxidative stress, DNA damage, or energy perturbation. When ER stress is persistent and excessive, the unfolded protein response (UPR) initiates apoptosis to eliminate stressed cells and also activates NF-κB and the inflammasome. ER stress has been implicated as a contributor to pathology in human intrauterine growth restriction, likely due to deficient placental perfusion inducing oxidative stress [32-35]. Again, our findings are contradictory to our hypothesis that ER stress increases in the nutritionally inadequate environment of IUGR. In our study, overall protein expression of BIP decreases with increasing severity of maternal FR, with no change in apoptotic markers between groups. This finding may again be related to the unique ability of the placenta to immunologically mediate stress responses in order to maintain cellular viability and function to protect and provide for the developing fetus. IL10 has been found to modulate ER stress in other inflammatory disorders [36-37], but its role in placental ER stress has not been defined. By RNA sequencing, we have discovered 3 novel markers of ER stress that are differentially expressed in placentas of food-restricted mothers. We demonstrate decreased levels of Pdia4 (also known as ERP72), a mediator of the unfolded protein response, in FR groups compared to control mice. We also demonstrated decreased levels of Creld2, a stress-inducible gene that may regulate the ER stress response and progression. Mutations in promoter sites of this gene result in decreased basal activity and responsiveness to ER stress stimuli using luciferase reporter analyses [38]. Lastly, Derl3 was found to have decreased expression in FR placentas. Derl3 encodes an important component of ER-associated degradation. In vitro studies have demonstrated that overexpression of this gene enhances ER stress responses and promotes cellular survival, whereas decreased expression decreases ER response but increased cell death in response to ischemia [39]. Taken together, the decreased expression of these 3 genes would result in decreased functional ER stress activity in the face of nutritional deprivation. Lastly, the protective effects of IL10 on vascular function and inflammation have been observed both in pregnancy models and non- pregnancy states [22-23]. IL10 knockout mice have been shown to exhibit impaired spiral artery remodeling and poor placental angiogenesis, resulting in IUGR, when exposed to environmental toxins. Treatment with recombinant IL10 rescues the pregnancy, seemingly via restoration of endovascular activity [40]. Outside of pregnancy, IL10 has also been implicated as a mediator of vascular protection in hypertension, diabetes and atherosclerosis [41-43]. Therefore, one interesting consequence of disordered IL10 seen in adverse pregnancy outcomes is that it may be involved in vascular remodeling seen in placental insufficiency and the developmental programming of cardiovascular disease seen in the offspring of pregnancies complicated by IUGR, preeclampsia, or prematurity. An interesting candidate gene that was greatly increased in FR placentas is Map3k6 (mitogen-activated protein 3 kinase 6), which mediates angiogenic and tumorigenic effects via VEGF expression [44]. Again, this increase may represent an attempt at compensation for poor placental vascularization secondary to nutritional restriction-induced remodeling, as is evident by our immunohistochemical staining for CD34+ endothelial cells. We also demonstrated decreased levels of C1qa, a polypeptide chain of complement subcomponent C1q. Complement C1q-induced activation of β-catenin signaling has recently been shown to contribute to hypertensive arterial remodeling [45]. Contrary to our expectations, C1qa levels were decreased in our FR placentas, again highlighting the inconsistencies of whether cellular protective mechanisms are impaired or enhanced in response to adverse environments in these pathologic conditions of pregnancy. Our histopathologic findings were consistent with the reported placental findings in human IUGR [46-47], where placental hypovascularity and trophoblast degeneration lead to poor blood flow and nutrient transfer to the fetus [48]. However, it should be noted that despite decreased vascularity and damaged trophoblast layers within the labyrinthine area of FR-associated placentas, placental weight was not changed. It may be that in mild FR, placental mass is relatively maintained at the expense of fetal growth, whereas moderate FR crosses a critical threshold, beyond which placental self-preservation is impaired. Taken together, our histopathologic data suggests that alterations in immune tolerance, and placental compensatory responses to protect cellular health via decreasing autophagic and ER stress responses, may allow for functional compensation at mild levels of FR, but are inadequate at more moderate levels of FR. There are several strengths and limitations to our study. The use of animal models to study human disease is often necessary in diseases like IUGR, where detection occurs late in the course of disease making progression of disease difficult to study. However, careful consideration into the specific animal model chosen is essential, as there are both similarities and differences to human placental structure and pregnancy with any animal model [49,50]. Though both mouse and human placentas are hemochorial, meaning fetally-derived trophoblasts are directly bathed in maternal blood [48], there are significant differences in gestation and litter size, which may explain why human pregnancies demonstrate much greater adaptive capacity in protecting fetal weight. These differences present a major limitation of our study, as the extent to which animal data can be applied to human disease remains under debate. We specifically chose this mouse model of late chronic maternal food restriction as it has been shown to result in IUGR, and it has been well-characterized in its effect of maternal health and hormonal status during pregnancy, nutrient transfer to the fetus, and short- and long-term effects on the offspring [7,48,51]. However, as stated previously, architectural differences in mouse and human placenta present challenges in comparing changes specific to the nutrient exchange layers. To address this, we utilized a discovery-based technique of RNA sequencing to identify patterns of placental gene expression changes that may be altered in growth restriction. This allows for a non-biased evaluation of how specific genes involved in immunologic function and cellular maintenance are affected in IUGR, and identification of potentially novel players in placental insufficiency. Using whole placenta, we found 700 genes that were significantly differentially expressed between groups, and performed pathway analysis, which demonstrated that the pathways of interest were well represented among the differentially expressed genes. However, another limitation of our study was that adjusted p-values from RNA sequencing analysis were nonsignificant in some of our genes of interest involved in immunologic pathways. This limitation may have occurred because of the smaller sample sizes used for RNA sequencing. This sample size was chosen as genome-wide sequencing techniques applied to large groups can be cost-prohibitive, and the main purpose of RNA sequencing in this study was to screen for pathway changes. To address this issue on a gene-specific basis, we validated RNA expression of specific genes of interest by qRT-PCR using larger sample sizes across all three experimental groups. In addition, there is still significant debate and remaining unknowns in the field on the crosstalk between autophagy, ER stress and apoptotic pathways. Our study does not establish cause-and-effect, and further mechanistic studies on these pathways in IUGR are warranted to more definitively link decreased IL10 with autophagy and ER stress. In conclusion, our murine model of chronic, mild to moderate late gestational FR of the pregnant mouse represents an animal model of IUGR with reasonable fidelity to the human condition, based on histopathologic similarities. Consistent with our hypothesis, we found that IL10 expression in the murine placenta is decreased in maternal gestational food restriction. Using RNA sequencing techniques, we have demonstrated that a significant portion of gene expression changes seen on a whole placental level involve immunologic pathways and associated cellular maintenance processes. However, contrary to our hypothesis that maternal FR results in increased autophagy and ER stress, leading to cellular death, we found that bulk measures of these pathways are decreased in maternal FR-associated placentas. We believe that these findings suggest that the placenta serves as a unique interface, that must preserve fetal growth in the face of adverse maternal environment, and that these mechanisms are immunologically mediated. As such, placental compensatory responses appear to be distinct and opposite to the inflammatory, autophagic and ER stresses described in in vitro nutrient deprivation. This work was supported by the UCLA Children's Discovery and Innovation Institute [CDI-SGA-01012016 (AC)], the American Heart Association [15BGIA25710060 (AC)], and the National Institutes of Health [5K12HD034610, HD 081206, HD 41230 (SUD)]. Abbreviations BAX Bcl-2 associated X protein BCL2 B-cell lymphoma BIP Binding immunoglobulin protein ER endoplasmic reticulum GD gestational day FR food restriction IL10 interleukin 10 IUGR intrauterine growth restriction LC3B microtubule-associated protein 1 light chain 3 beta Figure 1 Scheme representing crosstalk between IL10, autophagy, ER stress, and apoptotic pathways. Figure 2 qRT-PCR validation of placental RNA expression of genes involved in vascular inflammation, autophagy and ER stress in mice exposed to maternal FR For each candidate gene, average mRNA expression level from control, 25% FR, and 50% FR groups (n=6/group, based on power calculations for detect a 25% difference in mean expression between groups to achieve 89% power at a 0.05 overall significance level) was calculated by qRT-PCR. Data are represented in graphs as means ± SEM. Asterisks indicate a significant difference between indicated FR group compared to control (p<0.05) by post-hoc Tukey's multiple comparison testing. Reported p-value for each gene is by one-way ANOVA between all three groups. Figure 3 Western immunoblotting of apoptosis and ER stress markers in the placentas of gestational FR-exposed mice Representative blots of BAX (A), BCL2 (B) proteins as markers of apoptosis, and BIP (C) as a marker of ER stress are shown. There were no significant differences between groups for BAX and BCL2 expression. BIP expression however, was decreased in both the 25% and 50% FR groups, compared to controls. Data are represented in graphs as means ± SEM. Asterisk indicates p<0.05 by ANOVA. C=control, 25%=25% FR group, 50%=50% FR group (n=9/group). Figure 4 Hematoxylin & eosin staining of control, mild and moderate FR mouse placentas at 4× magnification Representative murine placental sections stained by H&E from control, mild- and moderate-FR exposed mice (n=8/group). La: labyrinth; JZ: junctional zone; D: decidua. Scale bars represent 500μm. Figure 5 IL10 and LC3B staining in murine placenta after maternal FR (A) Representative sections from each group (control, 25% FR, 50% FR) stained for IL10 demonstrate decreasing positive staining for IL10 (brown; 20× magnification) with increasing severity of maternal FR. Arrows indicate positive staining. Scale bars represent 100 μm. D: decidua; JZ: junctional zone; La: labyrinth. (B) Decreasing histologic grading scores of overall positively of IL10 staining in FR groups compared to controls (n=4-7/group). Data are represented in graphs as means ± SEM. Asterisks indicate p<0.0001 between the indicated group compared to the control group, by post-hoc Tukey's multiple comparison testing. Listed p-value represents significance between groups, by ANOVA. (C) Representative sections from each group (control, 25% FR, 50% FR) stained for LC3B (brown; 20× magnification) demonstrating decreasing numbers of positively-stained spongiotrophoblasts in the junctional zone of FR mouse placenta with increasing severity of FR. Arrows indicate positive staining of spongiotrophoblasts. Scale bars represent 100μm. (D) Decreased average numbers of positively staining spongiotrophoblasts for LC3B per region of interest in FR groups compared to controls (n=3-4/group). Data are represented in graphs as means ± SEM. Asterisk indicates p<0.05 between all groups, by ANOVA. Fig 6 Vascular and trophoblast changes in the murine placenta with maternal FR (A) Representative sections from each group (control, 25% FR, 50% FR) stained for CD34 (brown; 20× magnification) in endothelial cells within the labyrinthine region (20×). Arrows indicate blood vessels. Scale bars represent 100μm. (B) Quantitative analysis of sum of vascular area per region of interest at 40×. Each placental section from all three groups (n=8/group) was analyzed in triplicate. Vascular areas were defined as outlined by contiguous positively stained cells. Data are represented in graphs as means ± SEM. Asterisks indicate p<0.05 (between indicated FR group and control), by post-hoc Tukey's multiple comparison testing. Listed p-value indicates significance between all groups, by ANOVA. (C) Representative placental sections from each group (control, 25% FR, 50% FR) stained for trophoblast cells using cytokeratin (brown, 20× magnification). Qualitatively, degenerative changes (dilated maternal spaces, with a decreased percentage of positive stained cells in the 25% and 50% FR groups compared to controls) are seen in murine trophoblast layers within the labyrinth. Arrows indicate trophoblast lining. Scale bars represent 100μm. (D) Decreased histologic grading scores of overall positivity of cytokeratin stain in FR groups compared to controls (n=8/group). Data are represented in graph as means ± SEM. Asterisks indicate p<0.01 between indicated FR group vs. control, by post-hoc Tukey's multiple comparison testing. Listed p-value indicates significance between all groups, by ANOVA. Table 1 Primer and probe sequences and conditions used for qRT-PCR Gene Annealing temperature Forward primer Reverse primer Probe Dram1 57°C 5′-ACACAGGAACAAC TCCTCCA 5′-AACGGGAGTGCT GAAGTAGC 5′-TCTCTGCATTTCT TGGCGCAGC Fbxo32 57°C 5′-TTCTCAGAGAGGCA GATTCG 5′-GAGAATGTGGCA GTGTTTGC 5′-CCAATCCAGCTGC CCTTTGTCA Scd1 59°C 5′-TTCTTCTCTCACGT GGGTTG 5′-CGGGCTTGTAGTA CCTCCTC 5′-CGCAAACACCCG GCTGTCAA Pdia4 57°C 5′-GGATGCTGCTAACA ACCTGA 5′-CCAGGGAGACTTT CAGGAAC 5′-CAAGTTTCACCAC ACTTTCAGCCCTG Creld2 57°C 5′-TGTGTGGATGTGGA TGAGTG 5′-AGCCGTTGACATT CTCACAG 5′-CATCTCCGTGCAG CGATGGC Derl3 57°C 5′-CTCTTCGTGTTCCG CTACTG 5′-AGGAATCCCAGC AGAGTCAT 5′-AACCCTCCTCCAG CATGCGG Map3k6 56°C 5′-TACAACGCGGATGT AGTGGT 5′-AACAGAGGAGCA CGTTGTTG 5′-TTCTACCACCTCG GCGTGCG C1qa 57°C 5′-GAGCATCCAGTTTG ATCGG 5′-CATCCCTGAGAG GTCTCCAT 5′-ACCACGGAGGCA GGGACACC Table 2 Genes differentially expressed between control and 50% FR groups by RNA sequencing that are involved in vascular, immunological and inflammatory pathways Five placentas from control and five placentas from 50% FR mice were processed for RNA sequencing. This table represents the candidate genes identified as differentially expressed between control and 50% FR groups, by unadjusted p-value<0.05, involved in immunologic, inflammatory and vascular pathways. For each gene listed, average expression level for the control and 50% FR group is reported, as well as log2 fold change, p-value based upon Student's t-test and adjusted p-value using Bonferroni correction between groups. Genes are grouped by functional roles in innate immunity, vascular and endothelial function, inflammation, autophagy and ER stress. Gene Average Expression Level (control) Average Expression Level (50% FR) Log2 Fold Change P-value P-value (adj) Innate Immunity IL21r (interleukin 21 receptor) 1.056 0.346 -1.6 7.73E-08 0.001 IL23r (interleukin 23 receptor) 0.366 0.078 -2.2 9.11E-06 0.042 Marco (macrophage receptor with collagenous structure) 0.019 0.856 5.5 0.0002 0.187 Cebpa (CCAAT/enhancer binding protein, alpha) 6.306 9.708 0.62 0.008 1 Sfrp1 (secreted frizzled-related protein 1) 1.199 0.844 -0.5 0.015 1 Syt11 (synaptotagmin XI) 1.481 1.080 -0.45 0.015 1 Siglec1 (sialic acid binding Ig-like lectin 1, sialoadhesin) 0.660 1.132 0.78 0.033 1 Pyhin1 (pyrin and HIN domain family, member 1) 0.300 0.564 0.91 0.034 1 Isg15 (ISG15 ubiquitin-like modifier) 20.849 34.689 0.73 0.045 1 Vascular and endothelial maintenance Tnfsf15 (tumor necrosis factor superfamily, member 15) 0.072 0.019 -1.9 4.03E-05 0.075 Gm52 (syncytin a) 17.555 32.574 0.89 0.0007 0.339 Wls (wntless homolog) 14.802 9.686 -0.61 0.0007 0.339 Ncf1 (neutrophil cytosolic factor 1) 0.322 0.598 0.89 0.001 0.412 Bmper (BMP-binding endothelial regulator) 6.383 11.646 0.87 0.004 0.737 Map3k6 (mitogen activated protein kinase 6) 1.823 2.862 0.65 0.006 0.981 Lyve1 (lymphatic vessel endothelial hyaluronic receptor 1) 11.950 23.472 0.97 0.012 1 Cldn5 (claudin 5) 7.497 11.338 0.60 0.013 1 Ntsr1 (neurotensin receptor 1) 0.349 0.067 -2.4 0.016 1 C5ar1 (complement component 5a receptor 1) 0.257 0.535 1.1 0.021 1 Kcnk6 (potassium inwardly-rectifying channel, K6) 3.905 2.975 -0.39 0.029 1 Lrg1 (leucine-rich alpha-2 glycoprotein 1) 2.044 3.732 0.87 0.035 1 Ucp2 (uncoupling protein 2, mitochondrial, proton carrier) 11.918 16.672 0.48 0.035 1 Trpv6 (transient receptor potential cation channel, V6) 9.530 5.234 -0.86 0.049 1 Gclm (glutamate-cysteine ligase, modifier subunit) 6.098 8.718 0.52 0.049 1 Inflammation Mmp8 (matrix metallopeptidase 8) 0.198 0.561 1.5 2.77E-05 0.070 Sfxn5 (sideroflexin 5) 0.495 0.325 -0.61 0.008 1 Slfn4 (schlafen 4) 0.433 0.736 0.77 0.010 1 IL18rap (interleukin 18 receptor accessory protein) 0.233 0.144 -0.70 0.011 1 Tnf (tumor necrosis factor) 0.338 0.176 -0.94 0.012 1 Bok (Bcl2-related ovarian killer protein) 51.091 38.383 -0.41 0.025 1 Fpr2 (formyl peptide receptor 2) 0.149 0.354 1.25 0.027 1 Plxnc1 (plexin C1) 0.142 0.238 0.74 0.032 1 Blnk (B-cell linker) 0.485 0.742 0.61 0.043 1 C1qa (complement component 1, q subcomponent, alpha polypeptide) 5.333 10.883 1.03 0.049 1 Autophagy Fbxo32 (f box protein 32) 23.176 13.730 -0.76 0.005 0.808 Scd1 (stearoyl-coenzyme A desaturase 1) 5.818 4.339 -0.42 0.017 1 Dram1 (DNA damage regulated autophagy modulator 1) 10.696 7.794 -0.46 0.009 1 ER stress Creld2 (cysteine-rich with EGF like domains 2) 42.240 27.444 -0.62 0.003 0.724 Derl3 (Der1-like domain family, member 3) 23.324 14.517 -0.68 0.019 1 Pdia4 (protein disulfide isomerase associated 4) 82.834 60.377 -0.46 0.010 1 This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final citable form. Please note that during the production process errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain. 1 Cross JC Hemberger M Lu Y Nozaki T Whitely K Masutani M Adamson SL Trophoblast functions, angiogenesis and remodeling of the maternal vasculature in the placenta Mol Cell Endocrinol 2002 187 1-2 207 12 11988329 2 Herr F Baal N Widmer-Teske R McKinnon T Zygmunt M How to study placental vascular development? 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PMC005xxxxxx/PMC5119927.txt
LICENSE: This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. 7702118 4161 Immunol Rev Immunol. Rev. Immunological reviews 0105-2896 1600-065X 27782328 5119927 10.1111/imr.12467 NIHMS802102 Article More than complementing Tolls: Complement–Toll-like receptor synergy and crosstalk in innate immunity and inflammation Hajishengallis George 1 Lambris John D. 2 1 Department of Microbiology, University of Pennsylvania School of Dental Medicine, Philadelphia, PA 19104, USA 2 University of Pennsylvania, Perelman School of Medicine, Department of Pathology and Laboratory Medicine, Philadelphia, PA 19104, USA Correspondence: Dr. George Hajishengallis, University of Pennsylvania, School of Dental Medicine, 240 South 40th Street, Philadelphia, PA 19104-6030, USA; Tel.: 215-898-2091, Fax: 215-898-8385; geoh@upenn.edu 14 7 2016 11 2016 01 11 2017 274 1 233244 This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. Summary Complement and Toll-like receptors (TLRs) play key roles in the host immune response and are swiftly activated by infection or other types of immunological stress. This review focuses on the capacity of complement and TLRs to engage in signaling crosstalk, ostensibly to coordinate immune and inflammatory responses through synergistic or antagonistic (regulatory) interactions. However, over-activation or dysregulation of either system may lead – often synergistically – to exaggerated inflammation and host tissue injury. Intriguingly, moreover, certain pathogens can manipulate complement-TLR crosstalk pathways in ways that undermine host immunity and favor their persistence. In the setting of polymicrobial inflammatory disease, subversion of complement-TLR crosstalk by keystone pathogens can promote dysbiosis. Knowledge of the molecular mechanisms underlying complement-TLR crosstalk pathways can, therefore, be used productively for tailored therapeutic approaches, such as, to enhance host immunity, mitigate destructive inflammation, or counteract microbial subversion of the host response. Complement TLR crosstalk inflammation immune evasion Introduction In co-evolving with the microbial world, mammalian innate immunity has developed effective sentinel mechanisms to promptly detect and respond to infections. Sentinel cells (e.g., neutrophils, macrophages, and dendritic cells) sense invading pathogens through pattern- recognition receptors (PRRs) and alert downstream innate and/or adaptive mechanisms aiming to eradicate or control the infection (1). A major PRR family is represented by the Toll-like receptors (TLRs), each member of which senses distinct types of conserved microbial structures (‘microbe-associated molecular patterns’; MAMPs), thus endowing the innate response with a degree of specificity (e.g., TLR2 responds to lipoteichoic acid, TLR3 to viral double-stranded RNA, TLR4 to lipopolysaccharide [LPS], TLR5 to flagellin and TLR9 to bacterial CpG DNA) (2, 3). The broad but distinct specificities of the TLRs as well as their ability to form heterotypic multi-receptor complexes and engage distinct intracellular signaling molecules further diversifies their recognition and signaling capacities (4, 5). These attributes of the TLRs (and other PRRs) enable the host to detect almost any type of infection, discriminate between different classes of microbes and hence mount a context-relevant immune response. In addition to sentinel cells, innate immunity also has a humoral arm that includes a heterogeneous group of pattern-recognition molecules (PRMs), such as, collectins (e.g., mannose-binding lectin; MBL), ficolins, pentraxins and the complement component C1q (6, 7). Soluble PRMs can be released either locally by stimulated inflammatory cells or systemically following their production in liver. Although structurally heterogeneous, these molecules share evolutionarily conserved functions, such as microbial opsonization as well as activation and regulation of the complement system (8). Historically established as a cascade of antimicrobial proteins in the blood, complement is now appreciated as a network of interacting fluid-phase and cell surface-associated molecules (PRMs, convertases and other proteases, regulators, and signaling receptors) that trigger, amplify, and regulate immunity and inflammation (9). The complement cascade is triggered by distinct mechanisms (classical, lectin, or alternative) that converge at the third component (C3) and lead to the generation of effectors with diverse functions (e.g., recruitment and activation of inflammatory cells via the C3a and C5a anaphylatoxins that activate specific G-protein-coupled receptors; microbial opsonization through C3b; and direct lysis of susceptible targeted microbes by means of the C5b-9 membrane attack complex) (9). During an infection, complement and TLRs are rapidly activated to provide critical frontline defense and act as key mediators between innate and adaptive immunity (10). Interestingly, several microbial products, including LPS (TLR4 agonist), zymosan (TLR2/6 agonist) and CpG DNA (TLR9 agonist), can activate complement in addition to initiating TLR signaling (11, 12). Therefore, an appropriately coordinated host immune response would necessitate signaling crosstalk between TLR and complement pathways, leading to synergistic or antagonistic interactions. Synergistic pathways can enhance the sensitivity of detection, since even individually weak stimuli can potentially combine to elicit a robust immune response. Conversely, antagonistic pathways can augment the specificity of the host response by controlling it and preventing bystander tissue damage (13). Typical examples for these contrasting functions include the cooperation between TLR2 and the C-type lectin dectin-1 for effective anti-fungal immunity (14) and the homeostatic suppression of TLR-induced pro-inflammatory responses by adenosine receptors (15, 16). This review summarizes recent literature on the biological importance of complement–TLR crosstalk pathways. Such pathways lead to diverse effects raging from reinforcement of innate immunity to exacerbation of pathologic inflammation or, conversely, regulation of unwarranted inflammation, depending on the receptors involved and the cellular context. Moreover, mechanisms that allow the interplay between complement and TLRs can be potentially exploited by certain pathogens to modulate the host response in ways that favor pathogen survival and persistence. Regulation of immune and inflammatory responses by complement-TLR cooperation As alluded to above, complement and TLRs are swiftly co-activated in response to microbial infection, while common microbial molecules (such as LPS and CpG DNA) can act as both TLR ligands and complement activators (9). At the cellular level, signaling crosstalk interactions between complement and TLRs have been shown in several cell types, including monocytes, macrophages, neutrophils, and dendritic cells (17–22). In vivo, the early innate immune response is shaped, to a large extent, by bidirectional crosstalk between the two systems (10). In perhaps the first in vivo systematic study to dissect complement-TLR crosstalk pathways, the authors employed systemic administration of different TLR ligands to mice lacking decay-accelerating factor (DAF), a major membrane-associated complement inhibitor. Specifically, LPS (TLR4), zymosan (TLR2/6), and CpG oligodeoxynucleotide (TLR9) all induced significantly higher tumor necrosis factor (TNF), interleukin-1β (IL-1β), and IL-6 responses compared to the same ligands given to wild-type mice (12). Similarly, mice systemically co-treated with TLR ligands and cobra venom factor, a potent complement activator, elicited remarkably high plasma levels of proinflammatory cytokines, further supporting that complement can amplify inflammation in co-operation with TLR signaling (12). Further work revealed a critical involvement of the anaphylatoxin receptors (C3aR and C5aR1 [CD88]) in the complement-TLR synergism for enhanced production of pro-inflammatory and antimicrobial mediators (12, 23). The signaling pathways involved in complement-TLR crosstalk converge at the level of mitogen-activated protein kinases (MAPK), specifically extracellular signal-regulated kinase-1 (ERK1), ERK2 and JUN N-terminal kinase (JNK), which activate the transcriptional factors nuclear factor-κB (NF-κB) and activator protein-1 (AP-1) (12) (Figure 1). Although this synergy could potentially enhance innate immune defenses against infection, it may also contribute to inflammatory pathology. For instance, complement-TLR synergy may actually account for earlier observations that the inhibition of C5a signaling protects against sepsis induced by high-dose LPS or by cecal ligation and puncture (CLP) peritonitis (24). Moreover, the synergistic complement–TLR interaction seen in DAF-deficient mice might explain, at least in part, why DAF-deficient mice are particularly susceptible to inflammatory and autoimmune diseases (25). Complement-TLR crosstalk synergy has also been demonstrated at mucosal sites. Indeed, in the murine gingival tissue, the concomitant activation of C5aR and TLR2 by local co-injection of specific agonists (C5a and the TLR2 ligand Pam3Cys) induced significantly higher levels of TNF, IL-1β, IL-6, and IL-17A mRNA and protein than activation of each receptor alone (26). In fact, destructive periodontal inflammation appears to depend on synergy between C5aR1 and TLR2, since mice deficient in either C5aR1 or TLR2 are essentially resistant against inflammatory bone loss in the periodontium (27, 28). Consistently, treatment of mice subjected to experimental periodontitis with PMX-53, a C5aR1 antagonist, inhibits periodontal inflammation (TNF, IL-1β, IL-6, and IL-17) and bone loss, regardless of the presence of TLR2 (i.e., inflammatory bone loss can be effectively inhibited by blocking just one of the two crosstalking receptors) (26). However, in other experimental systems, where interactions might be partially synergistic or additive, combined inhibition of complement and PRRs may be more effective than inhibition of each system alone. For instance, in a human whole-blood model, combined inhibition of complement and CD14 was shown to be more effective in blocking E. coli-induced cytokine responses than single inhibition (29, 30). CD14 lacks a transmembrane signaling domain but acts as a critical co-receptor of TLRs (mostly TLR4 and TLR2) (3), although it might also have TLR-independent effects that contribute to inflammation. Another study in the human whole-blood model focused on interactions between complement and TLR9 signaling induced by CpG oligodeoxynucleotides, which are considered as vaccine adjuvants (11). These investigators showed that complement inhibition at C3 suppresses both DNA-backbone-mediated maturation of antigen-presenting cells (upregulation of CD40 and CD83) and DNA-sequence-specific induction of cytokines. Interestingly, a CpG oligodeoxynucleotide (CpG-2006) could trigger the classical and the alternative pathway of complement, which in turn promoted the cellular uptake of CpG-2006 (11). Therefore, the immunostimulatory function of oligodeoxynucleotides such as CpG-2006, seems to be reliant upon the combined activation of complement and TLR9. Although C5aR1 synergizes with TLR2 for IL-17A induction in experimental mouse periodontitis (26), C5aR1 downregulates IL-17A in endotoxic shock in mice (21). It is uncertain whether this difference can be attributed to the different disease models or the different TLRs involved (TLR2 vs. TLR4). Intriguingly, C5aR1 promotes the induction of another IL-17 isoform (IL-17F) in endotoxic shock (31). In this regard, C5aR1 synergizes with TLR4 for IL-17F production in mouse macrophages via a MyD88- phosphatidylinositol-3 kinase (PI3K)-Akt pathway (31), whereas the same C5aR1-TLR4 crosstalk in the same cell type inhibits IL-17A production (21) (Figure 2). According to this study, the major source of IL-17A during endotoxemia in mice was not the ‘usual suspects’ (CD4+ T cells, γδ T cells, or NK cells) but rather CD11b+F4/80+ macrophages (21). Mechanistically, C5a was shown to activate PI3K-Akt and mitogen-activated protein kinase kinases 1/2 (MEK1/2)-ERK1/2 pathways, resulting in C5aR1 (but not C5aR2)-dependent induction of IL-10, which subsequently inhibits production of IL-17A (as well as IL-23) (21) (Figure 2). Because IL-17F has considerably reduced bioactivity as compared to IL-17A (32), C5a appears to shift the IL-17A – IL-17F balance toward the less bioactive molecule to mitigate excessive inflammation in acute conditions. However, it is currently unclear why C5aR1-induced IL-10 inhibits IL-17A preferentially over IL-17F. The relatively recently discovered C5aR2 (also referred to as C5a-like receptor 2; GPR77) functions as an alternative high-affinity receptor for C5a (33). Owing to its inability to productively couple to G proteins, C5aR2 was originally perceived as a non-signaling decoy receptor that could compete with C5aR1 for C5a binding, thereby mitigating C5a-dependent inflammation (34, 35). Consistently, upon pulmonary immune complex injury, C5aR2-deficient mice display increased lung inflammation (as revealed by elevated TNF and IL-6 responses and neutrophil recruitment) compared to wild-type controls, although the authors did not rule out G-protein-independent anti-inflammatory signaling downstream of C5aR2 (36). Subsequent studies indeed showed that C5aR2 might also play active, yet complex and poorly understood, roles in inflammation regulation including crosstalk interactions with TLRs (37–40). In the latter regard, C5aR2-deficient mice exhibited increased survival rates compared with wild-type controls after cecal ligation and puncture-induced sepsis (38). Rather than antagonizing C5aR1, C5aR2 synergizes with C5aR1 to cause sepsis by inducing the expression of the mobility group box 1 (HMGB1) protein (38). Interestingly, the induction of HMGB1 by LPS and C5a, or by LPS alone, is diminished in C5aR2-deficient macrophages. This finding suggests involvement of possible C5aR2–TLR4 crosstalk in the induction of HMGB1 that appears to require mitogen-activated protein MEK1/2, JNK1/2 and PI3K (38). Moreover, C5aR2 was shown to mediate C5a-induced activation of mast cells (41) and to promote atherosclerosis and neointimal plaque formation in apolipoprotein E-deficient mice (42). In contrast to these pro-inflammatory roles by C5aR2, other studies showed that C5aR2 interacts physically with and negatively regulates C5aR1 signaling in neutrophils and macrophages (39, 43), thereby providing a mechanistic basis for its reported anti-inflammatory action (36). In toto, the activities of C5aR2 appear to be dynamic and contextual depending on cell type, tissue, and disease model (44). In macrophages, complement receptor 3 (CR3; CD11b/CD18) can regulate the signaling activity of TLRs that utilize Mal (MyD88-adaptor like; also known as Toll/IL-1R(TIR)-domain-containing adaptor protein; TIRAP) as an adaptor, i.e., TLR2 and TLR4 (45) (Figure 3). Specifically, outside-in signaling by CR3 leads to activation of ADP ribosylation factor 6 (ARF6) and induction of phosphatidylinositol-(4,5)-bisphosphate (PIP2) production by phosphatidylinositol 5-kinase (PI5K), thereby promoting the targeting of Mal to membrane-bound PIP2 through its PIP2-binding domain. Mal can subsequently facilitate the recruitment of MyD88 to either TLR2 or TLR4 for initiation of MyD88-dependent signaling (45) (Figure 3). On the other hand, an independent study showed that CR3 may negatively regulate TLR-mediated inflammatory responses in macrophages by activating Syk and promoting degradation of MyD88 and TRIF via the E3 ubiquitin ligase Cbl-b (46) (Figure 3). Moreover, CR3 activation by a small-molecule allosteric agonist was shown to induce MyD88 degradation in macrophages also downstream of TLR7 and TLR8, thereby inhibiting TLR7/8-induced production of TNF (47). Intriguingly, this regulatory effect of CR3 was abrogated in macrophages expressing a genetic variant of CR3 (specifically a missense polymorphism, R77H, of CD11b) (47), which has been identified as a risk factor in systemic lupus erythematosus (48). It could thus be suggested that this mechanism may contribute to the pathogenesis of systemic lupus erythematosus, where RNA-containing immune complexes can readily trigger TLR7/8-mediated inflammation. Taken together, the above-discussed studies indicate that CR3 can exert both positive and negative regulation of TLR signaling by controlling the localization and/or degradation of TLR adaptors, although the contextual basis of these contrasting effects is not clear. TLR regulation of expression of complement components The previous section discussed several studies showing that complement receptors (e.g., C3aR, C5aR1, and CR3) regulate TLR-dependent responses, such as those induced by LPS (12, 21, 31, 45, 46). Reciprocally, TLR activation induces the expression of complement components, thereby potentially contributing to enhance complement activity in an inflammatory environment (49–52). For example, LPS induces robust production and release of factor B of the alternative pathway in macrophages (a major source of extra-hepatic complement synthesis) through a TLR4-TRIF pathway that leads to JNK and NF-κB activation (49). The same study showed that the double-stranded RNA analog polyI:C (a typical TLR3 agonist) also stimulates factor B production in macrophages via a JNK- and NF-κB-dependent mechanism; however, this pathway was not mediated by TLR3, suggesting the involvement of alternative receptors for polyI:C, such as the cytosolic sensors MDA-5 and RIG-I (49). An independent study showed that polyI:C induces factor B expression also in colonic epithelial cells, albeit via a TLR3-dependent mechanism (50). Importantly, the expression of factor B mRNA and protein is significantly enhanced in colonic biopsies of patients with ulcerative colitis and Crohn's disease as compared to healthy controls (50). Therefore, upon TLR stimulation, innate immune and epithelial cells can locally produce a critical component for alternative complement activation, which can in turn further amplify TLR-mediated responses. Although this positive feedback loop may contribute to host defense, the same mechanism could exacerbate pathology in diverse settings, such as inflammatory bowel disease and ischemia/reperfusion. In the latter condition, TLRs can respond to endogenous ligands released from stressed/ischemic tissues and local production of factor B (e.g., by cardiomyocytes in the context of myocardial infarction) may potentially contribute to complement-mediated injury during ischemia (53). Intestinal ischemia/reperfusion induces the expression of factor B and C3 in the gut of wild-type but not TLR4-deficient mice, which exhibit reduced inflammation and tissue damage (52). Administration of a complement inhibitor, CR2-Crry, during reperfusion ameliorated intestinal tissue damage in wild-type mice but did not further inhibit tissue damage in TLR4-deficient mice (52). These findings suggest that ischemia/reperfusion-induced tissue damage in this model requires a crosstalk involving TLR4 regulation of local production of complement, which in turn amplifies TLR4-mediated inflammation. A more recent study showed that, in addition to polyI:C and LPS, Pam3Cys activation of TLR2 (though not CpG activation of TLR9) also induces factor B production and release in macrophages and cardiac cells (51). Moreover, induction of polymicrobial sepsis by cecal ligation and puncture in mice was shown to increase the levels of factor B (in serum, peritoneal cavity, heart and other organs) in an MyD88-dependent manner, whereas genetic ablation of factor B reduced complement activation during sepsis, attenuated organ injury and improved survival (51). This study lends further support that factor B acts downstream of TLR activation and that bacterial sepsis is largely dependent on complement-TLR crosstalk. Modified low-density lipoprotein (mLDL) regulates the expression and release of C3 in macrophages by acting on TLR4 and liver X receptor (54). Specifically, uptake of mLDL by macrophages results in formation of oxysterols that activate Lliver X receptor-dependent transcription of target genes including C3. Moreover, on the cell surface, mLDL interacts with CD14 and TLR4 leading to induction of MEK1/2-ERK1/2-dependent C3 mRNA expression and NF-κB-dependent C3 protein secretion. Furthermore, subsequent activation of C3 leads to C3a activation of C3aR signaling that promotes mLDL uptake by macrophages, thereby reinforcing this positive regulatory feedback loop (54). As complement, TLRs, and mLDL metabolism are involved in atherosclerosis (55), this mechanism may be a contributing factor to the development of atherosclerotic lesions. Interestingly, TLR signaling suppresses the desensitization of GPCRs by downregulating the expression of G-protein-coupled receptor kinases, which induce GPCR phosphorylation and internalization, thereby potentially prolonging the activation of C3aR and C5aR1 (56). Moreover, TLR-induced cytokines, such as IL-6, promote the expression of C3aR and C5aR (57). In summary, TLRs regulate the expression of complement factors as well as the expression and/or activation of complement receptors, which in turn can amplify or limit TLR-dependent responses. Subversion of innate immunity by pathogen-induced complement-TLR crosstalk Periodontitis is a chronic inflammatory disease of the tooth-supporting tissues (periodontium) that is induced by local dysbiotic polymicrobial communities (58). These communities form on subgingival tooth sites and appear to have evolved collective strategies that enable them to persist in an inflammatory environment (59). A formidable challenge for these bacteria is to evade killing without resorting to immune suppression, as this would inhibit inflammation and hence limit their food supply, which is derived from inflammatory tissue breakdown (60). This selective pressure might be responsible for the development of some highly sophisticated microbial tactics, which represent new paradigms in immune evasion and are reviewed below. Immune subversion by periodontal bacteria Porphyromonas gingivalis, a low-abundance gram-negative bacterium associated with periodontitis, was shown to exert a disproportionately high impact on the dysbiotic transformation of periodontal microbial communities, thereby behaving as a keystone pathogen (61, 62). Specifically, P. gingivalis can subvert the innate host response in ways that alter the numbers and composition of the microbiota, that is, causing dysbiosis (63). The overgrowth of a subset of species, including inflammophilic pathobionts, leads to destructive periodontal inflammation and bone loss (59–61). The manipulation of the host response by P. gingivalis is based, at least in part, on its capacity to instigate subversive crosstalk interactions between complement and TLRs. For instance, P. gingivalis can induce a C5aR1-TLR2 crosstalk in neutrophils to uncouple bacterial immune clearance from inflammation (19) (Figure 4A), which creates a nutritionally favorable environment for the bacteria as they can feed off the inflammatory spoils (e.g., degraded collagen peptides and heme-containing compounds, a source of iron) (60, 64). In addition to stimulating TLR2, P. gingivalis can directly activate C5aR1 (i.e., independently of complement activation) through the action of its gingipains that can locally cleave C5 to generate C5a ligand (27, 65). In both human and mouse neutrophils, the P. gingivalis-instigated C5aR-TLR2 signaling crosstalk triggers ubiquitination and proteasomal degradation of the TLR2 adaptor MyD88, leading to suppression of downstream antimicrobial effects that would otherwise clear this bacterium (19, 66, 67) (Figure 4A). Although MyD88 induces also proinflammatory signaling for NF-κB activation, the nutritionally favorable inflammatory response is not abrogated but instead mediated by an alternative TLR2 adaptor, Mal (MyD88 adaptor-like). In this pathway, Mal activates PI3K which mediates a robust inflammatory response. Indeed, genetic ablation or pharmacological inhibition of Mal or PI3K suppresses the induction of pro-inflammatory cytokines by neutrophils in vitro and in vivo (19). Moreover, P. gingivalis-induced Mal-PI3K signaling inhibits GTPase RhoA-dependent actin polymerization and hence P. gingivalis phagocytosis (19) (Figure 4A). These actions also promote the survival of bystander bacteria that are otherwise susceptible to neutrophil killing (19). Conversely, inhibition of PI3K or any of the two crosstalking receptors, C5aR1 or TLR2, in the periodontium of P. gingivalis-colonized mice promotes the elimination of P. gingivalis, reverses the increase in total microbiota counts induced earlier by P. gingivalis colonization, and blocks periodontal inflammation (19). Therefore, P. gingivalis manipulates neutrophils through distinct mechanisms that collectively promote the survival of the microbial community and the perpetuation of inflammation. P. gingivalis induces a C5aR1-TLR2 crosstalk also in macrophages, which are thereby impaired for intracellular killing of this bacterium (68). However, the signaling mechanisms involved are completely different from those operating in neutrophils. In macrophages, the P. gingivalis C5aR1-TLR2 crosstalk leads to synergistic production of high and sustained levels of cAMP, which suppresses nitric oxide-dependent killing of P. gingivalis (68). Specifically, elevation of cAMP leads to activation of protein kinase A (PKA), which inactivates glycogen synthase kinase-3β (GSK3β) and inhibits the expression of inducible nitric oxide synthase (iNOS), hence reducing the production of nitric oxide, a potent antimicrobial molecule (68) (Figure 4B). The P. gingivalis-induced C5aR1-TLR2 crosstalk additionally regulates cytokine expression in macrophages (27). Specifically, P. gingivalis selectively suppresses TLR2-induced IL-12p70 through a C5aR1-dependent mechanism involving ERK1/2 (Figure 1), whereas the same C5aR1-TLR2 crosstalk upregulates the production of proinflammatory cytokines (IL-1β, IL-6, and TNF), which appear to mediate inflammatory bone loss in a murine model of experimental periodontitis (27). Moreover, the ability of P. gingivalis to manipulate TLR2 activation via the C5a-C5aR1 pathway enables this microbe to inhibit the production of IL-12p70 and secondarily interferon (IFN)γ resulting in enhanced pathogen survival (27). Therefore, overall, P. gingivalis appears to inhibit both IFNγ-dependent priming of macrophages and their nitric oxide-dependent pathway for intracellular killing. The ability of complement to regulate TLR-induced IL-12 is a more general property that includes additional TLRs and IL-12-relates cytokines, such as IL-23. For instance, earlier work has shown that activation of C5aR1 in macrophages inhibits TLR4-induced mRNA expression of IL-12p35, IL-12/IL-23p40, IL-23p19 and IL-27p28, and production of IL-12, IL-23 and IL-27 proteins. The underlying mechanism involves induction of PI3K and ERK1/2 signaling, which in turn inhibit critical transcription factors (the IFN regulatory factors 1 and 8; IRF-1 and -8) that are required for expression of IL-12 family cytokines (12, 69, 70) (Figure 1). Similar but relatively attenuated inhibitory effects were observed after C3aR activation (12, 69). CR3 plays many and diverse roles in immunity and inflammation, including leukocyte transmigration and iC3b-mediated phagocytosis (71). Besides interacting with host molecules (iC3b, fibrinogen, and intercellular adhesion molecule-1 [ICAM-1]), CR3 can also interact with various microbial molecules, such as LPS, Bordetella pertussis filamentous hemagglutinin, Leishmania gp63, and P. gingivalis FimA fimbriae (72–76). In this regard, P. gingivalis FimA fimbriae can induce TLR2 inside-out signaling which transactivates the high-affinity conformation and hence the ligand-binding capacity of CR3 (77, 78). The interactions of CR3 on monocytes or macrophages with P. gingivalis lead to induction of proinflammatory cytokines (TNF, IL-1β, and IL-6) (75, 79) and promotion of ICAM-1-dependent monocyte transmigration across endothelial cell monolayers (80). Intriguingly, the aforementioned TLR2-CR3 crosstalk is exploited by P. gingivalis for a relatively safe entry and persistence in macrophages (81). Indeed, the intracellular survival of P. gingivalis is significantly reduced in CR3-deficient (CD11b−/−) mouse macrophages, suggesting that CR3-mediated phagocytosis of P. gingivalis prevents or ameliorates its killing (81). This finding is in line with observations that CR3 is not linked to vigorous microbicidal mechanisms, in contrast to certain other phagocytic receptors, such as Fcγ receptor III (CD16) (82–85). Indeed, in macrophages, CR3-derived phagosomes do not fuse with lysosomes as readily as CD16-derived phagosomes (86). The relatively mild post-phagocytic events downstream of CR3 are consistent with its role in the phagocytosis of iC3b-opsonized apoptotic cells, which entail minimal ‘danger’ as compared to pathogen infection (87, 88). Accordingly, upon phagocytosis of apoptotic cells, the production of IL-12 in efferocytic macrophages is suppressed (87) (Figure 5). Similarly, direct CR3 binding by P. gingivalis FimA fimbriae mitigates TLR2-induced IL-12 via outside-in signaling that induces ERK1/2-dependent inhibition of IL-12p35 and IL-12/IL-23p40 mRNA expression (89) (Figure 5). Consistent with this mechanism, CR3 blockade in a mouse peritonitis model (induced by i.p. injection of P. gingivalis) promotes IL-12-dependent clearance of P. gingivalis. Moreover, CR3-deficient mice are superior to wild-type controls in controlling P. gingivalis i.p. infection owing to elevated production of IL-12 and, secondarily, IFN-γ, a major activator of intracellular killing (89). Although P. gingivalis can exploit C5aR1 in neutrophils and macrophages to suppress their antimicrobial functions (19, 68), as well as bind CR3 for a safe entry into macrophages (81), the same receptors on dendritic cells do not seem to enhance the intracellular persistence of P. gingivalis (90). In stark contrast, C5aR1 promotes the intracellular killing of P. gingivalis in dendritic cells, whereas CR3 does not function as a phagocytic receptor for P. gingivalis. Similar to C5aR1, C3aR enhances the intracellular killing of P. gingivalis in dendritic cells. In contrast to C5aR1, C5aR2 is associated with increased intracellular survival of P. gingivalis in macrophages, consistent with the notion that C5aR2 can – in a certain context - downregulate the activity of C5aR1 (39, 43). The differential effects of C5aR1 in dendritic cells as compared to macrophages might be attributed to differential regulation of the cAMP response in these two leukocyte types. As outlined above for macrophages, activation of C5aR1 leads to high levels of intracellular cAMP and thus PKA activation, which is critical for inhibiting nitric oxide-dependent killing of P. gingivalis (68). In dendritic cells, on the other hand, C5aR1 suppresses cAMP production and hence the activation of PKA (91). C3aR – which also facilitates intracellular killing of P. gingivalis in dendritic cells (90)– similarly inhibits the cAMP-PKA pathway (92). As both C3aR and C5aR1 activate Gαi protein-mediated signaling, it is not clear why the same receptors have different effects on the cAMP responses in macrophages versus dendritic cells.. However, some insights could be discussed at least at a theoretical level. Following activation of Gαi, the released Giβγ subunits regulate the production of cAMP by adenylate cyclase, either positively or negatively depending upon the specific enzyme isoform (93). The isoforms of adenylate cyclase isoforms that are positively regulated by Giβγ are different from those that are sensitive to the inhibitory action of Gαi (93). Thus, it can be reasoned that dendritic cells and macrophages express distinct isoforms of adenylate cyclase, thus C3aR- or C5aR-induced Gαi signaling has different effects on the regulation of the enzyme isoforms. Another cell type-specific difference is that whereas C5a inhibits P. gingivalis-induced IL-12p70 in macrophages (27), C5a promotes P. gingivalis-induced IL-12p70 in dendritic cells (90). The C5a-induced inhibition of IL-12p70 by P. gingivalis is mediated by ERK1/2 signaling (27), consistent with an earlier report that C5a-induced ERK1/2 signaling inhibits enterobacterial lipopolysaccharide-induced IL-12p70 in macrophages (69). Whereas C5a induces ERK1/2 signaling also in dendritic cells (94), the ERK1/2 pathway in this cell type upregulates, rather than inhibits, IL-12p70 production (95). Despite its ability to transactivate and bind CR3 in macrophages, P. gingivalis fails to utilize CR3 as a phagocytic receptor in dendritic cells (90). The reason for this difference is not understood, although a study has suggested that CR3 cannot be readily transactivated in dendritic cells (96). Therefore, C3aR, C5aR1, and CR3, mediate cell-type-specific effects on how innate leukocytes handle P. gingivalis. Since dendritic cells are not as potent in pathogen destruction as compared to neutrophils or macrophages (97), it appears paradoxical that P. gingivalis can exploit complement receptors in neutrophils and macrophages more efficiently than it does in dendritic cells. However, given the abundance of complement cleavage products in the periodontal pocket (98), it makes sense from an evolutionary perspective that P. gingivalis developed complement-dependent evasion mechanisms against those leukocyte types that are most often encountered in its niche. Indeed, the immediate threat to P. gingivalis in its predominant niche, the periodontal pocket, is represented by neutrophils and secondarily by macrophages, which predominate in the leukocyte infiltrate of the periodontal pocket over other leukocyte types (99). Immune subversion by other pathogens The TLR2–CR3 crosstalk pathway may be exploited by additional pathogens. Mycobacteria and spores of Bacillus anthracis can both induce TLR2 inside-out signaling for transactivating and binding CR3, thereby promoting their uptake via CR3 (100, 101). It is thought that the ability of Mycobacterium tuberculosis to parasitize within macrophages may, in part, be reliant on its capacity to stimulate TLR2-induced CR3 uptake (101). Moreover, CR3-deficient mice display enhanced resistance to infection with B. anthracis spores. The susceptibility of wild-type mice in this model was attributed to enhanced uptake of B. anthracis spores and their carriage by the macrophages to sites of spore germination and bacterial growth (100). Upon opsonization with iC3, Francisella tularensis also uses CR3 for efficient macrophage uptake and the resulting outside-in signaling suppresses TLR2-mediated and MAPK-dependent pro-inflammatory responses, thereby promoting the pathogenesis of F. tularensis infection (102). The crosstalk of CR3 with the TLR system is bidirectional since, as discussed above, CR3 also regulates TLR signaling (45, 46). In line with this notion, a recent study has shown CR3 regulation of TLR8 responses in dendritic cells. Indeed, whereas free HIV-1 induces robust TLR8-dependent inflammatory and anti-viral responses (induction of p38, ERK, and NF-κB pathways and activation of IFN regulatory factors 1 and 7) in immature dendritic cells, iC3b-opsonized HIV interacts with CR3 leading to CR3-TLR8 crosstalk that modulates the host response in a way that enhances viral transcription (103). In addition to CR3, gC1qR, a complement receptor for C1q, also suppresses TLR4-induced IL-12 in human monocytes (104) (Figure 5). This regulatory effect is mediated via PI3K signaling and is selective for IL-12 in that TNF, IL-6, and IL-8 are not impacted. However, this crosstalk appears to be exploited by the hepatitis C virus whose core protein acts as a ligand for gC1qR to inhibit IL-12 production and Th1 immunity (105) (Figure 5). The complement regulatory receptor CD46 also engages in a similar crosstalk with TLR4. Indeed, upon binding C3b dimers, CD46 inhibits LPS-induced IL-12 production in monocytes (106). The measles virus interacts with CD46 and thereby inhibits IL-12 production and cell-mediated immunity (106) (Figure 5). The underlying signaling mechanism is uncertain. However, a post-transcriptional mechanism was implicated in a study with human herpesvirus-6, which similarly uses CD46 as a cellular receptor to suppress TLR4-induced IL-12 (107). Concluding remarks and outlook The literature summarized in this review reveals an intricate interplay between complement and TLRs for regulating the expression and activation of critical components of the two systems, thereby contributing to the coordination of host immune and inflammatory responses. These bidirectional interactions range from antagonistic to synergistic (Figures 1–5) and can therefore enhance host immunity and inflammation to clear infections, or can dampen host responses to ameliorate exaggerated inflammation and tissue damage. In the latter case, future therapies for inflammatory or autoimmune diseases could focus on inhibiting either complement or TLRs, or both systems, depending on tissue or disease context (108–110). However, there may be instances where combined inhibition may have unfavorable outcomes. Indeed, although both complement and TLR2 induce inflammation in the context of renal ischemia/reperfusion (mice deficient in either factor B or TLR2 are protected from ischemic acute kidney injury), mice doubly deficient in factor B and TLR2 develop severe inflammatory tissue injury (111). These data suggest that, in this model, complement and TLR2 may also induce compensatory anti-inflammatory signals, the absence of which in the doubly deficient mice may have detrimental effects. Some crosstalk interactions between complement and TLRs appear to be proactively instigated by pathogens ostensibly to dysregulate or modify the host response in ways that favor their persistence, often with concomitant collateral tissue damage. For instance, by inducing a C5aR1-TLR2 crosstalk, periodontal bacteria can disengage immune bacterial clearance from inflammation (Figure 4), thereby contributing to the persistence of ‘inflammophilic’ communities of pathobionts that exacerbate polymicrobial inflammatory diseases, such as periodontitis (19). In this context, novel and potentially effective approaches may be to interfere with the host signaling circuitry that is exploited for microbial subversion of the immune response. Although this review has focused on innate immunity, complement-TLR interactions also impact on adaptive immunity. An important mechanism in this regard involves signaling crosstalk in antigen-presenting cells between C5aR1 and TLR4 which downregulates the expression of IL-12 family cytokines (IL-12, IL-23, and IL-27) (Figure 1) involved in the regulation of distinct T-cell subsets (Th1, Th2, and Th17) (12, 17, 69, 70, 112). The role of C5aR1 signaling in regulating T cell immunity in co-operation with TLRs is complex and contextual, as it can lead to different outcomes depending on the maturation stage of the antigen-presenting cell (20) or the type of crosstalking TLR (112). Moreover, cell type- and species-specific differences have been noted and reviewed elsewhere (17, 113–115)). The complex – and still incompletely understood – crosstalk interactions of complement with TLRs (and other systems reviewed elsewhere (9)) apparently aim to fine-tune a balance between homeostatic immunity and inflammatory pathology. Future research to further dissect the molecular mechanisms of complement-TLR crosstalk and their contextual nature may contribute to the design of novel approaches to maximize the beneficial and minimize the detrimental aspects of these interactions. The authors are supported by grants from the U.S. National Institutes of Health: DE015254, DE017138, DE021685, and DE024716 (GH); AI003040 and AI068730 (JDL) and the European Community’s Seventh Framework Programme under grant agreement number 602699 (DIREKT) (JDL). Figure 1 Synergistic and antagonistic interactions between complement and TLRs Complement and TLRs are co-activated in response to microbial infection. Complement anaphylatoxin receptor signaling induced by C3a or C5a synergizes with TLR signaling resulting in enhanced activation of MAPKs and transcription factors, such as NF-κB and AP-1, resulting in upregulation of proinflammatory cytokine expression. TLRs are activated by MAMPs, some of which (e.g., LPS and zymosan) can additionally co-activate complement. In contrast, complement can downregulate TLR-induced cytokines of the IL-12 family. Activation of C5aR1 by C5a suppresses TLR-induced mRNA expression of IL-12p35, IL-12/IL-23p40, IL-23p19, and IL-27p28 (hence production of bioactive IL-12, IL-23, and IL-27) in monocytes/macrophages. The underlying signaling mechanism involves induction of PI3K or ERK1/2 signaling, which in turn suppress crucial transcription factors (IRF-1 and IRF-8) that regulate these cytokines. Figure 2 C5aR1 regulation of IL-17 isoforms in LPS-activated macrophages C5aR1 and TLR4 promote the induction of IL-17F in mouse macrophages via a MyD88-PI3K-Akt pathway. On the other hand, C5a-induced activation of C5aR1 activates PI3K-Akt and MEK1/2-ERK1/2 pathways that lead to induction of IL-10, which subsequently inhibits production of IL-17A. Figure 3 TLR–CR3 crosstalk pathways CR3 can regulate the signaling activity of TLRs that utilize Mal as an adaptor, i.e. TLR2 and TLR4. Specifically, outside-in signaling by CR3 leads to activation of ADP ribosylation factor 6 (ARF6) and induction of phosphatidylinositol-(4,5)-bisphosphate (PIP2) production by phosphatidylinositol 5-kinase (PI5K). This in turn promotes the targeting of Mal, which has PIP2-binding domain, to membrane-bound PIP2. Mal in turn facilitates the recruitment of MyD88 to either TLR2 or TLR4 to initiate pro-inflammatory signaling. Moreover, CR3 outside-in signaling stimulates ITAM-coupled activation of the tyrosine kinases Src and Syk. Syk in turn binds and phosphorylates MyD88 and TRIF, which are thereby targeted by the E3 ubiquitin ligase Cbl-b for proteolytic cleavage. Figure 4 P. gingivalis-induced C5aR1-TLR2 crosstalk in neutrophils and macrophages P. gingivalis expresses ligands that activate the TLR2–TLR1 complex (TLR2/1) and enzymes (HRgpA and RgpB gingipains) with C5 convertase-like activity that generate high local concentrations of C5a ligand. The bacterium can thus co-activate C5aR and TLR2 in (A) neutrophils and (B) macrophages. In neutrophils (A), the resulting crosstalk leads to ubiquitination and proteasomal degradation of the TLR2 adaptor MyD88, thereby inhibiting a host-protective antimicrobial response. This proteolytic event requires C5aR1-TLR2-dependent release of TGF-β1, which mediates MyD88 ubiquitination via the E3 ubiquitin ligase Smurf1 (enlarged inset). Moreover, the C5aR1-TLR2 crosstalk activates PI3K, which inhibits phagocytosis through suppression of RhoA GTPase and actin polymerization, while inducing inflammatory cytokine production. In contrast to MyD88, Mal contributes to immune subversion by acting upstream of PI3K. In macrophages (B), P. gingivalis activates C5aR1 and induces intracellular Ca2+ signaling which synergistically enhances the otherwise weak cAMP responses induced by TLR2 activation alone. The resulting activation of the cAMP-dependent protein kinase A (PKA) inhibits NF-κB and glycogen synthase kinase-3β (GSK3β), thereby suppressing inducible nitric oxide synthase (iNOS)-dependent killing of the pathogen in macrophages. Figure 5 Immune evasion via complement-mediated suppression of TLR-induced IL-12 production The crosstalk between the indicated complement receptors (C5aR1, CR3, gC1qR and CD46) and TLRs selectively inhibits the induction of IL-12 in macrophages. Signaling molecules that have been implicated, such as ERK1/2, IRF-1, IRF-8 and PI3K, are shown downstream of the corresponding receptors. A posttranscriptional mechanism might be involved in IL-12 regulation by CD46. Activation of these complement receptors by their natural ligands likely mediates homeostatic functions. However, the same receptors can be activated by bacteria or viruses (see text for details) which can thereby downregulate TLR-induced IL-12 production and hence IFNγ to suppress cell-mediated immunity. HCV, hepatitis C virus; MV, measles virus. The authors declare no conflicting financial interests. 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PMC005xxxxxx/PMC5120389.txt
LICENSE: This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. 0376331 5212 J Psychiatr Res J Psychiatr Res Journal of psychiatric research 0022-3956 1879-1379 25263276 5120389 10.1016/j.jpsychires.2014.09.007 NIHMS831058 Article Association between mental disorders and subsequent adult onset asthma Alonso Jordi 123 de Jonge Peter 4 Lim Carmen C. W. 5 Aguilar-Gaxiola Sergio 6 Bruffaerts Ronny 7 Caldas-de-Almeida Jose Miguel 8 Liu Zhaorui 9 O'Neill Siobhan 10 Stein Dan J. 11 Viana Maria Carmen 12 Al-Hamzawi Ali Obaid 13 Angermeyer Matthias C. 14 Borges Guilherme 15 Ciutan Marius 16 de Girolamo Giovanni 17 Fiestas Fabian 18 Haro Josep Maria 192021 Hu Chiyi 22 Kessler Ronald C. 23 Lépine Jean Pierre 24 Levinson Daphna 25 Nakamura Yosikazu 26 Posada-Villa Jose 27 Wojtyniak Bogdan J 28 Scott Kate M. 29 1 Health Services Research Unit, IMIM (Hospital del Mar Medical Research Institute), Barcelona, Spain 2 CIBER Epidemiología y Salud Pública (CIBERESP), Spain 3 Pompeu Fabra University (UPF), Barcelona, Spain 4 Interdisciplinary Center Psychopathology and Emotion Regulation, University Medical Center, University of Groningen, Groningen, The Netherlands 5 Department of Psychological Medicine, Otago University, Dunedin, New Zealand 6 University of California, Davis, Center for Reducing Health Disparities, School of Medicine, Sacramento, California, USA 7 Universitair Psychiatrisch Centrum - Katholieke Universiteit Leuven (UPC-KUL), Leuven, Belgium 8 Chronic Diseases Research Center (CEDOC) and Department of Mental Health, Faculdade de Ciencias Medicas, Universidade Nova de Lisboa, Lisbon, Portugal 9 Institute of Mental Health, Peking University, Beijing, and People’s Republic of China 10 Bamford Centre for Mental Health and Well-Being, University of Ulster, Derry, Northern Ireland 11 University of Cape Town Department of Psychiatry & Mental Health, Groote Schuur Hospital, Cape Town, South Africa 12 Department of Social Medicine, Federal University of Espírito Santo (UFES), Vitória, Brazil 13 Al-Qadisia University College of Medicine, Diwania, Iraq 14 Center for Public Mental Health, Gosing am Wagram, Austria 15 Division of Epidemiological and Psychosocial Research, National Institute of Psychiatry (Mexico) & Metropolitan Autonomous University, Mexico City, Mexico 16 National School of Public Health and Professional Development, Bucharest, Romania 17 IRCCS Centro S. Giovanni di Dio Fatebenefratelli, Brescia, Italy 18 Evidence Generation for Public Health Research Unit, National Institute of Health, Lima, Peru 19 Parc Sanitari Sant Joan de Déu, Sant Boi de Llobregat, Barcelona, Spain 20 CIBER de Salud Mental (CIBERSAM), Spain 21 University of Barcelona, Barcelona, Spain 22 Shenzhen Institute of Mental Health and Shenzhen Kangning Hospital, Guangdong Province, PR China 23 Department of Health Care Policy, Harvard Medical School, Boston, MA, USA 24 Hôpital Saint-Louis Lariboisière Fernand Widal, INSERM U 705, CNRS UMR 8206, Paris, France 25 Mental Health Services, Ministry of Health, Jerusalem, Israel 26 Department of Public Health, Jichi Medical University, Yakushiji, Shimotsuke-shi, Tochigi-ken, Japan 27 Colegio Mayor de Cundinamarca University, CALLE 28 No. 5B-02, Bogota, DC, Colombia 28 National Institute of Public Health-National Institute of Hygiene and Department-Centre of Monitoring and Analyses of Population Health, Warsaw, Poland 29 Department of Psychological Medicine, Otago University, Dunedin, New Zealand Corresponding author: Jordi Alonso, jalonso@imim.es, Health Services Research Unit, IMIM (Hospital del Mar Research Institute), C. Dr. Aiguader, 88, PRBB building, 08003 BARCELONA, Spain. Phone: (+34) 933 160 760, Fax: (+34) 933 160 797 20 11 2016 16 9 2014 12 2014 23 11 2016 59 179188 This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. Background and objectives Associations between asthma and anxiety and mood disorders are well established, but little is known about their temporal sequence. We examined associations between a wide range of DSM-IV mental disorders with adult onset of asthma and whether observed associations remain after mental comorbidity adjustments. Methods During face-to-face household surveys in community-dwelling adults (n = 52,095) of 19 countries, the WHO Composite International Diagnostic Interview retrospectively assessed lifetime prevalence and age at onset of 16 DSM-IV mental disorders. Asthma was assessed by self-report of physician’s diagnosis together with age of onset. Survival analyses estimated associations between first onset of mental disorders and subsequent adult onset asthma, without and with comorbidity adjustment. Results 1,860 adult onset (21 years+) asthma cases were identified, representing a total of 2,096,486 person-years of follow up. After adjustment for comorbid mental disorders several mental disorders were associated with subsequent adult asthma onset: bipolar (OR=1.8; 95%CI 1.3–2.4), panic (OR=1.4; 95%CI 1.0–2.0), generalized anxiety (OR=1.3; 95%CI 1.1–1.7), specific phobia (OR=1.4; 95%CI 1.2–1.6); post-traumatic stress (OR=1.5; 95%CI 1.1–2.0); binge eating (OR=1.9; 95%CI 1.2–2.9) and alcohol abuse (OR=1.5; 95%CI 1.2–2.0). Mental comorbidity linearly increased the association with adult asthma. The association with subsequent asthma was stronger for mental disorders with an early onset (before age 21). Conclusions A wide range of temporally prior mental disorders are significantly associated with subsequent onset of asthma in adulthood. The extent to which asthma can be avoided or improved among those with early mental disorders deserves study. Asthma Mental Disorders Population Epidemiology Chronic Disease Comorbidity INTRODUCTION Asthma is a major public health problem because a lifetime course and an increasing prevalence (Jenkins et al. 1994; Pearce et al. 2000). An association between asthma and some mental disorders, in particular, anxiety and depression has been shown (Goodwin et al. 2003a; Goodwin et al. 2004; Perna et al. 1997; Shavitt et al. 1992); (Opolski and Wilson, 2005; Toren et al. 2006). While some of the previous evidence was based in small number of countries, recent data have extended similar results to a large number of countries; (Jiang et al. 2013; Wong et al. 2013). Most of the studies showing an association between asthma and mental disorders were cross-sectional in nature, thus limiting their ability to infer the temporal relationship between asthma and mental disorders. Several longitudinal studies suggest that asthma in childhood is followed by some subsequent internalizing mental disorders (Alati et al. 2005; Goodwin et al. 2013; Ramos Olazagasti et al. 2012) and with suicidal ideation and suicide attempts (Goodwin and Eaton, 2005). On the other hand, a number of studies have shown a longitudinal association between psychological distress and atopic disorders, mostly asthma, both in children and adults (Chida et al. 2008); (Sanna et al. 2014). Only very few of these studies included comprehensive diagnostic measures of mental disorders (i.e., based on standard psychiatric diagnostic criteria such as the Diagnostic Statistical Manual (DSM)) for mood and anxiety (Hasler et al. 2005; Wainwright et al. 2007); and eating disorders (Goodwin et al. 2009; Scott et al. 2007; Scott et al. 2008). An additional limitation of previous research is that the influence of mental comorbidity in the association of mental disorders and asthma has not been analyzed in depth. Knowing whether anxiety or depression specifically is associated with asthma (after adjusting for comorbidity with the other) can guide research focused on the mechanisms underlying the association with asthma. We previously reported, based on a large international study including many mental disorders, that there was a concurrent association between 12-month mental disorders and lifetime asthma in many countries, regardless of the important variation in asthma prevalence in these countries (Scott et al. 2008). Associations were similar for anxiety, mood and alcohol abuse disorders. In those analyses we did not assess the effect of mental comorbidity and our focus was on associations between current mental disorders and asthma, rather than on associations between temporally prior mental disorders and subsequent onset of asthma. We therefore undertook analyses that considered the sequential order of the mental disorders and asthma comorbidity and reported that early onset (i.e., before age 21) mental disorders predicted subsequent onset of diagnosed adult onset asthma (i.e., after age 21), even after adjusting for childhood adversities, smoking and other relevant variables (Scott et al. 2008). However in these analyses, we included a limited set of mental disorders and we did not adjust for mental disorder comorbidity. Nor did we examine whether the association held true for mental disorders starting after the age of 21 and subsequent adult asthma. Therefore, we could not determine whether the associations found between early onset and subsequent asthma were reflecting the onset timing of these disorders (i.e., that they occur at critical developmental periods) or were because early disorders are a risk marker for comorbidity. Aims of the Study In this study we analyzed only asthma cases with onset in adulthoods (21+ years of age), as we wanted to test the antecedent model (Scott MK 2009) of mental disorders preceding asthma onset. This model suggests that mental disorders that start early in life and are chronic or recurrent, may have physiological effects akin to chronic stress, leading to Hypothalamus-Pituitary-Adrenal (HPA) dysregulation (Chida Y et al, 2008; Scott KM, 2009). This altered physiological stress response in turn has been associated with immune system dysfunction and increased inflammatory response. These mechanisms could facilitate asthma onset among susceptible individuals, along with the lifestyle risk factors also associated with mental disorders. By selecting only adult-onset asthma cases and conducting survival analyses based on person years only up to asthma diagnosis, this allowed us to investigate this specific temporal sequence from mental disorder to asthma diagnosis, albeit with the limitation of retrospective data. We did not include childhood asthma as it would be difficult for respondents to clearly recall the temporal priority of mental disorders and asthma symptoms. We therefore conducted the present study using a larger dataset from the World Mental Health (WMH) Surveys to examine the associations between first onset of 16 mood, anxiety, impulse control and substance use disorders with subsequent adult onset asthma. Our aims were to examine the influence of mental disorder comorbidity on these associations; to investigate whether the associations vary according to the age of mental disorder or asthma onset; and to assess whether they vary by gender. In this study we analyzed only asthma cases with onset in adulthood, as it helped ensure the temporal order of the association of interest: from prior mental disorders to subsequent asthma. For childhood onset of asthma, which is fairly common, it might be difficult for respondents to clearly recall the temporal priority of mental disorders and asthma symptoms. Thus, we improved accuracy of the estimation of the association between mental disorders and asthma, to the expense of some generalization. METHOD Samples and Procedures This study uses data from 19 of the WMH surveys: Colombia, Mexico, Peru, United States, Shenzhen (China), Japan, New Zealand, Belgium, France, Germany, Italy, the Netherlands, Romania, Spain, Portugal, Israel, Iraq, Northern Ireland, and Poland (see Table 1). A stratified multi-stage clustered area probability sampling strategy was used to select adult respondents (18 years+) in most WMH countries. Most of the surveys were based on nationally representative household samples while Colombia, Mexico and Shenzhen were based on nationally representative household samples in urbanized areas. In most countries, internal subsampling was used to reduce respondent burden and average interview time by dividing the interview into two parts. All respondents completed Part 1, which included the core diagnostic assessment of most mental disorders. All Part 1 respondents who met lifetime criteria for any mental disorder and a probability sample of other respondents were administered Part 2, which assessed physical conditions and collected a range of other information related to survey aims. Part 2 respondents were weighted by the inverse of their probability of selection for Part 2 of the interview to adjust for differential sampling. Analyses in this paper are based on the weighted Part 2 subsample (n= 52,095). Additional weights were used to adjust for differential probabilities of selection within households, to adjust for non-response, and to match the samples to population socio-demographic distributions. Measures taken to ensure interviewer and data accuracy and cross-national consistency are described in detail elsewhere (Kessler and Ustun, 2004). All respondents provided informed consent and procedures for protecting respondents were approved and monitored for compliance by the Institutional Review Boards in each country (Kessler and Ustun, 2004). Measures All WMH instruments were cross-culturally adapted following the standard WHO procedures of translation, back-translation, cognitive debriefing and harmonization to make sure data collected would be comparable across countries. Such procedures are described in detail (Kessler and Ustun, 2008). Mental disorders All surveys used the WMH survey version of the WHO Composite International Diagnostic Interview (CIDI 3.0) (Kessler and Ustun, 2004), a fully structured interview, to assess lifetime history of mental disorders. Disorders were assessed using the definitions and criteria of the DSM-IV (American Psychiatric Association, 2000). The mental disorders adjusted for in this paper include anxiety disorders (panic disorder, agoraphobia without panic, specific phobia, social phobia, post-traumatic stress disorder, generalized anxiety disorder, obsessive compulsive disorder); mood disorders (major depressive episode/dysthymia, bipolar disorders I, II and broad); substance use disorders (alcohol abuse and dependence, drug abuse and dependence); and impulse control disorders (intermittent explosive disorder, bulimia nervosa and binge eating disorder). The selection of these 16 mental disorders was based on their prevalence, including disorders only when there were sufficient numbers of cases to warrant reliable analyses. As a result, for instance anorexia nervosa had to be excluded. We considered early onset mental disorders those with an onset before age of 21 years. CIDI organic exclusion rules were applied in making diagnoses. Clinical reappraisal studies conducted in some of the WMH countries indicate that lifetime diagnoses of anxiety, mood and substance use disorders based on the CIDI have generally good concordance with diagnoses based on blinded clinical interviews (Haro et al. 2006). Asthma In a series of questions adapted from the U.S Health Interview Survey, respondents were asked about the lifetime presence of selected chronic conditions. Respondents were asked: “Did a doctor or other health professional ever tell you that you had any of the following illnesses….asthma?” Clinical guidelines as those issued by the American Thoracic Society, recommend a combination of methods, including medical history, physical examination and respiratory function tests (Goodwin et al. 2003b; Pearce et al. 2000) but such methods are generally not feasible in large epidemiological surveys. It is important to note here that an investigation of the correspondence of self-reported chronic conditions in the US National Health Interview Survey with medical records abstracted in the prior 3 years found that self-reported current asthma to be in fairly good agreement with medical records, although underreported by 20–30% (NCHS, 1994). In our survey the definition of asthma was self-report of a diagnosis of asthma –not simply a self-report of asthma. So it may correspond more closely still to actual medical records. If respondents endorsed this question they were classified as having a history of asthma for these analyses. Respondents were also asked how old they were when they were first diagnosed with asthma. This year is referred to herein as the age of onset of asthma, although it is recognized that the underlying pathology develops over many years and that it is possible to have asthma without being detected. Only adult-onset asthma (onset age 21+) was investigated in this paper. No difference between atopic/non-atopic asthma was made in our study. Statistical Analysis Discrete-time survival analyses (Singer and Willett, 1993) with person-year as the unit of analysis were used to test sequential associations between first onset of mental disorders and subsequent onset of asthma. For these analyses, a person-year data set was created in which each year in the life of each respondent up to and including the age of onset of asthma or their age at interview (whichever came first) was treated as a separate observational record, with the year of asthma onset coded 1 and earlier years coded 0 on a dichotomous outcome variable. Persons who reported asthma onset before age 21 (N=2,186, corresponding to the 54% of all asthma cases in our study) were excluded from analysis. Mental disorder predictors were coded 1 from the year after first onset of each individual mental disorder. This time lag of 1 year in the coding of the predictors ensured that in cases where the first onset of a mental disorder and of asthma occurred in the same year, the mental disorder would not count as a predictor. Only person-years up to the diagnosis of asthma were analyzed so that only mental disorder episodes occurring prior to the onset of asthma were included in the predictor set. Logistic regression analysis was used to analyze these data with the survival coefficients presented as odds ratios, indicating the relative odds of asthma onset in a given year for a person with a prior history of mental disorder compared to a person without that mental disorder (including people without any mental disorder history). It is important to note that, given the retrospective nature of the information collected, results of the above analyses should be considered exploratory in nature. Longitudinal studies will be needed to confirm them. A series of bivariate and multivariate models was developed including the predictor mental disorder plus control variables. Models controlled for person-years, countries, gender, current age, and in the multivariate models, other mental disorders. Bivariate models investigated association of specific mental disorders with subsequent asthma onset. The next model, a multivariate model, estimated the associations of each mental disorder with asthma onset adjusting for mental disorder comorbidity. Our approach was to not control for covariates that could be on the causal pathway between mental disorders and subsequent asthma. However, we recognize that these variables may also confound associations so we re-estimated the multivariate model with adjustment for history of smoking (ever/never/current) and educational attainment. This made virtually no difference to associations (all previously significant associations remained significant and none reduced in magnitude – data available on request) so we report the results from the model unadjusted for smoking and education in this paper. We did not include BMI in the adjusted models, as estimates of current body weight only were available, and including this variable in the analyses would result in a biased estimation of the associations. Our earlier studies of concurrent mental-physical comorbidity in the WMH surveys found that these associations were generally consistent cross-nationally, despite varying prevalence of mental disorder and physical conditions (Lin et al. 2008; Von Korff, 2009). This was particularly the case for the association of mental disorders and adult onset asthma (Scott et al. 2007). All analyses for this paper were therefore run on the pooled cross-national dataset. As the WMH data are both clustered and weighted, the design-based Taylor series linearization (Shah, 1998) implemented in version 10 of the SUDAAN software system (SUDDAN, 1999) was used to estimate standard errors and evaluate the statistical significance of coefficients. RESULTS Sample information The survey characteristics are shown in Table 1 together with information about the number of survey respondents reporting a history of adult-onset asthma (n=1,860). They represented a total of 2,096,486 person-years of follow up. Four surveys had limited their eligible population to less than 65. The overall weighted response rate was 78%, ranging from 45.9% in France to 95.2 in Iraq. The prevalence of adult onset asthma ranged from 0.5% in the Shen Zen survey of People’s Republic of China to 7.4% in New Zealand. The mean age of adult asthma onset was 41 (SE=0.5) with a median age of onset of 38. Lifetime prevalence of mental disorders among those with and without asthma In Table 2 the lifetime prevalence rates of mental disorders are shown for the total sample without adult onset asthma (N= 49,296) and for those participants reporting adult onset asthma (final three columns). 20.8% of the adult onset asthma participants had lifetime MDE or dysthymia, 11.2% had specific phobia, 2% had intermittent explosive disorder, and 8.2%, alcohol abuse. Lifetime prevalence of mood and anxiety disorders among adult onset asthma cases was generally higher than in the total sample without adult onset asthma. It should be noted that the prevalence rates for mental disorders reported in this table represent the history of mental disorders occurring at any age up until the age of interview for each respondent. The analyses that follow include as predictors only those mental disorders occurring prior to the onset of asthma. Associations between temporally prior mental disorders and subsequent asthma onset Table 3 shows the associations between the first onset of temporally prior individual mental disorders and subsequent adult asthma onset. These associations were first investigated in a series of bivariate models (i.e., only one mental disorder considered at a time), but adjusted for age cohort, gender, person-year and country. First section of the table shows that 12 (out of the 16) mental disorders predicted adult onset asthma, with statistically significant ORs in the range of 1.5 to 2.8. Bipolar disorder showed the highest bivariate association (OR= 2.8) followed by binge eating disorder (OR= 2.6). The second section of table 3 shows that many bivariate associations remained significant, although attenuated, after adjusting for lifetime mental disorder comorbidity (that is, adjusting for mental disorders occurring before asthma onset). Dummy variables for all mental disorders were entered simultaneously and the highest multivariate associations observed correspond to binge eating disorder (OR= 1.8), bipolar disorder (OR= 1.8), PTSD (OR= 1.5), and alcohol abuse (OR= 1.5). Of interest, the observed association between major depressive episode/dysthymia became non-significant in the multivariate model. The global Chi square test for the joint effect of all mental disorders was statistically significant (X216= 140.3). That effect was not homogeneous for all mental disorders (X215=35.2). The final section in table 3 shows the coefficients of a multivariate model estimated with dummy predictors for the number of mental disorders without any information about the type of mental disorders, adjusted for age cohort, gender, person-year and country. The joint effect of the number of mental disorders is statistically significant X2=67.6 and a linear trend is observed, with an OR= 1.4 for exactly one mental disorder only to an OR= 3.1 for 5 or more mental disorders. We performed analyses with subgroups of countries (i.e., developed vs developing) and found that none of the interactions are significant indicating that there are no country income group differences in these associations. We also tested whether early onset (before age of 21) mental disorders were more strongly associated with subsequent adult asthma relative to late onset (after age of 21) mental disorders. Although we found that this was the case for most of the mental disorders, this difference between early and late onset became non-significant once all mental disorders were included in the models (results shown, but available on request). This suggests that the stronger association for early onset disorders with asthma is because early onset mental disorders are risk factors or risk markers for lifetime mental disorder comorbidity. Variation over the life-course (timing of asthma diagnoses) When we investigated whether associations between mental disorders and subsequent asthma varied by timing of the asthma diagnosis, we found significant interaction effects with person years for mood disorders (MDE/Dysthymia), and for GAD, Social phobia, and PTSD (Table 4). In all cases, the significant interactions indicate that the association of these mental disorders with adult asthma is stronger when asthma is diagnosed earlier in adulthood relative to later in adulthood. This is an important qualifier of the findings in Table 3 where the multivariate associations between MDE/dysthymia and Social phobia and asthma are not significant, as these results included adult asthma diagnosed throughout the whole adult lifespan. Finally, we assessed whether the association between mental disorders and adult onset asthma was different by gender (Table 5). We did find an interaction effect with gender for the association of two disorders with asthma: specific phobia, which was more strongly associated with subsequent asthma among females (stratified OR for female= 1.5) and for PTSD, which was more strongly associated with asthma among males (stratified OR for male= 2.9). DISCUSSION The results of this study must be interpreted taking into account several limitations. First, our assessment of asthma and mental disorders as well as their age of onset (AOO) is retrospective, which is associated with underestimates and errors (Wells and Horwood, 2004). Nevertheless, there is evidence that retrospective reported age of onset of asthma is reliable (Pattaro et al. 2007) and accurate (Toren et al. 2006). In addition, the instrument used for assessing mental disorders was specifically modified to improve accuracy in reporting age of onset, including decomposition of questions and bounding uncertainty interviewer techniques (Kessler and Ustun, 2004). Moreover, while neuroticism and distress may bias the reporting of disease symptoms (Janssens et al. 2009), they do not bias the reporting of diagnosed conditions (Vassend and Skrondal, 1999). Second, our assessment of asthma is based on self-report rather than on the most recommended strategy of combining medical history, physical examination and respiratory function tests (Douwes et al. 2011; Goodwin et al. 2003b; Pearce et al. 2000). But, as mentioned earlier, in our survey the definition of asthma was self-report of a diagnosis of asthma –not simply a self-report of asthma, a strategy that is associated with a lower bias (Baumeister et al. 2010; Kriegsman et al. 1996). Memory and diagnostic biases might have lead us to inaccurately classify some individuals in relation to their mental disorders and/or asthma status, and misclassification usually results in a bias towards the null, that is, an underestimation of the real association between mental disorders and asthma (Green et al. 2010; Loerbroks et al. 2012). Overall the retrospective nature of the data leads us to consider our results as preliminary evidence to be confirmed by longitudinal studies. Thirdly, diagnosis requires access to health care and there might be differences in access to health care among the countries and regions included in our study, which we have not studied. However the asthma prevalence found is consistent with previous studies (Akinbami et al. 2011; Goodwin et al. 2003b; Loerbroks et al. 2012), if we consider that we are analyzing adult onset asthma cases only, which correspond to a little less than half (46%) of the total asthma cases in our sample. Also a major strength of the WMH-surveys is that it contains a series of population-based samples in which all participants underwent the CIDI interview. The likelihood of mental disorders being diagnosed thus plays no role as every respondent is scored according to DSM criteria. But there may be substantial cultural differences in the likelihood of asthma being diagnosed. It is quite likely, for example, that in developing countries fewer people will get asthma diagnoses and care. This will result in a non-differential misclassification, that is, respondents being classified as non-asthma cases when in fact they are cases (undiagnosed). The effect of this is to bias associations towards the null. Finally, we did not explore asthma severity nor specific asthma symptoms, which are more strongly associated with depression and anxiety disorders than overall asthma (Opolski and Wilson, 2005). Notwithstanding these limitations, we believe our study provides valuable knowledge in several respects. Specifically, we confirm an important association of anxiety disorders and subsequent adult onset asthma (PTSD, panic, specific phobia and GAD) and report an even stronger association for bipolar, binge eating, and alcohol abuse disorders. We provide evidence for the first time that the number of comorbid mental disorders shows an additive association with subsequent asthma. We also show that the association of mental disorders and subsequent adult onset asthma is stronger for early onset mental disorders, and some associations are stronger when asthma occurs earlier rather than later in adulthood. Finally, we determine that for the most part associations between mental disorders and subsequent asthma onset are similar for men and women. This is an interesting finding given the higher prevalence of mood and anxiety disorders, and of adult-onset asthma, among women. The association between anxiety disorders and adult asthma is consistent with previous findings (Deshmukh et al. 2008; Goodwin et al. 2003a; Goodwin et al. 2004; Katon et al. 2004; ten and Petermann, 2000). Several studies have shown an association of adult asthma with panic (Goodwin et al. 2003b); (Favreau et al. 2014), with GAD (Goodwin et al. 2003a; Lavoie et al. 2011) and with PTSD (Katon et al. 2004; Kean et al. 2006; Spitzer et al. 2009; Spitzer et al. 2011), the anxiety disorders which showed the highest association in our study. Less evidence is available about the association of asthma and bipolar disorder (Goodwin et al. 2004) and eating disorders (Moreau et al. 2009; Stevenson, 2003). It is notable that binge eating was the single disorder most strongly associated with adult asthma in our study. This fact, together with a lack of association with bulimia, strongly suggests that obesity may be a causal mechanism. No doubt, this association deserves further research. We found a stronger association between specific phobia and asthma for women, and indeed associations between all anxiety disorders (with the notable exception of PTSD) and asthma were somewhat stronger for women, although this gender difference was only significant for specific phobia. This pattern is consistent with prior research suggesting that women have greater psychobiological reactivity to stress, and a more sensitized hypothalamic-pituitary-adrenal axis than men (Meewisse et al. 2007). In light of this research suggesting greater physiological stress reactivity in women, the stronger association we observed between PTSD and asthma for men is surprising (Olff et al. 2007). It may therefore be a chance finding, or it may reflect complex interactions between gender, traumatic stress and respiratory function that require further investigation to elucidate. A number of mechanisms have been suggested to explain the association between asthma and mental disorders. Among others, the symptomatic nature of asthma, which might be a life-threatening condition, would lead to developing some psychopathological manifestations (Goodwin et al. 2012; Kean et al. 2006); and asthma medication, in particular oral steroids, could cause psychological symptoms among asthma patients (Opolski and Wilson, 2005). These mechanisms assume that asthma would be the antecedent (Scott, 2009) leading to the development of mental disorders. But our study suggests that mental disorders can be the antecedent of subsequent adult-onset asthma, as it had been previously indicated (Chida et al. 2008; Goodwin et al. 2009). Possible pathways for such causation would include alterations in the autonomic nervous (sympathetic-adrenal-medullary -SAM- axis) and/or the neuroendocrine (hypothalamic-pituitary-adrenal –HPA- axis) systems associated to mental disorders, which would increase vulnerability to asthma onset; (Goodwin et al. 2012; Scott, 2009; Wright, 2005). The possibility of a causal role of mental disorders in adult onset asthma is reinforced by our observation that the association was stronger among those individuals whose mental disorder started during their childhood or early youth (early onset). It is also possible that certain behaviors or risk factors which are more frequent among individuals with mental disorders, such as smoking (McLeish et al. 2011) or obesity (Anto et al. 2010), among others, could mediate in the development of asthma in adulthood. It is important to note that the results presented here are adjusted by smoking history and education years. But we could not adjust by obesity due to lack of information regarding obesity prior to asthma onset. Overall our results are compatible with the antecedent model which proposes that mental disorders could, through their association with dysregulated stress physiology and lifestyle risk factors (Chida Y et al, 2008; Scott KM, 2009) contribute to the development of adult-onset asthma. Such mechanisms could occur in concert with others. The evidence of a possible “bidirectional” association (Chida et al. 2008) strongly suggests the existence of mechanisms that are common for both mental disorders and asthma (Van Lieshout and MacQueen, 2012). Inflammation would be one of such mechanisms, as it has been shown to underpin asthma and it has been suggested to have a role in depressive disorders (Dantzer et al. 2008); (Berk et al. 2013). Recently, a bidirectional pathway between depression and comorbid systemic illnesses has been proposed (Iwata et al. 2013; ten and Petermann, 2000), which could imply novel strategies for treating mental disorders. And as stress can affect the autonomous nervous system, its dysregulation could be a mechanism by which stress increases the risk of developing both asthma and emotional problems (Van Lieshout and MacQueen, 2012). Stress, endocrine and immune systems are strongly related and very likely mechanisms in such bidirectional relationship between mental disorders and asthma (Wright, 2005). Shared determinants acting very early in life, maybe in utero, would be also compatible with this bidirectional association. Family and genetic associations between asthma and depression have been described (Van Lieshout and MacQueen, 2012). Childhood adversities are a well-known risk factor for mental disorders, and they have been also found to be risk factors of physical conditions (Scott et al. 2011). More recently we showed that childhood adversities were a risk factor for adult onset asthma (Korkeila et al. 2012), but we also reported that associations between early onset mental disorders and subsequent onset of asthma were independent of childhood adversities. Further research on common pathways for mental disorders and adult onset asthma might bring clues to new therapeutic approaches. We found that early mental disorders (before age of 21) are more strongly associated with subsequent adult onset asthma, but many of these associations became non-significant when the presence of other mental disorders prior to asthma onset was taken into account. We interpret this as the result of earlier onset mental disorders being markers for mental comorbidity, rather than the timing of mental disorders per se having an effect on the risk of asthma. The important role of mental comorbidity is supported in our study by the evidence of a linear effect of mental comorbidity on subsequent asthma and by the fact that the statistical model including only the number of comorbid mental disorders had a better fit predicting adult onset asthma than any of the other more complex models analyzed here. Individuals with mental comorbidity should be considered a group with a higher risk of subsequent asthma. From an etiological perspective, the higher risk of asthma with each additional comorbid mental disorder suggests that pathways towards development of adult onset asthma are not totally overlapping. Our study adds to previous knowledge: a) a large sample of culturally different individuals worldwide; b) a wide range of mental disorders assessed with a face to face diagnostic interview; and c) clear, consistent association between mental disorders and subsequent adult-onset asthma, with adjustment for some obvious confounders. While the cross-sectional nature of the study is a major weakness, our study adds distinctly novel contributions with regard to a) and b) above in particular, with adjustment for some obvious confounders. In conclusion, in this international study we found that there is an association between a wide range of mental disorders and subsequent adult onset asthma, even after adjusting for mental disorder comorbidity. By analyzing only adult onset asthma cases, this helped ensuring the temporal order of the associations under investigation (from prior mental disorder to subsequent asthma). This also means that our results are generalizable only to adult onset asthma. Earlier onset mental disorders were more strongly associated with asthma than later onset disorders; this was explained by mental disorder comorbidity. Some mental disorders were more strongly associated with asthma when the asthma occurred earlier rather than later in adulthood. Associations were for the most part similar for men and women. The study also reveals the importance of comorbid mental disorders, as they increased risk for subsequent asthma. While pathological mechanisms implicated in the development of asthma and/or improving some of their outcomes among those with preexisting mental disorders should be better understood, the possibilities of avoiding asthma by intervening with potential psychological issues deserve further research. Table 1 Characteristics of WMH samples and proportion (and number) with history of adult-onset asthma. Sample Size History of Adult-Onset Asthma Diagnosis1 Country Field Dates Age Range Part 1 Part 2 sub- sample Response Rate (%) Number Unweighted (N) Weighted (%) Americas   Colombia 2003 18–65 4426 2381 87.7 23 0.7   Mexico 2001–2 18–65 5782 2362 76.6 22 0.7   United States 2002–3 18+ 9282 5692 70.9 324 5.6   Peru 2005–6 18–65 3930 1801 90.2 53 2.9 Asia and South Pacific   Japan 2002–6 20+ 4129 1682 55.1 57 2.7   PRC Shenzhen 2006–7 18+ 7132 2475 80.0 20 0.5   New Zealand 2003–4 18+ 12790 7312 73.3 544 7.4 Europe   Belgium 2001–2 18+ 2419 1043 50.6 26 2.4   France 2001–2 18+ 2894 1436 45.9 43 2.4   Germany 2002–3 18+ 3555 1323 57.8 40 3.3   Italy 2001–2 18+ 4712 1779 71.3 56 3.0   The Netherlands 2002–3 18+ 2372 1094 56.4 47 4.0   Spain 2001–2 18+ 5473 2121 78.6 77 3.0   Northern Ireland 2004–7 18+ 4340 1986 68.4 88 4.0   Portugal 2008–9 18+ 3849 2060 57.3 60 2.8   Romania 2005–6 18+ 2357 2357 70.9 83 2.7   Poland 2010–11 18–64 10081 4000 50.4 72 1.3 Middle East   Israel 2002–4 21+ 4859 4859 72.6 188 3.9   Iraq 2006–7 18+ 4332 4332 95.2 37 1.2 Weighted average response rate (%) 78.0 Total sample size 98,714 52,095 1,860 3.4 1 This is the onset of asthma in those 21 years and over. Table 2 Prevalence of mental disorders across WMH samples Types of mental disorders Among the total sample (21+ years) (n= 49296) Among those with adult-onset asthma (n = 1860) n % SE n % SE I. Mood disorders   Major Depressive Episode/Dysthymia 11639 12.9 0.2 615 20.8 1.0   Bipolar Disorder (Broad) 1561 1.8 0.1 98 3.2 0.4 II. Anxiety disorders   Panic Disorder 1670 1.9 0.1 126 4.2 0.5   Generalized Anxiety Disorder 3625 4.3 0.1 270 9.5 0.7   Social Phobia 3646 4.3 0.1 207 7.1 0.6   Specific Phobia 5814 7.2 0.1 354 11.2 0.8   Agoraphobia without Panic 751 0.9 0.0 38 1.2 0.2   Post-Traumatic Stress Disorder 2718 3.4 0.1 221 8.3 0.8   Obsessive Compulsive Disorder 729 1.2 0.1 17 0.4 0.1 III. Impulse-control disorders   Intermittent Explosive Disorder 1523 2.0 0.1 47 2.0 0.4   Binge Eating Disorder 530 0.7 0.0 39 1.5 0.3   Bulimia Nervosa 355 0.4 0.0 27 0.7 0.1 IV. Substance disorders   Alcohol Abuse 4806 7.5 0.2 216 8.2 0.7   Alcohol Dependence with Abuse 1627 2.1 0.1 97 3.3 0.4   Drug Abuse 1746 2.4 0.1 72 2.5 0.3   Drug Dependence with Abuse 678 0.9 0.1 34 1.0 0.2 Table 3 Bivariate and multivariate associations (odds ratios) between DSM-IV mental disorders and the subsequent diagnosis of adult-onset asthma. The WMH Surveys. Bivariate Models1 Multivariate Type Model2 Multivariate Number Model3 OR (95% C.I.) OR (95% C.I.) OR (95% C.I.) I. Mood disorders   Major Depressive Episode/ Dysthymia 1.6* (1.4–1.9) 1.2 (1.0–1.4) - -   Bipolar Disorder (Broad) 2.8* (2.0–3.9) 1.8* (1.3–2.5) - - II. Anxiety disorders   Panic Disorder 2.2* (1.6–3.1) 1.4* (1.0–2.0) - -   Generalized Anxiety Disorder 2.0* (1.6–2.4) 1.3* (1.1–1.7) - -   Social Phobia 1.5* (1.2–1.9) 1.0 (0.8–1.3) - -   Specific Phobia 1.7* (1.4–2.0) 1.3* (1.1–1.6) - -   Agoraphobia without Panic 1.3 (0.9–2.0) 0.8 (0.6–1.3) - -   Post-Traumatic Stress Disorder 2.1* (1.6–2.7) 1.5* (1.1–1.9) - -   Obsessive Compulsive Disorder 0.8 (0.4–1.7) 0.6 (0.3–1.1) - - III. Impulse-control disorders   Intermittent Explosive Disorder 1.5 (1.0–2.2) 1.0 (0.7–1.4) - -   Binge Eating Disorder 2.6* (1.7–3.9) 1.8* (1.2–2.9) - -   Bulimia Nervosa 1.7 (1.0–3.0) 1.0 (0.5–1.8) - - IV. Substance disorders   Alcohol Abuse 2.0* (1.6–2.4) 1.5* (1.1–2.0) - -   Alcohol Dependence with Abuse 2.5* (1.8–3.4) 1.3 (0.9–2.0) - -   Drug Abuse 1.7* (1.2–2.4) 0.9 (0.6–1.4) - -   Drug Dependence with Abuse 1.9* (1.2–3.1) 0.8 (0.5–1.4) - - Joint effect of all types of disorders, χ216 140.3* Difference between types of disorders, χ215 35.2* V. Number of disorders   Exactly 1 disorder - - - - 1.4* (1.2–1.6)   Exactly 2 disorders - - - - 1.6* (1.4–2.0)   Exactly 3 disorders - - - - 2.2* (1.7–2.9)   Exactly 4 disorders - - - - 2.9* (2.0–4.1)   5+ disorders - - - - 3.1* (2.2–4.2) Joint effect of number of disorders, χ25 67.6* * Significant at the 0.05 level, two-tailed test. 1 Bivariate models: each mental disorder type was estimated as a predictor of the physical condition onset in a separate discrete time survival model controlling for age cohorts, gender, person-year and country. 2 Multivariate Type model: the model was estimated with dummy variables for all mental disorders entered simultaneously, including the controls specified above and additionally adjusted for smoking (ever/never/current) and education (number of years). 3 Multivariate Number model: the model was estimated with dummy predictors for number of mental disorders without any information about type of mental disorders, including the controls specified above. Table 4 Interaction between mental disorder and person-year in predicting the subsequent diagnosis of adult-onset asthma. The WMH Surveys. Mental disorder*Person-year interaction1 Type of Mental Disorders OR (95% C.I.) χ21 [p] Major Depressive Episode/Dysthymia 0.97* (0.96–0.98) 49.4* [0.000] Generalized Anxiety Disorder 0.99* (0.97–1.00) 5.3* [0.021] Social Phobia 0.99* (0.98–1.00) 5.5* [0.019] Post-Traumatic Stress Disorder 0.98* (0.97–0.99) 12.1* [0.001] * OR significant at the 0.05 level, 2-sided test 1 A series of multivariate models were estimated. For example, the model for depression included the dummy variables for all mental disorders plus the cross-product term for depression and person-year (as a continuous variable), plus the controls specified for earlier models. Table 5 Multivariate type models for adult-onset asthma, stratified by gender. The WMH Surveys. Stratified Multivariate Type Models Type of Mental Disorders Male Female OR (95% C.I.) OR (95% C.I.) 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PMC005xxxxxx/PMC5120393.txt
LICENSE: This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. 0376333 5218 J Psychosom Res J Psychosom Res Journal of psychosomatic research 0022-3999 1879-1360 26526305 5120393 10.1016/j.jpsychores.2015.08.005 NIHMS830490 Article Associations between DSM-IV mental disorders and subsequent COPD diagnosis Rapsey Charlene M. a* Lim Carmen C.W. a Al-Hamzawi Ali b Alonso Jordi c Bruffaerts Ronny d Caldas-de-Almeida J.M. e Florescu Silvia fg de Girolamo Giovanni h Hu Chiyi i Kessler Ronald C. j Kovess-Masfety Viviane k Levinson Daphna l Elena Medina-Mora María m Murphy Sam n Ono Yutaka o Piazza Maria p Posada-Villa Jose q ten Have Margreet r Wojtyniak Bogdan g Scott Kate M. a a Department of Psychological Medicine, University of Otago, Dunedin, New Zealand b College of Medicine, Al-Qadisiya University, Diwania governorate, Iraq c IMIM-Institut Hospital del Mar d'Investigacions Mèdiques) CIBER en Epidemiolgía y Salud Pública (CIBERESP) UPF-Pompeu Fabra University, Spain d University Psychiatric Centre, University of Leuven, Campus Gasthuisberg, Belgium e Chronic Diseases Research Center (CEDOC) and Department of Mental Health, Faculdade de Ciências Médicas, Universidade Nova de Lisboa, Portugal f National School of Public Health, Management and Professional Development, Bucharest, Romania g Centre of Monitoring and Analyses of Population Health, National Institute of Public Health-National Institute of Hygiene, Poland h IRCCS Centro S. Giovanni di Dio Fatebenefratelli, Brescia, Italy i Shenzhen Insitute of Mental Health & Shenzhen Kanging Hospital, PRC - Shenzhen j Department of Health Care Policy, Harvard Medical School, Boston, MA, United States k Ecole des Hautes Etudes en Santé Publique (EHESP), EA 4057 Paris Descartes University, Paris, France l Ministry of Health Israel, Mental Health Services, Israel m Nacional Institute of Psychiatry Ramon de la Fuente, Mexico n School of Psychology, University of Ulster, Northern Ireland o Center for Cognitive Behavior Therapy and Research, National Center for Neurology and Psychiatry, Japan p Unit of Analysis and Generation of Evidence for Public Health, Peruvian National Institute of Health, Peru q Colegio Mayor de Cundinamarca University, Colombia r Trimbos-Instituut, Netherlands Institute of Mental Health and Addiction, Netherlands * Corresponding author at: Department of Psychological Medicine, University of Otago, PO Box 913, Dunedin, New Zealand. charlene.rapsey@otago.ac.nz (C.M. Rapsey). 17 11 2016 02 9 2015 11 2015 23 11 2016 79 5 333339 This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. Objectives COPD and mental disorder comorbidity is commonly reported, although findings are limited by substantive weaknesses. Moreover, few studies investigate mental disorder as a risk for COPD onset. This research aims to investigate associations between current (12-month) DSM-IV mental disorders and COPD, associations between temporally prior mental disorders and subsequent COPD diagnosis, and cumulative effect of multiple mental disorders. Methods Data were collected using population surveys of 19 countries (n = 52,095). COPD diagnosis was assessed by self-report of physician's diagnosis. The World Mental Health-Composite International Diagnostic Interview (WMH-CIDI) was used to retrospectively assess lifetime prevalence and age at onset of 16 DSM-IV disorders. Adjusting for age, gender, smoking, education, and country, survival analysis estimated associations between first onset of mental disorder and subsequent COPD diagnosis. Results COPD and several mental disorders were concurrently associated across the 12-month period (ORs 1.5–3.8). When examining associations between temporally prior disorders and COPD, all but two mental disorders were associated with COPD diagnosis (ORs 1.7–3.5). After comorbidity adjustment, depression, generalized anxiety disorder, and alcohol abuse were significantly associated with COPD (ORs 1.6–1.8). There was a substantive cumulative risk of COPD diagnosis following multiple mental disorders experienced over the lifetime. Conclusions: Mental disorder prevalence is higher in those with COPD than those without COPD. Over time, mental disorders are associated with subsequent diagnosis of COPD; further, the risk is cumulative for multiple diagnoses. Attention should be given to the role of mental disorders in the pathogenesis of COPD using prospective study designs. Alcohol abuse Anxiety disorders Comorbidity COPD Depression Introduction Mental disorders are highly prevalent among those with COPD. [1–3] Mental disorder and COPD comorbidity may negatively affect adaptive functioning, quality of life, exercise capacity, treatment adherence, and mortality. [4,5] A review of studies published between 1968 and 2004 reported that in those with COPD, prevalence of depression ranged from 7%-79% and prevalence of anxiety ranged from 10%–100%; [2] a review of studies between 1966 and 2012, which only included studies using a clinical diagnostic tool to assess mental disorder, found rates ranging between 0%–42% and 10%–55% respectively. [1]. The research investigating mental disorder and COPD comorbidity prevalence is limited by multiple methodological weaknesses including use of small samples, clinical populations of patients with COPD, and symptom rating scales rather than diagnostic clinical measures. Symptom rating scales for mental disorders do not differentiate between diagnostic categories, sometimes overlap with COPD, and may describe negative emotional responses to COPD. Thus, it is not surprising that estimates of the prevalence of mental disorder and COPD comorbidity vary widely. Cross-sectional analysis of general population samples reveals elevated risk of mental disorder in those with COPD. [6–8] However, it is difficult to conclude whether there is an association between COPD and some mental disorders but not others; whether there are differences in the relative strength of association between different mental disorders and COPD, or whether there is a non-specific association between COPD and any mental disorder (that is, mental distress generally). Moreover, prospective studies that identify the direction of the association between COPD and mental disorders are needed. Understanding the direction of the association between COPD and mental disorders may help clarify the mechanisms that connect these debilitating conditions. The majority of prospective studies have been conducted with participants with COPD at baseline and have determined that mental disorders increase poor outcomes in those with COPD. [3] However, prospective studies investigating mental disorder as a risk factor for COPD onset are lacking. One study provides evidence toward the hypothesis that mental disorder increases risk for COPD, finding that depression doubled the risk for later COPD diagnosis [9]. The World Mental Health (WMH) Surveys comprise cross-national data drawn from the general populations of a range of developed and developing countries, clinically valid assessment of lifetime prevalence of a wide range of DSM-IV mental disorders, and self-reported physician's diagnosis and year of diagnosis of chronic lung disease (referred to herein as COPD). The surveys are cross-sectional in design but collected information retrospectively on age of diagnosis of mental disorders and of COPD, which allows the use of survival analysis to examine associations between temporally prior mental disorders and the subsequent diagnosis of COPD. The aims of the study were three-fold. First, we estimated concurrent (12 month) associations between lifetime COPD and a wide range of 12 month DSM-IV mental disorders. Second, we investigated associations between first onset of temporally prior mood, anxiety, impulse control, and substance use disorders with subsequent COPD diagnosis, with and without adjustment for mental disorder comorbidity. Third, we investigated whether there was a cumulative effect of multiple mental disorders and subsequent risk of COPD. Adjustment was made for smoking in all analyses. Method Samples and procedures This study uses data from 19 of the WMH surveys (see Table 1). The World Mental Health (WMH) Survey Initiative is a project of the World Health Organization aimed at addressing the global burden of mental disorders. [10,11] A stratified multi-stage clustered area probability sampling strategy was used to select adult respondents (18 years +) in most WMH countries. In most countries, internal subsampling was used to reduce respondent burden and average interview time by dividing the interview into two parts. All respondents completed Part 1 which included the core diagnostic assessment of most mental disorders. All Part 1 respondents who met lifetime criteria for any mental disorder and a probability sample of respondents without mental disorders were administered Part 2 which assessed physical conditions and collected a range of other information related to survey aims. Part 2 respondents were weighted by the inverse of their probability of selection for Part 2 of the interview to adjust for differential sampling, resulting in an unbiased sample. Analyses in this paper are based on the weighted Part 2 subsample (n = 52,095; person years = 2,167,404). Additional weights were used to adjust for differential probabilities of selection within households, to adjust for non-response, and to match the samples to population socio-demographic distributions. Measures taken to ensure data accuracy, cross-national consistency and protection of respondents are described in detail elsewhere. [11,12] All respondents provided informed consent and procedures for protecting respondents were approved and monitored for compliance by the Institutional Review Boards in each country (see [11] for details). Measures Mental disorders All surveys used the WMH survey version of the WHO Composite International Diagnostic Interview (now CIDI 3.0, [12]) a fully structured interview, to assess lifetime history of mental disorders. Retrospective age-of-onset reports were based on a question series designed to avoid the implausible response patterns obtained in using the standard CIDI age-of-onset question. [13] Disorders were assessed using the definitions and criteria of the DSM-IV. The mental disorders adjusted for in this paper include anxiety disorders, mood disorders, substance use disorders, and impulse control disorders. CIDI organic exclusion rules were applied in making diagnoses. Clinical reappraisal studies conducted in some of the WMH countries indicate that lifetime diagnoses of anxiety, mood and substance use disorders based on the CIDI have generally good concordance with diagnoses based on blinded clinical interviews. [14]. COPD status In a series of questions adapted from the U.S Health Interview Survey, [15] respondents were asked about the lifetime presence of selected chronic conditions. Respondents were asked: “Did a doctor or other health professional ever tell you that you had any of the following illnesses… Other chronic lung disease, like COPD or emphysema?” If respondents endorsed this question they were classified as having a history of COPD for these analyses. Asthma was not included in this category because it was asked about in a separate question that preceded this ‘other chronic lung disease’ question. Although it is possible that some respondents with chronic lung diseases other than COPD/emphysema may have endorsed this question we use the term COPD as this is likely to comprise the majority of cases captured by this question. Respondents were also asked how old they were when they were first diagnosed with COPD. Only adult-onset COPD (onsets age 21 +) was investigated in this paper on the assumption that pre-adult onsets would reflect congenital processes, rather than any possible influence of temporally prior mental disorders. Smoking status Smoking was assessed with one item and respondents were classified according to three-levels, current smoker, ex-smoker, or never smoked. Statistical analysis Aim 1 The prevalence of specific mental disorders was estimated separately among respondents with and respondents without a COPD diagnosis. The ORs of the associations between lifetime COPD and specific 12 month DSM-IV mental disorders were calculated in logistic regression equations that adjusted for age, gender, country, smoking, and years of education. Aim 2 Although the data collection was cross-sectional, there was a time element in the data as we asked for the time of onset of mental disorders and of COPD. We analyzed the associations between mental disorder and COPD diagnosis by using this time-related information. Comparable with previous studies [16,17] using these data we used discrete-time survival analyses [19,20] with person-year as the unit of analysis to investigate sequential associations between first onset of mental disorders and the subsequent diagnosis of COPD. For these analyses a person-year data set was created in which each year in the life of each respondent up to and including the age of diagnosis of COPD or their age at interview (whichever came first) was treated as a separate observational record, with the year of COPD diagnosis coded 1 and earlier years coded 0 on a dichotomous outcome variable. As stated earlier, we were interested in adults with a COPD diagnosis over the age of 20, therefore the small number of people who reported COPD diagnosis before age 21 were excluded from the analyses. Mental disorder predictors were coded 1 from the year after first diagnosis of each individual mental disorder. This time lag of 1 year in the coding of the predictors ensured that in cases where the first diagnosis of a mental disorder and of COPD occurred in the same year, the mental disorder would not count as a predictor. Only person-years up to the diagnosis of COPD were analyzed so that only mental disorder episodes occurring prior to the diagnosis of COPD were included in the predictor set. Logistic regression analysis was used to estimate associations with the survival coefficients presented as odds ratios, indicating the relative odds of COPD diagnosis in a given year for a person with a prior history of the specific mental disorder compared to people without that mental disorder and people without any mental disorder history at all. First, a series of single disorder multivariate models were developed including the predictor mental disorder plus control variables to investigate whether each individual mental disorder contributed to an accelerated diagnosis of COPD. Second, a multi disorder model was developed including all mental disorders thereby adjusting for comorbidity to investigate the contribution of each mental disorder over and above the effect of other types of mental disorder. Aim 3 To investigate the cumulative effect of an increasing number of mental disorders, discrete time survival analysis was used to estimate a model that included number of disorders coded as dummy variable (1, 2, 3, 4, 5 +) without information about type of disorder. For example, those with exactly 1 disorder were coded 1 and the rest of the sample was coded 0 in the exactly 1 disorder category. All models control for countries, gender, current age, smoking, education level, and cohort (defined by ages at interview 18–29, 30–44, 45–59, 60 +). Our earlier studies of concurrent mental-physical comorbidity in the WMH surveys found that these associations are generally consistent cross-nationally, despite varying prevalence of mental disorder and physical conditions. [10,21] All analyses for this paper were therefore run on the pooled cross-national dataset. As the WMH data are both clustered and weighted, the design-based Taylor series linearization [22] implemented in version 10 of the SUDAAN software system [23] was used to estimate standard errors and evaluate the statistical significance of coefficients. Results The survey characteristics are shown in Table 1 together with information about the number of survey respondents reporting a history of COPD (n = 790). Prevalence of COPD diagnosis ranged from 0.1 (Mexico) to 3.4 (Israel) with an averaged prevalence across all countries of 1.3%. It should be noted that prevalence of COPD diagnosis will be underestimated in those 4 countries with upper age limits of 65 relative to the other countries with unrestricted upper ages of respondents. Prevalence of COPD diagnosis is also likely to vary considerably according to country differences in health service availability and assessment procedures. The prevalence of COPD reported in this study is lower than other studies, for example in a US study using a similar method for assessing COPD, the prevalence of COPD was 6.0%. [24]. Twelve-month prevalence of mental health disorders by lifetime COPD status and concurrent comorbidity As can be seen in Table 2, across a 12-month period, most mood and anxiety disorders were associated with a 50–220% (OR: 1.5–3.2) increased risk of COPD. The impulse control disorders and most substance use disorders were not associated with significantly elevated risk for COPD, excepting drug abuse with dependence, which was associated with a 280% increased risk of COPD diagnosis. Type and number of mental disorders as predictors of subsequent COPD diagnosis Results of analysis examining associations between temporally prior mental disorders and subsequent COPD are presented in Table 3. In the single disorder models, with no adjustment for comorbid disorders, all but two mental disorders (binge eating disorder and bulimia nervosa) are associated with COPD with ORs between 1.7–3.5. In the multi-disorder model, with adjustments for mental disorder comorbidity, the magnitude of associations was reduced (ORs from 1.6–1.8). Depression/dysthymia, generalized anxiety disorder, and alcohol abuse continued to predict diagnosis of COPD over and above the effect of the other disorders. The global chi square test for the joint effect of all mental disorders was significant (χ162 = 112.9, p < 0.001), however the test for variation in ORs indicates that the associations do not differ significantly in magnitude (χ152 = 17.4, p = 0.298). A cautious interpretation of this latter test result would be that we have found a generalized link between psychopathology and COPD diagnosis, with some suggestion that depression, anxiety, and alcohol abuse may have specific associations with COPD, but these specific relationships would require confirmation in subsequent studies. Table 4 displays the clear dose–response relationship between number of mental disorders experienced over the life course (prior to COPD diagnosis) and an accelerated COPD diagnosis. At each level of number of mental disorders (1, 2, 3, 4, 5 +) a greater proportion of those with COPD experienced mental disorder (18.3%, 9.0%, 6.2%, 1.9%, 3.8%) compared to those without COPD (16.0%, 6.6%, 2.8%, 1.4%, 1.6%). Further, the results from a multivariate model that considered only number of mental disorders (i.e., not including information about type) are presented in the final columns of data in Table 3., with ORs ranging from 1.6 for one mental disorder to 5.8 for 5 + mental disorders. This model was a better fit for the data than the multivariate type model just presented, again reinforcing the idea that it is psychopathology in general that matters most in terms of increasing COPD risk rather than specific types of mental disorders. Additional analyses Multivariate type and number models were developed; other more complex non additive multivariate models were also run, for example including both type and number of mental disorders in the same model, but model fit statistics did not indicate these provided a better fit for the data, so the simpler models are reported here (model fitting statistics available on request). Gender differences were examined by including interaction terms between gender and each mental disorder in the multivariate type model but as results were substantively the same for men and women we report results with adjustment for gender. Minimal changes were observed in the associations between mental disorders and COPD diagnosis after adjustment for nicotine use (data not shown but available on request). Discussion This is the first study evaluating the association of a wide range of DSM-IV mental disorders with COPD diagnosis in an international sample. The main finding were that there was an increased likelihood of COPD and mental disorder comorbidity across a 12-month period; those with mood, anxiety, and drug abuse with dependence were 50–280% more likely to also have a COPD diagnosis, which addressed the first aim of the study. The second aim was to investigate associations between temporally prior mental disorders and subsequent COPD diagnosis; significant associations between most mental disorders and COPD were found. After adjusting for comorbidity, depression, generalized anxiety disorder, and alcohol abuse contributed independently to an increased risk of COPD diagnosis at each time point (year of life). Third, there was a marked dose response for cumulative number of mental disorders experienced over the lifetime and the risk of COPD. The conclusions from this study are constrained by several caveats. COPD status was assessed by self-report of medical diagnosis without verification by clinical assessment and by retrospective report, which may have led to errors in classification and reported age of diagnosis timing. [13] Prevalence of COPD in this study appeared lower than previously reported [24] and rates varied between countries. Moreover, in four countries participation was limited to individuals under the age of 65, which likely excluded the greater proportion of individuals with COPD in those localities. Furthermore, COPD is likely to be markedly under-diagnosed in the general population whereby those who meet criteria for COPD have not received a medical diagnosis. [25] Thus, it is probable that classification errors were made whereby some of those with COPD were classified as not having COPD. Mood has not been found to influence reports of clinician diagnosed conditions [26,27] therefore it is unlikely that current mood disorder moderated self-report of COPD. The result of non-differential, under-reporting would be to weaken possible associations between variables and therefore the findings from this study may be conservative. The age of mental disorder onset distributions from the WMH surveys are consistent across countries and with other research; [28,29] however, some degree of inaccuracy with the precise timing of onset is likely to remain. Mitigating this, the validity of the survival analysis depends more on the temporal sequence of the mental disorders and COPD being correct, and less on accuracy in their precise onset timing. For most individuals their mental disorders and diagnosis of COPD occurred decades apart, thus the temporal sequence is likely to be correct. To further ensure this though, we do not include as predictors any mental disorders that were reported to occur in the same year as their COPD diagnosis. Selective classification errors whereby those most affected by mental disorders and COPD are absent from the sample due to hospitalization or early mortality would also influence associations in the direction of a null finding. Finally, this is a retrospective study and although the information on timing of COPD diagnosis and mental disorder onset allowed the estimation of predictive associations that are indicative of specific temporal associations from mental disorder to COPD, these results are regarded as preliminary and await confirmation from prospective studies. Despite its limitations, this study has a number of unique characteristics that allow for novel contributions to the literature. Controlling for cultural differences was possible through multi-national participation. Selection bias was reduced through surveying the general population. The sample size was sufficient to consider possible associations between COPD and a range of mental disorders, including disorders with lower prevalence rates. Mental disorders were assessed using a clinical instrument allowing for discrimination between diagnostic categories and for adjustment for comorbidity among disorders. Although as noted, prospective studies will be required to confirm the study findings, it is worth considering the potential causal pathways that mental disorders have in common and how these may increase susceptibility to COPD. One direct, biological mechanism that may connect mental disorders with COPD onset is raised inflammatory response and impaired immune regulation. [5] The immune irregularities in depression are complex and there is evidence for both suppression of cellular immunity through HPA axis mediated hyper-secretion of cortisol, but also of immune activation marked by elevated circulating levels of pro-inflammatory cytokines. [30] To the extent that depression does increase inflammation, it may contribute to the development of COPD in conjunction with other COPD pathogenic factors. Factors that contribute to increased inflammatory response that are common to mental disorders, such as disrupted sleep, may also add to the risk of COPD diagnosis. [6,31]. Smoking is another factor common to mental disorders and to COPD, however minimal changes were observed in the associations between mental disorders and COPD diagnosis after adjustment for nicotine use. Consistent with this, adjustment for smoking did not markedly attenuate the relationship between depression and COPD in other studies. [7,9] Goodwin et al. [8] has argued that it is nicotine dependence rather than nicotine use that is explanatory. Thus our limited assessment of nicotine use may have influenced our findings. The current study contributes to accumulating evidence that alcohol is involved in the pathogenesis of COPD, independent of nicotine exposure; alcohol abuse doubled the risk of COPD diagnosis after taking into account smoking and other mental disorders. Interestingly, there was no concurrent association between alcohol use and COPD. Alcohol use may no longer be present in older age when COPD is present; however it may be a risk factor for the development of COPD. Mechanisms that explain the role of heavy alcohol use in impaired lung function include the effects of alcohol and its metabolites and nonalcohol congeners, leading to immunosuppressive effects and compromised mucociliary clearance. [32] Perhaps surprisingly alcohol abuse but not alcohol dependence was associated with an increased risk for COPD. One speculative explanation for this finding may be that those who tolerate alcohol to the extent of developing dependence are genetically less susceptible to alcohol related lung pathology. For example, Asian populations are more likely to have a reduced ability to metabolize alcohol and one of several undesirable results is alcohol triggered asthma. [33]. Although we have discussed possible causal mechanisms thus far, we do not assume these associations are causal as there are also non-causal pathways, common to mental disorder and to COPD, that may explain the association between these conditions such as nutrition and exercise, [5] genetics, [34] and childhood adversities. [35] Moreover, COPD is comorbid with multiple conditions including osteoporosis and coronary heart disease; [5] it may be that diagnosis of other chronic conditions precedes diagnosis of COPD and that the associations we document here reflect in part the associations between mental disorders and these other conditions, or between mental disorders and multiple physical condition comorbidities. Another non-causal pathway may be socio-economic status whereby those with lower SES are more likely to experience mental disorders [36] and are also at greater risk for COPD through several pathways including occupational exposure to lung irritants, exposure to biomass smoke, and poor nutrition and housing. [37] In this study, adjustment was made for education level, which may not have fully controlled for SES. One further conceivable non-causal connection between mental disorders and COPD diagnosis is that seeking medical attention for mental disorders increases the likelihood of receiving a diagnosis of COPD. For example, panic disorder may increase catastrophic interpretation of dyspnea, thereby increasing the chance of COPD assessment. Additionally, patients seeking attention for any mental disorder may have an increased likelihood of a physician noting symptoms of COPD following greater attendance at a medical practice. Inconsistent with this explanation, adjustment for health care use only slightly attenuated the significant association between COPD and depression observed in another study. [9]. In summary this research contributes new evidence to our understanding of the breadth of associations between mental disorders and COPD. This is the first study to identify the relative contribution of different mental disorders to COPD diagnosis and to identify substantive cumulative risk of COPD diagnosis with the experience of multiple mental disorders. The association between COPD and mental disorders is likely to be bidirectional; however research has focused on identifying COPD as a risk factor for mental disorder [3] rather than mental disorder as a risk factor for COPD. This research indicates that future research should prospectively attend to mental disorders as a risk factor for developing COPD. Acknowledgments The authors appreciate the helpful contributions to WMH of Herbert Matschinger, PhD. A complete list of all within-country and cross-national WMH publications can be found at http://www.hcp.med.harvard.edu/wmh/. A complete list of all within-country and cross-national WMH publications can be found at http://www.hcp.med.harvard.edu/wmh/. Funding/support The World Health Organization World Mental Health (WMH) Survey Initiative is supported by the National Institute of Mental Health (NIMH; R01 MH070884), the John D. and Catherine T. MacArthur Foundation, the Pfizer Foundation, the US Public Health Service (R13-MH066849, R01-MH069864, and R01 DA016558), the Fogarty International Center (FIRCA R03-TW006481), the Pan American Health Organization, Eli Lilly and Company, Ortho-McNeil Pharmaceutical, GlaxoSmithKline, and Bristol-Myers Squibb. We thank the staff of the WMH Data Collection and Data Analysis Coordination Centers for assistance with instrumentation, fieldwork, and consultation on data analysis. The Colombian National Study of Mental Health (NSMH) is supported by the Ministry of Social Protection. The ESEMeD project is funded by the European Commission (Contracts QLG5-1999-01042; SANCO 2004123, and EAHC 20081308), the Piedmont Region (Italy)), Fondo de Investigación Sanitaria, Instituto de Salud Carlos III, Spain (FIS 00/0028), Ministerio de Ciencia y Tecnología, Spain (SAF 2000-158-CE), Departament de Salut, Generalitat de Catalunya, Spain, Instituto de Salud Carlos III (CIBER CB06/02/0046, RETICS RD06/0011 REM-TAP), and other local agencies and by an unrestricted educational grant from GlaxoSmithKline. Implementation of the Iraq Mental Health Survey (IMHS) and data entry were carried out by the staff of the Iraqi MOH and MOP with direct support from the Iraqi IMHS team with funding from both the Japanese and European Funds through United Nations Development Group Iraq Trust Fund (UNDG ITF). The Israel National Health Survey is funded by the Ministry of Health with support from the Israel National Institute for Health Policy and Health Services Research and the National Insurance Institute of Israel. The World Mental Health Japan (WMHJ) Survey is supported by the Grant for Research on Psychiatric and Neurological Diseases and Mental Health (H13-SHOGAI-023, H14-TOKUBETSU-026, H16-KOKORO-013) from the Japan Ministry of Health, Labor and Welfare. The Mexican National Comorbidity Survey (MNCS) is supported by The National Institute of Psychiatry Ramon de la Fuente (INPRFMDIES 4280) and by the National Council on Science and Technology (CONACyT-G30544- H), with supplemental support from the PanAmerican Health Organization (PAHO). Te Rau Hinengaro: The New Zealand Mental Health Survey (NZMHS) is supported by the New Zealand Ministry of Health, Alcohol Advisory Council, and the Health Research Council (HRC 11/200). The Northern Ireland Study of Mental Health was funded by the Health & Social Care Research & Development Division of the Public Health Agency. The Chinese World Mental Health Survey Initiative is supported by the Pfizer Foundation. The Shenzhen Mental Health Survey is supported by the Shenzhen Bureau of Health and the Shenzhen Bureau of Science, Technology, and Information. The Peruvian World Mental Health Study was funded by the National Institute of Health of the Ministry of Health of Peru. The Polish project Epidemiology of Mental Health and Access to Care —EZOP Poland was carried out by the Institute of Psychiatry and Neurology in Warsaw in consortium with Department of Psychiatry — Medical University in Wroclaw and National Institute of Public Health-National Institute of Hygiene in Warsaw and in partnership with Psykiatrist Institut Vinderen — Universitet, Oslo. The project was funded by the Norwegian Financial Mechanism and the European Economic Area Mechanism as well as Polish Ministry of Health. No support from pharmaceutical industry neither other commercial sources was received. The Portuguese Mental Health Study was carried out by the Department of Mental Health, Faculty of Medical Sciences, NOVA University of Lisbon, with collaboration of the Portuguese Catholic University, and was funded by Champalimaud Foundation, Gulbenkian Foundation, Foundation for Science and Technology (FCT) and Ministry of Health. The Romania WMH study projects “Policies in Mental Health Area” and “National Study regarding Mental Health and Services Use” were carried out by National School of Public Health & Health Services Management (former National Institute for Research & Development in Health, present National School of Public Health Management & Professional Development, Bucharest), with technical support of Metro Media Transilvania, the National Institute of Statistics — National Centre for Training in Statistics, SC. Cheyenne Services SRL, Statistics Netherlands and were funded by Ministry of Public Health (former Ministry of Health) with supplemental support of Eli Lilly Romania SRL. Additional funding Work on this paper was funded by a grant from the Health Research Council of New Zealand (HRC 11/200) to Kate M. Scott. Financial disclosure Dr. Kessler has been a consultant for Analysis Group, GlaxoSmithKline Inc., Kaiser Permanente, Merck & Co, Inc., Ortho-McNeil Janssen Scientific Affairs, Pfizer Inc., Sanofi-Aventis Groupe, Shire US Inc., SRA International, Inc., Takeda Global Research & Development, Transcept Pharmaceuticals Inc., Wellness and Prevention, Inc., and Wyeth-Ayerst; has served on advisory boards for Eli Lilly & Company, Mindsite, and Wyeth-Ayerst; and has had research support for his epidemiological studies from Analysis Group Inc., Bristol-Myers Squibb, Eli Lilly & Company, EPI-Q, Ortho-McNeil Janssen Scientific Affairs., Pfizer Inc., Sanofi-Aventis Groupe, and Shire US, Inc. He owns stock in Datastat, Inc. Table 1 Characteristics of WMH samples and percent (and number) with history of chronic lung diseases. Country Field dates Age rangea Sample size Response rate (%) History of adult onset chronic lung diseases (21+) Part 1 Part 2 sub-sample N Weighted % SE Mean age of diagnosis SE Americas Colombia 2003 18–65 4426 2381 87.7 3 0.2 0.1 33.7 2.2 Mexico 2001–2 18–65 5782 2362 76.6 7 0.1 0.0 39.6 6.4 United States 2002–3 18+ 9282 5692 70.9 128 2.1 0.3 53.3 1.9 Peru 2005–6 18–65 3930 1801 90.2 4 0.4 0.2 36.8 7.1 Asia and South Pacific Japan 2002–6 20+ 4129 1682 55.1 16 0.9 0.3 55.1 4.2 PRC Shen Zhenb 2006–7 18+ 7132 2475 80.0 20 0.4 0.1 36.2 4.5 New Zealand 2003–4 18+ 12,790 7312 73.3 107 1.4 0.2 54.3 2.3 Europe Belgium 2001–2 18+ 2419 1043 50.6 34 2.4 0.5 51.3 4.2 France 2001–2 18+ 2894 1436 45.9 51 2.9 0.6 41.6 2.2 Germany 2002–3 18+ 3555 1323 57.8 25 1.7 0.4 47.5 3.4 Italy 2001–2 18+ 4712 1779 71.3 37 1.6 0.3 48.9 3.0 The Netherlands 2002–3 18+ 2372 1094 56.4 20 1.1 0.5 50.8 3.7 Spain 2001–2 18+ 5473 2121 78.6 55 1.5 0.3 47.4 2.0 Northern Ireland 2004–7 18+ 4340 1986 68.4 11 0.3 0.1 47.0 3.1 Portugal 2008–9 18+ 3849 2060 57.3 20 0.8 0.2 43.1 3.4 Romania 2005–6 18+ 2357 2357 70.9 31 1.2 0.3 35.8 2.3 Poland 2010–11 18–64 10,081 4000 50.4 26 0.6 0.1 43.5 1.7 Middle East Israel 2002–4 21+ 4859 4859 72.6 177 3.4 0.3 43.4 1.1 Iraq 2006–7 18+ 4332 4332 95.2 18 0.5 0.1 51.9 5.4 Mean age of diagnosis (all countries combined) 47.6 0.8 Prevalence of chronic lung disease (all countries combined) 1.3 0.1 Weighted average response rate (%) 67.4 Total sample size 98,714 52,095 790 a For the purposes of cross-national comparisons we limit the sample to 18 + . b People's Republic of China. Table 2 Prevalence and concurrent associations between 12-month mental disorders and lifetime COPD. Type of 12-month disorder Among those with lifetime COPD Among those without lifetime COPD Concurrent associations between 12 month disorders and lifetime COPD1 % SE % SE OR (95% C.I) Mood disorder Major depressive episode/Dysthymia 8.7 1.5 5.3 0.1 2.1 (1.5–2.9) Bipolar disorder (Broad) 1.8 0.5 1.3 0.1 2.3 (1.2–4.2) Anxiety disorder Panic disorder 2.2 0.6 1.1 0.1 2.5 (1.6–3.9) Generalized anxiety disorder 6.4 1.3 2.0 0.1 2.6 (1.7–4.1) Social phobia 7.0 1.2 2.8 0.1 2.4 (1.7–3.4) Specific phobia 8.5 1.4 5.8 0.1 1.5 (1.1–2.1) Agoraphobia without panic 1.4 0.5 0.5 0.0 3.2 (1.7–5.9) Post-traumatic stress disorder 3.2 0.7 1.7 0.1 2.3 (1.5–3.5) Obsessive compulsive disorder 1.6 0.8 1.2 0.1 2.7 (1.0–7.3) Impulse-control disorder Intermittent explosive disorder 3.0 1.1 2.1 0.1 1.6 (0.8–3.5) Bulimia nervosa – – 0.2 0.0 – – Binge eating disorder 0.7 0.4 0.6 0.1 1.4 (0.5–3.9) Substance use disorder Alcohol abuse 1.7 0.8 1.6 0.1 1.7 (0.8–3.9) Alcohol abuse with dependence 0.9 0.3 0.6 0.0 1.7 (0.8–3.5) Drug abuse – – 0.5 0.0 – – Drug abuse with dependence – – 0.2 0.0 – – “–”: Unstable estimates due to low number of cases(<5). 1 Each 12-month mental disorder type was estimated as a predictor in separate logistic regression model controlling for current age, gender, country, smoking (ever/current/never) and years of education. Table 3 Bivariate and multivariate associations (odds ratios) between DSM-IV mental disorders and the subsequent diagnosis of COPD. Type of disorders Single disorder models1 Comorbid disorders model2 OR (95% C.I.) OR (95% C.I.) I. Mood disorders Major Depressive Episode/Dysthymia 2.2 (1.7–2.8) 1.6 (1.3–2.0) Bipolar Disorder (Broad) 3.5 (2.2–5.7) 1.5 (0.8–2.7) II. Anxiety disorders Panic Disorder 2.1 (1.4–3.3) 1.2 (0.8–1.8) Generalized Anxiety Disorder 2.8 (2.0–3.9) 1.7 (1.2–2.4) Social Phobia 2.1 (1.4–3.0) 1.1 (0.8–1.6) Specific Phobia 1.7 (1.3–2.3) 1.2 (0.9–1.6) Agoraphobia without Panic 2.7 (1.5–5.0) 1.5 (0.8–2.8) Post-Traumatic Stress Disorder 2.1 (1.4–3.1) 1.2 (0.8–1.7) Obsessive Compulsive Disorder 2.7 (1.2–6.5) 1.7 (0.7–4.1) III. Impulse-control disorders Intermittent Explosive Disorder 3.0 (1.8–4.9) 1.6 (0.9–2.8) Binge Eating Disorder 1.6 (0.8–3.2) 1.0 (0.5–1.8) Bulimia Nervosa 0.9 (0.3–3.3) 0.4 (0.1–1.5) IV. Substance disorders Alcohol Abuse 2.4 (1.7–3.4) 1.8 (1.3–2.7) Alcohol Dependence with Abuse 2.9 (1.6–5.0) 1.1 (0.6–2.2) Drug Abuse 2.3 (1.5–3.8) 1.2 (0.7–2.1) Drug Dependence with Abuse 2.4 (1.2–4.9) 0.8 (0.4–1.8) Joint effect of all types of disorders, χ216 112.9 Difference between types of disorders, χ215 17.4 1 Single disorder models: each mental disorder type was estimated as a predictor of the physical condition diagnosis in a separate discrete time survival model controlling for age cohorts, gender, person-year, country, smoking (ever/current/never) and years of education. 2 Comorbid disorders model: the model was estimated with dummy variables for all mental disorders entered simultaneously, including the controls specified above. Table 4 Prevalence and association between number of disorders and COPD. Number of mental disorder Among those with lifetime chronic lung diseases Among those without lifetime chronic lung diseases All Number of disorders model1 % SE % SE % SE OR (95% C.I) Exactly 1 disorder 18.3 2.0 16.0 0.2 16.0 0.2 1.6* (1.3–2.1) Exactly 2 disorders 9.0 1.4 6.6 0.1 6.6 0.1 2.4* (1.7–3.5) Exactly 3 disorders 6.2 1.0 2.8 0.1 2.9 0.1 3.8* (2.6–5.8) Exactly 4 disorders 1.9 0.5 1.4 0.1 1.5 0.1 3.1* (1.8–5.6) 5+ disorders 3.8 0.8 1.6 0.1 1.6 0.1 5.8* (3.5–9.6) Joint effect of number of disorders, χ25 – – – – – – 64.2* 1 Numberofdisordersmodel:the model was estimated using a discrete-time survival model with dummy variables for number of mental disorders without any information about type of mental disorders, including the controls specified in Table 3. References [1] Willgoss TG Yohannes AM Anxiety disorders in patients with COPD: a systematic review Respir. 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Psychiatry 2007 29 123 133 17336661 [22] Shah BV Armitage P Colton T Linearization Methods of Variance Estimation Encyclopedia of Biostatistics 1998 2276 2279 John Wiley and Sons Chichester [23] SUDAAN Software for the Statistical Analysis of Correlated Data [Program] 1999 Research Triangle Park North Carolina, USA [24] CDC Chronic obstructive pulmonary disease among adults — United States, 2011 MMWR 2012 61 938 943 23169314 [25] Bednarek M Maciejewski J Wozniak M Prevalence, severity and underdiagnosis of COPD in the primary care setting Thorax 2008 63 402 407 18234906 [26] Vassend O Skrondal A The role of negative affectivity in self assessment of health: a structural equation approach J. Health Psychol 1999 4 465 482 22021640 [27] Kolk AM Hanewald GJ Schagen S Predicting medically unexplained physical symptoms and health care utilization. A symptom-perception approach J. Psychosom. 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PMC005xxxxxx/PMC5120396.txt
LICENSE: This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. 101589550 40869 JAMA Psychiatry JAMA Psychiatry JAMA psychiatry 2168-622X 2168-6238 26018466 5120396 10.1001/jamapsychiatry.2015.0575 NIHMS830489 Article Psychotic experiences in the general population: a cross-national analysis based on 31,261 respondents from 18 countries McGrath John J. PhD, MD 123* Saha Sukanta PhD 123 Al-Hamzawi Ali MD 4 Alonso Jordi DrPH, MD 56 Bromet Evelyn J. PhD 7 Bruffaerts Ronny PhD 8 Caldas-de-Almeida José Miguel PhD, MD 9 Chiu Wai Tat MS 10 de Jonge Peter PhD 11 Fayyad John MD 12 Florescu Silvia PHD, MD 13 Gureje Oye MD 14 Haro Josep Maria PhD, MD 15 Hu Chiyi PhD, MD 16 Kovess-Masfety Viviane PhD, MD 17 Lepine Jean Pierre HDR, MD 18 Lim Carmen W. MSc 19 Mora Maria Elena Medina PhD 20 Navarro-Mateu Fernando PhD, MD 21 Ochoa Susana PhD 22 Sampson Nancy BA 10 Scott Kate PhD 19 Viana Maria Carmen PhD, MD 23 Kessler Ronald C. PhD 10 1 Queensland Centre for Mental Health Research, The Park Centre for Mental Health, Wacol, QLD 4076, Australia 2 Discipline of Psychiatry, University of Queensland, St Lucia, QLD 4072, Australia 3 Queensland Brain Institute, University of Queensland, St Lucia, QLD 4072, Australia 4 College of Medicine, Al-Qadisiya University, Diwania governorate, Iraq 5 Health Services Research Unit, IMIM-Institut de Recerca Hospital del Mar, Barcelona, Spain 6 CIBER en EpidemiologÕïa y Salud Puïblica (CIBERESP), Barcelona, Spain 7 Department of Psychiatry, Stony Brook University School of Medicine 8 Universitair Psychiatrisch Centrum - Katholieke Universiteit Leuven (UPC-KUL), Campus Gasthuisberg, Belgium 9 Chronic Diseases Research Center (CEDOC) and Department of Mental Health, Faculdade de Ciências Médicas, Universidade Nova de Lisboa, Portugal 10 Department of Health Care Policy, Harvard Medical School, Boston, Massachusetts, USA 11 University of Groningen, University Medical Center, Groningen Department of Psychiatry, Interdisciplinary Center, Psychopathology and Emotion regulation (ICPE), Groningen, The Netherlands 12 Institute for Development, Research, Advocacy, and Applied Care (IDRAAC), Beirut, Lebanon 13 National School of Public Health, Management and Professional Development, Bucharest, Romania 14 Department of Psychiatry, University College Hospital, Ibadan, Nigeria 15 Parc Sanitari Sant Joan de Déu, CIBERSAM, Universitat de Barcelona, Spain 16 Shenzhen Insitute of Mental Health & Shenzhen Kanging Hospital, China 17 Ecole des Hautes Etudes en Santé Publique (EHESP), EA 4057 Paris Descartes University, Paris, France 18 Hôpital Lariboisière Fernand Widal, Assistance Publique Hôpitaux de Paris INSERM UMR-S 1144, University Paris Diderot and Paris Descartes Paris, France 19 Department of Psychological Medicine, Dunedin School of Medecine, University of Otago, New Zealand 20 National Institute of Psychiatry Ramón de la Fuente, Mexico 21 Subdirección General de Salud Mental y Asistencia Psiquiátrica. Servicio Murciano de Salud, El Palmar (Murcia), Spain 22 Parc Sanitari Sant Joan de Déu, CIBERSAM, Universitat de Barcelona 23 Department of Social Medicine, Federal University of Espírito Santo, Brazil * Corresponding author: Professor John McGrath, Queensland Centre for Mental Health Research, The Park Centre for Mental Health, Wacol, Queensland, 4076, Australia. j.mcgrath@uq.edu.au, Phone: +61 7 3271 8694, Fax: +61 7 3271 8698 17 11 2016 7 2015 23 11 2016 72 7 697705 This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. IMPORTANCE Community-based surveys find that many otherwise healthy individuals report histories of hallucinations and delusions. To date, most studies have focused on the overall lifetime prevalence of ever having any of these psychotic experiences (PEs), possibly masking important features related to types and frequencies of PEs. OBJECTIVE To explore detailed epidemiological information of PEs in a large cross-national sample. DESIGN, SETTING, AND PARTICIPANTS Data came from the WHO World Mental Health (WMH) Surveys, a coordinated set of community epidemiological surveys of the prevalence and correlates of mental disorders in representative household samples in countries throughout the world. 31 261 adult (aged 18 and older) WMH respondents across 18 countries were asked about lifetime and 12-month prevalence and frequency of six types of PEs (two hallucinatory experiences [HEs] and four delusional experiences [DEs]). MAIN OUTCOMES Prevalence, frequency, and correlates of PEs. RESULTS Mean lifetime prevalence (standard error) of ever having a lifetime PE was 5.8% (0.2), with hallucinatory experiences (5.2% [0.2]) much more common than delusional experiences (1.3% [0.1]), More than two-thirds (72.0%) of respondents with lifetime PEs reported experiencing only one type. PEs were typically infrequent, with 32.2% of respondents with lifetime PEs reporting only one occurrence and an additional 31.8% only 2–5 occurrences. There was a significant relationship between having more than one type of PE and having more frequent PE episodes. Lifetime prevalence estimates were significantly higher among respondents in middle and high income countries than low income countries, women than men, the non-married than the married, not employed and those with low family income. CONCLUSIONS AND RELEVANCE The epidemiology of PEs is more nuanced than previously thought. Research is needed that focuses on similarities and differences in predictors of the onset, course, and consequences of distinct PEs. There has been a growing interest in recent years in the epidemiology of hallucinations and delusions.1 These psychotic experiences (PEs) are reported by a sizeable minority of the general population. A recent meta-analysis based on 61 studies reported that the median lifetime prevalence of PE was 7.2%.2 Because this is substantially higher than the lifetime morbid risk (MR) of psychotic disorders such as schizophrenia (median MR 0.7%),3 the field of psychiatric epidemiology has been forced to rethink how PEs ‘fit’ into the epidemiologic landscape of psychotic disorders. The terminology to describe these experiences has also evolved over time. Sometimes referred to as psychotic-like experiences, we will use the general term psychotic experiences to encompass both hallucinatory experiences (HEs) and delusional experiences (DEs).2 Early work on the epidemiology of PEs focused on these experiences as risk indicators for later conversion to full psychosis. There is an appealing logic to this type of research, as many of the risk factors associated with PEs are also associated with schizophrenia/psychosis.4 More recently, evidence has accumulated that PEs are also associated with the subsequent onset of a wide array of common mental disorders including anxiety, mood, and substance use disorders,5–7 as well as with an increased risk of suicidal ideation and intent.8–10 Thus, there is a growing awareness that the presence of PEs may reflect a vulnerability to a wide range of adverse mental health outcomes (in addition to psychotic disorders).11–16 These findings, and the concern that antipsychotic medications may be inappropriately used to treat individuals with isolated PEs, may have influenced the decision to exclude ‘Attenuated Psychosis Syndrome’ in recently revised diagnostic criteria.17 As the empirical data have accumulated, systematic reviews have pooled prevalence estimates and applied meta-regression techniques in order to explore the socio-demographic correlates of PEs.2,15,18,19 These reviews provide valuable clues to the nature of PEs, but also highlight important gaps in the literature. Four of these gaps are of special importance for the current study. Firstly, the use of pooling in systematic reviews of PEs has encouraged the use of coarse dichotomous measures (e.g. lifetime prevalence present/absent) in order to harmonize the wide array of scales and diagnostic instruments used to assess PEs.2 This has reduced the subtlety of the associations examined in these reviews. Secondly, the studies included in the systematic reviews have varied in many key design elements. As noted by Linscott and van Os 2 substantial heterogeneity in the data has hampered analyses related to the relationship between PEs and socio-demographic variables. Thirdly, the vast majority of community studies of PE prevalence and correlates have been carried out in high income countries. A major exception is the World Health Survey (WHS), which included four brief PE questions in surveys of 52 nations.20 However, the WHS assessment of PEs had several limitations (e.g. it lacked information on frequency of PE occurrence; and questions about DEs were not asked in a fashion that excluded experiences related to alcohol, illicit drugs or sleep). Finally, in order to allow pooling of data from different studies, some reviews have collapsed different variables across orthogonal axes. For example, Kaymaz et al15 compiled composite variables related to ‘weak’ and ‘strong’ PEs, which in theory could be built from data related to: (1) the count of different types of PEs, (2) the frequency of occurrence, (3) associated distress, (4) comorbidity, and/or (5) ‘certainty’ (e.g. confidence in the psychotic nature of the experience). Leading commentators have repeatedly called for more fine-grained analyses of PE in order to guide the field.1,21 The current report presents initial results of analyses designed to address the above limitations by examining data collected in the WHO World Mental Health (WMH) Surveys, a series of population-based surveys carried out in many countries using consistent instruments and field procedures designed to facilitate pooled cross-national analyses of the prevalence and correlates of mental disorders. These data provide an unprecedented opportunity to explore the epidemiologic landscape of PEs. Methods Participants The WMH surveys are a coordinated set of community epidemiological surveys administered in probability samples of the household population in countries throughout the world (www.hcp.med.harvard.edu/WMH). Eighteen of the 26 WMH surveys completed up to now administered the CIDI Psychosis Module. These 18 countries are distributed across North and South America (Colombia, Mexico, Peru, Sao Paulo in Brazil, USA); Africa (Nigeria); the Middle East (Iraq, Lebanon); Asia (Shenzhen in the People’s Republic of China [PRC]); the South Pacific (New Zealand); and Europe (Belgium, France, Germany, Italy, the Netherlands, Portugal, Romania, Spain). All 18 surveys were based on multi-stage, clustered area probability household sampling designs (Table 1). The weighted average response rate across all 18 countries was 72.1%. Most surveys were based on nationally representative sample frames, but a few excluded rural areas (Colombia, Mexico), or focused on particular regions (Nigeria, Shenzhen), or cities (Sao Paulo). Participating sites were grouped into 3 country-level income strata according to World Bank criteria22 - ‘low and lower-middle income’ countries (Colombia, Iraq, Nigeria, PRC-Shenzhen, Peru), upper-middle income (Sao Paulo, Lebanon, Mexico, Romania), and high-income countries (the European countries, New Zealand, USA). The age ranges reported here include 18 years and over except in three countries (Mexico, Colombia, Peru) where 65 years was the upper age limit. In keeping with previous studies of PEs,9,11,23–28 we made the a priori decision to exclude individuals who had PEs but who also screened positive for possible schizophrenia/psychosis, and manic-depression/mania (i.e. respondents who (a) reported (1) schizophrenia/psychosis or (2) manic-depression/mania” in response to the question “What did the doctor say was causing (this/these) experiences?”; and (b) those who ever took any antipsychotic medications for these symptoms). This resulted in the exclusion of 140 respondents (0.4% of all respondents), leaving 31,261 respondents for this study (see Table 1). Measures and Assessments All WMH surveys were conducted face-to-face in the homes of respondents by trained lay interviewers. Informed consent was obtained before beginning interviews in all countries. Procedures for obtaining informed consent and protecting individuals (ethical approval) were approved and monitored for compliance by the institutional review boards of the collaborating organisations in each country.29 Full details of these procedures are described elsewhere.30,31 All WMH interviews had two parts. Part I, administered to all respondents, contained assessments related to core mental disorders. Part II included additional information relevant to a wide range of survey aims, including assessment of PEs. All Part I respondents who met criteria for any Part I DSM IV mental disorder as well as a probability sample of other respondents were administered Part II. Part II respondents were weighted by the inverse of their probability of selection for Part II to adjust for differential sampling. Within the different sites, questions related to PEs were either administered to all respondents or a random sample of those administered Part II. Analyses in this article were based on the weighted Part II subsample of respondents administered the CIDI Psychosis Module. Additional weights were used to adjust for differential probabilities of selection within households, nonresponse, and to match the samples to population socio-demographic distributions. The instrument used in the WMH surveys was the WHO Composite International Diagnostic Interview (CIDI),32 a validated fully-structured diagnostic interview designed to assess the prevalence and correlates of a wide range of mental disorders according to the definitions and criteria of both the DSM-IV and ICD-10 diagnostic systems. The CIDI Psychosis Module included questions about 6 PE types – 2 related to HEs (visual hallucinations, auditory hallucinations) and 4 related to DEs (two ‘bizarre’ delusional items - thought insertion/withdrawal, mind control/passivity; two ‘paranoid’ delusional items - ideas of reference, plot to harm/follow) (See Appendices A1 & A2). For example, respondents were asked if they ever experienced PEs (e.g. “Have you ever heard any voices that other people said did not exist?”). This was followed by a probe question to determine if the reported PEs ever occurred when the person was ‘not dreaming, not half-asleep, or not under the influence of alcohol or drugs’. Only responses of the latter type are considered here. The sequence of these follow-up probe types differed slightly between the first 6 WMH surveys, which were carried out in Europe (Belgium, France, Germany, Italy, the Netherlands, Spain), and the remaining 12 countries (See eTables 1 and 2). Respondents who reported PEs were then asked about: (a) presence of the PEs in the past 12 months; and (b) frequency/occurrences of the PEs in their lifetime. In this paper we present prevalence estimates for any PE, any HE (with or without associated DEs), any DE (with or without associated HEs), ‘pure’ HE (without DEs) and ‘pure’ DE (without HEs). In addition, we will present two key PE-related metrics: (a) count of types of PEs (henceforth referred to as PE type metric); and (b) frequency of occurrence of PE episodes (henceforth referred to as PE frequency metric). Respondents may have had more than one hallucination and/or delusion type associated with a single episode of PEs. For the PE frequency metric, reported frequency of lifetime PE episodes was divided into 5 categories: only once, 2–5 times, 6–10 times, 11–100 times, and 101 and above. This five-category scheme was collapsed into 1–10 versus 11+ in analyses of socio-demographic correlates of PE frequency among respondents with lifetime PEs. The socio-demographic factors considered here include: gender, age, number of years of education, employment history, marital status, family income, and nativity (i.e. born inside the country of assessment). For the bivariate and multivariate analyses, the socio-demographic variables were stratified into broad categories based on methodology described elsewhere.29 Statistical Analysis Weighted prevalence estimates were calculated for the various PE types and related metrics. Odds ratios (ORs) and design-corrected 95% confidence intervals (CIs) are reported. Because the WMH survey data featured geographical clustering and weighting, standard errors (se) of parameter estimates were generated using the design-based Taylor series linearization method implemented in a SAS macro (SAS Institute inc. version 9.4). Multivariate significance was evaluated using Wald χ2 tests based on design-corrected coefficient variance–covariance matrices. The association between the PE type metric versus the PE frequency metric was evaluated using the Cochran-Armitage test. Statistical significance was evaluated consistently using two-tailed .05-level tests. Results Prevalence of PEs Table 2 presents country-specific lifetime PE prevalence estimates. Lifetime prevalence (se) of at least 1 PE was reported by 5.8% (0.2) of the 31 261 respondents. Lifetime prevalence of any HE was 5.2% (0.2) and of any DE 1.3% (0.1). The median and interquartile range (IQR) of lifetime PEs, HEs and DEs were 5.5% (IQR: 2.8–7.5), 4.4% (IQR: 1.8–6.5), and 1.3% (IQR: 0.9–1.8), respectively (see eFigures 1–3 for cumulative distribution of PE, HE and DE estimates respectively). Twelve-month prevalence (se) of any PE was 2.0% (0.1), while the median (IQR) was 1.4% (1.0–2.8). Lifetime PEs prevalence (se) was significantly higher among women than men (6.6% [0.2] vs. 5.0% [0.3]; χ21=16.0, p< .001). Similar gender differences were found for prevalence of HEs (5.9% [0.2] vs. 4.3% [0.3]; χ21 =19.4, p< .001) but not DEs (1.4% [0.1] vs. 1.3% [0.1]; χ21=0.3, p=.61). The significant gender difference was also found for respondents with ‘pure’ HEs (5.2% [0.2] vs. 3.7% [0.3]; χ21=19.3, p < .001), but not ‘pure’ DEs (0.7% [0.1] vs. 0.7% [0.1]; χ21=0.1, p = .80). Significant differences were found across the three country-level income strata in lifetime prevalence of any PE, any HE and any DE – in each comparison the prevalence estimates were significantly higher among respondents in middle and high income countries than low income countries (χ22 ranged from 7.1 to 58.2, each p < .001). The prevalence of individual PEs and the distribution of the PE type metric Table 3 shows the lifetime prevalence estimates of individual PE types and counts of different PE types. The most common PE type overall was visual hallucinations (3.8% [0.2]) followed by auditory hallucinations (2.5% [0.1]). Prevalence estimates of individual DE types were low (0.3– 0.7%). Among those with any lifetime PE, 72.0% (representing 4.2% of the total sample) reported only 1 PE type, 21.1% (representing 1.2% of the total sample) exactly 2 types, and 6.8% (representing 0.4% of the total sample) 3 or more types. The distribution of the PE frequency metric, and the relationship between PE type and PE frequency metrics PEs were typically infrequent, with 32.2% of the respondents with lifetime PEs reporting only one solitary episode (Table 4). An additional 31.8% of respondents with lifetime PEs experienced only 2–5 PE episodes. Thus, for nearly two-thirds of respondents (64.0%) with lifetime PEs, these experiences occurred only 1–5 times in their lives. An additional 10.0% of respondents with lifetime PEs reported 6–10 lifetime episodes, 20.0% 11–100 episodes, and 6.0% 101 or more episodes. The relationship between the PE type metric and the PE frequency metric is best displayed in Table 5. Those with more PE types are disproportionately more likely to have more PE episodes (Cochran-Armitage z = −10.0, p <.001). Associations between socio-demographic factors with lifetime PEs, HEs and DEs eTable 3 shows the association of socio-demographic variables with lifetime PEs, HEs and DEs in bivariate and multivariate models. Several socio-demographic variables were associated with increased Odds Ratios for PEs, HEs and DEs in both models: (a) being a homemaker or classified as ‘other’ employment (looking for work, disabled etc.) (versus employed); (b) being non-married (never married or separated/widowed/divorced) (versus married), and (c) lower household income (versus high income). In addition to these findings, several socio-demographic variables were associated with only one type of PE. Young respondents (18–29 years) were significantly more likely to have DEs (compared to those over 60 years), while age was unrelated to HEs (and overall PEs). While female sex was associated with an increased prevalence of PEs (in both models), this finding was driven by an increased risk of HEs (but not DEs). Low education, in comparison, was associated with an increased risk of DEs, but not HEs. Unexpectedly, those born outside the country (i.e. migrants) were significantly less likely than the native born to report HEs (but not DEs) in both bivariate and multivariate models. Associations of socio-demographic factors with PE type and PE frequency metrics Concerning factors that influence the PE type metric (in those who had experienced PEs), in the multivariate model, the three younger age strata (i.e. that spanned 18 to 59 years) were significantly more likely to have more than one PE type (compared to those aged 60+ years) (eTable 4). None of the other socio-demographic characteristics was associated with the PE type metric. Concerning the correlates of the PE frequency metric, student status was significantly associated with lower frequency of PE occurrence. None of the other socio-demographic variables was associated with PE frequency (eTable 5). Discussion Based on cross-national samples from 18 countries, we found that 5.8% of respondents reported having one or more PEs at least once in their lifetime and 2.0% in the previous year. These overall estimates are broadly consistent with the previous literature.2 In addition, though, our study foregrounds important new information regarding the count of PE types and frequency of PEs that go beyond the issues considered in previous community-based studies of PEs. Perhaps the most striking finding is that these experiences are infrequent for the majority of individuals who experience PEs, with 32.2% reporting only one PE episode in their life and 64% reporting no more than 5 lifetime occurrences. In the general population, those with 2 or more types of PEs are also significantly more likely to have more PE episodes. For example, of those who reported 3 or more PE types, nearly a quarter (24.5%) reported more than 101 occurrences. Our findings provide an empirical foundation upon which to investigate factors that influence the persistence of PEs.1 When viewed within the context of the gap between 12-month and lifetime PE estimates from the current study (i.e. 2.0% versus 5.8%), we can infer that most individuals do not have persistent PEs. Mindful that lifetime prevalence estimates for mental health disorders are often downward-biased due to under-reporting.33 Linscott and van Os2 estimated that of those who report any PEs, approximately 80% would have had transient experiences. This estimate is consistent with our empirical finding that about 64% of individuals with PEs report only 1–5 lifetime occurrences. Based on the set of PEs examined, our study confirms that hallucinations were more common than delusions (5.2% versus 1.3%), and this general pattern was consistent across the 3 country-level income strata. We note that the lifetime prevalence of PEs was lower in the low-lower middle income countries (3.2%) compared to the upper-middle and high income countries (7.2%, 6.8% respectively). While we cannot directly compare our results with the one previous cross-national study of PEs 20 due to differences in how PEs were assessed, we note that both studies (optimized for consistent design and PE assessment) provided insights in variation between sites. One of the strengths of cross-national studies such as the WMH Survey is that they are able to identify risk factors that exist consistently across countries despite site-specific cultural factors. We found an increased prevalence of both HEs and DEs associated with being unmarried, not employed, and having low household income. However, certain demographic features were differentially associated with HEs but not DEs, and vice versa. For example, women had a significantly higher prevalence of HEs but not DEs. We found a significant relationship between younger age and DEs, but not HEs. Unexpectedly, migrants in our study were significantly less likely to report lifetime HEs (compared to native born respondents). These novel findings provide important points of distinction between the epidemiology of psychotic disorders and PEs.4,34 It is of interest to note that while several socio-demographic variables were significantly associated with the lifetime prevalence of PEs, these features were not associated with the PE type or PE frequency metrics. We speculate that comorbid psychiatric illness (e.g. depression, anxiety disorders) and other risk factors known to be associated with PEs and mental disorders (e.g. family history, substance use, trauma exposure) may contribute to these PE-related metrics. The comprehensive nature of the WMH survey will allow us to explore these hypotheses in future analyses. While the study has many strengths (e.g. large sample size, range of countries, uniform methodology for data collection, innovative analysis of PE-related metrics), there are several limitations. In keeping with other population-based surveys, we relied on trained lay interviewers to administer the questionnaire. While we excluded those who were screen-positive for possible psychotic disorders, we did not have access to valid measures of clinical psychotic disorders. Lifetime prevalence estimates are prone to under-reporting.33 We only assessed four types of DEs, and these probes may have been insensitive to culture-specific delusional beliefs.16 Conclusions We have provided the most comprehensive description of the epidemiology of PEs published to date. While the lifetime prevalence of PEs is 5.8%, these are mostly rare events. For nearly a third of those who have PEs (i.e. 32.2%), these were solitary (i.e. one-off) events. In the general population there is a small subgroup of individuals who have multiple types of PEs and who experiences these PEs more frequently. The research community needs to leverage this fine-grained information in order to better determine how PEs reflect risk status. Our study highlights the subtle and variegated nature of the epidemiology of PEs, and provides a solid foundation upon which to explore the bi-directional relationship between PEs and mental health disorders. Supplementary Material Appendix Tables The surveys discussed in this article were carried out in conjunction with the World Health Organization (WHO) World Mental Health (WMH) Survey Initiative. We thank the WMH staff for assistance with instrumentation, fieldwork, and data analysis. These activities were supported by the US National Institute of Mental Health (NIMH: R01MH070884), the John D. and Catherine T. MacArthur Foundation, the Pfizer Foundation, the US Public Health Service (R13-MH066849, R01-MH069864, and R01 DA016558), the Fogarty International Center (FIRCA R01- TW006481), the Pan American Health Organization, Eli Lilly and Company, Ortho-McNeil Pharmaceutical Inc., GlaxoSmithKline, and Bristol-Myers Squibb. A complete list of WMH publications can be found at www.hcp.med.harvard.edu/wmh/. Each WMH country obtained funding for its own survey. The São Paulo Megacity Mental Health Survey is supported by the State of São Paulo Research Foundation (FAPESP) Thematic Project Grant 03/00 204-3. The Shenzhen, People’s Republic of China Mental Health Survey is supported by the Shenzhen Bureau of Health and the Shenzhen Bureau of Science, Technology and Information. The Colombian National Study of Mental Health (NSMH) is supported by the Ministry of Social Protection, with supplemental support from the Saldarriaga Concha Foundation. The ESEMeD project is funded by the European Commission (Contracts QLG5–1999–01042; SANCO 2004123), the Piedmont Region (Italy), Fondo de Investigación Sanitaria, Instituto de Salud Carlos III, Spain (FIS 00/0028), Ministerio de Ciencia y Tecnología, Spain (SAF 2000–158-CE), Departament de Salut, Generalitat de Catalunya, Spain, Instituto de Salud Carlos III (CIBER CB06/02/0046, RETICS RD06/0011 REM-TAP), and other local agencies and by an unrestricted educational grant from GlaxoSmithKline. Implementation of the Iraq Mental Health Survey (IMHS) and data entry were carried out by the staff of the Iraqi MOH and MOP with direct support from the Iraqi IMHS team with funding from both the Japanese and European funds through United Nations Development Group Iraq Trust Fund (UNDG ITF). The Lebanese National Mental Health Survey (LEBANON) is supported by the Lebanese Ministry of Public Health, the WHO (Lebanon), anonymous private donations to IDRAAC, Lebanon, and unrestricted grants from Janssen Cilag, Eli Lilly, GlaxoSmithKline, Roche, and Novartis. The Mexican National Co-Morbidity Survey (MNCS) is supported by The National Institute of Psychiatry Ramon de la Fuente (INPRFMDIES 4280) and by the National Council on Science and Technology (CONACyT-G30544-H), with supplemental support from the Pan American Health Organization (PAHO), Te Rau Hinengaro: The New Zealand Mental Health Survey (NZMHS), is supported by the New Zealand Ministry of Health, Alcohol Advisory Council, and the Health Research Council. The Nigerian Survey of Mental Health and Wellbeing (NSMHW) is supported by the WHO (Geneva), the WHO (Nigeria), and the Federal Ministry of Health, Abuja, Nigeria. The Peruvian World Mental Health Study was funded by the National Institute of Health of the Ministry of Health of Peru. The Portuguese Mental Health Study was carried out by the Department of Mental Health, Faculty of Medical Sciences, NOVA University of Lisbon, with the collaboration of the Portuguese Catholic University, and was funded by the Champalimaud Foundation, the Gulbenkian Foundation, the Foundation for Science and Technology (FCT) and the Ministry of Health. The Romania WMH study projects ‘Policies in Mental Health Area’ and ‘National Study regarding Mental Health and Services Use’ were carried out by the National School of Public Health and Health Services Management (former the National Institute for Research and Development in Health, present National School of Public Health Management and Professional Development, Bucharest), with technical support from Metro Media Transylvania, the National Institute of Statistics – National Center for Training in Statistics, Cheyenne Services SRL, Statistics Netherlands and were funded by the Ministry of Public Health (formerly the Ministry of Health) with supplemental support from Eli Lilly Romania SRL. The US National Co-Morbidity Survey Replication (NCS-R) is supported by the US NIMH (U01- MH60220) with supplemental support from the National Institute of Drug Abuse (NIDA), the Substance Abuse and Mental Health Services Administration (SAMHSA), the Robert Wood Johnson Foundation (RWJF; Grant 044708), and the John W. Alden Trust. JMcG was funded by the John Cade Fellowship from the National Health and Medical Research Council (APP1056929). The views and opinions expressed in this report are those of the authors and should not be construed to represent the views or policies of any of the sponsoring organizations, agencies, or the WHO. The funders had no input into the design and conduct of the study; collection, management, analysis and interpretation of the data; or preparation, review or approval of the manuscript. Table 1 World Mental Health (WMH) sample characteristics by World Bank income categoriesa, and sample for psychotic experiences (PEs) after exclusion of 140 respondents who were screen-positive for possible schizophrenia/psychosisb Country by income categorya Sample characteristicsc, d Field dates Age range Sample size Response rate e Part I PEs sample I. Low and lower middle income countries Colombia All urban areas of the country 2003 18–65 4,426 722 87.7 Iraq Nationally representative 2006–7 18–96 4,332 4,329 95.2 Nigeria 21 of the 36 states in the country 2002–3 18–100 6,752 1,417 79.3 PRCf – Shenzheng Shenzhen metropolitan area 2006–7 18–88 7,132 2,468 80.0 Peru Nationally representative 2004–5 18–65 3,930 530 90.2 TOTAL 26,572 9,466 84.7 II. Upper-middle income countries Brazil - São Paulo São Paulo metropolitan area 2005–7 18–93 5,037 2,922 81.3 Lebanon Nationally representative 2002–3 18–94 2,857 1,029 70.0 Mexico All urban areas of the country 2001–2 18–65 5,782 715 76.6 Romania Nationally representative 2005–6 18–96 2,357 2,357 70.9 TOTAL 16,033 7,023 75.8 III. High-income countries Belgium Nationally representative 2001–2 18–95 2,419 319 50.6 France Nationally representative 2001–2 18–97 2,894 301 45.9 Germany Nationally representative 2002–3 18–95 3,555 408 57.8 Italy Nationally representative 2001–2 18–100 4,712 617 71.3 Netherlands Nationally representative 2002–3 18–95 2,372 348 56.4 New Zealandg Nationally representative 2003–4 18–98 12,790 7,263 73.3 Portugal Nationally representative 2008–9 18–81 3,849 2,053 57.3 Spain Nationally representative 2001–2 18–98 5,473 1,159 78.6 United States Nationally representative 2002–3 18–99 9,282 2,304 70.9 TOTAL 47,346 14,772 65.5 IV. Total 89,951 31,261 72.1 a Based on World Bank country level of economic development (The World Bank. (2008). Data and Statistics. Accessed May 12, 2009 at: http://go.worldbank.org/D7SN0B8YU0) b Respondents were excluded if they endorsed any PE but also (a) reported (1) schizophrenia/psychosis or (2) manic-depression/mania” in response to the question “What did the doctor say was causing (this/these) experiences?”; and (b) those who ever took any antipsychotic medications for these symptoms. This resulted in the exclusion of 140 respondents (0.4% of all respondents), leaving 31,261 respondents for this study. c NSMH (The Colombian National Study of Mental Health); IMHS (Iraq Mental Health Survey); NSMHW (The Nigerian Survey of Mental Health and Wellbeing); EMSMP (La Encuesta Mundial de Salud Mental en el Peru); LEBANON (Lebanese Evaluation of the Burden of Ailments and Needs of the Nation); M-NCS (The Mexico National Comorbidity Survey); RMHS (Romania Mental Health Survey); ESEMeD (The European Study Of The Epidemiology Of Mental Disorders); NZMHS (New Zealand Mental Health Survey); NMHS (Portugal National Mental Health Survey); NCS-R (The US National Comorbidity Survey Replication). d Most WMH surveys are based on stratified multistage clustered area probability household samples in which samples of areas equivalent to counties or municipalities in the US were selected in the first stage followed by one or more subsequent stages of geographic sampling (e.g., towns within counties, blocks within towns, households within blocks) to arrive at a sample of households, in each of which a listing of household members was created and one or two people were selected from this listing to be interviewed. No substitution was allowed when the originally sampled household resident could not be interviewed. These household samples were selected from Census area data in all countries other than France (where telephone directories were used to select households) and the Netherlands (where postal registries were used to select households). Several WMH surveys (Belgium, Germany, and Italy) used municipal resident registries to select respondents without listing households. 13 of the 18 surveys are based on nationally representative household samples. e The response rate is calculated as the ratio of the number of households in which an interview was completed to the number of households originally sampled, excluding from the denominator households known not to be eligible either because of being vacant at the time of initial contact or because the residents were unable to speak the designated languages of the survey. The weighted average response rate is 72.1%. f People’s Republic of China g For the purposes of cross-national comparisons we limit the sample to those 18+. Table 2 Lifetime and 12-month prevalence of psychotic experiences in the World Mental Health surveys Lifetime Any PEb Lifetime Any HEc Lifetime Any DEd 12-month PE Total Sample Income categorya Country n1e (%f, SE) n1e (%f, SE) n1e (%f, SE) n1e (%f, SE) Ng Low and Lower-Middle Colombia 73 (7.5,1.2) 68 (7.1,1.2) 11 (0.9,0.3) 25 (2.1,0.5) 722 Iraq 51 (1.2,0.2) 46 (1.1,0.2) 13 (0.4,0.2) 25 (0.7,0.2) 4329 Nigeria 39 (2.2,0.5) 32 (1.7,0.4) 16 (1.0,0.4) 15 (1.0,0.4) 1417 PRC-Shenzhen 151 (5.3,0.8) 116 (3.8,0.6) 54 (1.8,0.4) 45 (1.4,0.3) 2468 Peru 36 (6.4,1.4) 33 (6.1,1.4) 7 (1.1,0.4) 18 (3.3,0.9) 530 Total Low and Lower-Middle 350 (3.2,0.3) 295 (2.6,0.2) 101 (0.9,0.1) 128 (1.2,0.2) 9466 Upper-Middle Brazil-Sao Paulo 548 (14.9,0.9) 471 (13.3,0.9) 183 (3.6,0.3) 230 (5.6,0.4) 2922 Lebanon 37 (1.9,0.4) 30 (1.6,0.4) 14 (0.6,0.3) 15 (0.9,0.4) 1029 Mexico 53 (4.1,1.0) 49 (3.6,0.9) 12 (0.8,0.4) 22 (1.4,0.4) 715 Romania 24 (1.0,0.4) 21 (0.9,0.4) 5 (0.1,0.1) 9 (0.3,0.1) 2357 Total Upper-Middle 662 (7.2,0.4) 571 (6.4,0.4) 214 (1.7,0.1) 276 (2.7,0.2) 7023 High Belgium 32 (8.3,2.5) 19 (5.0,1.6) 20 (5.7,2.3) 11 (4.1,2.4) 319 France 27 (5.7,1.4) 23 (4.9,1.3) 7 (1.6,0.6) 6 (1.3,0.7) 301 Germany 25 (2.8,0.5) 16 (1.8,0.4) 13 (1.3,0.3) 6 (1.0,0.2) 408 Italy 38 (4.5,0.8) 31 (3.5,1.0) 16 (1.9,0.6) 12 (1.3,0.5) 617 Netherlands 47 (10.8,2.5) 41 (10.1,2.5) 11 (1.6,0.5) 13 (3.0,1.2) 348 New Zealand 724 (6.9,0.4) 667 (6.5,0.4) 134 (0.9,0.1) 271 (2.4,0.2) 7263 Portugal 140 (5.2,0.7) 106 (3.9,0.5) 66 (2.6,0.5) 43 (1.7,0.3) 2053 Spain 91 (6.7,1.5) 77 (5.8,1.5) 35 (1.4,0.4) 19 (0.9,0.2) 1159 United States 249 (8.6,0.9) 232 (8.2,0.9) 41 (1.3,0.2) 79 (2.8,0.4) 2304 Total High 1373 (6.8,0.3) 1212 (6.2,0.3) 343 (1.4,0.1) 460 (2.2,0.2) 14772 All Countries 2385 (5.8,0.2) 2078 (5.2,0.2) 658 (1.3,0.1) 864 (2.0,0.1) 31261 a Income = Based on World Bank country level of economic development (The World Bank. (2008). Data and Statistics. Accessed May 12, 2009 at: http://go.worldbank.org/D7SN0B8YU0); b PE = Psychotic experience (any of the six types); c HE = Hallucinatory experience (either of the two types); d DE = Delusional experience (any of the four types); e n1 = Unweighted number of respondents who reported the PEs; f Prevalence estimates are based on weighted data; g N = The total unweighted number of respondents who were asked about PEs. Table 3 Lifetime prevalence of individual psychotic experiences in the World Mental Health surveys Type Lifetime prevalence na (%b, SE) HE - visual 1545 (3.8,0.2) HE - auditory (verbal) 1051 (2.5,0.1) Any HEc 2078 (5.2,0.2) DE - thought insertion/withdrawal 193 (0.4,0.0) DE - mind control/passivity 148 (0.3,0.0) DE - ideas of reference 209 (0.4,0.0) DE - plot to harm/follow 328 (0.7,0.1) Any DEd 658 (1.3,0.1) Any PEe 2385 (5.8,0.2) Exactly 1 PE type 1631 (4.2,0.2) Exactly 2 PE types 544 (1.2,0.1) 3 or more PE types 210 (0.4,0.0) Total Sample (N f ) 31261 (100,0.0) a n = Unweighted number of respondents who reported the PEs; b Prevalence estimates are based on weighted data; c HE = Hallucinatory experience (either of the two items); d DE = Delusional experience (any of the four items); e PE = Psychotic experience (any of the six items); f N = The total unweighted number of respondents who were asked about PEs. Table 4 Frequency of lifetime occurrence of psychotic experiences (PEs) among respondents who reported ever having one or more PE in the World Mental Health surveys Sample Type PE frequency metric Row Sample Size 1 2–5 6–10 11–100 101 or more na %b (SE) %b (SE) %b(SE) %b(SE) %b(SE) All countries (except for ESEMed#) HE - visual 1379 31.9 (1.7) 32.0 (1.7) 10.5 (1.0) 18.7 (1.4) 6.7 (0.9) HE - auditory (verbal) 965 20.8 (1.9) 31.7 (2.2) 11.1 (1.3) 26.5 (1.9) 9.9 (1.3)  Any HEc 1871 30.4 (1.4) 32.4 (1.4) 10.0 (0.8) 20.6 (1.3) 6.6 (0.8) DE - thought insertion/withdrawal 162 28.9 (4.1) 27.1 (3.9) 9.7 (2.0) 15.6 (2.9) 18.8 (3.3) DE - mind control/passivity 136 27.1 (5.0) 18.2 (3.5) 11.8 (2.5) 24.2 (4.5) 18.8 (4.6) DE - ideas of reference 169 15.5 (2.6) 24.5 (4.5) 13.2 (2.8) 23.7 (4.0) 23.1 (5.2) DE - plot to harm/follow 278 36.4 (3.5) 26.2 (2.8) 12.6 (2.2) 18.7 (2.4) 6.0 (1.8)  Any DEd 556 29.1 (2.5) 27.6 (2.1) 12.6 (1.5) 18.2 (1.8) 12.5 (2.0)  Any PEe 2125 31.7 (1.4) 31.9 (1.3) 10.1 (0.7) 20.0 (1.2) 6.4 (0.7) Exactly 1 PE type 1452 37.5 (1.7) 32.3 (1.5) 8.9 (0.8) 18.0 (1.4) 3.3 (0.7) Exactly 2 PE types 491 16.7 (3.3) 35.3 (3.6) 12.8 (2.5) 24.9 (2.5) 10.3 (1.9) 3 or more PE types 182 17.2 (2.8) 17.6 (3.5) 13.8 (3.4) 25.6 (3.9) 25.8 (4.3) ESEMed# only  Any PEe 260 36.4 (3.3) 30.7 (2.9) 9.5 (1.5) 20.3 (2.3) 3.2 (0.9) Exactly 1 PE type 179 43.0 (3.9) 29.6 (3.7) 4.3 (1.4) 21.0 (2.1) 2.1 (0.9) Exactly 2 PE types 53 23.6 (8.6) 33.7 (4.7) 32.3 (5.7) 6.8 (1.3) 3.6 (1.4) 3 or more PE types 28 2.1 (0.6) 34.0 (12.1) 2.5 (1.0) 48.2 (12.5) 13.2 (5.6) All countries  Any PEe 2385 32.2 (1.3) 31.8 (1.2) 10.0 (0.7) 20.0 (1.1) 6.0 (0.6) Exactly 1 PE type 1631 38.1 (1.5) 32.0 (1.4) 8.4 (0.7) 18.3 (1.2) 3.2 (0.6) Exactly 2 PE types 544 17.4 (3.1) 35.1 (3.3) 14.6 (2.3) 23.2 (2.2) 9.7 (1.8) 3 or more PE types 210 15.6 (2.5) 19.3 (3.3) 12.7 (3.1) 27.9 (3.9) 24.5 (3.9) a n = Unweighted number of respondents who reported the PEs; b Prevalence estimates are based on weighted data; c HE = Hallucinatory experience (either of the two types); d DE = Delusional experience (any of the four types); e PE = Psychotic experience (any of the six types); # ESEMeD = European Study of the Epidemiology of Mental Disorders. Table 5 Cross table of psychotic experiences (PE) frequency metric and PE type metric in the World Mental Health surveys PE frequency metric Row Sample Size 1 2–5 6 or more Cochran- Armitage test Chi-Square test Sample Type na %b (SE) %b (SE) %b (SE) z (p-value) χ22 (p-value) All countries Exactly 1 PE type 1631 38.1 (1.5) 32.0 (1.4) 29.9 (1.5) −10.0* (<.001) 32.1* (<.001) 2 or more PE types 754 16.9 (2.4) 31.2 (2.6) 51.8 (2.9) a n = Unweighted number of respondents who reported the PEs; b Prevalence estimates are based on weighted data; * Significant at 0.05 level, two-sided test (p value shown in table). Potential Conflict of Interests Over the past three years RK has been a consultant for Hoffman-La Roche Inc, Johnson & Johnson Wellness and Prevention, Sonofi-Aventis Group. RK has served on advisory boards for Mensante Corporation, Plus One Health Management, Lake Nona Institute and US Preventive Medicine. There are no other competing interests. 1 van Os J The Many Continua of Psychosis JAMA Psychiatry 2014 2 Linscott RJ van Os J An updated and conservative systematic review and meta-analysis of epidemiological evidence on psychotic experiences in children and adults: on the pathway from proneness to persistence to dimensional expression across mental disorders Psychol Med 2013 43 6 1133 1149 22850401 3 Saha S Chant D Welham J McGrath J A Systematic Review of the Prevalence of Schizophrenia PLoS Med 2005 2 5 e141 15916472 4 Kelleher I Cannon M Psychotic-like experiences in the general population: characterizing a high-risk group for psychosis Psychol Med 2010 1 6 5 Freeman D Fowler D Routes to psychotic symptoms: trauma, anxiety and psychosis-like experiences Psychiatry Res 2009 169 2 107 112 19700201 6 Varghese D Scott J Welham J Psychotic-like experiences in major depression and anxiety disorders: a population-based survey in young adults Schizophr Bull 2011 37 2 389 393 19687152 7 Johns LC Cannon M Singleton N Prevalence and correlates of self-reported psychotic symptoms in the British population Br J Psychiatry 2004 185 298 305 15458989 8 Nishida A Sasaki T Nishimura Y Psychotic-like experiences are associated with suicidal feelings and deliberate self-harm behaviors in adolescents aged 12–15 years Acta Psychiatr Scand 2010 121 4 301 307 19614622 9 Saha S Scott JG Johnston AK The association between delusional-like experiences and suicidal thoughts and behaviour Schizophr Res 2011 132 2–3 197 202 21813264 10 Kelleher I Devlin N Wigman JT Psychotic experiences in a mental health clinic sample: implications for suicidality, multimorbidity and functioning Psychol Med 2014 44 8 1615 1624 24025687 11 Saha S Scott JG Varghese D McGrath JJ The association between general psychological distress and delusional-like experiences: a large population-based study Schizophr Res 2011 127 1–3 246 251 21239145 12 Stochl J Khandaker GM Lewis G Mood, anxiety and psychotic phenomena measure a common psychopathological factor Psychol Med 2014 1 11 13 Armando M Nelson B Yung AR Psychotic-like experiences and correlation with distress and depressive symptoms in a community sample of adolescents and young adults Schizophr Res 2010 119 1–3 258 265 20347272 14 Werbeloff N Drukker M Dohrenwend BP Self-reported Attenuated Psychotic Symptoms as Forerunners of Severe Mental Disorders Later in Life Arch Gen Psychiatry 2012 15 Kaymaz N Drukker M Lieb R Do subthreshold psychotic experiences predict clinical outcomes in unselected non-help-seeking population-based samples? A systematic review and meta-analysis, enriched with new results Psychol Med 2012 1 15 16 DeVylder JE Burnette D Yang LH Co-occurrence of psychotic experiences and common mental health conditions across four racially and ethnically diverse population samples Psychol Med 2014 44 16 3503 3513 25065632 17 Carpenter WT van Os J Should attenuated psychosis syndrome be a DSM-5 diagnosis? Am J Psychiatry 2011 168 5 460 463 21536700 18 Linscott RJ van Os J Systematic reviews of categorical versus continuum models in psychosis: evidence for discontinuous subpopulations underlying a psychometric continuum. Implications for DSM-V, DSM-VI, and DSM-VII Annu Rev Clin Psychol 2010 6 391 419 20192792 19 van Os J Linscott RJ Myin-Germeys I Delespaul P Krabbendam L A systematic review and meta-analysis of the psychosis continuum: evidence for a psychosis proneness-persistence-impairment model of psychotic disorder Psychol Med 2008 1 17 20 Nuevo R Chatterji S Verdes E Naidoo N Arango C Ayuso-Mateos JL The Continuum of Psychotic Symptoms in the General Population: A Cross-national Study Schizophr Bull 2010 21 David AS Why we need more debate on whether psychotic symptoms lie on a continuum with normality Psychol Med 2010 1 8 22 World Bank World Development Indicators Washington, D.C World Bank 2003 23 Saha S Scott J Varghese D McGrath J The association between physical health and delusional-like experiences: a general population study PLoS ONE 2011 6 4 e18566 21541344 24 Saha S Scott J Varghese D McGrath J Anxiety and depressive disorders are associated with delusional-like experiences: a replication study based on a National Survey of Mental Health and Wellbeing BMJ Open 2012 2 3 25 Saha S Scott JG Varghese D Degenhardt L Slade T McGrath JJ The association between delusional-like experiences, and tobacco, alcohol or cannabis use: a nationwide population-based survey BMC Psychiatry 2011 11 202 22204498 26 Saha S Scott JG Varghese D McGrath JJ Socio-economic disadvantage and delusional-like experiences: A nationwide population-based study Eur Psychiat 2013 28 1 59 63 27 Scott J Chant D Andrews G Martin G McGrath J Association between trauma exposure and delusional experiences in a large community-based sample Br J Psychiatry 2007 190 339 343 17401041 28 Varghese D Saha S Scott JD Chan RCK McGrath JJ The Association Between Family History of Mental Disorder and Delusional-Like Experiences: A General Population Study American Journal of Medical Genetics Part B-Neuropsychiatric Genetics 2011 156B 4 478 483 29 Kessler RC Ustun TB The WHO World Mental Health Surveys: Global Perspectives on the Epidemiology of Mental Disorders New York Cambridge University Press 2008 30 Kessler RC Haro JM Heeringa SG Pennell BE Ustun TB The World Health Organization World Mental Health Survey Initiative Epidemiol Psichiatr Soc 2006 15 3 161 166 17128617 31 Kessler RC Üstün TB The World Health Organization Composite International Diagnostic Interview Kessler RC Üstün TB The WHO World Mental Health Surveys: Global Perspectives on the Epidemiology of Mental Disorders New York Cambridge University Press 2008 58 90 32 Kessler RC Ustun TB The World Mental Health (WMH) Survey Initiative Version of the World Health Organization (WHO) Composite International Diagnostic Interview (CIDI) Int J Methods Psychiatr Res 2004 13 2 93 121 15297906 33 Moffitt TE Caspi A Taylor A How common are common mental disorders? Evidence that lifetime prevalence rates are doubled by prospective versus retrospective ascertainment Psychol Med 2010 40 6 899 909 19719899 34 Kelleher I Cannon M Whither the psychosis-neurosis borderline Schizophr Bull 2014 40 2 266 268 24436054
PMC005xxxxxx/PMC5120543.txt
LICENSE: This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. 8803460 3682 Eur Respir J Eur. Respir. J. The European respiratory journal 0903-1936 1399-3003 27587549 5120543 10.1183/13993003.00120-2015 NIHMS830760 Article Control of Lung Defense by Mucins and Macrophages: Ancient defense mechanisms with modern functions Janssen William J. 12 Stefanski Adrianne L. 2 Bochner Bruce S. 3 Evans Christopher M. 2 1 Department of Medicine, National Jewish Health, 1400 Jackson St. Denver, Colorado 80206 2 Department of Medicine, University of Colorado School of Medicine, 12700 E 19th Avenue, Mailstop 8611, Research Complex 2, Room 3121, Aurora, Colorado, 80045, USA 3 Department of Medicine, Division of Allergy-Immunology, Northwestern University Feinberg School of Medicine, 240 E. Huron St., Room M-306, Chicago, IL 60611 Corresponding Author: Christopher M. Evans, PhD, Associate Professor, Department of Medicine, Division of Pulmonary Sciences and Critical Care, University of Colorado Denver School of Medicine, 12700 E 19th Avenue, Mailstop 8611, Aurora, CO, 80045, (303) 724-6573 [tele], Christopher.Evans@ucdenver.edu 19 11 2016 1 9 2016 10 2016 01 4 2017 48 4 12011214 This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. Due to the need to balance the requirement for efficient respiration in the face of tremendous levels of exposure to endogenous and environmental challenges, it is crucial for the lungs to maintain sustainable defense that minimizes damage caused by exposures and the detrimental effects of inflammation to delicate gas exchange surfaces. Accordingly, epithelial and macrophage defenses constitute essential 1st and 2nd lines of protection that prevent the accumulation of potentially harmful agents in the lungs, and under homeostatic conditions do so effectively without inducing inflammation. Though seemingly distinct, recent data show that epithelial and macrophage mediated defenses are linked through their shared reliance on airway mucins, in particular the polymeric mucin MUC5B. This review highlights our understanding of novel mechanisms that link mucus and macrophage defenses. The roles of phagocytosis and the effects of factors that are contained within mucus on phagocytosis, as well as newly identified roles for mucin glycoproteins in the direct regulation of leukocyte functions are discussed. The emergence of this nascent field of glycoimmunobiology sets forth a new paradigm for considering how homeostasis is maintained under healthy conditions and how it is restored in disease. Introduction The principal function of the lungs is gas exchange. To this end, under normal tidal breathing, 8,000–12,000 liters of air pass through lungs each day. Gas flows through multiple generations of conducting airways, which ultimately terminate in the alveoli. Alveoli are bounded by type I epithelial cells that cover over 95% of the lung surface, and to allow for efficient exchange of O2 and CO2, type I epithelia are extremely thin and together with alveolar capillaries create a diffusion distance of <1 µm. Consequently, these thin surfaces are protected by elaborate defense mechanisms that must trap and eliminate particulates and pathogens before they reach the alveolar walls, while simultaneously preventing and/or suppressing potentially inflammatory responses that could injure delicate gas exchange structures. This review concentrates on the mucociliary escalator and alveolar macrophages (AMs) as crucial first and second lines of host defense in the lungs. Airway tissues are exposed to ~100 billion inhaled particles daily (1). Airborne particles can arise from natural and manmade sources, can vary in size and chemical composition, can differ in concentrations based on geography and local environments, and can thus result in heterogeneous pathological responses (2–8). Most inspired materials are large enough to impact upon nasopharyngeal and tracheal mucosae where they are transported proximally by mucociliary clearance (MCC) and are ultimately eliminated by expectoration or swallowing. The remainder deposit in the lung periphery where they are ingested by AMs. Under healthy conditions, particulate deposition in the periphery is primarily limited to small particles (<1 µm diameter). However, under conditions where particulate concentrations are high or in pathological settings where MCC is impaired, larger particles can also accumulate in the lung periphery. Together, the coordinated functions of MCC and AMs eliminate inhaled particulates from the alveoli and airways, and hence comprise robust mechanisms for exogenous clearance. At the same time, clearance also removes endogenous materials that are generated during normal cell turnover or as a consequence of disease. Critically, although AM and MCC functions are ordinarily considered distinct, emerging data show that their functions are tightly linked through physiological and biochemical mechanisms. Below we describe mucus and macrophages separately, and this is followed by a discussion of emerging knowledge of interactions between them. The mucus barrier and MCC MCC involves the coordinated activities of secretory cells that release polymeric mucin glycoproteins, and multi-ciliated cells whose apically localized motile cilia provide a means for transport and elimination. Cilia are molecular machines whose structural and motile components are highly regulated; their complex assembly, function, and dysfunction in diseases are reviewed elsewhere (9, 10). For the purposes of this review, we consider physiological roles of motile cilia, and we highlight key aspects of mucociliary interactions that are essential in the airways. MCC requires the coordinated regulation of airway surface liquid to control the osmolarity, viscoelasticity, and resultant transportability of secreted mucus (11, 12). This control is driven by electrolyte transport machinery intracellularly as well as the presence of osmolytes in the extracellular space. Although ciliated and mucous layers have been considered as separate entities (‘sol’ and ‘gel’ phases), this distinction is challenged by recent studies demonstrating it as a more continuous glycoprotein hydrogel. Membrane mucins (MUC1, MUC4, and MUC16) that are present along cilia surfaces form a hydrated brush that allows for the free movement of cilia. The overlying, viscoelastic mucus layer is positioned atop this grafted brush of cilia. As a result, airway surface hydration regulates the balance between cilia and mucus structures maintained in a ‘gel-on-brush’ conformation that promotes effective motility and MCC (13). Loss of MCC is a significant cause of respiratory infections. For instance, impaired MCC is a primary pathophysiological feature of infection-related diseases such as primary ciliary dyskinesia (PCD) where cilia motility is impaired or absent, and cystic fibrosis (CF) where airway surface dehydration causes mucus adhesion to airway surfaces and hyperosmotic collapse of underlying cilia. Less appreciated perhaps are findings in COPD and asthma, which also show significant MCC impairment (14–21). Unlike the primary roles of altered mucus and ciliary structures in CF and PCD, COPD and asthma-related changes are secondary to inflammatory or injurious stimuli that cause impairments in ciliary motility and the dysregulated production of the two major secreted mucins, MUC5AC and MUC5B (22–25). Expression of the airway mucins MUC5AC and MUC5B Under healthy conditions, MUC5AC and MUC5B are both produced in the lungs. MUC5AC is found predominantly in surface epithelia throughout the central conducting airways, whereas MUC5B is found mainly in submucosal glands of central airways (trachea and bronchi) and in non-ciliated surface epithelial cells of peripheral airways. MUC5AC levels increase in both airway surface and glandular epithelia in asthma (22, 23) and COPD (24, 26, 27). By contrast, MUC5B levels are more variable. For example, in patients with established CF and COPD, MUC5B levels are increased in sputum (28, 29), which is predominated by central airway secretions that are supplied by tracheobronchial submucosal glands. However, in patients with early or pre-clinical COPD or with strong allergic asthma MUC5B levels actually decrease, especially within epithelial cells that line central and peripheral airway surfaces where MUC5B transcript levels are reduced by 90% or more (22–24, 27). It is thus plausible that differential repression of MUC5B could affect MCC and contribute to lung pathologies. Indeed, recent studies in mice provide mechanistic support for this. In mice, deletion of the Muc5b gene caused severe upper and lower airway MCC impairments and led to the development of lethal spontaneous infections (30). Interestingly, although chronic infection and inflammation were prominent outcomes in Muc5b knockout mice, their pathobiological impacts were stronger than those observed in models of PCD. In cilia-defective Dnaic, Pcdip1, Spef2, and Cby knockout mice, although MCC is severely impaired, upper airway pathologies were not reported to be lethal, and they did not carry over to the lower respiratory tract (31–33). Thus, among MCC components in the lungs, Muc5b is a dominant regulator of homeostatic microbial elimination. In addition, during chronic spontaneous and acute experimental infections, Muc5ac production increased in Muc5b knockout mice. Although not entirely protective itself, Muc5ac could have played a role in delaying the effects of infections (30). Possible explanations for the mucin functions in airway defense (as well as differences between Muc5ac and Muc5b) may reflect differences in their polymeric structures, glycosylation, and interactions with microbes or anti-microbial molecules. Determination of the specific and overlapping roles of Muc5ac and Muc5b remains an area of urgent investigation. Mucin Expression MUC5AC/Muc5ac and MUC5B/Muc5b gene expression levels are regulated by endogenous and environmental factors. For human MUC5B, single nucleotide polymorphisms have been shown to regulate expression via control of promoter activity (34–36). These genetic controls likely impact (or are impacted upon) by numerous innate and adaptive immune cytokine signaling pathways, as well as growth factor regulated mechanisms that are associated with responses to inflammation, injury, and tissue repair. These are reviewed extensively elsewhere (37–42). Lastly, endogenous factors include developmental (43–46) and epigenetic (47–49) regulatory mechanisms, which may play roles in the expression of mucins in cancers. Mucin polymerization The abilities of secreted mucins to regulate MCC are largely dependent on their polymer structures formed through disulfide bonds (Figure 1). Like other members of the secreted polymeric mucin family, Muc5ac and Muc5b are composed of ~5–6% cysteines (~250–300 per molecule). They have cysteine-rich N- and C- terminal von Willebrand factor (vWF) type D-like and C- terminal cysteine knot disulfide bonding domains that are critical for intermolecular mucin assembly (50–52). Additional highly conserved cysteine-rich CysD domains are interspersed in varying numbers in polymeric mucin carbohydrate-rich repeats (53–55). Through intramolecular disulfide linkages, CysD domains are proposed to form hydrophobic loop structures that facilitate mucin alignment and regulate mucus mesh spacing (56). Furthermore, in each mucin at least 100 cysteines exist that are not found in defined “domains”. In all cases, the majority of disulfide bonds are thought to form intracellularly during assembly. In the extracellular environment, free cysteines that do exist may become oxidized and form additional cross-links that increase the elastic moduli of mucus gels (57). Disruption of N- and C-terminal bonds or CysD’s may be sufficient to “loosen” obstructive mucus. Accordingly, current mucolytic therapies such as N-acetylcysteine, as well as investigative therapies, target these by reducing disulfides and decreasing mucus viscoelasticity, thereby enhancing mucus transport (58–60). A current challenge is to determine which therapies can be given at doses that are well-tolerated and still maintain the benefits of efficient defense. Mucin glycosylation While disulfide polymerization is an important but underappreciated aspect of secreted mucins, their glycosylation is perhaps more eminent. Mucins are defined by their heavy glycosylation, especially within variable-sized glycan-rich domains (see Figure 1). In MUC5AC and MUC5B, these regions are called ‘PTS’ domains due to their enrichment in prolines, threonines, and serines. PTS-rich repeats are sites of O-glycosylation, starting with N-acetylgalactosamine on serine and threonine residues. Galactose and N-acetylglucosamine are then attached and elaborated linearly or in branches, and the sugars can be modified by sulfation or by the addition of terminal sialic acid and fucose glycans. Two chief purposes of mucin glycans are to adsorb water and to participate in host defense. For water adsorption, glycan variations can greatly affect the osmotic pressures imparted by mucus gels. For example, sialylated and sulfated termini are strongly charged, and their large polar surface areas promote both hydration and electronegative repulsion (11, 13). On the other hand, fucose has a lower charge and an approximately 50% lower polar surface area, which hypothetically promotes mucus aggregation, increases viscoelasticity, and thereby inhibits MCC. For host defense, mucin glycans are known to interact with sugar binding molecules on a variety of bacteria that colonize or infect the lungs (61–67) and gastrointestinal tract (68–74), fungi such as Aspergillus fumigatus (75) and respiratory viruses such as respiratory syncytial virus and influenza (76, 77). Whether these interactions are beneficial to the host or the microbe vary widely. Nonetheless, as the result of host genetics and environmental exposures (such as infectious or allergic states) protection is limited. Impaired defense may be affected by changes in the properties of mucus (e.g., through variations in MUC5AC/Muc5ac vs MUC5B/Muc5b expression levels or glycosylation) that are often coupled with ciliary dysfunction (e.g., through loss/absence of ciliated cells or components of motile cilia) (78–91). Taken together, the roles of mucins in the formation and maintenance of a mucus gel, and their abilities to bind microorganisms demonstrate the coordinated function and dysfunction of mucus binding and clearance dynamics in host defense. In summary, this conventional view of the mucociliary barrier as a defense system regulated by mucus and ciliary functions has been refined by the identification of key factors such as Muc5b and by the dissection of complex biophysical regulation of mucociliary interactions. An immediate challenge is to relate these to specific and required molecular components that regulate their intrinsic biophysical functions. Furthermore, new findings have introduced a novel set of interactions through which mucins regulate defense and inflammation in the lungs via resident and recruited pulmonary leukocyte populations. In particular, dendritic cell, eosinophil, and macrophage functions in various tissues have been demonstrated to be regulated specifically by mucin terminal glycans. Below we focus on macrophage and eosinophil functions that are regulated by extracellular oligosaccharides, including the airway mucin Muc5b. Macrophage ontogeny and clearance mechanisms Particulates and microbes that evade the first line of defense--epithelial mucus--reach the distal lung where they must be cleared rapidly and efficiently by the second line of defense--phagocytes. AMs are the dominant phagocytic cell in the lungs, and during health account for up to 90% of the leukocytes in airspaces (92–95) They reside in the alveolar lumen, and perhaps also in the airways. In addition to clearing inhaled particulates, they are critical for removing dying cells and maintaining alveolar homeostasis. Recent evidence suggests that AMs arise from progenitors that occupy the fetal liver and yolk sac during embryogenesis (96–98). At birth, these cells populate the airspaces where they quickly mature into resident AMs. Importantly, AMs self-renew throughout life, and in the absence of disease, they are not replaced by monocytes from the circulation (99–101). During inflammation, resident AMs proliferate locally (102). At the same time monocytes from the circulation migrate to inflamed regions where they mature into macrophages, termed monocyte-derived AMs (MDAMs) (103). Hence, the inflammatory AM pool contains cells of both embryonic and post-natal origin. Although both macrophage subsets demonstrate phagocytic capacity, their respective contributions to the clearance of exogenous particulates and pathogens and to the removal of endogenous debris and cells remain unknown. Intriguingly, as inflammation resolves MDAMs undergo programmed cell death and are removed from the lungs, leaving behind the embryonically derived resident AMs to maintain alveolar homeostasis (103). During health, resident AMs function as sentinels, constantly surveying the luminal environment for pathogens and inhaled particulates. Under most circumstances, such agents are cleared silently and quickly - without inducing systemic inflammatory responses that could injure alveolar gas exchange structures. Indeed, experimental depletion of AMs results in exaggerated inflammatory responses (104–112), yet at the same time AM absence impairs the ability to control infection (107, 110, 113) demonstrating that restrained responses are more efficacious and beneficial. As discussed below, the alveolar environment plays an essential role in regulating AM endocytic and inflammatory responses, and it also contains a diverse array of molecules that recognize pathogens and facilitates clearance by non-inflammatory phagocytic defense. Phagocytic Mechanisms AMs employ a number of mechanisms to ingest particulates and pathogens, all of which involve endocytosis, a process in which the plasma membrane surrounds a target, invaginates, and then pinches off to form a membrane bound vesicle (reviewed in (114, 115)). Phagocytosis is the primary endocytic process by which AMs clear exogenous materials and is driven by cytoskeletal rearrangements that lead to rapid internalization of pathogens such as bacteria or fungi in a membrane bound phagosome. The phagosome becomes acidified after sequential fusion with endosomes and lysosomes, which contain hydrolytic enzymes and reactive oxygen species that digest and destroy the target. An initial interface that AM’s have with particles and pathogens occurs through a phagocytic synapse formed by a diverse array of plasma membrane proteins that recognize phagocytic targets through specific moieties on them, including microbial and host cell glycoconjugates. These AM receptors initiate and/or modulate phagocytosis. Phagocytic Receptors AMs are equipped with a vast repertoire of phagocytic receptors. Importantly, during microbial contact many different receptor families are often simultaneously activated. Some receptors directly recognize specific molecules on phagocytic targets (e.g., phosphatidyl serine or inflammasome molecules), whereas others bind to targets coated with opsonins (e.g., immunoglobulins, complement, and surfactant materials). In addition, whereas some (e.g. Fc receptors) lead directly to pathogen engulfment, others (e.g. Toll-like receptors (TLRs)) promote phagocytosis indirectly by upregulating the expression of phagocytic receptors and their downstream signaling molecules (116–118). Here we discuss main classes of receptors on AMs in the context of opsonins and signals present in airway mucus (119–125). Immunoglobulin (Ig) signaling is an important adaptive immune process that mediates AM phagocytosis. AMs express high levels of Fcγ-receptors I (CD64), II (CD32) and III (CD16) that recognize the Fc region of IgG. Biologically relevant concentrations IgG can be found in the alveolar lining fluid of healthy humans (126). To trigger phagocytosis, Fcγ-receptors bind multiple IgG molecules within an immune complex. FcγRI is a high affinity receptor that in addition to respiratory burst and microbial killing also leads to phagocytosis. In comparison, FcγRII and FcγRIII may also promote phagocytosis but have low binding affinity. Respiratory epithelial cells secrete IgA by transcytosis, and IgA can easily be detected in the lumens of both the proximal airways and alveoli (126, 127). AMs express low levels of both FcαRI (CD89) and Fcα/µR that bind IgA and drive phagocytosis (128). Adaptive immune Ig functions are linked to glycan structures through the recognition of carbohydrate antigens, N- and O-glycosylation of their Fc domains, and physical association with secreted mucins that have specific Ig binding domains (129–132). The complement system aids in innate host defense by opsonizing immune complexes and pathogens, enhancing their killing and removal. Alveolar lavage fluid of healthy humans contains components of the classical (C1q, C2, C3, C4) and alternative (C3, Factor B) pathways (133–135). The classical pathway is primarily activated by the interaction of C1q with antigen-antibody complexes, but it can also be activated by direct binding of C1q to bacterial, fungal and virus membrane components (136, 137). Opsonization of targets by either means can stimulate phagocytosis. AMs express three complement receptors (CRs), CR1, CR3 and CR4. CR1 is incapable of internalizing opsonized particles on its own, but can enhance Fc-mediated phagocytosis. CR3 and CR4 are heterodimers that share a common β2 integrin chain (CD18) paired with specific α chains. CR4 contains the αX subunit (CD11c) and binds to particles opsonized with C3b and iC3b fragments. CR3 contains an αM chain (also known as CD11b) with a carbohydrate-binding lectin site. Accordingly, in addition to binding particles opsonized with C3b and iC3b fragments, CR3 binds microbial cell wall glycan-containing components including LPS, mannan, β-glucan, and others (138, 139). While CR3 appears to be capable of internalizing opsonized bacteria independently (140, 141) it also functions cooperatively with other receptors including CR1, CD14, FcγR and FcαRI (138, 142–144) to enhance particle clearance. Not surprisingly, mice deficient in CR3 have impaired host defense to gram-negative bacteria, gram-positive bacteria and yeast (145, 146). Importantly, studies from rodents demonstrate that cell surface expression of complement receptors varies markedly on resident AMs versus recruited MDAMs (103): Resident AMs express high levels of CD11c/CR4 but not CD11b/CR3, whereas recruited MDAMs have high CD11b/CR3 but low CD11c/CR4. This raises the intriguing hypothesis that AM subpopulations have complementary functions to control infectious and inflammatory host defense. Like Ig’s, complement components are found in airway mucus, and their levels are upregulated in inflammation (147, 148). Furthermore, complement also increases the expression of Muc5ac in airway epithelial cells (149). Other classes of carbohydrate lectins, the C-type lectins, are calcium-dependent carbohydrate binding proteins that contain a conserved glycan recognition domain and are involved in pathogen recognition and phagocytosis (150). In the context of lung host defense, two groups of C-type lectins are well recognized: the pulmonary collectins (surfactant proteins A and D), and pathogen-binding receptors (namely the mannose receptor (CD206) and dectin-1). Surfactant proteins A and D (SP-A, SP-D) are comprised of highly oligomerized monomers that are formed by N-terminal collagen-like domains linked to a C-terminal carbohydrate recognition domain (CRD) by a central hinge region. Through their CRDs, SP-A and SP-D recognize sugar residues on microbial pathogens. Consequently, they opsonize gram-negative and gram-positive bacteria, mycobacteria, fungi, and viruses such as influenza A and respiratory syncytial virus. A number of candidate receptors for collectin-opsonized particles exist on AMs, including C1qRp, SP-R210, CD14, and the calreticulin-CD91 complex (reviewed extensively in (151)). In addition to enhancing phagocytosis through their opsonizing effects, collectins may also promote phagocytosis indirectly. For example, SP-A enhances expression of scavenger receptor A (SR-A) and may augment Fc-receptor and CR-mediated phagocytosis (152–154). In addition, both SP-A and SP-D appear to increase cell surface localization and hence the phagocytic function of the mannose receptor (155–157). The mannose receptor (CD206) is highly expressed on AMs, and contains an extracellular domain that recognizes mannose, N-acetylglucosamine, and fucose glycans. Accordingly, CD206 promotes phagocytosis of pulmonary pathogens with diverse extracellular carbohydrate signatures including Streptococcus pneumoniae, Klebsiella pneumoniae, Mycobacterium tuberculosis, Pneumocystis jerovecii, and fungi such as candida and aspergillus (158). Precise mechanisms by which CD206 participates in phagocytosis are unclear, and it is likely that interactions with co-receptors are required (159). Dectin-1 was originally identified as a dendritic cell-specific receptor, but it is also expressed on AMs (160). Dectin-1 recognizes β-glucans found in fungal cell walls (161, 162) and also particles opsonized with pentraxin-3, a protein rapidly synthesized and secreted by mononuclear phagocytes in response to pro-inflammatory signals (163). Together these classes of receptors highlight a group of surface molecules that interact with exogenous and endogenous constituents of airway surface liquid and mucus to mediate AM phagocytic defense. In immunocompetent individuals, defensive components such as IgG increase in the lungs during infection, promoting pathogen clearance through recognition of numerous antigen types, including carbohydrate epitopes. Indeed bacterial targets such as surface polysacharrides are exploited for use in developing effective pneumococcal vaccines (164). Conversely, recurrent sinopulmonary infections and impaired pathogen clearance are common in patients with Ig deficiencies (165–171). In addition, in common chronic airway diseases including asthma, COPD and cystic fibrosis, impaired clearance of microbial pathogens by AMs has been extensively documented (172–175). AM dysfunction correlates with disease severity and exacerbation frequency (176–178). While etiologies vary among diseases, common features include altered expression of phagocytic receptors, reduced lysosomal killing, and enhanced production of mediators that can worsen inflammation by inducing collateral damage to surrounding tissues. These defects in AMs are either absent or reduced in mononuclear phagocytes isolated from other sites (e.g. blood). Therefore, perturbations in the local environment appear to play a dominant role in altering AM function in these diseases. Emerging links between airway mucins and AM function Based on the distinct anatomical localization and the highly dedicated cellular mechanisms involved in the specification of mucin-producing goblet cells in the airways and phagocytic macrophages in the alveoli, there is an outward appearance of discrete compartmentalization of their functions. However, the limiting the localization of resident AM’s to the alveolar space is not entirely warranted, as intraluminal macrophages in conducting airways account for 2–8% of the total resident macrophage population in rat lungs (179–185). Even within the alveolar compartment recent evidence demonstrates that a subpopulation of AMs, termed sessile AMs, can communicate across great distances through via a calcium-dependent signaling AM:alveolar epithelial circuit that ultimately suppresses immune function (186). Recent studies show that there are indeed functional links between airway mucus and macrophage function, and that these links are crucial for host defense. At one level, secreted factors such as Ig’s and complement are abundant in secreted mucus, suggesting that mucus is an important carrier of these defensive molecules. In addition, there are also direct links between secreted mucins and resident innate immune cells through their coordinated activities during resolving inflammation and physical interactions between glycans on mucins and carbohydrate-binding lectin receptors on leukocytes such as the sialic acid binding immunoglobulin-like lectins (siglec’s). We propose that mucin-leukocyte interactions regulate homeostatic, inflammatory, and resolving immune functions through signaling and physical clearance mechanisms (Figure 2). In the mouse, the intestinal mucin, Muc2, interacts with glycan-selective immuno-regulatory receptors on dendritic cells that mediate the development of inflammatory and regulatory lymphocyte subsets. In this setting, Muc2 glycans bind to two lectins (Dectin-1 and Galectin-3) that function cooperatively with the inhibitory IgG receptor FcγR3 to suppress inflammatory signals and promote tolerance (187). In a similar vein, goblet cells have also been shown to be an important mechanism for the delivery of antigens to resident monocyte-derived dendritic cells in the small intestine (188). The result of these activities is the development of tolerance to foreign antigens introduced by ingested food particles. In the lungs, inhibitory regulation of leukocyte functions appears to be mediated by acute control of leukocyte activation states. In mice, Muc5b, through its α2,3-linked sialoside glycans binds to Siglec-F, an inhibitory SHP-phosphatase signaling immunoreceptor on eosinophils and AMs (189) (Figure 3). On eosinophils, Siglec-F mediates apoptosis (190–193), thereby functioning as a significant mechanism for resolving allergic inflammation. Indeed, mice lacking Siglec-F or one particular enzyme needed for this Muc5b sialylation step, ST3Gal-III, fail to make airway ligands for Siglec-F, and these mice display exaggerated and selective lung eosinophilia in a type 2 allergic inflammation lung model (194–198). In this context, Muc5b presumably contributes to the physical removal of cells by MCC while simultaneously preventing continued activation and mediator release into airspaces during elimination from the mouse lung. In humans, the Siglec-F paralog Siglec-8 also reduces eosinophil survival via sialylated and sulfated ligands, but the specificity observed between Muc5b and Siglec-F in mice is not as well conserved between MUC5B and Siglec-8 in humans (199–201). Rather, Siglec-9 is an isoform that is bound by MUC5B sialosides, and it is expressed on neutrophils, natural killer cells, dendritic cells, and monocytes/macrophages (199). Indeed, resident alveolar macrophages in healthy mouse lungs also express Siglec-F, but its role beyond that of a cell surface marker is not yet clear. Given the associations of mucus and macrophage dysfunction in numerous lung pathologies, determining the nature of their interactions will be of tremendous interest as the field advances. With the emergence of mucins as important mediators of defense, and the recognition of the crucial significance of the glycobiology of innate and adaptive immunity, efforts to interrogate these will involve both challenging and exciting experimental approaches. Conclusion Innate defenses in the lungs are essential for maintaining efficient gas exchange. As first and second lines of host defense, mucins and macrophages play critical roles that are integrated by their physical and physiological interactions. The emergence of these links presents a convergence of new challenges that connect epithelial and innate immune programs. Grant Support: WJJ: NIH HL109517, NIH HL114381. BSB: NIH AI72265, NIH HL107151; CME: NIH HL080396, NIH ES023384, AHA 14GRNT19990040. Figure 1 Polymeric and macromolecular structures of the major secreted mucins in the airways - MUC5AC and MUC5B MUC5AC and MUC5B (and their orthologs) have amino (N) and carboxyl (C) termini that are evolutionarily conserved in polymeric mucins and von Willebrand factor (vWF, grey and black regions). The vWF-like domains are involved in covalent intermolecular disulfide assembly of C-terminal linked dimers and N-terminal linked multimers. Multimers may exist as linear or branched structures with sizes in the 1 to >10 MDa range. Between vWF-like domains are additional cysteine rich regions (CysD domains, green hexagons) that are rich in hydrophobic amino acids and intramolecular disulfide bonds. CysD’s are suggested to mediate the distribution of mucin strands and gel-pore size after secretion in healthy mucus, but may become oxidized and increase in polymer size and stiffness in disease (57). Lastly, the majority of the remaining mucin apoprotein backbone is rich in proline, serine, and threonine. This ‘PTS’ domain (white) is an imperfect repeat region and is the primary site of O-linked glycosylation. O-linkages on serine and threonine residues form Core1–4 structures, which are defined the presence of N-acteylgalactosamine (GalNAc, yellow squares) linkages on the hydroxyl groups of serine and threonine followed by single or paired attachments of galactose (yellow circles) and/or N-acetylglucosamine (GlcNAc, blue squares). Lastly, galactose and GlcNAc glycans can be further substituted with fucose, sialic acid, and sulfates that impart diverse charges that may affect mucus gel hydration and also form 3-D structural confirmations that are critical for interactions with both pathogens and host-cell lectins. Glycan structures shown are examples of possible linkages and do not necessarily represent those found on specific mucins. Polar and non-polar glycans can be found on sugars from each core type, and may be found along the same or different branches. Figure 2 Mucin:leukocyte interactions during homeostasis and inflammation In healthy lungs, resident resting alveolar macrophages (AMs) are defensive and non-inflammatory. MUC5B from bronchioles mixes with alveolar fluids, providing a route for MUC5B to contact alveolar AMs. Homeostatic or low dose stimuli elicit defensive functions such as phagocytosis. During inflammation resident AMs can become activated, and this is associated with a decrease in their Siglec-F surface expression. In addition, leukocytes, such as monocyte-derived macrophages (which lack Siglec-F) or eosinophils (which express Siglec-F) are recruited and persist for brief periods of time. These transient populations are eliminated as inflammation resolves. In mice, resolution involves Siglec-F-mediated reductions in leukocyte activation and survival. Dampened and apoptotic cells are subsequently eliminated by MUC5B-mediated MCC. Figure 3 Putative Muc5b:Siglec-F signal transduction mechanism Muc5b, via its display of multivalent α2,3-sialic acid (SA) linkages on galactose residues, binds to the N-terminal lectin domain of Siglec-F, thereby driving immunoreceptor tyrosine-based inhibitory motif (ITIM) and ITIM-like domain activation. ITIM signals putatively activate SH2 domain-containing phosphatase (SHP) enzymes that suppress kinase-activated inflammatory signals and can also promote apoptosis. 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PMC005xxxxxx/PMC5120545.txt
LICENSE: This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. 0376343 5302 J Thorac Cardiovasc Surg J. Thorac. Cardiovasc. Surg. The Journal of thoracic and cardiovascular surgery 0022-5223 1097-685X 26027913 5120545 10.1016/j.jtcvs.2015.03.041 NIHMS830993 Article Coronary artery bypass grafting in diabetics: A growing health care cost crisis Raza Sajjad MD a Sabik Joseph F. III MD a Ainkaran Ponnuthurai MS b Blackstone Eugene H. MD ab a Department of Thoracic and Cardiovascular Surgery, Heart and Vascular Institute, Cleveland Clinic, Cleveland, Ohio b Department of Quantitative Health Sciences, Research Institute, Cleveland Clinic, Cleveland, Ohio Address for reprints: Joseph F. Sabik III, MD, Department of Thoracic and Cardiovascular Surgery, Cleveland Clinic, 9500 Euclid Ave/Desk J4-1, Cleveland, OH 44195 (sabikj@ccf.org) 19 11 2016 01 4 2015 8 2015 23 11 2016 150 2 3042.e2 This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. Objectives To determine 4-decade temporal trends in the prevalence of diabetes and cardiovascular risk factors among patients undergoing coronary artery bypass grafting (CABG) and to compare in-hospital outcomes, resource utilization, and long-term survival after CABG in diabetics versus nondiabetics. Methods From January 1972 to January 2011, 10,362 pharmacologically treated diabetics and 45,139 nondiabetics underwent first-time CABG. Median follow-up was 12 years. Direct technical cost data were available from 2003 onward (n = 4679). Propensity matching by diabetes status was used for outcome comparisons. Endpoints were in-hospital adverse events, resource utilization, and long-term survival. Results Diabetics undergoing CABG increased from 7%in the 1970s to 37%in the 2000s. Their outcomes were worse, with more (P < .05) in-hospital deaths (2.0% vs 1.3%), deep sternal wound infections (2.3% vs 1.2%), strokes (2.2% vs 1.4%), renal failure (4.0% vs 1.3%), and prolonged postoperative hospital stay (9.6% vs 6.0%); and their hospital costs were 9% greater (95% confidence interval 7%–11%). Survival after CABG among diabetics versus nondiabetics at 1, 5, 10, and 20 years was also worse: 94% versus 94%, 80% versus 84%, 56% versus 66%, and 20% versus 32%, respectively. Propensity-matched patients incurred similar costs, but the prevalence of postoperative deep sternal wound infections and stroke, as well as long-term survival, remained worse in diabetics. Conclusions Diabetes is both a marker for high-risk, resource-intensive, and expensive care after CABG and an independent risk factor for reduced long-term survival. These issues, coupled with the increasing proportion of patients needing CABG who have diabetes, are a growing challenge in reining in health care costs. Graphical abstract Four-decade trend in prevalence of diabetes among patients undergoing primary isolated coronary artery bypass grafting. Each circle represents a yearly percentage, and the solid line is the locally estimated scatterplot smoother (loess) estimate. Coronary artery bypass grafting diabetes health care costs Diabetes is an emerging worldwide epidemic that affects 382 million people,1 including 25.8 million in the United States alone.2 In 2013, global health expenditures resulting from diabetes were estimated at $548 billion and are expected to exceed $627 billion by 2035.1 In the United States, the total economic burden of diabetes was $245 billion in 2012.3 Because coronary artery disease is common in diabetics,4 it is an important driver of diabetes-related health care cost.3 As the prevalence of diabetes has risen, cardiovascular disease associated with it has increased as well.5 Today, diabetics represent an important subset of patients undergoing coronary artery bypass grafting (CABG), an expensive procedure. Therefore, we sought to determine 4-decade temporal trends in the prevalence of diabetes and cardiovascular risk factors for patients undergoing CABG, compare overall in-hospital adverse outcomes, hospital resource utilization and costs, and long-term survival after CABG in diabetics versus nondiabetics, then compare these same factors in diabetics versus nondiabetics who have similar high-risk profiles using propensity matching. METHODS Patients From January 1, 1972, to January 1, 2011, 57,278 patients underwent first-time isolated CABG at Cleveland Clinic. Data on the presence or absence of pharmacologically treated diabetes mellitus (insulin or oral hypoglycemic agent) were available for 55,501 (97%) of these patients: 45,139 nondiabetics and 10,362 diabetics. Patients were identified, and preoperative, operative, and postoperative variables (Appendix E1) were retrieved from the prospective Cleveland Clinic Cardiovascular Information Registry. This database is populated concurrently with patient care and has been approved for use in research by the institutional review board, with the requirement for patient consent waived. Variables and Definitions A coronary artery system was considered meaningfully stenotic if it contained a ≥50%-diameter obstruction. Incomplete revascularization was defined as failure to graft any coronary system containing ≥50% stenosis, or both left anterior descending and circumflex coronary systems for ≥50% left main trunk stenosis. Left ventricular function was echocardiographically graded as normal (ejection fraction ≥60%), mild dysfunction (ejection fraction 40%–59%), moderate dysfunction (ejection fraction 25%–39%), or severe dysfunction (ejection fraction <25%). Endpoints Endpoints were: (1) in-hospital adverse outcomes defined as in the Society of Thoracic Surgeons national database (www.ctsnet.org/file/rptDataSpecifications252_1_ForVendorsPGS.pdf); (2) in-hospital direct technical costs (the sum of direct preoperative, operative, and postoperative costs), both total and broken down according to resource utilization areas; and (3) time-related mortality. Actual direct technical cost data (not charge data), exclusive of physician professional salaries, were obtained from Decision Support Services of Cleveland Clinic. Data were available for patients from only 2003 onward (n = 4679: 1776 diabetics and 2903 nondiabetics). Costs were corrected to constant 2011 dollars.6 Indirect costs, including institutional costs and capital equipment costs used for all operations, could not be estimated on a per patient basis and are not included, but they were assumed to be distributed uniformly across groups. Vital status after hospital discharge was obtained by routine anniversary follow-up questionnaires supplemented with data from the Social Security Death Master File,7 accessed on October 27, 2011, with a closing date of April 27, 2011. A total of 714,709 patient-years of follow-up data were available for analyses. Median follow-up was 11.8 years, with 25% of survivors followed for >21 years, and 10% for >30 years. For diabetic patients, 86,153 patient-years of follow-up data were available for analyses, with a median follow-up period of 7.5 years; 25% of survivors were followed for >12 years, and 10% for >18 years. For nondiabetic patients, 628,556 patient-years of follow-up data were available for analyses, with a median follow-up period of 13 years; 25% of survivors were followed for >24 years, and 10% for >31 years. Statistical Analysis Temporal trends Four-decade temporal trends in the prevalence of diabetes and cardiovascular risk factors among patients undergoing CABG were assessed using plots of yearly percentages or averages over time. A nonparametric locally estimated scatterplot smoother, PROC LOESS (SAS Institute, Cary, NC), was used to smooth these temporal trends. In-hospital adverse outcomes Comparisons of outcomes after CABG between diabetics and nondiabetics, unmatched and propensity matched, were made using the χ2 test for categoric endpoints. Resource utilization and total direct technical cost Hours in the intensive care unit and postoperative and total hospital lengths of stay had right-skewed distributions, so the Wilcoxon rank-sum test, and the median score test for continuous endpoints, were used for comparisons between diabetics and nondiabetics. To identify the relative difference in direct technical costs, we estimated the ratio of the median cost between the 2 groups. The percentile bootstrap confidence method8 was used to estimate 95%confidence intervals. This procedure was applied to the overall and matched cohorts. Long-term survival Survival was assessed nonparametrically, using the Kaplan-Meier method, and parametrically, using a multiphase hazard model.9 The latter involved resolving the number of hazard phases for instantaneous risk of death (hazard function), and estimating shaping parameters. (For details, see www.lerner.ccf.org/qhs/software/hazard.) Because the shape of time-varying risk of death may differ for diabetics versus nondiabetics, we constructed separate hazard models for each group. Propensity-score matching Although overall assessment of outcomes in diabetics compared with nondiabetics represents the realities of the real world, diabetics as a group present with a higher-than-average risk profile. We therefore treated diabetes as a “natural experiment,”10 comparing outcomes of propensity-matched diabetics and nondiabetics.11–13 This comparison was accomplished in 2 steps. First, a parsimonious multivariable logistic regression was used to identify differences in preoperative characteristics of diabetic versus nondiabetic patients, to obtain insight into these differences (see Appendix E1 for a list of variables analyzed). Bootstrap bagging for variable selection with automated analysis of 500 resampled datasets was used to accomplish this, followed by tabulation of the frequency of both single factors and closely related clusters of factors.14 We retained factors that occurred in ≥50% of the bootstrap models (Table E1). The C-statistic for this parsimonious model was .83. Second, the parsimonious model was augmented into a saturated propensity model by including patient characteristics that were not statistically significantly different between groups. These characteristics were demographic, cardiac, and noncardiac comorbidities not represented (see Appendix E1). The C-statistic for this model was .84. A propensity score representing the probability of diabetes—group membership given the variables included in the propensity model, regardless of whether the patient had diabetes—was then calculated for each patient. A greedy matching strategy based on the propensity scores alone was used to match diabetic with nondiabetic patients, yielding 8926 well-matched pairs (86% of possible matches; Figure E1). Diabetes cases with propensity scores that deviated >0.10 from those of nondiabetes cases were considered unmatched. Standardized differences demonstrated that covariable balance was achieved across nearly all variables (Figure E2). Using a similar approach, separate propensity matching was done between the subset of diabetics and nondiabetics undergoing an operation in the period from 2003 to 2011, during which cost data were available. This yielded 1368 well-matched pairs (77% of possible matches). Missing values Several variables examined in multivariable analyses had missing values. We used fivefold multiple imputation15 with a Markov chain Monte Carlo technique to impute missing values (SAS PROC MI; SAS Institute, Cary, NC). In multivariable modeling, for each imputed complete dataset, we estimated regression coefficients and their variance–covariance matrix. After this step, following Rubin,15 we combined estimates from the 5 models (SAS PROC MIANALYZE; SAS Institute, Cary, NC) to yield final regression coefficient estimates, the variance–covariance matrix, and P values. Presentation Continuous variables are summarized by mean ± SD, or equivalent 15th, 50th (median), and 85th percentiles when the distribution of values is skewed. Analyses were performed using SAS statistical software, version 9.1 (SAS Institute, Cary, NC) and R (version 3.0.2). Uncertainty is expressed by confidence limits (CLs) equivalent to ±1 SE (68%). RESULTS Compared with nondiabetics, diabetic patients undergoing CABG were older and more likely to be overweight, and more likely to be women. In addition, they were more likely to have a history of heart failure, peripheral arterial disease, carotid disease, hypertension, renal failure, stroke, and advanced coronary artery disease (Table 1). Temporal Trends The proportion of patients presenting for CABG who have diabetes increased from 7% per year in the 1970s to 37% in the 2000s (Central Image). The cardiovascular risk factor profile also changed during this time, more so for diabetics than nondiabetics. Today, patients are likely to be older (Figure 1, A) and obese (Figure 1, B); to have had a stroke (Figure 1, C); and to have hypertension (Figure 1, D), peripheral arterial disease (Figure 1, E), lower total cholesterol (Figure 1, F), higher high-density lipoprotein cholesterol (Figure 1, G), lower triglycerides (Figure 1, H), and more-advanced coronary artery disease (Figure 1, I) (see Table E1). Overall Outcomes In-hospital adverse outcomes, and resource utilization and direct technical costs Diabetics had higher in-hospital mortality and greater occurrence of deep sternal wound infection, stroke, atrial fibrillation, renal failure, and respiratory failure (Table 2). Hours spent in the intensive care unit and of length of stay > 14 days were higher in diabetics than nondiabetics (Table 2). As a result, the total cost of CABG was 9% greater (95% CI, 7%–11%) in diabetics. Most of this difference was due to higher costs of clinical and laboratory testing, diagnostic imaging, pharmacy services, and nursing care (Figure 2). Long-term survival The instantaneous risk of death was high immediately after CABG, decreased over the ensuing 6 months, and then gradually increased for both diabetics and nondiabetics (Figure 3, A), resulting in early divergence of their survival curves (Figure 3, B). In addition, late hazard was elevated in diabetics; thus, ever-increasing divergence of survival was observed out to at least 20 years. Among diabetics, overall survival at 6 months, 1, 5, 10, 15, and 20 years after CABG was 95%, 94%, 80%, 54%, 31%, and 18%, respectively. In contrast, for nondiabetics, it was 97%, 97%, 90%, 76%, 59%, and 42%, respectively (P < .0001). Comparison of Diabetics with Similar High-Risk Nondiabetics In-hospital adverse outcomes, and resource utilization and direct technical costs After matching, the incidence of deep sternal wound infection and stroke remained significantly higher among diabetics (Table 2). After propensity matching, no significant difference remained in total cost of CABG between diabetics and nondiabetics (Figure 2). Hours spent in the intensive care unit were similar, but length of stay > 14 days remained higher for diabetics (Table 2). Long-term survival Among propensity-matched patients, instantaneous risk of death (hazard function) was similar for both diabetics and nondiabetics until 1 year after surgery, after which risk of death was greater for diabetics (Figure 3, C). Early survival was similar between the 2 groups, but late survival was worse for diabetics (Figure 3, D). Late survival continued to diverge as long as patients were followed, because of the substantial difference in late hazard for at least 20 years after CABG. Survival of diabetics at 6 months, 1, 5, 10, 15, and 20 years after operation was 96%, 94%, 80%, 56%, 35%, and 20%, respectively, versus 96%, 94%, 84%, 66%, 47%, and 32% for nondiabetics. DISCUSSION Principal Findings This study shows that the proportion of patients presenting for CABG who have diabetes increased each year during the past 4 decades, as did the proportion with cardiovascular risk factors. Thus, compared with diabetics undergoing operation in the 1970s, 1980s, and 1990s, those operated on more recently were more likely to be obese and have more comorbidities and advanced coronary artery disease. For diabetics, CABG was more resource intensive and expensive, and in-hospital adverse events and long-term survival were worse. However, the increase in in-hospital resource utilization was not specific to diabetics, but rather commensurate with that of patients coming to surgery with a similar extent of comorbidities, but without diabetes. Unadjusted in-hospital and early mortality (1-year) were higher in diabetics than in nondiabetics, but similar for propensity-matched patients with a similar comorbidity profile. Long-term survival was worse in diabetics than in either nondiabetic patients or matched, nondiabetic, high-risk patients. Thus, diabetes is both a marker for highrisk, resource-intensive, and expensive care after CABG, and an independent risk factor for reduced long-term survival. Trends In 2010, nearly 40% of those undergoing CABG at our institution were diabetic, paralleling the rising prevalence of diabetes in the general population. However, the increasing use of percutaneous coronary intervention for revascularization, and the choice of CABG as the preferred revascularization strategy for diabetics, could also have been contributing factors.16 Although cardiovascular disease–related morbidity and mortality has clearly been reduced in the United States over the past 50 years, the cardiovascular disease burden attributable to diabetes has increased.5 Current estimates are that 18.8 million people in the United States have been diagnosed with diabetes, and 7 million remain undiagnosed.2 In addition, nearly 79 million people aged ≥20 years have prediabetes,2 a condition that places them at increased risk of developing diabetes and cardiovascular disease.17 We also observed a change in the cardiovascular risk-factor profile over time. Diabetics undergoing CABG in recent years are more likely to be obese and to have more-advanced coronary artery disease than those operated on in the 1970s, 1980s, and 1990s. In addition, they are more likely to have hypertension, one component of metabolic syndrome, together with diabetes, hyperlipidemia, and obesity—all risk factors for coronary artery disease.18 Obesity is now considered a national epidemic and is of particular importance as a well-recognized contributor to diabetes. More than one third of US adults are obese,19 and in the next 20 years, obesity may play a contributing role in an estimated 6 million cases of diabetes.20 On the other hand, diabetics undergoing CABG in recent years had lower total cholesterol, higher high-density lipoprotein cholesterol, and lower triglycerides than did patients operated on in earlier years; this difference may be attributable to better control of lipids in the statin era. In-Hospital Adverse Outcomes In-hospital adverse outcomes after CABG were more common in diabetics than nondiabetics. In part, this difference is attributable to diabetic patients being sicker and having more comorbidities than nondiabetics, because some of the differences, including hospital death, septicemia, renal failure, and respiratory failure, became statistically insignificant after comparison with similar high-risk nondiabetic patients through propensity matching. However, occurrence of deep sternal wound infection and stroke remained significantly higher in diabetics even after matching. Deep sternal wound infection results in prolonged postoperative length of stay and thus increases hospital resource utilization. Strokes may cause permanent disability, resulting in unemployment and thus increasing the indirect cost of diabetes through loss of productivity. Other studies have also revealed worse hospital and long-term outcomes of CABG in diabetics.21,22 The SYNTAX trial showed that at 3 years, diabetes had little effect on outcomes of CABG, and diabetes control (as indicated by baseline hemoglobin A1c levels) was not predictive of major adverse cardiac and cerebrovascular events. In our study, overall postoperative prevalence of stroke and in-hospital death was higher in diabetics, and occurrence of myocardial infarction was higher in nondiabetics. However, after comparison with similar, high-risk, nondiabetic patients, occurrence of death and myocardial infarction was similar in the 2 groups, as was true in the SYNTAX trial, but stroke remained higher in diabetics.23 Health Care Costs Our study additionally shows that resource utilization and the actual direct technical cost of CABG were greater in diabetics, mainly because of longer intensive care unit and postoperative stays, and higher costs of clinical and laboratory testing, diagnostic imaging, pharmacy services, and nursing care. Greater severity of disease among diabetics necessitates preoperative admission and more-extensive laboratory and diagnostic workup. Furthermore, managing postoperative adverse events and the resulting increase in postoperative length of stay both lead to higher in-hospital costs. After using propensity matching to compare similar high-risk, nondiabetic patients, no significant difference between the total cost of CABG in diabetics versus nondiabetics with a similar high-risk profile was observed, demonstrating that most of the increased cost was due to diabetics being sicker and having more comorbidities. In 2012, $176 billion was spent on direct health care for diabetics in the United States, with in-hospital care representing 43% of that amount.3 Because heart disease is one of the leading causes of hospitalization in diabetics, a large share of in-hospital costs can be attributed to CABG and its postoperative complications. Others have also demonstrated the association of diabetes with increased cost of CABG.24,25 A study of 114 diabetics and 198 nondiabetics showed that insulin-treated diabetics have longer hospital stays and higher hospital charges than non–insulin-treated diabetics and nondiabetics.24 A recently published study from China also showed that CABG was more costly, with worse long-term results, in diabetics than in nondiabetics.26 Survival Diabetic patients as a group had a higher early (1-year) risk of death after CABG than nondiabetics, as has been documented by others.21 However, an interesting finding of our study is that among propensity-matched patients, early risk was similar to that of nondiabetic high-risk patients with a similar comorbidity profile. Long-term survival, however, was worse in diabetics than in both nondiabetic patients and nondiabetic high-risk patients. Other studies have also demonstrated diabetes to be an independent risk factor for reduced long-term survival after CABG.21,26 Although long-term survival after CABG is worse in diabetics and high-risk nondiabetics, in general, high-risk patients reap the greatest survival benefit from CABG.27 Moreover, using surgical techniques that are associated with better long-term survival after CABG in diabetics could further enhance this survival benefit.28 Diabetes: An Avoidable Economic Burden Diabetes is a growing threat to the US economy. Diabetic patients’ medical expenses are nearly 2.3 times higher than those of nondiabetics,3 and this economic burden is expected to increase as the number of diabetes cases rises. Fortunately, however, this situation is largely preventable. In people with prediabetes, cost-effective lifestyle interventions have been shown to have a positive effect on preventing development of the disease.29–31 In people with diagnosed diabetes, controlling blood sugar and cardiovascular disease risk factors, such as hypertension and hypercholesterolemia, has been shown to help reduce cardiovascular events.32,33 With appropriate use of these approaches, we can help prevent development of diabetes and its complications, reducing the diabetes-related economic burden. Strengths and Limitations This study includes 4 decades of patients who underwent CABG at a single, high-volume academic medical center. An advantage of a long observation period is having a long follow-up period, but generalizing these late results to a contemporary patient population may not accurately reflect the changing patient case mix and advances in managing these patients over time. For adjusted comparison of outcomes, propensity-score matching was performed. Although the patient pairs were well matched, any patient factors that significantly affect outcomes after CABG but were not included in the propensity analysis might bias our adjusted results. In addition, circumstances of each death, which may differ among diabetic and nondiabetic patients, were not reliably captured during follow-up inquiries. CONCLUSIONS Diabetes is both a marker for high-risk, resource-intensive, and expensive care after CABG and an independent risk factor for reduced long-term survival. These issues, coupled with the annually increasing number of patients needing CABG who are diabetic, present a growing challenge to reining in health care costs, both in the United States and internationally. Diabetic patients, and those with a similar high-risk profile, set to undergo CABG should be made aware that their risks of postoperative complications are higher than average, and measures should be taken to reduce their postoperative complications. Moreover, trying to reverse the diabetes epidemic is important; if left uncontrolled, it will increase the prevalence of cardiovascular disease and add to the ever-increasing economic health care burden. Research and policies focused on reducing diabetes, and programs that raise awareness about preventive strategies, should be developed and implemented to check rising health care costs. Supplementary Material 01 This study was funded in part by the Sheikh Hamdan bin Rashid Al Maktoum Distinguished Chair in Thoracic and Cardiovascular Surgery (held by JFS), and the Kenneth Gee and Paula Shaw, PhD, Chair in Heart Research (held by EHB). These philanthropists played no role in the design of the study, collection of data, analysis and interpretation of the data, or writing of the report, and did not approve or disapprove publication of the article. Abbreviation and Acronym CABG coronary artery bypass grafting FIGURE 1 Four-decade trends in prevalence of diabetes and cardiovascular risk factors among patients undergoing primary isolated coronary artery bypass grafting. Each circle is a yearly percentage or mean value, and solid lines are loess estimates. The factors shown are: (A) age; (B) body mass index; (C) stroke; (D) hypertension; (E) PAD; (F) total cholesterol; (G) HDL cholesterol; (H) triglycerides; and (I) percentage with 3-system disease. PAD, Peripheral arterial disease; HDL, high-density lipoprotein. FIGURE 2 Median (triangles) ratio of total direct technical costs (overall and propensity matched) in diabetics versus nondiabetics. Error bars are 95% confidence intervals. FIGURE 3 Time-related death after primary isolated coronary artery bypass grafting in diabetics and nondiabetics. Solid lines are parametric estimates enclosed within dashed 68% confidence bands equivalent to ±1 SE. The panels show: (A) instantaneous risk of death (overall); (B) survival (overall); (C) instantaneous risk of death (propensity-matched cohort); and (D) survival (propensity-matched cohort). Each symbol represents a death; vertical bars are confidence limits equivalent to ±1 SE; and values in parentheses are numbers of patients remaining at risk. TABLE 1 Patient characteristics and revascularization details of nondiabetics and diabetics undergoing coronary artery bypass grafting Nondiabetics (n = 45,139) Diabetics (n = 10,362) Characteristic n No. (% or mean ± SD n No. (%) or mean ± SD P value Demographics   Age (y) 45,139 60 ± 10 10,362 63 ± 9.7 <.001   Male 45,139 37,626 (83) 10,362 7249 (70) <.001   Body mass index (kg/m2) 27,739 28 ± 4.7 8883 30 ± 5.8 <.001 Symptoms and surgical priorities   NYHA functional class 44,775 10,317 <.001     I 7645 (17) 1800 (17)     II 16,533 (37) 3982 (39)     III 4702 (11) 1468 (14)     IV 15,895 (35) 3067 (30)   Emergency operation 45,137 1242 (2.8) 10,362 248 (2.4) .04 Cardiac comorbidity   Myocardial infarction 45,139 22,916 (51) 10,362 5932 (57) <.001   Left ventricular dysfunction 42,404 8996 <.001     None 37,013 (87) 6300 (70)     Mild 2492 (5.9) 948 (11)     Mild to moderate 514 (1.2) 238 (2.6)     Moderate 1315 (3.1) 688 (7.6)     Moderate to severe 492 (1.2) 384 (4.3)     Severe 578 (1.4) 438 (4.9)   Preoperative AF or flutter 36,357 411 (1.1) 8967 163 (1.8) <.001   Heart failure 45,139 2219 (4.9) 10,362 1750 (17) <.001   Coronary artery disease 35,015 20,687 (59) 7042 3446 (49) <.001   No. of coronary systems diseased (stenosis ≥50%) 43,113 9908 <.001     0 366 (0.85) 69 (0.70)     1 5310 (12) 615 (6.2)     2 13,807 (32) 2332 (24)     3 23,630 (55) 6892 (70)   Left main disease (stenosis ≥50%) 41,909 6704 (16) 9277 1749 (19) <.001 Noncardiac comorbidity   Peripheral arterial disease 45,139 4551 (10) 10,362 1840 (18) <.001   Carotid disease 45,139 3434 (7.6) 10,362 2278 (22) <.001   Stroke 45,139 1515 (3.4) 10,362 880 (8.5) <.001   Hypertension 29,346 17,615 (60) 9077 6966 (77) <.001   COPD 14,360 1079 (7.5) 6639 584 (8.8) <.001   Smoking 44,244 24,133 (55) 10,208 5319 (52) <.001   Creatinine (mg/dL) 13,969 1.2 ± 0.83 6464 1.3 ± 1.2 .07   Blood urea nitrogen (mg/dL) 13,954 18 ± 9.0 6460 22 ± 12 <.001   Renal dialysis 7375 59 (0.80) 4060 98 (2.4) <.001   Total cholesterol (mg/dL) 35,236 235 ± 56 7422 208 ± 60 <.001   HDL cholesterol (mg/dL) 14,734 40 ± 12 5283 39 ± 13 <.001   LDL cholesterol (mg/dL) 9616 128 ± 46 4309 113 ± 45 <.001   Triglycerides (mg/dL) 29,248 185 ± 116 6672 203 ± 173 .002   Bilirubin (mg/dL) 12,683 0.65 ± 0.50 5803 0.59 ± 0.51 <.001   Hematocrit (%) 13,037 40 ± 5.1 5993 38 ± 5.5 <.001 Experience   January 1, 1972 to index operation 45,139 14 ± 9.5 10,362 21 ± 9.6 <.001 Revascularization details   ITA grafts at index operation 45,139 10,362 <.001     None 14,888 (33) 2018 (19)     Single 25,160 (56) 7570 (73)     Bilateral 5091 (11) 774 (7.5)   Complete revascularization* 45,139 40,405 (90) 10,362 9432 (91) <.001   Cardiopulmonary bypass 45,139 43,761 (97) 10,362 9817 (95) <.001 Values in “n” columns are numbers of patients with data available. SD, Standard deviation; NYHA, New York Heart Association; AF, atrial fibrillation; COPD, chronic obstructive pulmonary disease; HDL, high-density lipoprotein; LDL, low-density lipoprotein; ITA, internal thoracic artery. * Incomplete revascularization was defined as failure to graft any system containing 50% stenosis or both the left anterior descending and circumflex coronary artery systems for 50% left main trunk stenosis. TABLE 2 In-hospital outcomes after coronary artery bypass grafting: overall and propensity matched Overall Propensity matched Nondiabetic (total n = 45,139) Diabetic (total n = 10,362) Nondiabetic (total n = 8926) Diabetic (total n = 8926) Outcome n No. (%) n No. (%) P value n No. (%) n No. (%) P value Hospital death 45,139 566 (1.3) 10,362 211 (2.0) <.001 8926 152 (1.7) 8926 174 (1.9) .2 Deep sternal wound infection 45,139 526 (1.2) 10,362 239 (2.3) <.001 8926 116 (1.3) 8926 197 (2.2) <.001 Septicemia 14,298 226 (1.6) 6633 151 (2.3) .004 6393 139 (2.2) 5352 113 (2.1) .8 Stroke 45,139 640 (1.4) 10,362 233 (2.2) <.001 8926 134 (1.5) 8926 200 (2.2) <.001 Perioperative MI 45,139 1023 (2.3) 10,362 135 (1.3) <.001 8926 118 (1.3) 8926 123 (1.4) .8 Bleeding or tamponade 45,139 1791 (4.0) 10,362 348 (3.4) .004 8926 271 (3.0) 8926 314 (3.5) .07 Atrial fibrillation 45,139 5148 (12) 10,362 1979 (19) <.001 8926 1914 (21) 8926 1672 (19) <.001 Renal failure 45,139 569 (1.3) 10,362 418 (4.0) <.001 8926 258 (2.9) 8926 285 (3.2) .2 Renal failure requiring dialysis 14,298 104 (0.73) 6633 86 (1.3) <.001 6393 79 (1.2) 5352 60 (1.1) .6 Prolonged ventilation (>24 h) 3492 320 (9.2) 2100 249 (12) .001 1838 212 (12) 1563 160 (10) .2 Length of stay*   ICU (h) 14,296 24/24/72 631 24/26/95 <.001 6391 24/24/75 5351 24/24/76 <.001   Postoperative (d) 44,014 6.1/8.0/11 10,263 5.9/7.9/12 <.001 8864 5.2/7.0/11 8829 5.9/7.9/11 <.001   Hospital (d) 44,014 7/11/17 10,263 6.3/10/18 <.001 8864 6.3/9.3/16 8829 6.3/10/17 <.001   Prolonged (>14 d) 45,139 2688 (6.0) 10,362 995 (9.6) <.001 8926 679 (7.6) 8926 785 (8.8) .004 Values in “n” columns are numbers of patients with data available. P values are given for the median score test. MI, Myocardial infarction; ICU, intensive care unit. * 15th/50th/85th percentiles. Median score test was used to compare medians and Wilcoxon rank-sum test to compare tails of distributions. Central Message Increasingly, patients needing CABG have diabetes, a marker for high-risk, resource-intensive, expensive care after CABG, and an independent risk factor for reduced long-term survival, creating a growing challenge to health care cost reduction. Perspective The proportion of patients needing CABG who have diabetes has increased to nearly 40% of all patients undergoing CABG at our institution. The procedure is more resource intensive and expensive for diabetics than for nondiabetics, partly because of postoperative complications. However, when surgeons present the risks and benefits of CABG to diabetic patients, they should explain that CABG offers the best chance for long-term survival. Supplemental material is available online. Conflict of Interest Statement Dr Sabik is the North American principal investigator for the Abbott Laboratories–sponsored left main coronary disease randomized trial (EXCEL), is on the Society of Thoracic Surgeons Board of Directors, and is on the scientific advisory board of Medtronic. All other authors have nothing to disclose with regard to commercial support. 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PMC005xxxxxx/PMC5120553.txt
LICENSE: This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. 0375363 4713 J Endocrinol J. Endocrinol. The Journal of endocrinology 0022-0795 1479-6805 27799461 5120553 10.1530/JOE-16-0447 NIHMS828225 Article Hepatocyte-specific, PPARγ-regulated mechanisms to promote steatosis in adult mice Greenstein Abigail Wolf 123* Majumdar Neena 12* Yang Peng 12 Subbaiah Papasani V. 12 Kineman Rhonda D. 12 Cordoba-Chacon Jose 12# 1 Research and Development Division, Jesse Brown Veterans Affairs Medical Center, University of Illinois at Chicago, Chicago, IL 2 Department of Medicine, Section of Endocrinology, Diabetes, and Metabolism, University of Illinois at Chicago, Chicago, IL 3 Biologic Resources Laboratory, University of Illinois at Chicago, Chicago, Illinois, USA # Corresponding Author: Jose Cordoba-Chacon, PhD. Dept Medicine, Section Endocrinology, Diabetes and Metabolism, 1819 W Polk St, M/C 640, Chicago, IL 60612, USA. jcordoba@uic.edu Ph: 1-312-569-7417 Fax: 1-312-569-8114 * equally contributed authors 9 11 2016 31 10 2016 1 2017 01 1 2018 232 1 107121 This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. Peroxisome proliferator-activated receptor γ (PPARγ) is the target for thiazolidinones (TZDs), drugs that improve insulin sensitivity and fatty liver in humans and rodent models, related to a reduction in hepatic de novo lipogenesis (DNL). The systemic effects of TZDs are in contrast to reports suggesting hepatocyte-specific activation of PPARγ promotes DNL, triacylglycerol (TAG) uptake and fatty acid (FA) esterification. Since these hepatocyte-specific effects of PPARγ could counterbalance the positive therapeutic actions of systemic delivery of TZDs, the current study used a mouse model of adult-onset, liver (hepatocyte)-specific PPARγ knockdown (aLivPPARγkd). This model has advantages over existing congenital knockout models, by avoiding compensatory changes related to embryonic knockdown, thus better modeling the impact of altering PPARγ on adult physiology, where metabolic diseases most frequently develop. The impact of aLivPPARγkd on hepatic gene expression and endpoints in lipid metabolism was examined after 1 or 18wks (Chow-fed) or after 14wks of low- or high-fat [HF] diet. aLivPPARγkd reduced hepatic TAG content but did not impact endpoints in DNL or TAG uptake. However, aLivPPARγkd reduced the expression of the FA translocase (Cd36), in 18wk-Chow and HF-fed mice, associated with increased NEFA after HF-feeding. Also, aLivPPARγkd dramatically reduced Mogat1 expression, that was reflected by an increase in hepatic monoacylglycerol (MAG) levels, indicative of reduced MOGAT activity. These results, coupled with previous reports, suggest that Cd36-mediated FA uptake and MAG pathway-mediated FA esterification are major targets of hepatocyte PPARγ, where loss of this control explains in part the protection against steatosis observed after aLivPPARγkd. adult-onset hepatocyte-specific knockdown Cd36 Mogat1 LC/MS diet-induced steatosis INTRODUCTION Non-alcoholic fatty liver disease (NAFLD) is defined as excessive accumulation of fat (steatosis) within hepatocytes that is independent of alcohol intake. NAFLD increases the risk of diabetes, non-alcoholic steatohepatitis (NASH), cirrhosis and hepatocellular carcinoma (Lade, et al. 2014; Michelotti, et al. 2013). Importantly, NAFLD is now recognized as the leading cause of chronic liver disease in the US (Younossi, et al. 2011) and the third most common reason for liver transplants (Zezos and Renner 2014). Given the negative association between NAFLD and human health, a concerted effort is being made to understand the cellular and molecular mechanisms that control hepatocyte triacylglycerol (TAG) content. It is clear that hepatocyte TAG content is dictated by the balance between fatty acid (FA) synthesis, uptake, esterification and oxidation, as well as TAG release via very-low density lipoprotein (VLDL) (Browning and Horton 2004). A better understanding of the mechanisms controlling these processes could help to identify individuals with higher risk of NAFLD, as well as identify novel drug targets to design therapeutic strategies that prevent or reverse NAFLD progression. Thiazolidinones (TZDs) are synthetic agonists of the nuclear receptor, peroxisome proliferator-activated receptor γ (PPARγ) used to treat diabetes type 2 (Ahmadian, et al. 2013). Treating patients with non-alcoholic steatohepatitis (an advance stage of NAFLD featured by elevated markers of liver injury and fibrosis) with TZDs reduces steatosis with variable effects on fibrosis (Belfort, et al. 2006; Ratziu, et al. 2008; Sanyal, et al. 2010). The reduction in steatosis is associated with a reduction in hepatic de novo lipogenesis [DNL, (Beysen, et al. 2008)]. Similar to clinical studies, TZDs have also been shown to reduce hepatic fat content in rodent models (Gupte, et al. 2010; Nan, et al. 2009). However, in striking contrast to the global impact of TZDs: 1) hepatocyte-specific PPARγ expression is positively associated with fatty liver in humans (Pettinelli and Videla 2011) and mouse models (Gavrilova, et al. 2003; Inoue, et al. 2005; Matsusue, et al. 2003; Rahimian, et al. 2001); 2) adenoviral overexpression of a PPARγ transgene in the liver of HF-fed PPARα knockout or WT mice dramatically increases hepatic fat content (Bai, et al. 2011; Yu, et al. 2003); 3) congenital hepatocyte-specific knockout of PPARγ reduces hepatic fat content in mice fed a high-fat (HF) diet (Moran-Salvador, et al. 2011), as well as in mice with fatty liver due to inactivating mutations in the leptin gene [ob/ob; (Matsusue et al. 2003)] or lipodystrophy induced by lack of adipocyte development [AZIP (Gavrilova et al. 2003)]. This disconnect between the impact of systemic TZD (PPARγ agonist) delivery compared to the impact of hepatic-specific alterations in PPARγ function can be attributed to the integrated effects of PPARγ on multiple target tissues. Specifically, TZDs increase systemic insulin sensitivity, which in turn reduces insulin demands. These changes are associated with an increase in adiponectin production by the adipocyte. Adiponectin in turn promotes hepatic fatty acid oxidation via phosphorylation of AMPK and ACC, (Xu, et al. 2003; Yamauchi, et al. 2002), which suppresses DNL (Xu et al. 2003). Therefore, TZD’s effects on lowering steatosis are likely due to extra-hepatocyte mechanisms (Furnsinn and Waldhausl 2002). Although the global therapeutic effects of TZDs have been largely positive, the direct actions of PPARγ on the hepatocyte could serve to counterbalance these effects. Therefore, in order to optimize the development and use of TZDs, it is important to understand the tissue (cell)-specific impact of PPARγ on lipid homeostasis. With respect to the hepatocyte, studies using hepatocyte-specific PPARγ knockout models have led to the conclusion that PPARγ directly promotes hepatic fat accumulation by increasing lipid uptake, as well as promoting DNL (Gavrilova et al. 2003; Matsusue, et al. 2014; Matsusue et al. 2003; Schadinger, et al. 2005; Zhang, et al. 2006). However, it remains unclear if the shifts in hepatic gene expression that support these conclusions are due directly to loss of hepatocyte PPARγ or to compensation by other hepatic genes during development and/or secondary to changes in the systemic metabolic milieu. Therefore, in the current study we have employed a mouse model of adult-onset, hepatocyte-specific knockdown of PPARγ (aLivPPARγkd), that is generated by treating adult (10wk) PPARγfl/fl mice with an adeno-associated virus serotype 8 (AAV8) bearing a liver-specific thyroxine-binding globulin (TBG)-promoter driving a Cre recombinase transgene (AAV8-TBGp-Cre) vector. This model allows us to study the immediate impact of hepatocyte-specific loss of PPARγ in the adult liver and how this deficit impacts liver function overtime under different dietary conditions. As indicated in this study and supported by accumulating evidence (Ashpole, et al. 2016; Shin, et al. 2016; Yanger, et al. 2014), injection of AAV8-TBGp-Cre is an efficient and reproducible method to knockdown a floxed allele only in hepatocytes, independent of age. Analysis of changes in hepatic gene expression and circulating metabolites, combined with assessment of hepatic FA composition (gas chromatography/mass spectrometry (GC/MS)] and relative levels of TAG, diacylglycerols (DAG) and monoacylglycerols (MAG) [liquid chromatography/mass spectrometry (LC/MS)], indicate that adult-onset loss of hepatocyte PPARγ has little direct impact on DNL, FA oxidation, lipid uptake and TAG export. However, evidence indicates that hepatic PPARγ plays a primary role in regulating FA uptake, likely through regulating the expression of Cd36, and the MAG pathway, through regulation the expression of Mogat1 which esterifies FA to MAG to form DAG. Impairment of these pathways following the loss of hepatocyte PPARγ may explain, in part, the protection against age and diet-induced steatosis. MATERIALS AND METHODS Animals All mouse studies were approved by the IACUC of the Jesse Brown VA Medical Center and performed in accordance with the Guide for the Care and Use of Laboratory Animals. PPARγfl/fl (He, et al. 2003) mice were purchased from Jackson Laboratories (Strain 004584, B3.129-Ppargtm2Rev/J, Bar Harbor, ME) and bred as homozygotes. Animals were housed in a temperature (22–24C) and humidity controlled specific-pathogen free barrier facility with 12h light/12h dark cycle (lights on at 0600h). Mice were fed a standard laboratory rodent chow diet (Formulab Diet 5008, Purina Mills, Richmond, IN), unless otherwise indicated. Ten to twelve week old male PPARγfl/fl littermate mice were randomized and injected in the lateral-tail vein with 100μl saline containing 1.5×1011 genome copies of an AAV8 bearing either a TBG-driven Cre recombinase (AAV8-TBGp-Cre, Penn Vector Core, University of Pennsylvania), which generates adult onset hepatocyte (liver)-specific PPARγ knockdown mice (aLivPPARγkd) or AAV8-TBGp-Null which generates controls. Chow-fed mice were killed in the post-absorptive state (4h after food removal at 0700h), at 1 or 18 weeks after PPARγ knockdown. A separate group of PPARγfl/fl mice were fed a low-fat (LF) diet with 10% kCal fat (D12450B, Research Diets, Inc. New Brunswick, NJ) from weaning onwards. At 10–12 weeks of age, mice were injected with either AAV8-TBGp-Cre or AAV8-TBGp-Null, and half the mice in each group switched to a nutrient matched 60% high-fat (HF) diet (D12492, Research Diets, Inc), while the remaining mice continued to receive a LF-diet. Animals were maintained on their respective diets for 14 weeks and killed in the post-absorptive state. Mice were euthanatized by decapitation and trunk blood was collected to determine blood glucose (Alphatrack2, Abbot, Abbot Park, IL), plasma insulin (Mercodia, Uppsala, Sweden), TAG, NEFA, cholesterol and 3-β-hydroxy-butyrate (Wako Diagnostics, Richmond VA) levels following the manufacturer’s instructions. Liver and fat sub-depots were weighed. Livers were snap-frozen in liquid nitrogen and stored at -80C. In a subset of mice killed 1 week after AAV8-TBGp-Null or AAV8-TBGp-Cre injection, multiple tissues were collected to assess AAV8-TBGp driven Cre expression. A group of 10–12 week-old C57Bl6/J mice were injected with 1.5×1011 genome copies of an AAV8-TBGp-EGFP (Cat #AV-8-PV0146, Penn Vector Core, GFP as a reporter gene) and killed 1 week after to collect multiple tissues to assess GFP expression. Also, a piece of liver was fixed in 10% formalin to assess hepatocyte-specific expression of GFP. Assessment of Hepatic Lipids To assess hepatic TAG content, neutral hepatic lipids were extracted in isopropanol and TAG measured as previously published (Cordoba-Chacon, et al. 2014a). To assess hepatic FA composition in mice fed LF and HF diets, total lipids were extracted using the Bligh & Dyer Method (Bligh and Dyer 1959). An aliquot of extracted lipids was transmetylated to quantify specific methyl esters of FA using GC/MS, as we previously reported (Kineman, et al. 2016). LC/MS was used to assess the relative content of hepatic TAG, DAG and MAG. Briefly, hepatic homogenates were spiked with standards (50μg trinonadecadienoin glyceride [TAG-(19:2/19:2/19:2)], 50μg dipentadecanoin glyceride [DAG-(15:0/15:0)] and 50μg monononadecanoin glyceride [MAG-(19:0)]; Nu-Chek, Waterville, MN) and extracted using the Bligh & Dyer Method (Bligh and Dyer 1959). Aliquots were dissolved in 80:19.5:0.5 parts of methanol/chloroform/water to dilute the standards to a concentration of 0.25μg/ml. Samples (10μl) were injected using an Agilent 2600 UPLC into the ABSciex 6500 Qtrap mass spectrometer (Agilent Technologies) without chromatography separation. The flow rate of mobile phase (methanol/chloroform/water 80:19:0.5 v/v) containing 0.1% of NH4COOH was set to 200μl/min. Electrospray ionization-mass spectrometry (ESI-MS) was performed in positive multiple reaction monitoring (MRM) mode for the quantitative and qualitative analysis. The spray voltage was 4.5 kV, the source temperature was set at 450 °C. Mass spectra were acquired and recorded by Analyst software (AB Sciex, version 6.1). The major neutral lipids species known to be present in the liver tissues were analyzed in MRM mode, with the transition from its ammoniated ion (Q1) to the product ion derived from the loss of its ammoniated fatty acid (Q3) (Yang and Subbaiah 2015). Quantification of individual molecular species was performed from the relative intensities of the various species and the corresponding internal standards respectively. Individual MRM of the internal standards was: MAG-(19:0) Q1 390.4, Q3 75.1; DAG-(15:0/15:0) Q1 558.5, Q3 299.3; TAG-(19:2/19:2/19:2) Q1 938.8, Q3 625.5. Gene expression analysis Hepatic and adipose tissue RNA was extracted using Trizol Reagent (Life Technologies, Carlsbad, CA) and treated with RQ1 RNase-free DNase (Promega, Madison, WI). DNA-free RNA was transcribed and qPCR performed as previously published (Cordoba-Chacon et al. 2014a; Kineman et al. 2016). qPCR primer sequences for PPARγ, carnitine palmitoyltransferase 1α (Cpt1α), adipose triglyceride lipase (Atgl), hormone-sensitive lipase (Hsl), sterol response element binding protein 1c (Srebp1c), acetyl-CoA carboxilase 1 (Acc1), fatty acid synthase (Fasn), fatty acid elongase (Elovl6), stearoyl –CoA desaturase 1 (Scd1), fatty acid translocase (Cd36), glycerol phosphate acyltransferase (Gpat1), monoacylglycerol acyltransferase 1 (Mogat1), Cre recombinase, GFP, Cyclophilin A, β-actin and Hypoxanthine-guanine phosphoribosyltransferase were previously published (Cordoba-Chacon et al. 2014a; Cordoba-Chacon, et al. 2015a; Kineman et al. 2016). Primer sequences for: PPARα (NM_011144): Se: GGGAAAGACCAGCAACAACC, As: GCAGTGGAAGAATCGGACCT; acyl-CoA synthetase long-chain family member 1 (Acsl1, NM_007981): Se: GAGGGTGAGGTGTGTGTGAAA, As: CCGTGTGTAACCAGCCATCT; hepatic nuclear factor 4 α (Hnf4α, NM_008261.3): Se: ACATTCGGGCAAAGAAGATTG, As: ACCTGGTCATCCAGAAGGAGTT; PPARγ co-activator 1 α; (Pgc1α, NM_008904.2): Se: TTCCCGATCACCATATTCCA, As: TTCATCCCTCTTGAGCCTTTC; Cyp4a10 (NM_010011.3): Se: CCACTGATTCTGTTGTGGAGC, As: CATTAGAAGAGAGGGGATGAGGA; monoacylglycerol lipase (Mgll, NM_001166251.1): Se: GTGGAATGCAAAAGCCAAGA, As: AGCTCATCATAACGGCCACA; apolipoprotein B (ApoB, NM_009693.2): Se: AGCCCAGCACTGACTGACTT, As: GAAGCCTTGGGCACATTG; microsomal triglyceride transfer protein (Mttp, NM_001163457.1): Se: CAGTGGATGCCTCTTTTGTG, As: GTCTCGAATTGCCTGAGTGG; hepatic lipase (Hl, NM_008280.2): Se: TTTTCCTGGTGTTCTGCATCT, As: CAGGCGATCGTTTTCATCTT; low density lipoprotein lipase receptor (Ldlr, NM_001252658.1): Se: TGTCACCTGTCAGTCCAATCAA, As: TCAGAGCCATCTAGGCAATCTC; very-low density lipoprotein receptor (Vldlr, NM_013703.2): Se: GTGCAAGGCAGTAGGCAAAG, As: GCTGAGATCAGCCCAAAACA; lipoprotein related protein 1 (Lrp1, NM_008512.2): Se: ACACACGCCAACTGTACCAA, As: TGACATTCGGGTCACAAACA; monoacylglycerol acyltransferase 2 (Mogat2, NM_146035.2): Se: TGTGAAAACTTGGAAATCGACA, As: CAGTCTCCAGCATGAAAAATCC; diacylglycerol acyltransferase 1 (Dgat1, NM_010046.2): Se: AGCTGTGGCCTTACTGGTTG, As: AGCAGCCCCACTGACCTT. Western-blot Livers were homogenized in extraction buffer pH 7.5, 50mM HEPES, 2mM EGTA, 2mM EDTA, 130mM NaCl, 10mM NaF, 20mM β-glycerophosphate, 2mM sodium pyrophosphate, 1mM sodium vanadate, 0.5mM PMSF, 0,1% nonidet P-40, 2mM benzamidine, 1mM TLCK, 10μg/ml leupeptin, 10% glycerol, with protease inhibitors (Complete, Roche, Indianapolis, IN), followed by sonication for 10 sec. Protein concentration was determined using Bradford reagent (Bio-Rad Laboratories, Hercules, CA). 100μg of denatured proteins were separated by SDS-PAGE (Mini-PROTEAN TGX and Criterion TGX Gels 10%, Bio-Rad Laboratories) and transferred to nitrocellulose membranes. Membranes were blocked with 5% nonfat, dry milk in Tris-buffered saline with 0.05% Tween-20 for 1h at 25C, then incubated with primary antibodies overnight at 4C [Rabbit anti-human PPARγ mAb (C26H12), 1/500; Rabbit anti-human Histone H3 mAb (D1H2), 1/1000 (Cell Signaling Technology)], washed and incubated with secondary antibodies for 2h at 25C [Goat Anti-Rabbit IgG (H+L)-HRP Conjugate, 1/2000 (Bio-Rad Laboratories)]. After washing, SuperSignal® WestFemto Maximum Sensitivity Substrate (Thermo Scientific, Rockford, IL) was added and the light signal detected and analyzed using a C-Digit Blot Scanner and Image Studio Lite Ver 3.1 (Li-Cor Biosciences, Lincoln, NE). Immunohistochemistry Livers were fixed in formalin and paraffin embedded. 5μm sections were deparaffinized, hydrated in graded-ethanol/water solutions, and then treated with 10mM citrate buffer at 125C for 5′ (GFP, desmin and F4/80 staining) followed by 0.05% porcine trypsin in TRIS buffered solution (TBS) for 10min at 37C (F4/80 staining only). Samples were blocked in TBS containing 1.5% goat-serum and 0.01% Tween-20 for 20′, and sections incubated (4C overnight in TBS 0.01% Tween-20) with mouse anti-GFP, 1:100 Cell Signaling (Danvers, MA) #2955; rabbit anti-desmin, 1:50 Cell Signaling #5332; rat anti-F4/80 1:50 eBiosciences (San Diego, CA) #14-4801-82. Secondary antibodies (1:500 in blocking buffer): goat-anti rabbit IgG Alexa Fluor®594 Cell Signaling #8889 (for desmin staining), goat-anti mouse IgG Alexa Fluor®594 Cell Signaling #8890 and goat-anti mouse IgG Fluor®488 Cell Signaling #4408 (for GFP stainings), goat-anti rat IgG Fluor®488 Cell Signaling #4416 (for F4/80 staining). Sections were mounted with Fluoroshield with DAPI (Sigma-Aldrich) and immunofluorescence detected using a Olympus BX43 microscope (Olympus, Center Valley, PA). Images were recorder using Olympus CellSens software (Olympus) and processed using ImageJ (NIH) and CellSens (Olympus). Statistics t-student’s tests were performed to analyze the effect of AAV8-TBGp-Cre on PPARγ expression in liver, epididymal fat (eWAT) and inguinal fat (iWAT) (Fig 1G). 2-way ANOVA, followed by Bonferroni’s post-hoc analysis, was used to determine the effect of aLivPPARγkd with age or the effect of aLivPPARkd with diet. p-values less than 0.05 were considered significant. All statistical analyses were performed using GraphPad Prism 5 (GraphPad Software, La Jolla, CA). RESULTS Validation of hepatocyte-specific expression of TBGp-driven transgene after AAV8 injection Hepatocyte specificity expression of transgenes delivered by AAV8 and driven by TBG was confirmed using an AAV8-TGBp-EGFP reporter (Fig. 1A–E), that led to GFP positive staining only in hepatocytes and not in other cell types, including vascular endothelial cells, connective tissue surrounding vessels, cholangiocytes of bile ducts (Fig 1A,B), hepatic stellate cells (HSC; stained positive [red] for desmin [Fig. 1C]) and macrophages, (stained positive [red] F4/80 [Fig. 1D]). AAV8-TBGp-driven GFP and Cre expression was detected in hepatic but not in extrahepatic tissues (Fig 1E, F). Expression of PPARγ was reduced in liver but not in adipose tissue (Fig 1G). Interestingly, a modest increase of PPARγ expression was detected in eWAT of aLivPPARγkd mice. Effects of hepatocyte-specific PPARγ knockdown on metabolic endpoints in adult mice (aLivPPARγkd) After 1 and 18 weeks of chow diet AAV8-TBGp-Cre injection resulted in a clear knockdown of hepatocyte PPARγ mRNA and protein at 1 week after injection that persisted after 18 weeks of AAV8-injection (Fig 2A–C). Mouse PPARγ gene produces two isoforms PPARγ1 and PPARγ2 (NM_001127330.2 and NM_0111463). Three mRNA variants are described for PPARγ1 (variant 1: NM_001127330.2; variant 3: NM_001308352.1; variant 4: NM_001308354.1), but all encode for the same protein (isoform 1). In PPARγfl/fl mice two exons, previously described as exons 1 and 2 (He et al. 2003), are flanked by loxP sites. These exons expand 227 and 169 bp respectively, are located within the CDS of each variant and the qPCR primers employed in this study are placed in these two exons. Therefore, the qPCR result of PPARγ gene expression accounts for all variants and thereby the western-blot results account for both isoforms. Of note, hepatic PPARγ mRNA levels modestly, but significantly, increased with age in control but not aLivPPARγkd mice (Fig 2B,C). To assess if hepatic lipid metabolism was altered in chow-fed aLivPPARγkd mice we measured whole body, liver and adipose tissue (unilateral epididymal, inguinal and retroperitoneal fat depots) weights, hepatic TAG levels, as well as circulating blood glucose, plasma insulin, ketones, TAG, NEFA and cholesterol (Table 1). For the majority of endpoints examined aLivPPARγkd had no effect in either diet group. However, there was an overall inhibitory effect of aLivPPARγkd on hepatic TAG levels (p=0.0185), indicating hepatic PPARγ plays a role in hepatic lipid accumulation, even under standard feeding conditions. After 14 wk of LF- or HF-diet To further explore if hepatic lipid accumulation induced by excess dietary fat intake is altered by aLivPPARγkd, we fed a HF- or a nutrient-matched LF control diet to aLivPPARγkd mice and their littermate controls. After 14 weeks of either LF- or HF-feeding (Fig 2D) hepatic PPARγ mRNA/protein expression remained suppressed in aLivPPARγkd mice, compared to controls (Fig 2E,F). Consistent with previous reports (Inoue et al. 2005; Moran-Salvador et al. 2011; Yamazaki, et al. 2011), HF feeding in control mice increased hepatic PPARγ expression, compared to those fed a LF-diet (Fig 2E,F). Also, in control mice, HF-feeding increased body, liver and fat mass weight and elevated hepatic TAG content and plasma glucose, insulin and cholesterol levels, but plasma TAG and NEFA were reduced (Table 1). Although TAG and NEFA are reported to be elevated in HF-fed mice after an overnight fast, in the post-absorptive state (4h fasted mice at 1100h), TAG and NEFA levels are reported to be reduced (Cordoba-Chacon, et al. 2014b; Cordoba-Chacon, et al. 2015b; Guo, et al. 2009; Horakova, et al. 2016; Obrowsky, et al. 2013), likely due to elevated insulin levels under these conditions. aLivPPARγkd, in LF-fed mice, did not impact any of the metabolic endpoints examined (Table 1), including food intake (data not shown). However, HF-fed aLivPPARγkd mice showed reduced relative liver weight and this was associated with a reduced hepatic TAG content (Table 1). Despite reduced hepatic TAG levels, there were no differences in post-absorptive blood glucose, plasma insulin and TAG levels in HF-fed aLivPPARγkd mice, compared to diet-matched controls (Table 1). However, normal glucose and insulin levels in the post-absorptive mouse may not be indicative of the whole body glucose homeostasis which requires dynamic evaluation by glucose and insulin tolerance tests. Of note, plasma ketones and cholesterol were reduced in HF-fed aLivPPARγkd mice, while plasma NEFA were increased as compared to HF-fed control littermates (Table 1). Association between aLivPPARγkd-mediated alterations in hepatic gene expression and metabolic endpoints It has been previously reported that congenital liver-specific knockout of PPARγ alters the expression of a number of genes related to the regulation of hepatic TAG levels (Gavrilova et al. 2003; Matsusue et al. 2003; Moran-Salvador et al. 2011). However, from these studies it is difficult to determine which changes may be due to the direct actions of hepatocyte PPARγ and which may be altered by secondary changes that occur overtime. Therefore, qPCR was used to screen changes in expression of key genes related to fatty acid oxidation, intrahepatic TAG hydrolysis, hepatic TAG export, DNL, hepatic lipid uptake and TAG synthesis, in liver samples from chow-fed (1 and 18 wks post-aLivPPARγkd, Fig. 3A) and LF- and HF-fed (14 wks post-aLivPPARγkd, Fig. 3B) mice. The data shown in Fig. 3 is expressed as fold-change in hepatic gene expression in aLivPPARγkd mice, compared to PPARγ-intact controls (set at 0), within age and diet, while Supplemental Table 1A,B provides absolute values. There were small, but significant, changes in the expression of a number of genes in aLivPPARγkd mice, compared to PPARγ-intact controls within specific groups. However, collective examination of this data set provides insight into which genes (pathways) are major targets of PPARγ, that could explain why aLivPPARγkd protects against hepatic fat accumulation. De novo lipogenesis Although experimental evidence suggests that hepatocyte PPARγ promotes liver fat accumulation by regulating the expression of genes important for DNL (Matsusue et al. 2014; Matsusue et al. 2003), aLivPPARγkd did not significantly reduce the expression of DNL genes (Srebp1c, Acc1, Fasn, Elov6, Scd1) across age or diet. However, we could not exclude the fact aLivPPARγkd could indirectly mediate the activity of DNL enzymes, independent of changes in gene expression. Therefore, in order to estimate the impact of aLivPPARγkd on hepatic DNL we used GC/MS to measure FA composition in livers of mice fed either a LF or HF diet. Supplemental Table 2 provides data for all FA detected, while Fig. 4A shows absolute levels of palmitic acid (16:0), palmitoleic acid (16:1(n-7)) and linoleic acid (18:2(n-6)). The absolute levels of these FAs were significantly reduced in HF-fed aLivPPARγkd mice as compared to HF-fed controls, consistent with the reduction in hepatic TAG content. Specific ratios of these FA (Fig 4B) have been shown to be indicative of DNL (SCD-1 index 16:1/16:0 (Kineman et al. 2016; Lee, et al. 2015; Silbernagel, et al. 2012); DNL index, 16:0/18:2 (Kineman et al. 2016; Lee et al. 2015; Sevastianova, et al. 2012; Silbernagel et al. 2012). As previously reported, HF-diet reduces the rate of DNL (Duarte, et al. 2014) and expression of DNL proteins (Benard, et al. 2016), as reflected by significant reduction in both the SCD-1 and DNL index, as well as the reduction in DNL gene expression (Acc1, Fasn, Elovl6, Scd1; Supplemental table 1B). Independent of diet, loss of hepatocyte PPARγ did not impact these indices (Fig 3B). Taken together, these results suggest hepatic PPARγ plays a minimal role in directly regulating hepatic DNL. Hepatic TAG export, FA oxidation and lipid uptake A reduction in hepatic fat content observed in aLivPPARγkd mice could be due to an increased rate of hepatic VLDL production or a decreased rate of TAG lipoprotein clearance. However, examination of genes critical for these processes were not consistently altered by aLivPPARγkd (Fig. 3) and circulating TAG in aLivPPARγkd did not differ from PPARγ-intact controls, within age and diet group (Table 1). It could also be possible that the reduced TAG content observed in livers of aLivPPARγkd mice is due to an increase in intrahepatic TAG hydrolysis and FA oxidation. However, the fact that the expression of Atgl, Hsl, Mgll, PPARα, Acsl1, Cpt1, Hnf4α, Pgc1α and Cyp4a10 were not increased across groups (Fig 3), while HF-aLivPPARγkd mice exhibited a decrease in plasma ketones (Table 1), suggests that hepatic FA oxidation is actually reduced. It is possible that this reduction in FA oxidation/ketogenesis is secondary to a reduction intrahepatic FA availability due to a reduction in FA uptake, since aLivPPARγkd reduced the expression of hepatic Cd36 (FA translocase), where this was associated with an increase in circulating NEFA in HF-fed mice (Table 1). In fact, Cd36 has been previously shown to be a PPARγ target gene (Tontonoz, et al. 1998). However, it should be noted that a significant reduction in Cd36 was not observed in aLivPPARγkd after 1 wk of knockdown, or in LF-fed mice, suggesting that under these conditions the low level of PPARγ is not sufficient to maintain Cd36 expression or that the full expression requires additional factors that are activated with age or diet, such as LXR and PXR (Zhou, et al. 2008). TAG synthesis TAG, DAG and MAG are generated by esterification of newly synthetized FA or extrahepatic FA into acylglycerol backbones, as illustrated in Fig 5A. In the liver, it is thought that the primary source of TAG is via the glycerol-3-phosphate (G3P) pathway, that generates DAG (Coleman and Mashek 2011; Mashek 2013) which serves as a substrate of DAG transferases 1 and 2 (Dgat1/2). However, it is becoming evident that the MAG pathway [ie. generation of DAG from MAG via MAG transferases 1 and 2 (Mogat1/2 in mice)], may be a relevant pathway in NAFLD (Hall, et al. 2012; Mashek 2013). Examination of the expression of key genes involved in TAG synthesis revealed there was an overall inhibitory effect of aLivPPARγkd on the expression of Mogat1 (Supplemental Table 1) that reached significance with age and HF feeding (Fig. 3B), without a reduction in Gpat, Mogat2, Dgat1 or Dgat2 expression (Fig 3B). Of note, Mogat1 has been reported to be a direct target of PPARγ (Lee, et al. 2012; Yu, et al. 2015) and in fact, expression of Mogat1 increases with age and HF-feeding, p-value: 0.0063 and <0.0001, respectively, (Supplemental Table 1A,B), mirroring the relative changes observed in hepatic PPARγ expression (Fig. 2). To indirectly test if the reduction in Mogat1 gene expression translated into a reduction in MAG pathway activity, we used LC/MS to measure the relative levels of MAG, DAG and TAG in LF- and HF-fed mice with or without hepatic PPARγ. Overall, aLivPPARγkd increased MAG levels, which reached significance in LF-fed mice. In HF-fed aLivPPARγkd mice, this was associated with a decrease in DAG and TAG (Fig 5B). Interestingly, in LF-fed aLivPPARγkd, the relative levels of DAG and TAG were not altered. Taken together, loss of hepatocyte PPARγ signaling preferentially reduces esterification of FA via direct transcriptional regulation of the MAG pathway, where loss of this effect could contribute to the protection against excess TAG accumulation observed in aLivPPARγkd mice. DISCUSSION Hepatocyte PPARγ has been defined as a steatogenic factor (Gavrilova et al. 2003; Inoue et al. 2005; Matsusue et al. 2003; Moran-Salvador et al. 2011; Pettinelli and Videla 2011; Rahimian et al. 2001), while others suggest that its activation decreases hepatic steatosis (Belfort et al. 2006; Ratziu et al. 2008; Sanyal et al. 2010). The fact that PPARγ is the target of TZDs, that are used in the treatment of diabetes and NAFLD, raises the question if the hepatic-specific agonism of PPARγ is well understood (Ahmadian et al. 2013). Therefore, we sought to determine which molecular processes are the primary targets for hepatocyte PPARγ that promotes TAG accumulation. We have taken advantage of the novel adult-onset, hepatocyte-specific PPARγ knockdown (aLivPPARγkd) model, that allowed us to study early events altered by aLivPPARγkd (1wk of knockdown) and how this deficit impacts liver function overtime under different dietary conditions. Our approach has benefits over existing congenital knockout models, because it avoids compensatory changes that could occur with embryonic knockout and therefore better models the consequence of manipulating PPARγ function in adult, where NALFD/NASH typically develops. As discussed in detailed below, our primary findings are that hepatic PPARγ has minimal direct effects on hepatic DNL, TAG uptake, TAG export or FA oxidation, but plays a major role in upregulating genes/pathways critical for hepatic FA uptake and MAG pathway - mediated FA esterification. Congenital hepatocyte-specific PPARγ knockout has been reported to be associated with a reduction of hepatic expression of genes critical for DNL (Gavrilova et al. 2003; Matsusue et al. 2003; Moran-Salvador et al. 2011; Yu et al. 2003). Also, use of antisense oligonucleotide strategy to suppress elevated hepatic PPARγ in apoB/BATless mice, reduced hepatic TAG accumulation, as well as the expression of DNL genes and DNL rate as assessed by 3H2O incorporation into TAG-associated FA (Zhang et al. 2006). In addition, overexpression of PPARγ in a hepatic cell line [AML-12; (Schadinger et al. 2005)] was shown to increase SREBP1c and Fasn expression that was associated with an increase in 14C-acetate incorporation into TAG. Finally, overexpression of PPARγ in some (Yu et al. 2003), but not all (Bai et al. 2011) in vivo models, increased expression of genes associated with DNL. In contrast to these reports, in the aLivPPARγkd model system, expression of DNL genes were not suppressed in any conditions tested, consistent with the lack of an effect on DNL indices (16:1/16:0 and 16:0/18:2). In fact, we have recently reported although PPARγ expression was associated with TAG accumulation in a model of DNL-generated steatosis (Kineman et al. 2016), adult-onset hepatic PPARγ knockdown in this steatotic model did not reduce hepatic TAG content or FA indices of DNL (Cordoba-Chacon et al. 2015a). The question arises, why are our current results counter to that previously reported by others? We might speculate that any changes observed in the expression of DNL genes in congenital liver-specific PPARγ knockout models could be secondary to changes that occur due to compensation during development or systemic metabolic changes that occur overtime. Also, the use of antisense oligonucleotides (ASO) to acutely suppress enhanced PPARγ expression in vivo (Zhang et al. 2006), is not a hepatocyte-specific approach, and therefore a reduction in PPARγ in other cell types could contribute to the phenotype observed. Finally in vivo (Zhang et al. 2006) or in vitro (Schadinger et al. 2005) overexpression of PPARγ may have off-target effects. Therefore we can conclude that in the context of adult metabolic function, loss of hepatic PPARγ does not directly control hepatic DNL. Early work by Gavrilova et al (Gavrilova et al. 2003) and Matsusue et al (Matsusue et al. 2003), who crossbred the congenital liver-specific PPARγ model with a lipodystrophic model (AZIP, (Gavrilova et al. 2003)), and ob/ob mice (Matsusue et al. 2003), respectively, observed a reduction in hepatic TAG content associated with elevated plasma TAG and thus concluded that hepatic PPARγ was critical to maintain hepatic TAG uptake. However, in chow-fed WT mice (Matsusue et al. 2003; Moran-Salvador et al. 2011) and HF-fed (Moran-Salvador et al. 2011) mice with congenital liver-specific PPARγ knockout, as well as in our HF-fed aLivPPARγkd model, circulating TAG did not differ from PPARγ-intact controls, despite the dramatic reduction in hepatic TAG content. Also, there were no decreases in the expression of genes known to be critical in hepatic TAG uptake in mouse livers, including low density lipoprotein receptor [Ldlr; (Havel and Hamilton 2004; Ishibashi, et al. 1994)] and hepatic lipase [HL;(Freeman, et al. 2007; Havel and Hamilton 2004)]. However, it should be noted that the expression of very low density lipoprotein receptor (Vldr), a known PPARγ target in adipocytes (Tao, et al. 2010), was significantly reduced in HF-fed aLivPPARγkd mice. The expression of hepatic Vldlr is normally low, but is increased in mouse models of fatty liver (also observed with HF-feeding in this study, see Supplemental Table 1), and whole body knockout of Vldlr reduces ER stress and HF-diet induced hepatic steatosis (Jo, et al. 2013). However, a liver-specific role of Vldlr in hepatic TAG uptake remains to be determined. Although the role of PPARγ in regulating hepatic TAG uptake remains to be further explored, our current results coupled with previous reports, do provide compelling evidence that hepatic PPARγ promotes hepatic FA uptake by regulating the expression of Cd36. Specifically, in both aged and HF-fed aLivPPARγkd mice expression of Cd36 was reduced. Cd36 has been shown to be a direct target of PPARγ (Tontonoz et al. 1998) and its expression is increased in steatotic livers. In the current study, a reduction in Cd36 levels in aLivPPARγkd mice was only observed with age or HF-feeding, consistent with the fact that in addition to PPARγ, LXR and PXR are also required for full expression of Cd36 (Zhou et al. 2008). Although global Cd36 knockout does not protect against high fructose-induced hepatic steatosis (Hajri, et al. 2002) or prevent fatty liver in ob/ob mice (Nassir, et al. 2013), a more recent report supports a liver-specific role of Cd36 in FA uptake. Specifically, congenital liver-specific Cd36 knockout reduced steatosis in liver-specific Jak2 knockout mice that led to an increase in plasma NEFA (Wilson, et al. 2015). Also in that same study, liver-specific Cd36 knockout mice with intact hepatic Jak2, dramatically reduced HF-diet induced steatosis that was associated with a reduction in hepatic FA uptake as measured by hepatic accumulation of BODIPY-FA in vivo (Wilson et al. 2015). However, loss of hepatic Cd36 did not entirely prevent hepatic FA uptake which could be mediated by other facilitated transport mechanisms or passive diffusion (Glatz, et al. 2010), indicating the reduction in CD36 after aLivPPARγkd is only in part responsible for the reduction in hepatic TAG content. Of the selected genes examined in this study, the expression of Mogat1 was the most sensitive to PPARγ loss. As previously reported, the expression of Mogat1 in the lean mouse liver is low, but increases in association with TAG accumulation, similar to that observed for PPARγ (Hall, et al. 2014; Lee et al. 2012; Soufi, et al. 2014; Yu, et al. 2016), as we also observed in the current study. In addition hepatic expression of Mogat1, as well as PPARγ, is elevated in humans with NAFLD (Hall et al. 2012; Yu et al. 2015). There is an ongoing debate regarding the physiologic role hepatic Mogat1 plays in TAG synthesis, since it was originally thought that the glycerol-3-phosphate pathway, not the MAG pathway, is the dominant route to form TAG in the liver (Coleman and Mashek 2011; Mashek 2013). In fact one laboratory could not detect hepatic MOGAT activity (Cortes, et al. 2009) and recently reported that global Mogat1 knockout in the ob/ob or Agpat2KO mice did not impact steatosis (Agarwal, et al. 2016). However, hepatic MOGAT activity has been detected by other laboratories (Hall et al. 2012; Yen, et al. 2002). Importantly, the increase in Mogat1 expression observed in HF-fed and ob/ob mice is associated with an elevation of hepatic MOGAT activity, which is reduced by Mogat1 ASO ip treatment (Hall et al. 2014; Soufi et al. 2014). The Mogat1-ASO injections reduced hepatic TAG accumulation in one study (Soufi et al. 2014), but not the other (Hall et al. 2014). However, it was acknowledge that the knockdown of Mogat1 was not hepatocyte-specific, and actually led to a reduction Mogat1 expression in the adipose tissue that could offset any hepatocyte-specific effect (Soufi et al. 2014). In strong support of a physiologic role of hepatic Mogat1 in maintaining hepatic TAG levels, adenoviral shRNA-Mogat1 delivery (that is preferentially taken up by the liver) (Lee et al. 2012), and nonviral siRNA-Mogat1 delivery (Hayashi, et al. 2014), reduced Mogat1 expression and hepatic TAG levels in HF-fed mice. The results of the present study indicate PPARγ is necessary to maintain Mogat1 activity, as well as Mogat1 expression, based on the increase in hepatic MAG levels in aLivPPARγkd mice. Interestingly, it has been postulated that Mogat1 may prefer extrahepatic (dietary FA) over those produced by hepatic DNL, to synthesize DAG (Steneberg, et al. 2015). This would be consistent with our observation that although MAG levels were increased in LF-fed aLivPPARγkd mice, DAG and TAG levels were normal, where in this context hepatic DAG and TAG are mainly derived from DNL. However, in HF-fed aLivPPARγkd mice (where the bulk of FA is coming from the diet), a reduction in DAG and TAG levels was observed. Taken together, results suggest that hepatocyte PPARγ expression in adult livers is not essential to maintain expression of DNL genes, but it is essential to induce the expression of genes important in hepatic FA uptake (Cd36) and re-esterification (Mogat1). Certainly other pathways may be mediated by hepatic PPARγ that were not revealed by our targeted approach. Nonetheless, our current data, coupled with previous reports suggest that impairment of the Cd36-mediated FA uptake and MAG pathway FA esterification pathways could explain in part the protection against steatosis observed in aLivPPARγkd mice. Supplementary Material 01 02 FUNDING This work was supported by Department of Veterans Affairs, Office of Research and Development Merit Award (BX001090, BX001114), National Institutes of Health (R21AT008457, S10OD010660, R01DK088133), Chicago Biomedical Consortium with support from the Searle Funds at The Chicago Community Trust (PDR-033) and 2014 Endocrine Scholar Award in Growth Hormone Research (Endocrine Society). Figure 1 Hepatocyte-specificity expression of AAV8-TBGp driven transgene Hepatocyte-specific expression of GFP in AAV8-TBGp-EGFP injected wild-type mice (green, A,B). GFP expression was absent in non-hepatocyte cells (yellow arrows) in sinusoids (Sn), central vein (CV), portal vein (PV), bile duct (BD) or artery (HA). TBGp-GFP was not expressed in hepatic stellate cells (HSC, desmin +, red, C) or macrophages (Mac, F4/80+, red, D). Sections were counterstained with DAPI (blue nuclei, A–D). Hepatic GFP (E) and Cre (F) expression was detected only in liver extracts of AAV8-TBGp-EGFP and AAV8-TBGp-Cre injected mice, respectively. In order to confirm the hepatocyte-specific activity of Cre recombinase, PPARγfl/fl mice were injected with AAV8-TBGp-Cre and expression of PPARγ was reduced in hepatic extracts but not adipose tissue (G). eWAT, epididymal fat; iWAT, inguinal fat; Ctx, cortex; Int, intestine. Asterisks indicate difference between AAV8-TBGp-Cre injected mice as compared to AAV8-TBGp-Null mice. *, p<0.05; ***, p<0.0001. n=3–6 mice/group. Figure 2 Adult-onset hepatocyte-specific PPARγ knock-down (aLivPPARγkd) in chow-fed mice (A–C) and diet-induced obese mice (D–F) A) PPARγfl/fl mice were injected at 10 weeks of age with 1.5*1011GC AAV8-TBGp-Null (C, open columns) or 1.5*1011GC AAV8-TBGp-Cre (Kd, shaded columns) via lateral tail vein and killed 1 or 18 weeks after. B) Hepatic PPARγ mRNA and (C) protein expression of 1 wk and 18 wks aLivPPARγkd and their littermate control mice. Representative image of the western-blot for hepatic PPARγ and Histone [as loading control]). Of note, nuclear protein variability within total hepatic extracts (assessed by Histone) alters the amount of PPARγ protein detected. n=4–5 mice/group. D) LF-fed PPARγfl/fl mice were injected at 10 weeks as described above and immediately half of the mice were fed at high-fat diet (HF, 60% Kcal from fat) to induce liver steatosis while the rest were maintained on a low fat diet (LF, 10% Kcal from fat). Mice were killed 14 weeks after. E). Hepatic PPARγ mRNA and (F) protein expression of 14 wks LF- and HF-fed aLivPPARγkd and their littermate controls. Representative image of the western-blot for hepatic PPARγ and Histone [as loading control]. Asterisks indicate differences between C and Kd. *, p<0.05; ***, p<0.0001. Letters indicate differences between 1wk and 18 wks or LF and HF-fed mice within group. b, p<0.01; c, p<0.0001. n=5–6 mice/group Figure 3 Impact of aLivPPARγkd in hepatic gene expression of molecular mechanisms controlling hepatic TAG levels A) 1 wk (top) and 18 wks (bottom) chow-fed and B) 14 wks LF-fed (top) and HF-fed (bottom) aLivPPARγkd-induced regulation of hepatic gene expression. Graphs represent the natural logarithm of the relative change in the gene expression of aLivPPARγkd mice as compared to their littermates controls (set at 0, x-axis), within age (A) or diet (B). Absolute values are included in Supplemental Table 1A,B. Asterisks show significant changes between C and aLivPPARγkd within age (A) or diet (B). *, p<0.05; **, p<0.01, ***, p<0.0001. Livers were collected at 1100h (4h after food removal). FAox: fatty acid oxidation, TAGhydr: TAG hydrolysis, VLDLsyn: VLDL synthesis, DNL: de novo lipogenesis and TAGsyn: TAG synthesis. Selected genes of these metabolic pathways represented in figure 3: peroxisome proliferator-activated receptor α (PPARα), acyl-CoA synthetase long-chain family member 1 (Acsl1), carnitine palmitoyltransferase 1α (Cpt1α), hepatic nuclear factor 4 α (Hnf4α), PPARγ co-activator 1 α; (Pgc1α), Cyp4a10, adipose triglyceride lipase (Atgl), hormone-sensitive lipase (Hsl), monoacylglycerol lipase (Mgll), apolipoprotein B (ApoB), microsomal triglyceride transfer protein (Mttp), sterol response element binding protein 1c (Srebp1c), acetyl-CoA carboxilase 1 (Acc1), fatty acid synthase (Fasn), fatty acid elongase (Elovl6), stearoyl –CoA desaturase 1 (Scd1), hepatic lipase (Hl), low density lipoprotein lipase receptor (Ldlr), very-low density lipoprotein receptor (Vldlr), lipoprotein related protein 1 (Lrp1), fatty acid translocase (Cd36), glycerol phosphate acyltransferase (Gpat1), monoacylglycerol acyltransferase 1 or 2 (Mogat1/2), diacylglycerolacyltransferase 1/2 (Dgat1/2). Figure 4 aLivPPARγkd reduces HF diet-induced FA levels, but has little impact on FA indices of DNL A) Hepatic FA levels of 16:0, palmitate; 16:1, palmitoleate; and 18:2, linoleate, levels and B) hepatic FA ratios indicative of DNL include the SCD-index (16:1/16:0) and the DNL-index (16:0/18:2), where control (open columns, C) and aLivPPARγkd (closed columns, Kd) mice were fed a LF- or a HF-diet for 14 weeks. Asterisks indicate differences between C and Kd. ***, p<0.0001. Letters indicate differences between LF and HF-fed mice within group. a, p<0.05; c, p<0.0001. n=4–6 mice/group. Figure 5 aLivPPARγkd reduces HF diet-induced hepatic TAG and DAG levels while increasing MAG levels, independent of diet, indicative of impaired hepatic MAG pathway activity in aLivPPARγkd mice A) Schematic representation of acylglycerol synthesis by glycerol-3-phosphate (G3P) pathway that produces DAG by subsequent re-esterification of FA in G3P and lysophosphatidic acid (LPA) or by monoacylglycerol (MAG) pathway that produces DAG after re-esterification of FA in MAG. B) Relative hepatic TAG, DAG and MAG levels assessed by liquid chromatography/mass spectrometry (LC/MS) in control (open columns) and aLivPPARγkd (close columns) mice. TAG, DAG and MAG are shown as relative values of LF-fed controls. Asterisks indicate differences between control and aLivPPARγkd. ***, p<0.0001. Letters indicate differences between LF and HF-fed mice within group. b, p<0.01; c, p<0.0001 n=5–6 mice/group. Table 1 Impact of aLivPPARγkd on body, liver and fat depot (sum of the unilateral epididymal, inguinal and retroperitoneal fat depot) weight, hepatic TAG levels and circulating metabolic endpoints (blood glucose, plasma insulin, ketones, TAG, NEFA and NEFA), in chow-fed (top, 1 wk and 18 wks) and LF/HF-fed (bottom, 14 wks) aLivPPARγkd mice and their littermate controls. 1 wk aLivPPARγkd - chow diet 18 wk aLivPPARγkd - chow diet Overall effect (p-value) of Control aLivPPARγkd Control aLivPPARγkd Mean SEM Mean SEM Mean SEM Mean SEM Age aLivPPARγkd Body weight g 25.36 ± 0.84 24.60 ± 0.64 31.81b ± 1.88 32.49c ± 0.60 <0.0001 0.9719 Liver g/g BW 0.045 ± 0.0008 0.043 ± 0.0022 0.038a ± 0.0011 0.038 ± 0.0021 <0.0022 0.3959 Fat mass g/g BW 0.015 ± 0.0015 0.013 ± 0.0011 0.029a ± 0.0066 0.023 ± 0.0031 0.0091 0.2680 Hepatic TAG mg/g 47.63 ± 6.987 38.63 ± 3.027 50.36 ± 4.611 34.72 ± 3.653 0.9024 0.0185 Blood Glucose mg/dL 187.0 ± 14.77 176.8 ± 18.87 190.4 ± 15.70 199.7 ± 8.92 0.3797 0.9748 Plasma insulin ng/ul 1.59 ± 0.15 1.69 ± 0.12 1.88 ± 0.37 1.34 ± 0.14 0.8925 0.3323 Plasma ketones μM 372.1 ± 62.194 372.1 ± 57.920 153.9a ± 40.907 226.1 ± 33.635 0.0017 0.4704 Plasma TAG mg/dL 91.26 ± 3.772 83.95 ± 5.728 61.35 ± 12.607 67.25 ± 10.736 0.0220 0.9396 Plasma NEFA mEq/L 1.05 ± 0.038 1.12 ± 0.063 1.06 ± 0.095 1.07 ± 0.064 0.7687 0.5581 Plasma Cholesterol mg/dL 104.83 ± 5.568 107.83 ± 5.233 116.17 ± 8.003 116.61 ± 5.334 0.1177 0.7812 14 wks aLivPPARgkd - LF diet 14 wks aLivPPARgkd - HF diet Overall effect (p-value) of Control aLivPPARγkd Control aLivPPARγkd Mean SEM Mean SEM Mean SEM Mean SEM Diet aLivPPARγkd Body weight g 30.88 ± 0.95 29.65 ± 0.60 49.52c ± 0.55 48.52c ± 1.13 <0.0001 0.1827 Liver g/g BW 0.0376 ± 0.0007 0.0373 ± 0.0006 0.049c ± 0.0010 0.032b*** ± 0.002 0.0062 <0.0001 Fat mass g/g BW 0.0313 ± 0.0035 0.0296 ± 0.0032 0.055c ± 0.0024 0.065c ± 0.002 <0.0001 0.1564 Hepatic TAG mg/g 37.13 ± 9.114 41.27 ± 9.188 326.25c ± 16.654 111.37b*** ± 18.11 <0.0001 <0.0001 Blood Glucose mg/dL 182.6 ± 20.78 187.2 ± 9.14 218.0 ± 15.12 231.2 ± 12.31 0.0128 0.5449 Plasma insulin ng/ul 1.39 ± 0.11 1.96 ± 0.30 11.27c ± 0.85 9.39c ± 1.68 <0.0001 0.4500 Plasma ketones μM 232.3 ± 42.17 215.4 ± 30.85 348.71 ± 22.787 215.41* ± 31.53 0.0886 0.0323 Plasma TAG mg/dL 52.78 ± 7.716 57.18 ± 7.479 35.80 ± 3.672 40.83 ± 4.21 0.0138 0.4479 Plasma NEFA mEq/L 1.17 ± 0.050 1.1 ± 0.08 0.53b ± 0.070 1.15** ± 0.20 0.0221 0.0340 Plasma Cholesterol mg/dL 117.71 ± 12.99 104.57 ± 9.20 212.86b ± 37.85 110.29** ± 8.35 0.0177 0.0078 Superscript letters indicate differences between 1wk and 18 wks or LF and HF-fed mice within group. a p<0.05; b p<0.01; c p<0,0001. Asterisks indicate differences between control and aLivPPARγkd mice. * p<0.05; ** p<0.01; *** p<0.0001. n=4–6 mice/group DECLARATION OF INTEREST Authors do not have any conflict of interest. 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22394502 Hall AM Soufi N Chambers KT Chen Z Schweitzer GG McCommis KS Erion DM Graham MJ Su X Finck BN 2014 Abrogating monoacylglycerol acyltransferase activity in liver improves glucose tolerance and hepatic insulin signaling in obese mice Diabetes 63 2284 2296 24595352 Havel RJ Hamilton RL 2004 Hepatic catabolism of remnant lipoproteins: where the action is Arterioscler Thromb Vasc Biol 24 213 215 14766735 Hayashi Y Suemitsu E Kajimoto K Sato Y Akhter A Sakurai Y Hatakeyama H Hyodo M Kaji N Baba Y 2014 Hepatic Monoacylglycerol O-acyltransferase 1 as a Promising Therapeutic Target for Steatosis, Obesity, and Type 2 Diabetes Mol Ther Nucleic Acids 3 e154 24643205 He W Barak Y Hevener A Olson P Liao D Le J Nelson M Ong E Olefsky JM Evans RM 2003 Adipose-specific peroxisome proliferator-activated receptor gamma knockout causes insulin resistance in fat and liver but not in muscle Proc Natl Acad Sci U S A 100 15712 15717 14660788 Horakova O Hansikova J Bardova K Gardlo A Rombaldova M Kuda O Rossmeisl M Kopecky J 2016 Plasma Acylcarnitines and Amino Acid Levels As an Early Complex Biomarker of Propensity to High-Fat Diet-Induced Obesity in Mice PLoS One 11 e0155776 27183228 Inoue M Ohtake T Motomura W Takahashi N Hosoki Y Miyoshi S Suzuki Y Saito H Kohgo Y Okumura T 2005 Increased expression of PPARgamma in high fat diet-induced liver steatosis in mice Biochem Biophys Res Commun 336 215 222 16125673 Ishibashi S Herz J Maeda N Goldstein JL Brown MS 1994 The two-receptor model of lipoprotein clearance: tests of the hypothesis in “knockout” mice lacking the low density lipoprotein receptor, apolipoprotein E, or both proteins Proc Natl Acad Sci U S A 91 4431 4435 8183926 Jo H Choe SS Shin KC Jang H Lee JH Seong JK Back SH Kim JB 2013 Endoplasmic reticulum stress induces hepatic steatosis via increased expression of the hepatic very low-density lipoprotein receptor Hepatology 57 1366 1377 23152128 Kineman R Majumdar N Subbaiah PV Cordoba-Chacon J 2016 Hepatic PPARγ is not essential for the rapid development of steatosis following loss of hepatic GH signaling, in adult male mice Endocrinology 157 1728 1735 26950202 Lade A Noon LA Friedman SL 2014 Contributions of metabolic dysregulation and inflammation to nonalcoholic steatohepatitis, hepatic fibrosis, and cancer Curr Opin Oncol 26 100 107 24275855 Lee JJ Lambert JE Hovhannisyan Y Ramos-Roman MA Trombold JR Wagner DA Parks EJ 2015 Palmitoleic acid is elevated in fatty liver disease and reflects hepatic lipogenesis Am J Clin Nutr 101 34 43 25527748 Lee YJ Ko EH Kim JE Kim E Lee H Choi H Yu JH Kim HJ Seong JK Kim KS 2012 Nuclear receptor PPARgamma-regulated monoacylglycerol O-acyltransferase 1 (MGAT1) expression is responsible for the lipid accumulation in diet-induced hepatic steatosis Proc Natl Acad Sci U S A 109 13656 13661 22869740 Mashek DG 2013 Hepatic fatty acid trafficking: multiple forks in the road Adv Nutr 4 697 710 24228201 Matsusue K Aibara D Hayafuchi R Matsuo K Takiguchi S Gonzalez FJ Yamano S 2014 Hepatic PPARgamma and LXRalpha independently regulate lipid accumulation in the livers of genetically obese mice FEBS Lett 588 2277 2281 24857376 Matsusue K Haluzik M Lambert G Yim SH Gavrilova O Ward JM Brewer B Jr Reitman ML Gonzalez FJ 2003 Liver-specific disruption of PPARgamma in leptin-deficient mice improves fatty liver but aggravates diabetic phenotypes J Clin Invest 111 737 747 12618528 Michelotti GA Machado MV Diehl AM 2013 NAFLD, NASH and liver cancer Nat Rev Gastroenterol Hepatol 10 656 665 24080776 Moran-Salvador E Lopez-Parra M Garcia-Alonso V Titos E Martinez-Clemente M Gonzalez-Periz A Lopez-Vicario C Barak Y Arroyo V Claria J 2011 Role for PPARgamma in obesity-induced hepatic steatosis as determined by hepatocyte- and macrophage-specific conditional knockouts Faseb J 25 2538 2550 21507897 Nan YM Fu N Wu WJ Liang BL Wang RQ Zhao SX Zhao JM Yu J 2009 Rosiglitazone prevents nutritional fibrosis and steatohepatitis in mice Scand J Gastroenterol 44 358 365 18991162 Nassir F Adewole OL Brunt EM Abumrad NA 2013 CD36 deletion reduces VLDL secretion, modulates liver prostaglandins, and exacerbates hepatic steatosis in ob/ob mice J Lipid Res 54 2988 2997 23964120 Obrowsky S Chandak PG Patankar JV Povoden S Schlager S Kershaw EE Bogner-Strauss JG Hoefler G Levak-Frank S Kratky D 2013 Adipose triglyceride lipase is a TG hydrolase of the small intestine and regulates intestinal PPARalpha signaling J Lipid Res 54 425 435 23220585 Pettinelli P Videla LA 2011 Up-regulation of PPAR-gamma mRNA expression in the liver of obese patients: an additional reinforcing lipogenic mechanism to SREBP-1c induction J Clin Endocrinol Metab 96 1424 1430 21325464 Rahimian R Masih-Khan E Lo M van Breemen C McManus BM Dube GP 2001 Hepatic over-expression of peroxisome proliferator activated receptor gamma2 in the ob/ob mouse model of non-insulin dependent diabetes mellitus Mol Cell Biochem 224 29 37 11693197 Ratziu V Giral P Jacqueminet S Charlotte F Hartemann-Heurtier A Serfaty L Podevin P Lacorte JM Bernhardt C Bruckert E 2008 Rosiglitazone for nonalcoholic steatohepatitis: one-year results of the randomized placebo-controlled Fatty Liver Improvement with Rosiglitazone Therapy (FLIRT) Trial Gastroenterology 135 100 110 18503774 Sanyal AJ Chalasani N Kowdley KV McCullough A Diehl AM Bass NM Neuschwander-Tetri BA Lavine JE Tonascia J Unalp A 2010 Pioglitazone, vitamin E, or placebo for nonalcoholic steatohepatitis N Engl J Med 362 1675 1685 20427778 Schadinger SE Bucher NL Schreiber BM Farmer SR 2005 PPARgamma2 regulates lipogenesis and lipid accumulation in steatotic hepatocytes Am J Physiol Endocrinol Metab 288 E1195 1205 15644454 Sevastianova K Santos A Kotronen A Hakkarainen A Makkonen J Silander K Peltonen M Romeo S Lundbom J Lundbom N 2012 Effect of short-term carbohydrate overfeeding and long-term weight loss on liver fat in overweight humans Am J Clin Nutr 96 727 734 22952180 Shin S Wangensteen KJ Teta-Bissett M Wang YJ Mosleh-Shirazi E Buza EL Greenbaum LE Kaestner KH 2016 Genetic Lineage Tracing Analysis of the Cell of Origin of Hepatotoxin-Induced Liver Tumors in Mice Hepatology 10.1002/hep.28602 Silbernagel G Kovarova M Cegan A Machann J Schick F Lehmann R Haring HU Stefan N Schleicher E Fritsche A 2012 High hepatic SCD1 activity is associated with low liver fat content in healthy subjects under a lipogenic diet J Clin Endocrinol Metab 97 E2288 2292 23015656 Soufi N Hall AM Chen Z Yoshino J Collier SL Mathews JC Brunt EM Albert CJ Graham MJ Ford DA 2014 Inhibiting monoacylglycerol acyltransferase 1 ameliorates hepatic metabolic abnormalities but not inflammation and injury in mice J Biol Chem 289 30177 30188 25213859 Steneberg P Sykaras AG Backlund F Straseviciene J Soderstrom I Edlund H 2015 Hyperinsulinemia Enhances Hepatic Expression of the Fatty Acid Transporter Cd36 and Provokes Hepatosteatosis and Hepatic Insulin Resistance J Biol Chem 290 19034 19043 26085100 Tao H Aakula S Abumrad NN Hajri T 2010 Peroxisome proliferator-activated receptor-gamma regulates the expression and function of very-low-density lipoprotein receptor Am J Physiol Endocrinol Metab 298 E68 79 19861583 Tontonoz P Nagy L Alvarez JG Thomazy VA Evans RM 1998 PPARgamma promotes monocyte/macrophage differentiation and uptake of oxidized LDL Cell 93 241 252 9568716 Wilson CG Tran JL Erion DM Vera NB Febbraio M Weiss EJ 2015 Hepatocyte-specific disruption of CD36 attenuates fatty liver and improves insulin sensitivity in HFD fed mice Endocrinology 157 570 585 26650570 Xu A Wang Y Keshaw H Xu LY Lam KS Cooper GJ 2003 The fat-derived hormone adiponectin alleviates alcoholic and nonalcoholic fatty liver diseases in mice J Clin Invest 112 91 100 12840063 Yamauchi T Kamon J Minokoshi Y Ito Y Waki H Uchida S Yamashita S Noda M Kita S Ueki K 2002 Adiponectin stimulates glucose utilization and fatty-acid oxidation by activating AMP-activated protein kinase Nat Med 8 1288 1295 12368907 Yamazaki T Shiraishi S Kishimoto K Miura S Ezaki O 2011 An increase in liver PPARgamma2 is an initial event to induce fatty liver in response to a diet high in butter: PPARgamma2 knockdown improves fatty liver induced by high-saturated fat J Nutr Biochem 22 543 553 20801631 Yang P Subbaiah PV 2015 Regulation of hepatic lipase activity by sphingomyelin in plasma lipoproteins Biochim Biophys Acta 1851 1327 1336 26193433 Yanger K Knigin D Zong Y Maggs L Gu G Akiyama H Pikarsky E Stanger BZ 2014 Adult hepatocytes are generated by self-duplication rather than stem cell differentiation Cell Stem Cell 15 340 349 25130492 Yen CL Stone SJ Cases S Zhou P Farese RV Jr 2002 Identification of a gene encoding MGAT1, a monoacylglycerol acyltransferase Proc Natl Acad Sci U S A 99 8512 8517 12077311 Younossi ZM Stepanova M Afendy M Fang Y Younossi Y Mir H Srishord M 2011 Changes in the prevalence of the most common causes of chronic liver diseases in the United States from 1988 to 2008 Clin Gastroenterol Hepatol 9 524 530 e521 quiz 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PMC005xxxxxx/PMC5120587.txt
LICENSE: This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. 0147763 2979 Circulation Circulation Circulation 0009-7322 1524-4539 27364164 5120587 10.1161/CIRCULATIONAHA.116.022304 NIHMS792439 Article Leukocyte-Expressed β2-Adrenergic Receptors are Essential for Survival Following Acute Myocardial Injury Grisanti Laurel A. PhD 1 Gumpert Anna M. PhD 1 Traynham Christopher J. PhD 1 Gorsky Joshua E. BS 1 Repas Ashley A. BS 1 Gao Erhe MD 12 Carter Rhonda L. BS 1 Yu Daohai PhD 3 Calvert John W. PhD 4 García Andrés Pun MS 5 Ibáñez Borja MD, PhD 5 Rabinowitz Joseph E. PhD 12 Koch Walter J. PhD 12 Tilley Douglas G. PhD 12 1 Center for Translational Medicine, Temple University School of Medicine, Philadelphia, PA, USA 2 Department of Pharmacology, Temple University School of Medicine, Philadelphia, PA, USA 3 Department of Clinical Sciences, Temple University School of Medicine, Philadelphia, PA, USA 4 Department of Surgery, Division of Cardiothoracic Surgery, Emory University School of Medicine and Carlyle Fraser Heart Center, Atlanta, GA, USA 5 Spanish National Center for Cardiovascular Research, Madrid Spain Correspondence to Douglas G. Tilley, PhD, Room 945A MERB, Center for Translational Medicine, Lewis Katz School of Medicine, Temple University, 3500 N. Broad St., Philadelphia, PA 19140, Tel.: 215-707-2791, Fax: 215-707-9890, douglas.tilley@temple.edu 8 6 2016 30 6 2016 12 7 2016 12 7 2017 134 2 153167 This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. Background Immune cell-mediated inflammation is an essential process for mounting a repair response following myocardial infarction (MI). The sympathetic nervous system is known to regulate immune system function through β-adrenergic receptors (βAR), however their role in regulating immune cell responses to acute cardiac injury is unknown. Methods Wild-type (WT) mice were irradiated followed by isoform-specific βARKO or WT bone-marrow transplantation (BMT) and after full reconstitution underwent myocardial infarction (MI) surgery. Survival was monitored over time and alterations in immune cell infiltration following MI were examined using immunohistochemistry. Alterations in splenic function were identified through the investigation of altered adhesion receptor expression. Results β2ARKO BMT mice displayed 100% mortality resulting from cardiac rupture within 12 days post-MI compared to ~20% mortality in WT BMT mice. β2ARKO BMT mice displayed severely reduced post-MI cardiac infiltration of leukocytes with reciprocally enhanced splenic retention of the same immune cell populations. Splenic retention of the leukocytes was associated with an increase in VCAM-1 expression, which was itself regulated via β-arrestin-dependent β2AR signaling. Further, VCAM-1 expression in both mouse and human macrophages was sensitive to β2AR activity, and spleens from human tissue donors treated with β-blocker showed enhanced VCAM1 expression. The impairments in splenic retention and cardiac infiltration of leukocytes following MI were restored to WT levels via lentiviral-mediated re-expression of β2AR in β2ARKO BM prior to transplantation, which also resulted in post-MI survival rates comparable to WT BMT mice. Conclusions Immune cell-expressed β2AR plays an essential role in regulating the early inflammatory repair response to acute myocardial injury by facilitating cardiac leukocyte infiltration. β-adrenergic receptor acute myocardial infarction leukocyte inflammation immune system Inflammation is critical for initiating reparative processes after ischemic injury1. Following myocardial infarction (MI) an intense inflammatory response is initiated leading to recruitment of pro-inflammatory leukocytes including monocytes, neutrophils and mast cells1-6. Secreted factors from these pro-inflammatory cell populations recruit and activate reparative cell populations to promote extracellular matrix (ECM) deposition and vascularization7, 8. This rapid inflammatory response is necessary for healing and preserving the structure of the left ventricle (LV) post-MI, as dysregulation of this process results in increased cardiomyocyte death and degradation of the ECM9. Sympathetic nervous system (SNS) regulation of immune responses is well-established10 and β-adrenergic receptor (βAR) expression has been reported on virtually all immune cell-types. All three βAR subtypes are expressed on various hematopoietic cell-derived immune cell populations with βAR subtype expression varying widely between populations and immune cell activation state11. Although the role of β1AR in the immune system is not well-established, β1AR expression has been shown to be limited primarily to cells of the innate immune system where it regulates inflammatory mediator production12, 13. β2AR is the most highly and widely expressed βAR isoform10, 14, with a similar level of immune cell expression in rodents and humans10, 14, and is known to regulate a number of functions including hematopoiesis, lymphocyte homing and immune cell maturation10. However, the focus of many of these studies involved the effect of β2AR on adaptive immune responses, while its involvement in mediating early, innate immune responses and initiation of inflammation remains unclear10, 15, 16. β3AR has been shown to be important in early stages of hematopoiesis for mediating immune cell mobilization and egress from the bone marrow17-19. While βAR subtype expression and function varies in the immune system, the role of Immune cell-expressed βAR in the acute inflammatory response post-MI has yet to be elucidated. In our current study, the impact of immune cell-specific βAR expression on cardiac inflammation and remodeling post-MI was investigated through the use of chimeric mice that lack specific βAR isoforms on cells of hematopoietic origin. We demonstrate that β2AR are essential in initiating early immune responses following acute cardiac injury and targeting immune cell-expressed β2AR may provide a novel therapeutic strategy for preventing adverse effects following MI. Methods Rationale and Study Design The purpose of this study was to investigate the impact of βAR in regulating immune responses following MI. To differentiate the effects of immune cell-expressed βAR from cardiac-expressed βAR, we generated chimeric mice using a BMT approach in which WT recipient mice received WT control or βAR subtype-specific KO BM to produce immune cell- and βAR isoform-specific KO mice. These mice were subjected to sham or MI surgery and survival outcome and immune responses were examined along with the mechanisms of observed changes. Bone Marrow Transplant WT C57BL/6 recipient mice (male, 8 wk) were lethally irradiated with 950 rads using x-ray irradiation to remove endogenous BM cells. Donor BM isolated from the femurs of β1ARKO, β2ARKO, β3ARKO or WT C57BL/6 mice was introduced by retro-orbital injection (1×107 cells) within 24 h of irradiation. BM was allowed to reconstitute for 1 month prior to MI surgery. Reconstitution was confirmed at the conclusion of the study for each mouse using RT-qPCR analysis for β1AR, β2AR and β3AR expression on recipient BM. All animal procedures were performed in accordance with the Institutional Animal Care and Use Committee at Temple University and in accordance to the NIH Guidelines on the Use of Laboratory Animals. Coronary Artery Occlusion Surgery Myocardial infarction was induced as previously described20. Mice were anesthetized with 2% isoflurane inhalation. A small skin incision was made and the pectoral muscles were retracted to expose the fourth intercostal space. A small hole was made and the heart popped out. The left coronary artery was sutured ~3 mm from its origin and the heart was placed back into the intrathoracic space followed by closure of muscle and skin. Animals received a single dose (0.3 mg/kg) of buprenorphine immediately following surgery. Splenectomy Surgery Mice were anesthetized as above and a small incision was made in the left subcostal abdominal wall. Sutures were placed around the splenic vasculature and the spleen was removed. The incision was closed in two layers, peritoneum and skin, using suture. Animals received a single dose (0.3 mg/kg) of buprenorphine immediately following surgery. Echocardiography Cardiac function was assessed via transthoracic two-dimensional echocardiography performed at baseline and at weekly intervals post MI using a 12-mHz probe on mice anesthetized with isoflurane (1.5%). M-mode echocardiography was performed in the parasternal short-axis view to assess several cardiac parameters including left ventricular (LV) end-diastolic dimension, wall thickness, LV fractional shortening and ejection fraction. Percent fractional shortening was calculated using the equation ((LVID;d-LVID;s)/LVID;s)*100%. Percent ejection fraction was calculated using the equation ((LV vol;d-LV vol;s)/LV vol;d)*100%. Lentivirus Infection of Bone Marrow BM isolated from the femurs of mice was transduced with lentiviral vectors for 3XFlag-β2AR-RFP or GFP using and MOI of 100. Transductions were performed in MEM+10%FBS in the presence of 5 μg/mL Polybrene (Sigma-Aldrich). For in vitro experiments, media was changed 24 h following infection to complete media (MEM+10% FBS) and incubated an additional 24 h prior experiments. For generation of bone marrow derived macrophages, isolated BM was cultured in 10% L929 conditioned MEM+10% FBS for 1 wk prior to lentiviral infection with GFP control, WT β2AR, β2ARTYY or β2ARGRK- constructs21, 22. For in vivo experiments, BM was rinsed 1 h following infection and transplanted into irradiated mice via retro-orbital injection. BM was allowed to reconstitute for 1 month. Human Macrophage Cell Culture THP-1 cells (American Type Culture Collection, Manassas, VA), a human monocytic cell line, were cultured in modified RPMI-1640 media containing 2 mM L-glutamine, 1.5 g/L sodium bicarbonate, 4.5 g/L glucose and 10 mM HEPES and 1 mM sodium pyruvate supplemented with 10% fetal bovine serum under standard cell culture growth conditions (37°C/5% CO2/95% humidified air). THP-1 cells were differentiated into macrophages using 200 nM PMA 48h prior to all experiments. Cells were washed with complete media and treated 24h with vehicle (PBS), 0.1 μM salbutamol or 0.1 μM ICI-118,551. Human Spleen Samples Spleen samples from deceased human tissue donors that had been chronically administered metoprolol, or age- and sex-matched subjects not treated with metoprolol, were procured by the National Disease Research Interchange (NDRI) with support from NIH grant 2 U42 OD011158. Control subjects: n=5, 74.6±15.5 y.o. (mean ± standard deviation), 1 male, 4 females; Metoprolol subjects: n=6, 77.5±8.4 y.o., 1 male, 5 females. Reverse Transcription Quantitative PCR cDNA was synthesized from the total RNA of BM and spleen using the High Capacity cDNA Reverse Transcription kit (Applied Biosystems). Reverse transcription quantitative PCR (RT-qPCR) was performed with SYBR® Select Master Mix (Applied Biosystems) in triplicate for each sample using primers listed in Supplemental Table 1 at an annealing temperature of 60.1°C. RT-qPCR data was analyzed using Applied Biosystems Comparative CT Method (ΔΔCT), using GAPDH, TPT-1 and 18s rRNA to normalize expression of genes of interest and calculate relative quantitation (RQ) and RQmin/max values for each. Immunoblot BM and spleen samples were homogenized in RIPA buffer containing 1X HALT protease inhibitor cocktail (78437; Thermo Scientific; Rockford, IL) and phosphatase inhibitor cocktail set IV (524628; Calbiochem, USA). Equal amounts of lysates were resolved by SDS-polyacrylamide gel electrophoresis (10% gels) and transferred to Immobilon-PSQ polyvinylidene fluoride 0.2μm pore size membranes (Millipore; Billerica, MA). Odyssey Blocking Buffer (LI-COR Biosciences; Lincoln, NE) was used to prevent non-specific binding. Immunoblotting was performed overnight at 4°C with diluted antibodies against Flag M2 (1:10,000; Sigma-Aldrich; St. Louis, MO), GFP (1:1000; Cell Signaling; Danvers, MA), VCAM-1 (1:1000; Santa Cruz Biotechnologies; Santa Cruz, CA), β-tubulin (1:1000; Cell Signaling), β-actin (1:1000; Santa Cruz) or GAPDH (1:1000; Cell Signaling). After washing with TBS-T, membranes were incubated at room temperature for 60 min with the appropriate diluted secondary antibody (IRDye680 Donkey anti-rabbit IgG (H + L) at 1:20,000; IRDye800CW Goat anti-mouse IgG (H + L) at 1:15,000; LI-COR Biosciences; IRDye680 Donkey anti-goat IgG (H+L) at 1:20,000). Bound antibody was detected using the LI-COR Biosciences Odyssey System (LI-COR Biosciences). Intensities were normalized to corresponding GAPDH, β-tubulin and β-actin intensities. Histological Analysis Excised hearts were fixed in 4% paraformaldehyde, paraffin embedded and sectioned at 5 μm thickness. Deparaffinized sections were stained for hematoxylin-eosin (H&E; Sigma-Aldrich). NIS Elements software was used to measure infarct size and visualize cell infiltration and morphology. Immunohistochemistry was performed on deparaffinized sections to examine infiltration of various immune cell types. Antigens were retrieved using a citrate-based antigen unmasking solution (Vector Laboratories; Burlingame, CA). Hearts were blocked (10% FBS/PBS) and a 0.3% H2O2 solution was used to block endogenous peroxide activity in sections used for immunohistochemical staining. Hearts were incubated with antibodies against CD3 (1:100; Abcam), CD68 (1:100; Abcam), major basic protein (MBP; Obtained from Nancy and Jamie Lee Laboratories; Mayo Clinic, Scottsdale, AZ), mast cell tryptase (1:100; Abcam), myeloperoxidase (MPO; 1:100, Santa Cruz, Dallas, TX) or VCAM-1 (1:100; Santa Cruz). Washed slides were incubated with the appropriate secondary antibodies, anti-mouse-HRP (1:1000; GE Healthcare; Piscataway, NJ), anti-goat-HRP (1:1000; Santa Cruz), anti-goat Alexa Fluor® 647 (1:1000; Invitrogen; Grand Island, NY) and anti-rabbit Alexa Fluor® 647 (1:1000; Invitrogen), followed by staining with DAPI for immunofluorescence or hematoxylin for immunohistochemical staining. Immunofluorescent stained hearts were mounted using Prolong® Gold Antifade Reagent (Invitrogen). Immunohistochemical stained hearts were developed using a DAB Substrate Kit (Vector Laboratories) and mounted using Permount™ Mounting Media (Thermo Scientific). Staining was visualized on a Nikon Eclipse microscope at 20X magnification and NIS Elements software was used for recording images and image analysis. Images were quantified as the number of positive cells per area. Flow Cytometry Flow cytometry analysis of immune cell populations were performed on cells isolated from blood and BM. Immune cells were separated using an antibody against CD45-FITC (BD Biosciences; San Jose, CA) and sorted on an LSRII flow cytometer for size and granularity by Forward Scatter (FSC) and Side Scatter (SSC). Analysis was performed using Flowjo software. Statistical Analysis Data presented is expressed as mean ± standard deviation (SD) for continuous variables and the count and/or percentage for categorical variables. Comparisons of a continuous variable between different treatment groups were performed using the nonparametric Kruskal-Wallis test for three or more groups and the exact Wilcoxon rank-sum test for two groups due to the small group sizes to guard against possibly non-normally distributed data. Comparisons of a survival endpoint between treatment groups were performed using the log-rank test. When data were collected over time on the same set of animals such as the fractional shortening in Fig 1B, they were analyzed using a mixed-effects model in order to take into account the correlation among repeated measures as well as the potential non-constant variability over time across different groups. Multiple pairwise comparison adjustments were made with Bonferroni or Dunnett correction as appropriate. P-value < 0.05 was considered statistically significant. P-values and n (group size) values are reported in the figure legends. All statistical analyses were performed using SAS version 9.3 software (SAS Institute Inc., Cary, NC). Results Lack of immune cell-expressed β2AR increases mortality following acute myocardial injury To examine the contribution of immune cell-specific βAR subtype expression on survival and cardiac function post-MI, chimeric animals were generated via WT, β1ARKO, β2ARKO or β3ARKO bone marrow transplant (BMT) into irradiated recipient WT mice. β1AR, β2AR and β3AR expression was examined by RT-qPCR on reconstituted BM from all animals (Figure 1A), confirming that β1AR, β2AR and β3AR were knocked out in their respective BM with no differences in the other two βAR subtypes. Following reconstitution, the BMT mice underwent sham or MI surgery and cardiac function was monitored via echocardiography (Supplemental Figure 1A, Supplemental Table 2). LV contractility, wall thickness and cardiac dimensions were significantly altered in each MI group as shown by decreased % fractional shortening (Figure 1B), increased LV hypertrophy and increased LV dilation relative to sham animals, although no differences were evident between WT, β1ARKO, β2ARKO and β3ARKO BMT groups. However, mortality rates among the BMT mice differed significantly post-MI. All sham BMT mice displayed 100% survival, and WT BMT mice exhibited ~20% mortality by two weeks post- MI (Figure 1C), consistent with prior studies in non-BMT mice20. β1ARKO and β3ARKO BMT animals had a small, but non-significant, increase in mortality following MI when compared to WT BMT animals. Strikingly, β2AR BMT mice displayed 100% mortality following MI due to cardiac rupture with death observed 4-12 days post-MI. Although infarct size one day post-MI was not different between WT and β2ARKO chimeric mice (Supplemental Figure 1B and 1C), H&E staining revealed wall thinning and weakening in β2ARKO BMT mice 4d post-MI compared to WT BMT hearts (Figure 1D), suggesting an impairment in early repair mechanisms. Lack of immune cell β2AR expression impairs leukocyte infiltration following acute myocardial injury A number of immune cell populations including monocytes/macrophages, neutrophils, mast cells and T cells are known to be important for the initiation of wound healing and cardiac remodeling post-MI. Due to the high mortality via cardiac rupture observed in β2AR BMT mice following MI, which could reflect decreased immune cell-initiated repair, we assessed whether WT and β2ARKO BMT mice display differences in MI-induced cardiac immune cell population infiltration. Immunostaining was performed to identify cells of monocyte/macrophage lineage (CD68), mast cells (tryptase), neutrophils (MPO), eosinophils (MBP) and T-cells (CD3) in sham BMT hearts and in the remote, border and infarct zones of BMT hearts following MI (Figure 2, Supplemental Figures 2 and 3). Compared to WT BMT hearts, β2ARKO BMT hearts had significantly less monocyte/macrophage, mast cell and neutrophil infiltration into both the border and infarct zones (Figure 2A). Quantification of the staining demonstrated that decreased monocyte/macrophage (Figure 2B, 2C), mast cell (Figure 2D, 2E) and neutrophil (Figure 2F, 2G) recruitment to β2ARKO BMT mouse hearts was maintained over time post-MI as compared to WT BMT mice. Not all immune cell populations were affected, however, as eosinophil and T-cell infiltration into the hearts of both WT BMT and β2ARKO BMT mouse hearts were not different (Supplemental Figure 3). Flow cytometric comparative analysis of immune cell populations in the BM or blood of WT and β2ARKO BMT animals showed there was no difference in granulocyte, monocyte or lymphocyte populations (Supplemental Figure 4). Therefore, despite having similar levels of hematopoietic-derived cells as compared to WT BMT mice, those with immune cell-specific deletion of β2AR have impaired leukocyte recruitment to the heart following acute injury. Mice lacking immune cell-expressed β2AR have increased splenic retention of leukocyte populations Since overall immune populations are similar between WT and β2ARKO BMT mice, but decreased leukocyte populations are observed in β2ARKO BMT hearts post-MI, we aimed to determine whether splenic retention of leukocytes could play role in this phenotype. Sham β2ARKO BMT mice had an increased spleen size compared to their WT BMT counterparts (Figure 3A), which was maintained post-MI (Figure 3B). Leukocyte levels in spleen sections from WT or β2ARKO BMT mice were examined to determine if an increase in leukocytes within the β2ARKO BMT spleens could account for the splenomegaly observed between the two groups in sham animals (Supplemental Figure 5) and 4d following MI (Figure 3C). Increased levels of monocyte/macrophages, mast cells and neutrophils (Figure 3D) were observed in β2ARKO BMT spleens compared to WT BMT mice, suggesting that β2ARKO leukocytes have an impaired ability to mobilize from the spleen to the heart following injury. Splenic and macrophage VCAM1 expression is sensitive to β2AR activity and expression in mice and humans VCAM-1 expression on splenic macrophages has recently been identified as a hematopoietic stem cell retention factor important for splenic myelopoiesis23. To determine if VCAM-1 levels were increased in the spleens of β2ARKO BMT mice, leading to the retention of myeloid populations, its expression was assessed in the spleens of WT or β2ARKO BMT mice. Immunostaining indicated increased splenic VCAM-1 expression with localization in the red pulp, where macrophages reside (Figure 4A and B). Protein levels of VCAM-1 were confirmed to be elevated in β2ARKO chimeric mouse spleens when compared to WT BMT mice via immunoblotting analysis (Figure 4C and D). Further, transcript expression of VCAM-1 was increased in β2ARKO BMT spleens both basally and 4d post-MI (Figure 4E). To determine if β2AR stimulation alters VCAM-1 expression at a cellular level, WT bone marrow-derived macrophages (BMDM) were treated with the β2AR-selective agonist salbutamol, which decreased VCAM-1 expression (Figure 4F). Strikingly, salbutamol also decreased VCAM-1 expression in a human macrophage cell line (Figure 4F), confirming that β2AR-mediated alterations in VCAM-1 are translatable between species. Since VCAM-1 was decreased by β2AR stimulation, we next tested whether pharmacological inhibition of β2AR could reciprocally increase VCAM-1 expression. Indeed, treatment of human macrophages with the β2AR-selective antagonist, ICI-118,551 (Figure 4G) increased VCAM-1 expression. Further, VCAM-1 expression was significantly increased in the spleens of human subjects treated with the β-blocker metoprolol versus age- and sex-matched subjects that had not taken a β-blocker (Figure 4H), demonstrating the clinical relevance of our findings. Proximal β2AR signaling through either G protein- or β-arrestin-dependent pathways have been shown to exert distinct cellular effects21, 22. Thus, to determine the proximal mechanism through which β2AR controls VCAM-1 expression, lentiviral constructs were generated containing either β2ARTYY, which is unable to couple to Gαs22, or β2ARGRK-, which cannot be phosphorylated by GRK21 thereby preventing the recruitment of β-arrestins (βARR). Using BMDM from WT or β2ARKO mice, VCAM-1 transcript expression was shown to be increased in β2ARKO macrophages (Figure 5A). Lentivirus-mediated restoration of β2AR expression in β2ARKO macrophages (Supplemental Figure 5E) decreased VCAM-1 expression to that in WT macrophages (Figure 5A), while a GFP control lentivirus had no effect on VCAM-1 expression. Mechanistically, β2ARKO BMDM transduced with β2ARGRK- had elevated expression of VCAM-1 where as β2ARTYY had decreased VCAM-1 similar to WT levels (Figure 5A), indicating that GRK-dependent β2AR signaling is required for regulation of VCAM-1 expression in macrophages. In support of this observation, βARR2KO mice had splenomegaly similar to β2ARKO mice (Figure 5B) with retention of monocytes/macrophages, mast cells and neutrophils (Figure 5C and D). Interestingly, βARR1KO mice had normal splenic size and leukocyte levels, indicating that β2AR regulates VCAM-1 expression selectively via βARR2 signaling. Splenectomized WT and β2ARKO BMT mice have similar levels of leukocyte infiltration following acute myocardial injury To confirm whether splenic retention of β2ARKO leukocytes is primarily responsible for their decreased infiltration into the heart following MI, we examined leukocyte recruitment to the heart in splenectomized WT and β2ARKO BMT animals receiving sham or MI surgery (Figure 6A, Supplemental Figure 6). Splenectomy in WT BMT animals decreased MI-induced infiltration of monocytes/macrophages (Figure 6B) and neutrophils (Figure 6D) into the border zone by about 50%, with less impact on mast cells (Figure 6C). Conversely, splenectomy of β2ARKO BMT animals increased cardiac infiltration of monocytes/macrophages, neutrophils and mast cells to levels not different from those observed in splenectomized WT BMT mice. Altogether, these results confirm that β2AR-deficient leukocytes accumulate in the spleen where they remain after MI, but do have the capacity to infiltrate the heart following injury in the absence of the spleen, similar to spleen-independent leukocyte infiltration levels attained in WT BMT mice. Restoration of β2AR expression reverses leukocyte dysfunction and restores survival rates following MI To determine if restoration of β2AR expression in β2ARKO BM could revert the β2AR BMT phenotype toward the WT BMT phenotype post-MI, β2ARKO BM was transduced with the WT β2AR lentivirus construct, or GFP control lentivirus, prior to transplantation. Immunoblotting was used to confirm protein expression of GFP in control and Flag-tagged β2AR expression for lentivirus-transduced reconstituted BM (Figure 7A) and β2AR expression in β2ARKO BM following reconstitution was approximately 95% of endogenous levels (Figure 7B). Similar to β2ARKO BMT mice, mice receiving β2ARKO BM transduced with GFP control lentivirus displayed 100% mortality post-MI with all mice dying between day 4 and 14 from cardiac rupture (Figure 7C), however restoration of β2AR expression in β2ARKO BM increased survival following MI to near WT BMT levels (Figure 7D). Reconstitution with β2AR-infected β2ARKO BM also reduced both spleen size (Figure 7E) and VCAM-1 expression (Figure 7F, 7G) compared with GFP-transduced β2ARKO BMT mice. Accordingly, restoration of β2AR in β2ARKO BM also reduced levels of the leukocyte populations in the spleen (Figure 8A and 8B) to those not different from WT BMT mice (Supplemental Table 3). Conversely, immunohistochemistry for leukocyte infiltration in sham (Supplemental Figure 7) and injured myocardium of β2AR-rescued β2ARKO BMT mice revealed the reciprocal results. Thus, leukocyte infiltration was increased in the border (Figure 8C) and infarct (Supplemental Figure 8) zones of the heart in β2ARKO BMT mice transduced with β2AR versus GFP lentivirus, including monocytes/macrophages, mast cells and neutrophils (Figure 8D), which were restored to WT BMT levels (Supplemental Table 3). Discussion Inflammatory responses are critical for wound-healing following MI1. All three βAR isoforms have been shown to mediate a number of effects in the immune system, including hematopoiesis, lymphocyte homing and cytokine/chemokine production, however little is known about how they regulate immune cell responses following acute cardiac injury10, 14. To investigate the immune cell-specific impact of βARs on cardiac survival and remodeling following MI, we generated chimeric mice lacking β1AR, β2AR or β3AR expression on cells of hematopoietic origin. The most striking outcome was observed with β2ARKO BMT animals, which displayed 100% mortality due to cardiac rupture, in contrast to their WT counterparts that had ~20% death. β2AR chimeric mice had decreased infiltration of leukocyte populations compared to their WT counterparts demonstrating impaired innate immune responses. Recent findings have shown the importance of pro-inflammatory monocytes in initiating early immune cell-dependent reparative responses following MI2. Thus, it is likely that the inability of leukocyte populations to traffic to the heart acutely following MI in β2ARKO chimeric mice impairs early repair processes, contributing to scar instability, cardiac rupture and death. Of great importance, the β2ARKO BMT mice had decreased leukocyte infiltration into the heart following MI with a reciprocal increase in spleen size and leukocyte retention, suggesting an impairment in immune cell egress from the spleen to the heart following acute cardiac injury. As such, splenectomy of the β2ARKO BMT mice restored cardiac leukocyte infiltration responses to those of splenectomized WT BMT mice. Recently, the spleen has been shown to be an important monocyte reservoir, holding active monocytes for release upon inflammatory injury6, 24, and has been demonstrated to be of particular importance following MI and during heart failure where there is increased antigen processing and adaptive immune system activation25. These processes are regulated through a variety of signals6. One molecular mechanism of leukocyte egress from the spleen through macrophage expression of VCAM-1 has recently been identified23. Our results demonstrate an increase in VCAM-1 in the macrophage-containing red pulp region of spleens from β2ARKO BMT animals, resulting in the retention of leukocyte populations in the spleens of these animals. VCAM-1 was also increased with a β2AR antagonist in human macrophages, with a reciprocal decrease in expression following β2AR stimulation. Interestingly, macrophage VCAM-1 expression appears to be regulated within this context in a β2AR/βARR2-dependent manner. A common limitation of studies in mice is that they do not always translate toward human pathophysiology. However, βAR activation has been implicated in reducing spleen size and release of certain immune cell populations in a number of different species including murine and swine models and humans26-30. These changes were independent of alterations in blood flow, although the mechanism was never identified. Furthermore, β-blocker administration was shown to prevent the splenic release of immune populations, similar to our current study using β2ARKO chimeric animals, and this response was amplified when combined with an inflammatory stimulus31. Mechanistically, our study demonstrates increased levels of leukocyte populations in the spleens of β2ARKO BMT mice both before and after MI, effects that are clearly independent of vascular or splenic β2AR expression. Importantly, inhibition of leukocyte egress from the spleen and decreased infiltration of these populations into the heart can be reversed by restoring β2AR expression in the bone marrow prior to transplantation using a lentiviral construct, confirming the specificity of the response and demonstrating the ability to modulate hematopoietic cell receptor expression using gene therapy approaches. In addition, our data in human macrophages are consistent with those in mouse macrophages and we also observed increased VCAM-1 expression in the spleens of human donors that had taken the β-blocker metoprolol. While metoprolol has preference for β1AR, it loses its selectivity at the higher doses often used clinically32 that would also antagonize β2AR. This could account for the retention of immune cell populations observed in other studies and confirmed in our chimeric mouse model, providing further clinical relevance. Interestingly, increases in circulating immune cells with epinephrine or isoproterenol is greatly diminished in splenectomized patients33, 34 and multiple long-term studies examining the effects of splenectomy in humans have demonstrated an increased incidence in MI and HF with worsened prognosis following such events35, 36. While many of the benefits of β-blockers are thought to be mediated through their actions on β1AR in cardiomyocytes37, immune cell-expressed βAR and β-blocker therapy have been suggested to play roles in the regulation of immune responses during HF38-42. Our findings suggest administration of β-blockers with selectivity toward β2AR around the time of MI could diminish leukocyte egress from the spleen and subsequent cardiac immune cell-dependent remodeling. The impact of such a process on overall cardiac remodeling would likely depend on the severity of β2AR inhibition, where a short-term decrease in activity may simply dampen the inflammatory response, but not ultimately prevent it, whereas chronic inhibition of leukocyte-expressed β2AR could negatively impact post-MI repair processes. Interestingly, it has recently been suggested that peri-operative use of β-blockers may actually increase cardiovascular events, including MI43 and, according to the American Heart Association/American College of Cardiology, continues to have an uncertain mortality risk44. A link between β2AR inhibition in leukocytes and these clinical observations has not been demonstrated, but warrants further investigation. Converse to inhibition, short-term β2AR agonist administration during the inflammatory phase following MI in combination with chronic β1AR antagonist administration may provide an improved therapeutic strategy to prevent detrimental remodeling and preserve cardiac function following cardiac injury. Several studies investigating the use of β2AR agonists in the treatment of heart failure have found beneficial effects, which was attributed to the promotion of cardiomyocyte survival, however the long term benefits of βAR blockade in HF has contraindicated the use of β2AR agonists45-50. In many of these studies β2AR agonist administration commenced at later time points, missing the acute inflammatory phase. Regardless, in animal models β2AR agonists have been shown to improve cardiac remodeling following MI or ischemia/reperfusion to a greater extent than that achieved by β1AR antagonists46, 49, 50, while cardiac function and survival were further improved with a combined β1AR blocker/β2AR agonist strategy46-48. Remarkably, a single dose of the β2AR agonist clenbuterol prior to ischemic insult was shown to decrease the resulting cardiac injury45. However, these studies did not assess the contribution of the early immune cell responses to their outcomes. In summary, using a chimeric mouse approach, we identified a critical role for hematopoietic cell-expressed β2AR in the regulation of acute cardiac inflammation and remodeling following MI. β2AR-deficient immune cells displayed impaired recruitment to the injured myocardium following MI, with reciprocal leukocyte retention within the spleen that was maintained following MI. Lentiviral-mediated re-expression of β2AR in β2ARKO BM prior to transplantation restored BM migration, splenic retention levels of leukocyte populations and leukocyte infiltration into the heart following injury. Altogether, our results highlight an immunomodulatory role for β2AR that could be targeted to promote early leukocyte-dependent reparative processes following MI, with negligible or even beneficial effects on cardiomyocytes, while avoiding issues inherent to the promotion of prolonged inflammatory events. Supplementary Material Supplemental Data Sources of Funding This work was supported by NIH grants HL105414 (to D.G.T.), HL091799 and HL085503 (to W.J.K.), HL098481 (to J.W.C.), and an AHA postdoctoral fellowship (to L.A.G.). Figure 1 Effects of hematopoietically expressed βAR subtypes on cardiac survival and function following MI. (A) C57BL/6 mice receiving WT, β1ARKO, β2ARKO or β3ARKO BMT were subjected to sham or MI surgery. Expression of β1AR, β2AR and β3AR was assessed by RT-qPCR on reconstituted WT, β1ARKO, β2ARKO and β3ARKO BM and presented as RQ+RQmax. n=6 for all groups, Exact Wilcoxon rank-sum tests with multiple comparison adjustment (3 comparisons), † p < 0.01 vs WT. (B) Left ventricular fractional shortening (FS) was measured at the short axis from M mode using Visual Sonic Analysis software. Mixed-effects modeling for repeated measures data with multiple comparison adjustments was performed indicating no significant differences compared to WT BMT. (C) WT (n=9 for sham, n=11 for MI), β1ARKO (n=7 for sham, n=11 for MI), β2ARKO (n=10 for sham, n=14 for MI) or β3ARKO (n=7 for sham, n=18 for MI) BMT mice were monitored daily for survival. Log-rank tests with multiple comparison adjustment (3 comparisons), ‡ p < 0.001 vs WT BMT MI. All sham groups had 100% survival following surgery. (D) H&E staining for sham and 4d post-MI hearts from WT and β2ARKO BMT mice. Figure 2 Effect of hematopoietic β2AR expression on immune cell infiltration following MI. A. Representative CD68, tryptase, and MPO staining of the border or infarct zones of hearts following MI surgery in WT BMT or β2ARKO BMT mice. Quantification of CD68 (B, C), tryptase (D, E) and MPO (F, G) staining in the border and infarct zones of WT and β2ARKO BMT mouse hearts. n=4 for WT BMT sham, n=5 for β2ARKO BMT sham, n=3 for WT BMT 6 h, n=3 for β2ARKO BMT 6 h, n=4 for WT BMT 1d, n=6 for β2ARKO BMT 1d, n=5 for WT BMT 4d, n=5 for β2ARKO BMT 4d, n=6 for WT BMT 7d, n=6 for β2ARKO BMT 7d. Exact Wilcoxon rank-sum tests, * p < 0.05, † p < 0.01 vs WT BMT. Figure 3 β2ARKO mice have splenomegaly and retention of leukocyte populations. (A) Representative images of spleens from WT and β2ARKO BMT animals. (B) Gravimetric analysis of spleen weight to body weight (SW/BW) of spleens from WT and β2ARKO BMT sham and MI animals. n=6 for WT BMT sham, n=8 for β2ARKO BMT sham, n=4 for WT BMT 1d, n=4 for β2ARKO BMT 1d, n=10 for WT BMT 4d, n=7 for β2ARKO BMT 4d, n=7 for WT BMT 7d, n=5 for β2ARKO BMT 7d. Exact Wilcoxon rank-sum tests, * p < 0.05, ‡ p < 0.001 vs WT BMT. (C) Representative CD68, tryptase and MPO staining from 4d post-MI spleens of WT or β2ARKO BMT mice. (D) Quantification of CD68, tryptase and MPO staining from WT and β2ARKO BMT spleens 4d following MI surgery. n=10 for WT BMT, n=8 for β2ARKO BMT, Exact Wilcoxon rank-sum tests, * p < 0.05, ‡ p < 0.001 vs WT BMT. Figure 4 VCAM-1 is increased in β2ARKO BMT spleens. (A) Immunohistochemistry for VCAM-1 (white) showing levels and localization of VCAM-1 expression in WT and β2ARKO BMT spleens. (B) Quantification of the intensity of VCAM-1 staining. n=5 for WT BMT, n=5 for β2ARKO BMT, Exact Wilcoxon rank-sum test, * p < 0.05 vs WT BMT. (C) Representative immunoblot showing VCAM-1 expression in WT and β2ARKO BMT spleens. Arrows indicate the three isoforms of VCAM-1. Β-tubulin, β-actin and GAPDH are shown as loading controls. (D) Quantification of VCAM-1 immunoblot expression from. n=12 for WT BMT, n=12 for β2ARKO BMT, Exact Wilcoxon rank-sum test, ‡ p < 0.001. (E) RT-qPCR was used to measure VCAM-1 expression in WT or β2ARKO BMT spleens and presented as RQ+RQmax. n=8 for WT BMT sham, n=6 for WT BMT MI, n=6 for β2ARKO BMT sham, n=8 for β2ARKO BMT MI, Exact Wilcoxon rank-sum tests, † p < 0.01, ‡ p < 0.001 vs WT BMT. (F) RT-qPCR was used to measure VCAM-1 expression in mouse (BMDM) or human (THP-1 derived) macrophages and presented as RQ+RQmax. n=7 for mouse vehicle, n=10 for mouse salbutamol, n=9 for human vehicle, n=10 for human salbutamol, Exact Wilcoxon rank-sum tests, † p < 0.01, ‡ p < 0.001 vs Veh. (G) VCAM-1 expression in human macrophages treated with vehicle or ICI-118,551 was quantified by RT-qPCR and presented as RQ+RQmax, Exact Wilcoxon rank-sum test, † p < 0.01 vs Veh. (H) RT-qPCR was used to measure VCAM-1 expression in human spleens from control or metoprolol-treated patients and presented as RQ+RQmax. n=5 for control, n=6 for metoprolol, Exact Wilcoxon rank-sum test, * p < 0.05 vs control. Figure 5 β2AR regulates VCAM-1 through β-arrestin dependent mechanisms. (A) RT-qPCR was used to measure VCAM-1 expression in BMDM from WT or β2ARKO mice and β2ARKO BMDM transduced with GFP, β2AR, β2ARTYY or β2ARGRK- lentivirus and presented as RQ+RQmax. n=9 for WT, n=6 for β2ARKO, n=6 for β2ARKO+β2AR, n=6 for β2ARKO+GFP, n=6 for β2ARKO+β2ARTYY, n=6 for β2ARKO+β2ARGRK-, Exact Wilcoxon rank-sum tests with multiple comparison adjustment (5 comparisons), * p < 0.05, † p < 0.01 vs WT. (B) Gravimetric analysis of spleen weight to body weight (SW/BW) of spleens from WT, β2ARKO, βARR1KO and βARR2KO animals. n=7 for WT, n=6 for β2ARKO, n=6 for βARR1KO, n=6 for βARR2KO, Exact Wilcoxon rank-sum tests with multiple comparison adjustment (3 comparisons), † p < 0.01 vs WT. (C) Representative CD68, tryptase, and MPO staining of spleens from βARR1KO and βARR2KO mice. (D) Quantification of CD68, tryptase and MPO staining from βARR1KO and βARR2KO spleens. n=6 for βARR1KO, n=4 for βARR2KO, Exact Wilcoxon rank-sum tests, † p < 0.01 vs βARR1KO. Figure 6 Splenectomy restores β2ARKO leukocyte infiltration into the heart following MI. (A) Representative CD68, tryptase, and MPO staining of the border or infarct zones of hearts 4d following MI surgery in WT or β2ARKO BMT that received sham and splenectomy surgery. Quantification of CD68 (B), tryptase (C) and MPO (D) staining in the border and infarct zones of 4d post-MI hearts from sham and splenectomy WT and β2ARKO BMT mice. n=6 for WT BMT Sham/MI, n=5 for WT BMT Splen/MI, n=6 for β2ARKO BMT Sham/MI, n=7 for β2ARKO BMT Splen/MI, Exact Wilcoxon rank-sum tests with multiple comparison adjustment (6 comparisons), * p < 0.05, † p < 0.01, ns = not significant. Figure 7 Restoration of β2AR expression in β2ARKO BM restores survival following MI. (A) Representative immunoblot showing protein expression of GFP and Flag in reconstituted BM from β2ARKO, β2ARKO+GFP and β2ARKO+β2AR BMT mice. β-tubulin, β-actin and GAPDH are shown as loading controls. (B) β2AR expression was measured by RT-qPCR in reconstituted BM from WT and β2ARKO mice and reconstituted BM from mice that had GFP or β2AR transduced into β2ARKO BM by lentivirus prior to transplantation. Values are presented as RQ+RQmax expressed relative to WT BMT. n=10 for WT, n=10 for β2ARKO BMT, n=9 for β2ARKO+GFP BMT, n=11 for β2ARKO+β2AR BMT. Exact Wilcoxon rank-sum tests with multiple comparison adjustment (3 comparisons), ‡ p < 0.001. (C) β2ARKO+GFP and β2ARKO+β2AR BMT were subjected to sham or MI surgery and monitored daily for survival. All sham groups had 100% survival following surgery. n=6 for β2ARKO+GFP and n=7 β2ARKO+β2AR BMT sham, n=27 for β2ARKO+GFP MI, n=26 for β2ARKO+β2AR BMT MI. Log-Rank test, ‡ p < 0.001 vs β2ARKO+β2AR BMT. (D) % survival of β2ARKO+GFP and β2ARKO+β2AR BMT mice 1 week post-MI. Log-Rank tests with multiple comparison adjustment (3 comparisons), * p < 0.05 vs WT BMT MI. (E) Gravimetric analysis of spleen weight to body weight (SW/BW) of spleens from β2ARKO+GFP and β2ARKO+ β2AR BMT mice. n=7 for β2ARKO+GFP sham, n=6 for β2ARKO+ β2AR sham, 4d post n=8 for β2ARKO+GFP MI and n=10 for β2ARKO+ β2AR MI. Exact Wilcoxon rank-sum tests, † p < 0.01, ‡ p < 0.001 vs β2ARKO+GFP BMT. (F) Representative VCAM-1 staining for β2ARKO+GFP and β2ARKO+β2AR BMT spleens 4d post-MI. (G) Quantification of VCAM-1 intensity from immunohistochemistry of β2ARKO+GFP (n=6) and β2ARKO+β2AR BMT (n=7) spleens. Exact Wilcoxon rank-sum test, † p < 0.01vs β2ARKO+GFP BMT. Figure 8 β2AR re-expression on reconstituted β2ARKO BM reverses splenic retention of leukocytes. (A) Representative CD68, tryptase and MPO staining of spleens from β2ARKO+GFP and β2ARKO+β2AR BMT mice 4d post-MI. (B) Quantification of CD68, tryptase and MPO staining from the spleens from (A). n=8 β2ARKO+GFP BMT and n=8 β2ARKO+β2AR BMT, Exact Wilcoxon rank-sum tests, † p < 0.01, ‡ p < 0.001 vs β2ARKO+GFP BMT. (C) Representative CD68, tryptase and MPO staining of the border zone of hearts from β2ARKO+GFP and β2ARKO+β2AR BMT animals 4d following MI surgery. (D) Quantification of CD68, tryptase and MPO staining from the border zone of 4d post-MI hearts from β2ARKO+GFP (n=8) and β2ARKO+β2AR BMT (n=6) mice. Exact Wilcoxon rank-sum tests, ‡ p < 0.001 vs β2ARKO+GFP BMT. Clinical Perspective What is new? Using chimeric mice, we demonstrate that immune cell-specific β2-adrenergic receptor (β2AR) expression is essential to the repair process following myocardial infarction. In the absence of β2AR, vascular cell adhesion molecule 1 (VCAM-1) expression is increased in leukocytes, inducing their splenic retention following injury and leading to impaired scar formation followed by rupture and death. VCAM-1 expression is regulated dynamically by βAR ligands, including β-blockers, in both mouse and human tissues. Splenectomy partially restores β2AR-deficient leukocyte infiltration into the heart following injury, and gene therapy to rescue leukocyte β2AR expression completely restored all injury responses to that observed in normal mice. What are the clinical implications? βARs regulate cardiac function and remodeling following injury, classically through their effects in cardiomyocytes, and are targeted by β-blockers to help prevent detrimental myocardial remodeling. However, our findings indicate that inhibition/deletion of immune cell-expressed β2AR causes leukocyte dysfunction and altered immunomodulatory responses to acute injury. These results have important clinical implications since β-blockers are used frequently in patients around the time of myocardial infarction, as well as peri-operatively for non-cardiac surgeries with uncertain mortality risk. 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PMC005xxxxxx/PMC5120619.txt
LICENSE: This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. 7600111 5310 J Neurosci Res J. Neurosci. Res. Journal of neuroscience research 0360-4012 1097-4547 27870439 5120619 10.1002/jnr.23826 NIHMS797243 Article Estradiol shifts interactions between the infralimbic cortex and central amygdala to enhance fear extinction memory in female rats Maeng Lisa Y. 12 Cover Kara K. 1 Taha Mohamad B. 12 Landau Aaron J. 1 Milad Mohammed R. 12 Lebrón-Milad Kelimer 12 1 Department of Psychiatry, Massachusetts General Hospital, Charlestown, MA, 02129, USA 2 Department of Psychiatry, Harvard Medical School, Boston, MA, 02115, USA Corresponding author: Lisa Y. Maeng, 149 13th Street, Room 2510, Charlestown, MA 02129, Phone: 617-643-1156, Fax: 617-726-5760, lmaeng@mgh.harvard.edu 25 6 2016 2 1 2017 02 7 2017 95 1-2 163175 This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. There is growing evidence that estradiol enhances fear extinction memory consolidation. However, it is unclear how estradiol influences the nodes of the fear extinction network to enhance extinction memory. This study begins to delineate the neural circuits underlying the influence of estradiol on fear extinction acquisition and consolidation in female rats. After fear conditioning (day 1), naturally cycling female rats underwent extinction learning (day 2) in a low estradiol state, receiving a systemic administration of either estradiol (E2) or vehicle prior to extinction training. Extinction memory recall was then tested 24h later (day 3). We measured immediate early gene c-fos expression within the extinction network during fear extinction learning and extinction recall. During extinction learning, E2 treatment increased centrolateral amygdala (CeL) c-fos activity and reduced lateral amygdala (LA) activity relative to vehicle. During extinction recall, E2-treated rats exhibited reduced c-fos expression in the centromedial amygdala (CeM). There were no group differences in c-fos expression within the medial prefrontal cortex and dorsal hippocampus. Examining c-fos ratios with the infralimbic cortex (IL) revealed that despite the lack of group differences within the IL, E2 treatment induced greater IL activity relative to both the prelimbic cortex (PL) and central amygdala (CeA) activity during extinction memory recall. Only the relationship between IL and CeA activity positively correlated with extinction retention. In conclusion, estradiol appears to modify interactions between the IL and CeA in females, shifting from stronger amygdalar modulation of fear during extinction learning to stronger IL control during extinction recall. Graphical abstract Estradiol’s modulatory effects on fear extinction memory consolidation may be driven by the IL-amygdala circuit of the fear network. With increasing estradiol levels, neuronal activation shifts during extinction from stronger CeA to IL activity to stronger IL to CeA activity, correlating with more and less fear during extinction recall, respectively. sex differences estradiol infralimbic cortex central amygdala c-fos fear extinction estrous cycle centromedial amygdala female PTSD anxiety fear ventromedial prefrontal cortex Introduction Estradiol influences many types of learning and memory processes (Luine et al., 1998; Goodman et al., 2004; Leuner et al., 2004; Inagaki et al., 2010; Cover et al., 2014), and studies examining estradiol’s effects on neurogenesis, dendritic branching, and long-term potentiation have demonstrated that it can alter brain structure and function as well (Galvin and Ninan, 2014; Mahmoud et al., 2016; Srivastava et al., 2013). Given the higher prevalence of fear and anxiety disorders in women compared to men, a better understanding of how estradiol can affect the neural substrates and mechanisms that control fear responses is necessary. Fear extinction protocols provide a means to investigate the brain networks involved in the regulation of fear. The basic neural mechanisms of fear extinction have been studied extensively in males. The fear extinction network includes the infralimbic (IL) and prelimbic (PL) subregions of the ventromedial prefrontal cortex (vmPFC), amygdala, and hippocampus. Electrophysiology experiments have demonstrated that microstimulation of the IL reduces conditioned freezing in rats (Milad and Quirk, 2002), while inactivation of the IL increases fear expression during extinction learning, indicating impaired extinction (Sierra-Mercado et al., 2011). The basolateral amygdala (BLA) is noted as a site involved in fear expression and consolidation through its connections with the PL, and its connections with the IL make it a critical region for fear extinction as well (Likhtik and Paz, 2015). The central amygdala (CeA) is composed of lateral (CeL) and medial (CeM) subregions, which mediate fear through different functions and connections with other nodes of the fear extinction network (Ciocchi et al., 2010; Duvarci and Pare, 2014; Haubensak et al., 2010). The CeM serves as the fear output region and can be modulated by parallel circuits that drive fear expression and inhibit conditioned fear responses. The hippocampus is important for the contextual gating of fear learning and extinction (Moustafa et al., 2013). Although the fear extinction circuits are well known in males, it is unclear whether these systems behave similarly in females or how they change across the estrous cycle as gonadal hormone levels naturally fluctuate. Our laboratory has demonstrated that female rats extinguished during the high-estradiol proestrus phase exhibited significantly better extinction memory recall compared to those that underwent extinction during the low-estradiol metestrus phase (Milad et al., 2009). Zeidan et al. (2011) showed that extinction recall was improved in metestrus females administered exogenous estradiol, while also reporting elevated levels of c-fos mRNA expression within the IL and reduced levels in the amygdala. However, other brain areas were not analyzed; thus, the neural substrates and mechanisms through which estradiol exerts its influence are still unclear. In this study, we investigated this by examining c-fos expression in the key nodes of the fear extinction network: PL, IL, amygdalar subnuclei, and hippocampus. Moreover, there is evidence in the human literature demonstrating that ratios of metabolic activity within various regions of the network appear to be more predictive of behavioral outcomes during fear conditioning and extinction (Linnman et al., 2012). Based on these data, we also assessed c-fos activity ratios across the nodes noted above. Given that the IL is associated with fear inhibition, and the PL and amygdala are associated with fear expression (Laurent and Westbrook, 2008, 2009; Burgos-Robles et al., 2009; Sotres-Bayon and Quirk, 2010), we expected that differences in the distribution of neuronal activation among these structures would be relevant for extinction retention. We hypothesized that estradiol administration in metestrus females prior to extinction training would: 1) enhance fear extinction memory recall, 2) alter neuronal function of the IL within the fear extinction network, and 3) enhance the IL/PL as well as IL/amygdala c-fos activity ratios, which would be associated with reduced fear during extinction recall. Materials and methods Subjects 64 adult female Sprague Dawley rats (8 weeks old and 250g; Harlan Laboratories, Inc., Indianapolis, IN) were housed in pairs at Massachusetts General Hospital Center for Comparative Medicine in Charlestown, MA. They were maintained on a 12h light/dark cycle and a diet of ad libitum rat chow and water. After an acclimation period of 5-7 days in the animal colony room, the animals were handled daily for at least a week. All procedures conducted in this study were approved by the Subcommittee on Research Animal Care at Massachusetts General Hospital and abide by the guidelines set forth by the Institutional Animal Care and Use Committee. Vaginal swabbing and cytology All female rats were monitored daily for their estrous cycles for at least 10 consecutive days prior to the experiments and also during the days of the experiment as previously described (Maeng et al., 2015). Samples of loose vaginal epithelial cells were collected using cotton-tipped applicators moistened with 0.9% saline. The samples were stained with Dipquick Quick Stain (Jorgensen Laboratories, Inc., Loveland, CO). Phases were identified by the cell types characteristic of each estrous phase (Westwood, 2008). Proestrus is characterized by clusters of purple-stained nucleated cells. Estrus is identified by aggregated blue cornified cells, metestrus by a combination of nucleated cells, cornified cells, and leukocytes, and diestrus as similar to metestrus but with sparse representation of the different cell types. The level of circulating gonadal hormones varies across phases of the estrous cycle. Higher levels of estradiol occur during proestrus and the first half of estrus, while lower levels occur during metestrus and the first half of diestrus. All rats underwent extinction training during the metestrus phase of the estrous cycle. Any animals that were not in metestrus on the day of extinction training were not included in the study. Behavior Prior to experimentation, all animals were pre-exposed to their assigned 25 × 29 × 29 cm Plexiglas behavioral chambers (Coulbourn Instruments, Whitehall, PA) with the house lights on for one 30-minute session per day for 3 days as described previously (Maeng et al., 2015). The Plexiglas chamber contained a single overhead house light, a speaker for conditioned stimulus (CS) presentations, and a video camera to monitor behavior. The experiment was run across 3 days. All the phases of the experiment were conducted in the same context. On day 1, all female rats underwent 5 trials of the conditioned stimulus (CS; tone) alone habituation trials and were then fear conditioned with 7 trials of CS paired with the unconditioned stimulus (US; footshock) during the estrus phase. On day 2, after vaginal swabbing for confirmation of the metestrus phase, the animals were injected subcutaneously with either sesame oil (vehicle; Sigma-Aldrich, St. Louis, MO) or estradiol (15ug/kg; Sigma-Aldrich, St. Louis, MO). Thirty minutes following the injection, all animals underwent extinction training, which consisted of 20 trials of CS alone presentations. On day 3, some of the animals were returned to the chamber and presented with 3 CS-alone trials for the extinction recall test. For all phases, the CS was a 30-s, 4-kHz, 80-dB tone. For the paired trials during fear conditioning, the CS coterminated with the 0.5-s, 0.5-mA US, using GraphicState 3.03 (Coulbourn Instruments, Whitehall, PA). Every phase was run with trials that had a variable intertrial interval averaging 3 minutes. c-fos immunohistochemistry In order to evaluate changes in neuronal activity separately during extinction training and recall, two groups of animals were sacrificed at different time points. One group was sacrificed 1h after the extinction session and did not undergo the extinction recall test (POST-EXT), and the other was sacrificed 1h after recall and completed all phases (POST-REC). Another separate group of female rats underwent the same behavioral protocol as the POST-REC group with the exception of extinction training on day 2 to serve as the no extinction control group (NO-EXT). One hour after the end of the extinction (POST-EXT) or recall (POST-REC and NO-EXT) session, all animals were given a lethal dose of Fatal-Plus® solution (Vortech Pharmaceutical Ltd., Dearborn, MI). Once deeply anesthetized, the animals were transcardially perfused with 0.9% saline for 15 minutes, followed by 4% paraformaldehyde for 20 minutes at a speed of 20ml/min. Their brains were extracted and placed in 4% paraformaldehyde overnight at 4° C. The brains were then cryoprotected in 20% sucrose potassium phosphate buffered saline (KPBS) solution for 24h and then stored in 30% sucrose KPBS solution at 4°C until processing. For cryostat sectioning, the brains were rapidly frozen in Tissue Freezing Medium (Triangle Biomedical Sciences, Durham, NC) and sectioned at −21°C in 40-μm thick coronal slices. Tissue containing the mPFC, amygdala, and hippocampus were collected and processed for c-fos immunohistochemistry using a modified version of the protocol described in Do-Monte et al. (2015). All antibodies used are listed in Table 1. The tissue sections were washed in KPBS (7min × 5) and then incubated in 2% normal goat serum (NGS), 3% Triton-X, KPBS solution with 1:20,000 polyclonal rabbit anti-c-fos antibody (Calbiochem, Billerica, MA) for 18h at room temperature (RT). This was followed by incubation in biotinylated goat anti-rabbit IgG secondary antibody (1:200; Vector Laboratories, Burlingame, CA, USA), for 2h at RT. The tissue was then incubated in avidin-biotin horseradish peroxidase complex solution (1:200; Vectastain Elite ABC kit, Vector Laboratories) for 90min at RT. The tissue underwent staining in 0.02% 3,3'-diaminobenzidine (DAB), 0.3% nickel-ammonium sulfate, 1.2% glucose oxidase sodium PBS solution reacted with D-glucose (10%) for 15-20min until darkly stained c-fos immunopositive nuclei were observed and the reaction stopped with KPBS. The sections were mounted onto gelatin-subbed slides, dehydrated, cleared with Citrosolv (Fisher Scientific, Pittsburgh, PA), and cover slipped with DPX medium (Electro Microscopy Sciences, Hatfield, PA). c-fos immunoreactivity analysis The PL, IL, CeL, CeM, BLA, LA, dorsal dentate gyrus (DG), dorsal CA1, and dorsal CA3 were imaged with a CCD color camera (Moticam Pro 252A, British Columbia, Canada) mounted on a compound microscope (Motic BA410, British Columbia, Canada) at 20X magnification. Photomicrographs were captured for sections of the PL and IL (+3.72mm to +3.00mm from Bregma), amygdala (−2.04mm to −3.24mm from Bregma), and dorsal hippocampus (−2.92mm to −3.60mm from Bregma). For each of these regions, cells from 2-3 sections were bilaterally counted and averaged over sections and hemispheres per animal. These average values were then placed into their respective drug groups and averaged to obtain average c-fos positive cell counts for the vehicle vs. estradiol-treated animals. The images were captured as a rectangular region of interest (ROI) box (dimensions: 268 × 329μm) anatomically defined by Paxinos and Watson (2007) for each target brain structure. The ROI box dimensions were determined by our laboratory to create a consistent area that encompassed across brain regions as in Matsuo et al. (2009). The c-fos-positive cells within this box were counted using ImageJ software (NIH, Bethesda, MD; RRID: SCR_003070) by a rater blind to the experimental condition. Data analysis Percent freezing was calculated over the duration of the trial as the index of fear: [(time spent freezing during trial)/30 seconds]*100. Freezing was recorded and analyzed using motion-sensing computer software FreezeScan (Clever Systems, Reston, VA). The extinction retention index (ERI) was calculated by subtracting the average of the percent freezing of the first two trials of extinction recall from the average of percent freezing of the last five trials of extinction training the day before. To assess behavior across the experimental phases, percent freezing was analyzed as blocks of 2 trials averaged. A mixed-design Analysis of Variance (ANOVA), with the 2-trial blocks as the within-subjects variable and drug as the between-subjects variable, was conducted on freezing behavior for each of the habituation, fear conditioning, and fear extinction phases, using SPSS 23.0 (IBM Corp., Armonk, NY). An independent samples t-test was performed to assess group differences in extinction recall (day 3). When the assumption of equal variances did not hold, the corrected values were reported. For c-fos analysis as described above, the number of c-fos immunopositive cells were counted and averaged for all sections within a range determined by Paxinos and Watson (2007) for each region per animal. These section averages were then averaged for each drug group (vehicle and estradiol). C-fos ratios were calculated by dividing the average number of IL c-fos positive cells by the average number of c-fos positive cells of the other regions (PL, CeM, CeL, BLA, LA). Independent samples t-tests were performed on these averaged c-fos positive counts and ratios to assess drug effects. The IL c-fos activity ratios were correlated with ERI for the POST-REC group to assess how these relationships were associated with freezing behavior during extinction recall. Results Behavior All rats underwent fear conditioning on day 1 during the estrus phase and extinction training on day 2 during metestrus phase. The POST-REC group underwent recall on day 3. A mixed-design ANOVA revealed that there were no differences between the POST-EXT and POST-REC groups in the vehicle-treated animals during habituation [F(1,26)=1.634, p=0.21], fear conditioning [F(1,26)=0.045, p=0.83], and fear extinction [F(1,26)=0.483, p=0.49]. This was also found to be true in the estradiol-treated groups for habituation [F(1,22)=0.066, p=0.80], fear conditioning [F(1,22)=0.119, p=0.73], and fear extinction [F(1,22)=0.232, p=0.64]. Because the POST-EXT and POST-REC groups both underwent the same protocols for habituation, fear conditioning, and fear extinction and were not different across all phases, these groups were combined for analysis purposes (Fig. 1; Vehicle, n=28; E2, n=24). Fear recall is represented only by the POST-REC group (Fig. 1; Vehicle, n=14; E2, n=14). The behavioral data are represented as blocks of 2 trials averaged. A mixed-design ANOVA revealed that there was an effect of block [F(1,50)=13.17, p=0.001], no drug × block interaction [F(1,50)=0.34, p=0.56], and no effect of drug during habituation [F(1,50)=0.30, p=0.59]. For the fear conditioning phase, there was an effect of block [F(2,100)=4.51, p=0.01], but no significant drug × block interaction [F(2,100)=1.68, p=0.19] or main effect of drug [F(1,50)=0.006, p=0.94]. A main effect of extinction block [F(9,450)=3.10, p=0.001] was observed, but no drug × block interaction [F(9,450)=1.30, p=0.23] or effect of drug during fear extinction training [F(1,50)=0.26, p=0.62]. To summarize, the results of the statistical analyses showed that: 1) there were differences across habituation and conditioning blocks and that extinction occurred, and 2) there were no significant group differences between the vehicle- and estrogen-treated animals during the habituation, conditioning, and extinction phases. In contrast, the POST-REC animals that received estradiol on day 2 exhibited a significant reduction in freezing during recall on day 3 compared to the animals that received vehicle [t(26)= 2.535, p=0.02], as revealed by an independent samples t-test. The amount of retention of extinction learning from day 2 observed during extinction recall (as indicated by ERI) was also significantly greater in estradiol-treated females compared to vehicle [t(24)=−2.652, p=0.01]. This result replicates our previous findings (Zeidan et al., 2011). c-fos Animals that were sacrificed 1h after extinction training (POST-EXT) exhibited no significant differences between drug groups in PL [t(9.259)=1.916, p=0.09] and IL [t(14)=1.459, p=0.17] c-fos expression as shown by an independent samples t-test (Vehicle, n=8; Estradiol, n=8; Fig. 2A). This was also observed in the PL [t(15)=0.012, p=0.99] and IL [t(15)=−0.390, p=0.70] of animals that were sacrificed 1h after recall (POST-REC; Vehicle, n=8; Estradiol, n=9). However, quantification of c-fos positive cells revealed that there were differences within the amygdala (Fig. 2B). In the POST-EXT group, estradiol administration significantly increased c-fos expression in the CeL [t(7.650)= −2.295, p=0.05] (Fig. 3), but significantly decreased c-fos immunoreactivity in the LA [t(14)= 3.325, p=0.01]. Estradiol did not affect c-fos expression in the BLA [t(8.639)= −2.106, p=0.07] and CeM [t(14)=−1.023, p=0.32] compared to vehicle during extinction (Vehicle, n=8; Estradiol, n=8). In the POST-REC group, estradiol treatment reduced c-fos expression only within the CeM relative to vehicle [t(9.707)= 2.494, p=0.03] and had no effect on c-fos immunoreactivity in the LA [t(15)= 2.059, p=0.06], CeL [t(15)= 1.173, p=0.259] or BLA [t(15)= 0.000, p=1.00] (Vehicle, n=8; Estradiol, n=9). We did not find differences in c-fos expression in any of the subregions of the hippocampus during extinction or extinction recall (p>0.05; Vehicle, n=5-8; Estradiol, n=7-9; Fig. 2C). c-fos ratios Based on findings in human literature (Linnman et al., 2012), we examined the effects of estradiol on the relationship of c-fos expression between the IL and other ROIs, represented by their ratios (IL c-fos positive cell count divided by c-fos positive cell count for a different region: PL, CeM, CeL, BLA, or LA; Figs. 4 and 5). For the POST-EXT group, an independent samples t-test showed that there was no significant difference as a function of drug treatment in the IL/PL c-fos ratio [t(14)=−0.147, p=0.89; Fig. 4]. In the POST-REC group, however, the IL/PL c-fos ratio was significantly higher in the estradiol-treated group [t(8.383)=−2.405, p=0.04]. There were no group differences in the IL/CeM c-fos ratio in the POST-EXT group [(t(7.197)=1.641, p=0.14], whereas estradiol increased this ratio in the POST-REC group [t(11)=−2.473, p=0.03; Fig. 5A]. IL/CeL c-fos immunoreactivity ratio was significantly lower in the estradiol-treated animals in the POST-EXT group [t(7.820)=3.173, p=0.01; Fig. 5B]. In contrast, the IL/CeL c-fos ratio was significantly higher with estradiol treatment in the POST-REC group [t(5.674)=−2.756, p=0.04]. There were no group differences in IL/BLA and IL/LA c-fos ratios in either the POST-EXT [t(14)=0.092, p=0.93] and POST-REC [t(10)=0.060, p=0.95] groups (Fig. 5C and 5D). c-fos ratio and ERI correlations The following results are reported for only the POST-REC group. The IL/PL c-fos ratio was not significantly correlated with the ERI (r=−0.048, p=0.86). IL/CeM c-fos ratio, on the other hand, was positively correlated with ERI (r=0.605, p=0.03). The IL/CeL c-fos ratio was also positively correlated with ERI (r=0.719, p=0.006). However, this result may have been driven by a single animal that had a very high ERI and IL/CeL ratio, as the effect was lost when the animal was omitted (Fig. 5B; correlation graph). This animal was not eliminated because it did not meet any criteria for exclusion. Therefore, it is important to note that the correlation between ERI and the IL/CeM c-fos ratio may be the more critical relationship than that with the IL/CeL c-fos ratio. Furthermore, neither IL/BLA (r=−0.039, p=0.90) nor IL/LA (r=0.156, p=0.69) correlated with ERI. Therefore, the effects of estradiol only emerge in the relationships between IL and CeA neuronal activity, and these relationships, primarily IL/CeM, are associated with extinction retention during recall. No extinction control group In order to evaluate whether the influence of estradiol on extinction recall was an effect of estradiol alone, a group of female rats (n=12) were tested in metestrus, just as described for the POST-REC group, excluding extinction training on day 2 (Fig. 6). Half of the rats received vehicle injections, and the other half received estradiol injections. A mixed-design ANOVA performed for each experimental phase revealed that there were no group differences during habituation [F(1,10)=0.020, p=0.89], fear conditioning [F(1,10)=0.021, p=0.89], or extinction recall [t(10)=−1.028, p=0.33] (Fig. 6A). Moreover, estradiol did not alter c-fos expression in any of the target brain structures or the c-fos ratios with the IL (p>0.05), which was in contrast to what was found for the POST-REC group (Fig. 6B and 6C). These results confirmed that estradiol’s effect in enhancing fear extinction memory was not due to estradiol’s effects alone. Discussion We used immediate early gene c-fos immunohistochemistry in the present study to investigate the effects of estradiol in the female brain, and in particular, in modulating mPFC-amygdala interactions during fear extinction. We found a significant increase in c-fos expression within the CeL in estradiol-treated rats, and the opposite effect in the LA during extinction. Estradiol significantly reduced CeM c-fos expression during recall. Contrary to what we had expected, estradiol did not alter neuronal activation in the PL or IL during recall. However, we observed effects of estradiol on c-fos ratios representing neuronal activity relationships within the IL and PL, as well as the relationships between the IL and specific amygdalar subnuclei. Interestingly, only the IL/CeA ratios positively predicted extinction retention during recall. Moreover, estradiol administered in the absence of extinction training had no effect on freezing behavior on day 3 or c-fos expression. These results indicate that: 1) estradiol impacts the fear extinction circuitry on a network level rather than on individual regions, 2) estradiol induces a shift in neuronal activation from greater CeA activity relative to IL during extinction learning to the reverse to enhance extinction memory consolidation and reduce fear during extinction recall, and 3) estradiol’s effects on extinction recall are synergistic with extinction training and have no effect on freezing during extinction recall when administered alone. Estradiol influences in amygdalar subnuclei Estradiol reduced neuronal activation within the LA, which receives and processes converging sensory information about the CS and US, suggesting a potential weakening of the CS-US association during extinction learning. In this circuitry, the BLA receives the integrated CS-US information from the LA before transmitting it to the CeM from which fear expression is controlled (Ehrlich et al., 2009; Lee et al., 2013; Tovote et al., 2015). Therefore, estradiol may be reducing LA input to the BLA, which reduces input to the CeM, and in turn, decreases the fear response. Recent findings have described distinct populations of neurons within the BLA that have opposing functions in modulating CeM output: fear neurons that promote the expression of fear and extinction neurons that inhibit fear (Duvarci and Pare, 2014). We did not find estradiol-induced differences in c-fos expression in the BLA, but this may be due to the presence of both types of neurons, which could not be distinguished from each other with the methods used here. Of the amygdala subregions, the data suggest that the CeA may be the most critical site in estradiol’s effects on fear extinction. We found that during extinction learning, estradiol increased CeL neuronal activation. Within the CeA microcircuit, it has been reported that the CeL exerts an inhibitory influence over the CeM via specific populations of neurons within the CeL (CeLon and CeLoff cells). CeLon cells inhibit the CeLoff neurons, causing the disinhibition of the CeM to enhance conditioned fear expression (Ciocchi et al., 2010; Haubensak et al., 2010). It is possible that estradiol strengthens this control of the CeL over the CeM (perhaps specifically enhancing CeL off neuronal activation) to reduce fear expression. Animals treated with estradiol before extinction exhibited significantly reduced CeM neuronal activation during recall, with no effects in the other regions of the amygdala. This result corroborates the aforementioned idea that estradiol may be dampening the amygdalar nuclei that are involved in driving fear expression (LA), while enhancing those that are inhibiting fear expression (CeL) during extinction training. It is interesting to note that these changes in the brain occurred during extinction training but did not manifest behaviorally (Fig. 1) until the following day, when estradiol-induced alterations in only the CeM correlated with reduced fear during recall. Other studies have described effects of estradiol within the CeA that are consistent with our findings. For example, Jasnow et al. (2006) demonstrated that estradiol enhanced fear conditioning in female mice was CeA-dependent via a corticotropin-releasing hormone (CRH)-mediated mechanism. Together, these data suggest that estradiol may modulate neuroplasticity within these amygdalar circuits during the extinction memory consolidation period, strengthening the circuit that exclusively dampens CeM activity, and thus fear expression, during recall. Estradiol-mediated shifts in prefrontal-amygdalar interactions Estradiol did not significantly impact neuronal activity within the PL or IL alone, despite the literature highlighting their critical roles in fear expression and extinction. However, examining c-fos activity ratios revealed relationships between the IL and other nodes of the fear extinction network that not only differed across the two time points, but also correlated with extinction retention. The parallel, and essentially competing, prefrontal-amygdalar circuits that drive and inhibit the expression of conditioned fear have been studied extensively (Quirk et al., 2003; Likhtik et al., 2005; for review, see Tovote et al., 2015). The greater IL/PL c-fos ratio indicates an estradiol-induced switch from the fear expression to fear inhibition circuits that appear to be dictated by these subregions. Estradiol appears to enhance consolidation of the extinction memory by shifting the balance of neuronal activation towards the IL relative to the fear-driving regions such as the PL and CeA. However, the IL/PL ratio did not predict ERI, whereas IL/CeA ratios did; this suggests that inter-region, and not intra-region, relationships are critical in predicting extinction retention (Fig. 4 and 5). Therefore, estradiol may be strengthening the circuit in which the IL projects to either the BLA or the intercalated cells (ITC) of the amygdala to inhibit the CeM (Lee et al., 2013; Fig. 7), although we did not find differences in the BLA. The influence of estradiol on the ITCs warrants future investigation, as they are the intermediary structures en route from the IL to the CeM. Given that extinction recall is impaired in individuals with PTSD and anxiety, these findings support the literature that describes a frontolimbic circuit imbalance (heightened amygdala activation and reduced vmPFC activation) in these psychopathologies (Kim et al., 2011; Hayes et al., 2012; Tromp et al., 2012). This effect is opposite that of estradiol on this circuit and is one potential mechanism through which estradiol may restore balance and improve extinction recall. Sex differences in the corticolimbic circuit Sex differences are increasingly reported in fear extinction and may be relevant to the heightened vulnerability of women to anxiety and stress-related psychopathologies (Breslau et al., 1997; Shvil et al., 2014; Maeng and Milad, 2015). Our current findings suggest that differences in the neural correlates of fear in female rats are in part mediated by estradiol, and these differences across estradiol states may underlie sex differences in engaged fear extinction circuitry. In fact, sex differences in the role of the mPFC in fear extinction have been reported previously (Baran et al., 2010; Fenton et al., 2014). Moreover, a recent study in humans reported sex differences and estradiol effects in resting state functional connectivity of the laterobasal and centromedial amygdala with higher connectivity with the vmPFC in men and women with higher levels of estradiol (Engman et al., 2016). Given that these regions are homologous with the rodent BLA, CeM and IL, this is consistent with our findings, which suggests that estradiol induces changes in prefrontal connectivity with the amygdala that yield sex differences by modifying IL-amygdala interactions and their contributions to fear extinction behavior. Clinical translation The present study is the first to examine the network-level effects of estradiol on fear extinction from extinction learning to extinction recall; as such, it provides critical insight into the brain networks underlying anxiety and fear-based disorders in women. Our data support the growing literature indicating that given the relationship between naturally fluctuating endogenous estradiol and fear extinction memory, the success of psychiatric treatment (efficacy, duration, efficiency) may depend on gonadal hormone status (Wegerer et al., 2014; Glover et al., 2015; Pineles et al., 2016). Based on these data, estradiol may strengthen the consolidation of extinction memory via modulation of the amygdalar nuclei by the IL. This has powerful implications for improved treatment targets and enhanced efficacy of treatments dependent on fear extinction processes, such as exposure therapy. Future directions Evidence suggesting that estradiol can strengthen extinction memory consolidation is important for improving therapeutic outcomes for individuals suffering from PTSD and other fear and anxiety-related disorders. However, the long-term maintenance of these effects on extinction memory has yet to be determined, and their durability is an important consideration for the potential augmentation of therapy with estradiol. We have identified brain regions and nuclei that are modified by estradiol and associated with its effects on behavior at critical time points (during extinction learning and during extinction recall); however, it is unclear which point of the extinction session is represented by the c-fos expression reported in this study as early and late extinction may induce differential effects. There is also still a need to investigate estradiol’s effects on fear extinction circuitry during memory consolidation to bridge the gap of neuronal change and plasticity that may occur between day 2 and day 3. To further explore this issue, examining the molecular signaling mechanisms of estradiol action would be advantageous. Estrogen can enhance learning and memory through activation of both non-genomic and classical transcriptional mechanisms. The classical mechanism of estrogen relies on a slower-acting, genomic process initiated by ER binding at nuclear receptors. On the other hand, the more rapid mechanism relies on activation of cell membrane receptors, involving intracellular signaling pathways. Both of these pathways appear to converge at the level of transcription and protein synthesis with evidence to suggest that this can occur through activation of the PI3K/Akt and/or MAPK/ERK signaling cascades (Pedram et al., 2002; for review, please see Cover et al., 2014). Given the rapid, yet long-lasting, effects of estradiol on fear extinction, both of these mechanisms may be activated within the CeA to elicit the neuronal and behavioral effects we report in this study. The current findings indicate that estradiol shifts the balance in neuronal activity between the IL and amygdala more towards the IL for increased inhibitory control over fear output from the CeM. Observing this relationship underscores the importance of investigating neural interactions within a network versus solely considering the contributions of individual brain regions. Moreover, the influence of estradiol on neuronal activity within the ventral hippocampus was not included in the current analyses, but this region also has critical connections to the IL and amygdala that can modulate fear extinction and should be explored as well. Given the limitations of c-fos in examining real-time connectivity between the IL and amygdala, future study of these sites in vivo, perhaps using electrophysiology or optogenetics, is necessary to further elucidate these estradiol-mediated relationships. Acknowledgments The authors thank the members of the Milad laboratory at MGH for their constructive feedback on the manuscript. Additionally, we thank Dr. Adriano Reimer for assistance with the figures. This work was supported by NIMH grant R01 MH097880-001 and departmental funds from the Department of Psychiatry at Massachusetts General Hospital to Mohammed R. Milad. Figure 1 Timeline of experiment and effect of estradiol on freezing behavior. All animals underwent a 3-day behavioral protocol. Habituation and fear conditioning took place on day 1, fear extinction training on day 2, and extinction recall on day 3. Extinction training occurred during the metestrus phase of the estrous cycle, and subcutaneous vehicle or estradiol injections (INJ) were performed 30 minutes (30”) prior to the start of the session. The POST-EXT group was sacrificed 1h after the extinction session, while the POST-REC group was sacrificed 1h after the recall session. Estradiol does not influence freezing behavior during fear conditioning and extinction, but does enhance extinction recall. POST-EXT and POST-REC groups (Vehicle, n=28; Estradiol, n=24) were combined for both the conditioning and extinction phases. The extinction recall phase is represented by the POST-REC group (Vehicle, n=14; Estradiol, n=14). *p≤0.05. Figure 2 Photomicrographs of c-fos stained sections and average c-fos positive cell counts. The first column consists of images containing the regions of interest (ROIs) bordered by dashed lines. The second column displays the c-fos positive cell counts for the POST-EXT group, and the third column for the POST-REC group. A. Quantification of c-fos positive expression within the PL and IL regions of the mPFC as outlined by the dashed lines in the image are represented in the graphs. There were no significant effects of drug in the mPFC (POST-EXT: Vehicle, n=8; Estradiol, n=8; POST-REC: Vehicle, n=8; Estradiol, n=9). B. C-fos expression was measured within the LA, BLA, CeL, and CeM. During extinction, estradiol increased CeL activity, while reducing LA and BLA activity (Vehicle, n=8; Estradiol, n=8). During recall, estradiol reduced neuronal activation in the CeM and LA (Vehicle, n=8; Estradiol, n=9). C. Hippocampal c-fos expression was counted for the dorsal subregions: DG (POST-EXT: Vehicle, n=8; Estradiol, n=8; POST-REC: Vehicle, n=5; Estradiol, n=9), CA1 (POST-EXT: Vehicle, n=8; Estradiol, n=8; POST-REC: Vehicle, n=6; Estradiol, n=9), and CA3 (POST-EXT: Vehicle, n=7; Estradiol, n=7; POST-REC: Vehicle, n=6; Estradiol, n=7). There were no differences in c-fos activity with estradiol administration. PL=prelimbic; IL=infralimbic; LA=lateral amygdala; BLA=basolateral amygdala; CeL=centrolateral amygdala; CeM=centromedial amygdala; DG=dentate gyrus; CA1=cornus ammonis; CA3=cornus ammonis. White bars represent vehicle-treated animals. Black bars represent estradiol-treated animals. *p≤0.05. Figure 3 Photomicrographs of the centrolateral amygdala comparing c-fos expression with vehicle vs. estradiol treatment in POST-EXT. The ROI for the CeL is zoomed in to 20X magnification (right column) from 4X magnification (left column) to visualize the pronounced increase in c-fos immunoreactivity following estradiol administration. Figure 4 IL/PL c-fos activity ratio of POST-EXT and POST-REC groups and correlation with extinction retention index. IL/PL c-fos activity ratio is significantly higher in the estradiol group during extinction recall, but not during extinction learning. The IL/PL c-fos ratio is not correlated with how much extinction was conserved (ERI). White bars represent vehicle-treated animals. Black bars represent estradiol-treated animals. White dots in the correlation graphs represent vehicle-treated animals, and black dots represent the estradiol-treated animals. POST-EXT: Vehicle, n=8; Estradiol, n=8. POST-REC: Vehicle, n=8; Estradiol, n=9. *p≤0.05. Figure 5 C-fos activity ratios with the IL and subregions of the amygdala and their correlations with extinction retention index. A. Estradiol did not alter the IL/CeM c-fos ratio in the POST-EXT group; however, it increased it in the POST-REC group. The IL/CeM ratio was positively correlated with ERI. B. The IL/CeL c-fos ratio was significantly reduced in the POST-EXT group but significantly increased in the POST-REC group. The IL/CeL c-fos ratio was also positively correlated with ERI. C and D. There were no differences in IL/BLA and IL/LA c-fos ratios with estradiol treatment, and similarly, no correlations were found between both ratios with ERI. White bars represent vehicle-treated animals. Black bars represent estradiol-treated animals. White dots in the correlation graphs represent vehicle-treated animals, and black dots represent the estradiol-treated animals. POST-EXT: Vehicle, n=8; Estradiol, n=8. POST-REC: Vehicle, n=8; Estradiol, n=9. *p≤0.05. Figure 6 No extinction control behavior and c-fos. A. A separate group of animals underwent the same 3-day protocol as the POST-REC group but did not receive extinction training following the vehicle (n=6) or estradiol (n=6) injection. There was no difference between drug treatments in percent freezing in fear conditioning or recall. INJ= vehicle or estradiol injection. B. Estradiol did not influence neuronal activation in any subregion of the mPFC, amygdala, or dorsal hippocampus. C. In contrast to the POST-REC group, the no extinction control group did not exhibit any differences in c-fos activity ratios with the IL (IL/PL, IL/CeM, IL/CeL). White bars represent vehicle-treated animals. Black bars represent estradiol-treated animals. Figure 7 Estradiol modulation of fear extinction memory and circuitry. Based on the findings in this study, we propose that estradiol’s modulatory effects on fear extinction memory consolidation are driven by the IL-amygdala circuit of the network. In the case of the metestrus females that received vehicle injections and thus had less estradiol during extinction training, the glutamatergic connections (blue) between the IL and ITC and GABAergic projections (black) to the CeA are weak, as indicated by the dashed lines. This leads to greater fear expression during fear extinction recall (red). Estradiol administration strengthens these connections (indicated by the solid lines) to reduce fear expression during recall (green) and enhance extinction retention. More specifically, it appears that with increasing estradiol levels, there is a shift in neuronal activation from stronger CeA to IL activity (red) to stronger IL to CeA activity (green). This shift is correlated with more and less fear during extinction recall, respectively. PL=prelimbic cortex; IL=infralimbic cortex; BLA=basolateral amygdala; CeL=centrolateral amygdala; CeM=centromedial amygdala; ITCv=ventral intercalated cells of the amygdala; CeA=central amygdala; E2=estradiol. Table 1 Antibodies used Antigen Description of Immunogen Source, Host Species, Cat. #, Clone or Lot#, RRID: Concentration Used Anti-c-fos Proto-oncogene reflects neuronal activity Calbiochem, rabbit, PC38, polyclonal/D00134698 RRID:AB_2106755 1:20,000 Rabbit IgG (H+L) Biotinylated goat anti- rabbit IgG (H+L) Vector Laboratories, goat, BA-1000, polyclonal/ZA0520, RRID:AB_2313606 1:200 Table 2 Minimum and maximum c-fos cell counts for each region, time point, and drug treatment Post-ext Post-rec No ext control Vehicle E2 Vehicle E2 Vehicle E2 mPFC PL Min=2; Min=0.33; Min=0.33; Min=0.33; Min=1.3; Min=2; Max=29 Max=14 Max=10.3 Max=21.5 Max=5 Max=5.6 IL Min=2.7; Min=0.33; Min=0.33; Min=1.7; Min=4; Min=6.2; Max=66.5 Max=22.7 Max=23 Max=36.5 Max=18.8 Max=26.8 Amygdala CeM Min=0.33; Min=0; Min=0; Min=0; Min=2.5; Min=1.3; Max=4.5 Max=8 Max=6 Max=2.5 Max=7.7 Max=8 CeL Min=2; Min=0.5; Min=0; Min=0; Min=5.3; Min=2.8; Max=13.5 Max=49.8 Max=26.7 Max=8.7 Max=18 Max=12.7 BLA Min=2; Min=0.7; Min=0; Min=0; Min=1.3; Min=1; Max=12 Max=4.5 Max=3.7 Max=8.3 Max=6 Max=8.3 LA Min=2; Min=0.7; Min=0.7; Min=0; Min=2; Min=1.5; Max=8.7 Max=2.5 Max=5 Max=3.5 Max=4.5 Max=3.7 Dorsal hippocampus DG Min=0.8; Min=3.4; Min=2.5; Min=2.7; Min=3.6; Min=4.3; Max=17.2 Max=8 Max=8.3 Max=6.5 Max=12.3 Max=19.6 CA1 Min=0; Min=0.8; Min=1; Min=0.7; Min=0; Min=0; Max=6 Max=4.2 Max=4.3 Max=2.3 Max=0.5 Max=2.4 CA3 Min=0.5; Min=1; Min=2; Min=0; Min=0.3; Min=0.8; Max=8.6 Max=3.3 Max=3 Max=4.7 Max=3.5 Max=5 Significance statement Anxiety- and fear-based disorders affect twice as many women as men. The neurobiology of fear has been extensively studied in males, and it has been found to overlap with brain networks that are altered by these psychopathologies. We have previously demonstrated that estradiol enhances fear extinction memory consolidation in female rats, implicating a potential neuromodulatory role for estradiol on extinction memory. This work elucidates how estradiol alters neuronal activation in the networks underlying fear conditioning and extinction to improve extinction retention. Identifying these neural correlates may contribute to the development of sex-specific psychiatric treatments that account for gonadal hormone influences. Conflict of interest statement The authors declare that they have no conflicts of interest. Role of authors All authors had full access to all the data in the study and take responsibility for the integrity of the data and the accuracy of the data analysis. Study concept and design: KL, MRM, LYM, and KKC. Acquisition of data: LYM, KKC, MBT, and AJL. Analysis and interpretation of data: LYM, MBT, KL, and MRM. Drafting of the manuscript: LYM. Critical revision of the manuscript for important intellectual content: LYM, MBT, KKC, AJL, MRM, and KL. Statistical analysis: LYM and MBT. Obtained funding: MRM. Administrative, technical, and material support: KKC and LYM. Study supervision: LYM and KL. Literature cited Baran SE Armstrong CE Niren DC Conrad CD Prefrontal cortex lesions and sex differences in fear extinction and perseveration Learn. Mem. Cold Spring Harb. N 2010 17 267 278 Breslau N Davis GC Andreski P Peterson EL Schultz LR Sex differences in posttraumatic stress disorder Arch. Gen. Psychiatry 1997 54 1044 1048 9366662 Burgos-Robles A Vidal-Gonzalez I Quirk GJ Sustained Conditioned Responses in Prelimbic Prefrontal Neurons Are Correlated with Fear Expression and Extinction Failure J. 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PMC005xxxxxx/PMC5120678.txt
LICENSE: This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. 2984705R 2786 Cancer Res Cancer Res. Cancer research 0008-5472 1538-7445 25267066 5120678 10.1158/0008-5472.CAN-14-0579 NIHMS761182 Article CD98hc (SLC3A2) Loss Protects Against Ras-Driven Tumorigenesis by Modulating Integrin-Mediated Mechanotransduction Estrach Soline 1a* Lee Sin-Ae 2* Boulter Etienne 1a Pisano Sabrina 1b Errante Aurélia 1a Tissot Floriane S. 1a Cailleteau Laurence 1a Pons Catherine 1a Ginsberg Mark H. 2 Féral Chloé C. 1a 1 INSERM, U1081, CNRS, UMR7284, Institute for Research on Cancer and Aging of Nice (IRCAN), Avenir Teama, AFM Core facilityb, University of Nice Sophia Antipolis, Medical School, 28 Avenue de Valombrose, F-06107, Nice, France. 2 Department of Medicine, University of California San Diego, La Jolla, CA 92093. CORRESPONDENCE: Chloé C. Féral: chloe.feral@inserm.fr * Contributed equally to this work 20 2 2016 29 9 2014 1 12 2014 23 11 2016 74 23 68786889 This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. CD98hc (SLC3A2) is the heavy chain component of the dimeric transmembrane glycoprotein CD98, which comprises the large neutral amino acid transporter LAT1 (SLC7A5) in cells. Overexpression of CD98hc occurs widely in cancer cells, and is associated with poor prognosis clinically, but its exact contributions to tumorigenesis are uncertain. In this study, we showed that that genetic deficiency of CD98hc protects against Ras-driven skin carcinogenesis. Deleting CD98hc after tumor induction was also sufficient to cause regression of existing tumors. Investigations into the basis for these effects defined two new functions of CD98hc that contribute to epithelial cancer beyond an intrinsic effect on CD98hc on tumor cell proliferation. First, CD98hc increased the stiffness of the tumor microenvironment. Second, CD98hc amplified the capacity of cells to respond to matrix rigidity, an essential factor in tumor development. Mechanistically, CD98hc mediated this stiffness-sensing by increasing Rho kinase (ROCK) activity, resulting in increased transcription mediated by YAP/TAZ, a nuclear relay for mechanical signals. Our results suggest that CD98hc contributes to carcinogenesis by amplifying a positive feedback loop which increases both extracellular matrix stiffness and resulting cellular responses. This work supports a rationale to explore the use of CD98hc inhibitors as cancer therapeutics, CD98hc/SLC3A2 Ras-driven cancer gain-amplifier stiffness YAP/TAZ Introduction Skin squamous cell carcinoma (SCC) is the second most common skin cancer (1). Expression of the type II transmembrane glycoprotein CD98 heavy chain (4F2, SLC3A2) is highly increased in most carcinomas, including SCC, as well as transformed cell lines (2), while in skin, CD98hc is required for proper homeostasis and efficient epidermal wound closure. Via its extracellular domain (C109), CD98hc covalently binds one of several catalytic subunits (the SLC7A5–11 family) to form the functional Heteromeric Amino acid Transporters (HAT) at the cell surface (3). Besides its role as amino acid transport mediator, CD98hc, by binding to intracellular domains to the adhesion receptor β1 integrins, enhances integrin outside-in signaling (4), thus modulating integrin-dependent cell functions. CD98hc over expressing NIH-3T3 fibroblasts developed malignant tumors in athymic mice (5,6). We previously showed that CD98hc deletion in mouse embryonic stem (ES) cells delays teratocarcinoma formation in mice (4). CD98hc is an integrin binding protein that enhances signals downstream of β1 integrin therefore regulating integrin-dependent cell behavior, including matrix remodeling in vitro (4,7,8). Tumorigenicity of CD98hc deficient ES cells can be reconstituted by expressing a chimeric form of CD98hc which is able to interact with β1 integrin (4). This CD98hc/β1 interaction contributes to cell transformation in vitro (9). Here we examine the role of CD98hc in a well-established (10) two step model of squamous cell carcinoma (SCC). In this Ras-driven cancer model, tumorigenesis begins with the initiation of a single epidermal cell, which occurs following a single subcarcinogenic dose of 7,12-dimethylbenz[a]-anthracene (DMBA). Following the initiation stage, the population of mutated cells is promoted to clonally expand during the second stage, referred to as “promotion”. Tumor promotion is elicited by the repeated topical application of chemical agents, such as the phorbol ester, phorbol 12-myristate 13-acetate (TPA) that leads to sustained epidermal hyperplasia as evidenced by an increase in the number of nucleated cell layers and an overall increase in thickness of the epidermis. Tumorigenesis proceeds through the promotion of benign tumors (papilloma) growth and finally the progression of some benign tumors into malignant and potentially metastatic lesions (SCC). This two-stage skin carcinogenesis model enables direct visualization of tumor development and permits evaluation of TPA-induced inflammation response (10). Here, we combined this model of epidermal tumor formation with conditional deletion of CD98hc in basal keratinocytes to reveal a major contribution of CD98hc in controlling the mechanical properties of the tumor microenvironment, independently of skin TPA-induced inflammation. Specifically, CD98hc deficient skin was protected against tumor formation, and that CD98hc deletion led to regression of pre-existing tumors. We demonstrate that, beyond CD98hc intrinsic proliferation effect within tumor cells, CD98hc-expressing environment is cancer-prone due to modulation of its mechanical properties. This model is known to be sensitive to integrin signaling and rigidity sensing. We now show that CD98hc acts as a gain amplifier for stiffness sensing via integrins. CD98hc is thus a gain amplifier of a positive feedback loop that increases ROCK signaling, matrix stiffness and YAP/TAZ-driven gene expression. Material and Methods Mice All procedures were approved by the Institutional Animal Care and Use Committee at the University of Nice-Sophia Antipolis, Nice, FR (CIEPAL-AZUR Agreement NCE/2012-66). K14-CreERT2, CD98hcfl/fl have been described previously (11). The experiments have been performed on pure FVB/n background mice. Chemical Carcinogenesis Chemical carcinogenesis experiments were performed on 10-week-old mice (20 animals/group), essentially as previously described (10). Mice received one topical application of 200 nmol of 7,12-dimethylbenz(a)anthracene (DMBA; Sigma-Aldrich) in 200 µL of acetone followed a week later by biweekly applications of 6.8 nmol of phorbol 12-myristate-13-acetate (TPA; Sigma-Aldrich) in 200 µl acetone. Papillomas and SCC numbers were scored once a week for up to 32 weeks after the start of promotion. Topical 4-OHT treatment was topically applied when indicated (6 treatments of 1.5 mg 4OHT in ethanol/back). No difference in benign tumor acquisition was observed in 4-OHT-treated wt mice ruling out any possible effects of 4-OHT treatment (data not shown). TPA-induced skin response Ears (both sides) of mice with WT- or CD98hc-deficient skin were topically treated with 20µl (per side) of either TPA (0.5µg per side) or vehicle (acetone). Ear thickness was measured with digital calipers, and ear swelling was calculated as (thickness at each time point)-(thickness at 0h). Paraffin sections were stained with H&E and granulocytes were quantified using ImageJ software. Histology and Immunohistochemistry Samples were collected as described by Montanez et al. (12). Histology and immunochemistry were performed as described previously (11). Paraffin-embedded sections were used for all stainings except CD98hc immunostaining, which was performed on frozen sections. Primary antibodies were: rabbit anti human P-cofilin (Cell Signalling), rabbit anti human P-MYPT1 (Millipore), rabbit anti human MYPT1 (Millipore), rat anti mouse CD98 (Clone RL388, e bioscience). Secondary antibodies were used according to manufacturer’s instructions, for immunofluorescence Alexa Fluor 594 anti Rat # A- 21209 anti rabbit #A-21207 (Life technologies); and for immunohistochemistry Vectastain ABC-Kit (Vector #4001) with DAB reagent (Vector #SK4100). Elastic Modulus Measurements To carry out topography imaging and simultaneous elastic modulus maps, a Bioscope Catalyst operating in Peak Force Quantitative Nanomechanical Mapping mode (Bruker Nano, Inc.), coupled with an inverted optical microscope (DMI 6000B, Leica), was used. The experiments were performed using V-shaped silicon SNL-D probes (nominal spring constant k= 0.06 N/m, side angle 23 °, Bruker Nano, Inc.). For each sample (10µm unfixed frozen sagittal section (13), a peak force of 5 nN and a tip velocity of 4 micron/s were used (detailed procedure in Supp. Mat. & Methods). For collagen deposition analysis, detailed procedure is in Supp. Mat. & Methods. Cells Mouse embryonic fibroblasts (MEFs) were derived from CD98hc-conditional knockout homozygote embryos as described previously (7). Similarly, murine keratinocytes were generated and cultured from backskin of adult mice as described in (11) (culture conditions, see Supp. Data). Both cell types were identified by PCR on genomic DNA (as for mice (7), CD98hc expressing or deficient lines), which was performed regularly during their use. MEFs were maintained in DMEM-H (Invitrogen) culture medium containing 10% (v/v) FBS (HyClone), 20 mM HEPES, pH 7.3 (Invitrogen), 0.1 mM nonessential amino acid (Invitrogen), 0.1 mM β-mercaptoethanol (Sigma-Aldrich), and 2 mM L-Glutamine (Invitrogen) at 37°C and 5% CO2. The CD98hc-null MEFs were generated by infecting CD98hc floxed MEFs with adeno-CRE encoding CRE recombinase. Cell Spreading Assay MEFs were replated on the fibronectin-coated gels (PDMS, Supp. Mat. & Methods, or for Supp. Fig. S3, Polyacrylamide, Matrigen, CA, USA) with indicated stiffness and incubated in DMEM plus 1% (v/v) BSA for 45 min, or grown on gels for 24 hours prior to treatment with 1µg/ml of either Rho inhibitor I or Rho activator II (Cytoskeleton, CO, USA) in serum-free medium for 4 hours. Alternatively, CD98hc-null MEFs infected with retroviruses encoding wild type CD98hc, wild type CD69 or chimeras (C69T98E98, C98T69E98, or C98T98E69) were replated on 30 kPa of PDMS gels for 45 min in the absence of serum. Cells were fixed with 3.7% formaldehyde in PBS, permeabilized with 0.5% Triton X-100 in PBS at room temperature (RT) for 10 min, and washed three times with PBS. The cells were then incubated with phalloidin-conjugated rhodamine (Molecular Probes) for 1 hr at RT. The cells on coverslips were washed three times with PBS, mounted with a mounting solution (ProLong® Gold antifade reagent; Invitrogen), and visualized by fluorescent microscopy (Eclipse TE2000-U, Nikon). Cell spreading was quantified by cell area by using customized software written in MATLAB (MathWorks). Western Blotting MEFs were replated on PDMS gels as described above. When mentioned, CD98hc-null MEFs were transiently transfected with wild type CD98hc, extracellular domain-deleted CD98hc or CD69 for 36hr then replated on 30 kPa PDMS substrates and incubated as above. Whole cell lysates were prepared using modified radioimmune precipitation assay buffer (50 mM Tris, pH 7.5, 150 mM NaCl, 50 mM NaF, 1 mM sodium pyrophosphate, 0.1% sodium deoxycholate, 1% Nonidet P-40, protease inhibitors cocktail and 1% CHAPS). Protein lysates were quantified using the bicinchoninic acid (BCA) method (Thermo Scientific Pierce), loaded on SDS-PAGE, and analyzed by Western blotting. The primary antibodies for western blotting were anti-phospho-Y576FAK (Invitrogen), anti-FAK (Santa Cruz Biotechnology), anti-phospho-S476Akt (Cell Signaling Technology), anti-Akt (Cell Signaling Technology) and anti-α-tubulin (Sigma Aldrich). qPCR RNAs were extracted from back skin samples (bearing or not tumors) using Trizol reagent (GIBCO), or from MEFs plated on gels using RNeasy plus kit (Qiagen),. Reverse transcription was performed on total RNA using Superscript II reverse transcriptase (Invitrogen) according to manufacturer’s instructions. Sets of specific primers (see supplemental Table 1) were used for amplification using 7900HT Real Time PCR System (AppliedBiosystems, Foster USA). Samples were normalized to GAPDH (tumors) or rplp0 (MEFs) using the ΔCt method. Statistical significance was determined with Student’s t-test. Results CD98hc deficiency inhibits Ras-induced tumorigenesis CD98hc expression is linked to malignancy (14,15,2) and CD98hc can regulate tumor-associated processes such as anchorage independence (8,4), nutrient transport (3,16), and mTOR (17). To assess CD98hc function in skin tumorigenesis, we generated mice with conditional deletion of CD98hc in the basal layer of the epidermis (K14CreERT2;CD98fl/fl) (11) and applied a two-stage chemical skin carcinogenesis protocol. Topical treatment with the carcinogen DMBA induced oncogenic Ras mutations, and subsequent repeated treatments with the phorbol ester TPA promoted outgrowth of initiated cells resulting in benign papillomas in control mice about 8 weeks after initiation (average of 3 papillomas/mouse at 10 weeks and 10 papillomas/mouse by 16 weeks) (Fig. 1B and 1C). Strikingly, papilloma formation was delayed by 8 weeks in CD98hc-deficient mice. Even after 25 weeks of TPA treatment, only 2 papillomas/mouse, on average, were detected on CD98hc deficient skin, whereas 10/mouse were observed in control mice (Fig. 1A and 1B). Tumor multiplicity was strongly reduced (Fig. 1A), suggesting that CD98hc promotes Ras-induced tumor formation and growth. Typical papillomas in vehicle-treated mice showed exophytic growth of squamous cells. In contrast, 4OHT-treated skin only occasionally manifested hyperplasia of the epidermis (Fig. 1D). CD98hc deletion was induced by 2 week-pretreatment with 4-hydroxy-tamoxifen (4OHT) compared to vehicle-treated skin (Fig. 1A and 1E). The rare papillomas or hyperplastic area, observed on skin treated with 4OHT, expressed CD98hc, (Fig. 1F), suggesting that they were formed by keratinocytes that had escaped Cre-mediated recombination. These data strongly suggest a tumor-promoting function of CD98hc in Ras-induced papillomas. TPA-associated inflammatory response in the skin is sustained in the absence of CD98hc Inflammation facilitates cancer development and growth. Because intestinal epithelia CD98hc is required for inflammation-induced tumorigenesis in the gut, promoting colitis-associated cancer in mice (15), we analyzed the effect of epidermal CD98hc loss in the inflammatory responses stimulated by topical TPA application, the known inflammatory inducer in skin model. First, we quantified the extent of skin edema by treating the ears with TPA and measuring their thickness. A strong reaction was observed following TPA application (vs. vehicle treated skin)(Fig. 2A and 2B), histologic analysis of the ears, prepared 6h after last TPA application, revealed no gross difference in ear thickening and swelling of WT versus CD98hc KO mice (Fig. 2A, 2B, and 2C). Besides, marked spongiosis and extensive infiltration of leukocytes were observed in the edematous dermis independent of CD98hc expression (Fig. 2A). Similar TPA-induced infiltration of inflammatory leukocytes was detected between CD98hc expressing and deficient mice (Fig. 2D). Thus, TPA-induced inflammatory response, ultimately leading to skin tumorigenesis, is CD98hc-independent. Altogether, these data strongly suggest that the dramatic effect of CD98hc loss on skin tumorigenesis relates to a cell autonomous effect. Loss of CD98hc causes Ras mutation-bearing tumor regression Because CD98hc has been shown to act intrinsically as cell proliferation enhancer both in tumoral and non-tumoral cells, Ras-induced tumorigenesis inhibition in CD98hc-deficient skin was expected. Thus, we analyzed the effect of CD98hc deficiency once tumors were already formed. Following either 11 or 23 weeks of DMBA/TPA (inducing respectively, early or large papillomas defined as a size of over 6mm (before SCC conversion), we treated mice with topical 4OHT or vehicle, and monitored succeeding tumor progression (Fig. 3A and 3B). In both cases and within 2 weeks (4OHT treatment period), not only further papilloma growth or conversion to SCC were totally abrogated, in spite of continued TPA application, but papillomas fully regressed, irrespective of papilloma initial size (Fig. 3A and 3B, regression within 5–7 weeks). In sharp contrast, in the first set-up, vehicle-treated mice exhibited progressive papilloma formation such that, at 19 weeks, they manifested an average of 18/mouse (Fig. 3A). In the second set-up, by 27 weeks post DMBA, SCC conversion occurred only in CD98hc expressing mice, with an average of one SCC per mouse, as judged by their flattened morphology and downward-appearing growth (Fig. 3B). Besides, these SCCs exhibited markedly increased CD98hc expression as compared to normal skin and a similar increased expression was observed in human SCC (Fig. 3C). The development of SCC in control mice was confirmed by histological analysis (Fig. 3D). Furthermore, increased CD98hc expression was a general feature of human SCC, being present in all 12 human SCC studies (GEO Profiles for SLC3A2), compiled over 310 samples. Thus, while CD98hc ablation in skin does not modulate apoptosis (11), it induces a drastic regression of Ras mutation-bearing tumors, preventing progression to SCC. CD98hc regulates the elasticity of the tumor microenvironment To assess how CD98hc deficiency impacts tumorigenesis, beyond its cell autonomous effect on proliferation and absence of extrinsic effect on TPA-induced inflammation, we analyzed mechanical features of the tumor microenvironment. A stiff and organized 3D microenvironment is important in tumor formation and tumor cell invasiveness (18) and we previously showed that, in fibroblasts, CD98hc can regulate RhoA (7), an important regulator of skin stiffness (13). Interestingly, CD98hc-deleted skin exhibited an atomic force microscopy (AFM) force map skewed toward low MPa values indicating more compliant tissue (Fig. 4A, 4B and Supp. Fig.S1A). The AFM nanoindentation of the epidermal CD98hc deficient skin revealed an elastic modulus of 0.063±0.01 MPa (n=4), while wt skin, elastic modulus in the papillary (upper) dermis reached 0.53±0.03 MPa (mean, n=3) (Fig. 4C). Although other methods have reported varying E values (19), (20), ’(21), our data are in good agreement with previous AFM studies (22) performed on skin. Thus, CD98hc deficiency decreases epidermal tissue stiffness. Highly aligned ECM molecules, in particular collagen fibers, increase matrix strength and stiffness in vivo. Skin sections of control and 4OHT treated mice stained with Masson’s trichrome (Supp. Fig.S1B) and sirius red (Fig. 4 D, 4E) highlight a major defect in fibrillar collagen, as seen using polarized filter, with a less organized collagen-rich dermis in CD98hc deficient skin (Supp. Fig.S1C–D). Similarly, abnormal fibronectin deposition was observed in KO skin. Therefore, we conclude that the loss of epidermal CD98hc results in more compliant skin due to drastic in vivo changes on collagen and fibronectin organization. CD98hc-mediates increased ROCK and YAP/TAZ signaling during tumorigenesis There is an intimate and bidirectional relationship between matrix organization/stiffness and RhoA-driven cellular contractility mediated by its effector Rho Kinase (ROCK) (13,19) : cellular contractility stimulates matrix assembly (23) and a stiffer matrix stimulates RhoA activity (24). We previously showed that, loss of CD98hc induces a reduction of RhoA activation in unchallenged skin (11). We therefore assessed the effect of CD98hc deletion in keratinocytes on RhoA signaling in papillomas as judged by the ROCK-mediated phosphorylation of the regulatory subunit of myosin phosphatase (Mypt) (Fig. 5A). Papillomas exhibited extensive phospho-Mypt in the epithelium, particularly in suprabasal layers. In contrast phospho-Mypt was nearly absent in the few papillomas derived from 4OHT-treated Slc3a2fl/fl-K14CreERT2 mice (Fig. 5A). Similarly, phosphorylation of cofilin, an indirect downstream target of ROCK, was lost in 4OHT-treated- compared to vehicle treated-skins (phospho-cofilin staining, Supp. Fig. S2). Thus, in contrast to wound healing with a soft provisional matrix (11), CD98hc deletion markedly reduced ROCK activity in papillomas associated with a reduction in matrix stiffness. ROCK regulates YAP/TAZ (Yes-associated protein/Transcriptional co-activator with PDZ-binding motif), which is an important transcriptional mechanism that controls production of fibrogenic factors, such as CTGF (connective tissue growth factor), in addition to controlling cell size, proliferation, and malignant transformation (25). Moreover, recent work shows that cells can “read” ECM cues as a function of the activity of YAP/TAZ through RhoA/ROCK signaling (25). We, therefore, analyzed the effect of CD98hc depletion on YAP/TAZ transcriptional activity by assaying expression of endogenous target genes. Real-time PCR on papillomas revealed that there was a major reduction in transcripts of both mANKRD1 and mCTGF (~5 and ~3 fold reduction respectively), two well characterized YAP/TAZ targets (25) in 4OHT-treated compared to vehicle treated mice (Fig. 5B). As expected, mANKRD1 and mCTGF were even more highly expressed in SCC reaching levels about 5 fold greater than in papillomas (Supp. Fig. S3A). Thus, loss of basal keratinocyte CD98hc markedly suppresses both RhoA/ROCK signaling and expression of YAP/TAZ regulated genes. CD98hc is a gain amplifier of stiffness sensing that enables a RhoA-driven self-reinforcing feedback loop that increases matrix stiffness Integrins play a central role in stiffness sensing (26),,(27). We previously reported that CD98hc expression modulates integrin signaling which can influence the growth of teratocarcinomas (4). This suggests that CD98hc might alter the cellular responses to the tumor microenvironment. Cell spreading is controlled by extracellular matrix stiffness (28). CD98hc null cells exhibited a striking defect in stiffness sensing. Specifically, when adhering to fibronectin covalently bound to silicone gels of varying compliance, CD98hc null fibroblasts failed to spread on 3.5 kPa substrates, an elasticity in the range of those found in skin (19) (Fig. 6A and 6B). Similarly, activation of two integrin-regulated promoters of cell survival, proliferation, and tumor cell invasion, pp125FAK and AKT, was reduced (Fig. 6C). These defects were specifically rescued in cells expressing full length human CD98hc (Fig. 6D). Remarkably, adhesion to stiffer substrates (30 and 300 kPa), resulted in partial restoration of both cell spreading and biochemical signaling in the CD98hc null fibroblasts. Loss of CD98hc in vivo markedly suppresses RhoA/ROCK signaling resulting in decreased transcription of YAP/TAZ regulated genes (Fig. 5 and Supp. S3A). Direct activation of Rho with cytotoxic necrotizing factor-1e (CNF-1) in CD98hc-deficient cells rescued YAP/TAZ activation (Supp. Fig. S3B); conversely, its inhibition by exoenzyme C3 in WT cells blocked YAP/TAZ driven gene expression (Supp. Fig. S3C), thus we propose Actin-Rho/ROCK-matrix stiffness-YAP/TAZ cascade is critical downstream of CD98hc. To assess whether effects on stiffness sensing were mediated through integrin interactions, we tested the capacity of reconstitution of the null cells with wild type CD98hc or with mutants (Fig. 7A and 7B). Both wild type and a mutant (C98T98E69) that couples only to integrins rescued the defect in stiffness sensing in the CD98hc fibroblasts. In contrast mutants that support amino acid transport but do not associate with integrins (C69T98E98 and C98T69E98) failed to rescue (Fig. 7A and 7B). Skin tumors arise from the underlying basal-layer cells, thus we tested the reconstitution of CD98hc deficient keratinocytes (Supp. Fig. S4) and found, similarly that, only mutant coupling with integrins (C98T98E69) rescued the defect in stiffness sensing. These data show that CD98hc, via its interaction with integrins, acts as a gain amplifier of stiffness sensing. Discussion In this study, we examined the sensitivity of the epidermal CD98hc-deficient mouse to Ras-driven skin carcinogenesis. Mice lacking epidermal CD98hc were protected against chemically-induced papilloma formation, even though TPA-associated inflammation response was preserved. Beyond this protection linked to CD98hc cell autonomous effect on cell proliferation, we demonstrate, for the first time, that when CD98hc deletion is induced after papillomas are formed, tumor regression is observed. Stiffness of the tumor microenvironment is crucial during cancer growth and integrins are involved in stiffness sensing. We reveal a new role for CD98hc as an amplifier of integrin-mediated cellular stiffness sensing leading to both ROCK-mediated increased matrix stiffness and nuclear relay of mechanical signals via YAP/TAZ signaling. Thus, CD98hc is a central gain amplifier in a self-reinforcing feedback loop that regulates both matrix stiffness and the cellular responses to stiffness. CD98hc is highly expressed in many tumors of different origins as well as in established tumor cell lines. Our results showing that loss of CD98hc protects against tumor formation is in good agreement with recent studies on more invasive and non-accessible tumors from the intestinal epithelium (15,29). Indeed, Nguyen et al. showed that CD98hc role in the gut tumorigenesis is partly due to an effect on epithelial intrinsic cell proliferation. We previously showed that the integrin-interacting function of CD98hc can mediate cellular proliferation in teratocarcinomas and lymphocytes (4,30). Notably, we report that, conversely to the gut, CD98hc in the skin does not perturb TPA-induced immune responses, involved during tumorigenesis. Furthermore, we show, for the first time, that not only CD98hc acts on tumor progression, but that its loss causes tumor regression. Importantly, CD98hc also forms the heavy chain of an amino acid co-transporter that can support the nutrient requirements of tumors (31) and consequent mTOR activation (17). Thus, it is likely that the capacity of CD98hc to support metabolic re-programming combined with its capacity to amplify mechanotransduction contribute to its critical role both in the clonal expansion of lymphocytes (30,32) and in tumorigenesis. The tumor microenvironment is a mechanically tunable meshwork comprising extracellular matrix (ECM) proteins, a heterogeneous population of stromal cells and secreted soluble factors. The modifications of the mechanical properties of this microenvironment, which are monitored by ECM receptors such as integrins, play an important role during tumor progression (33). Here, we provide a novel function of CD98hc independent of its required role in immune response linked to epithelial tumorigenesis. Our data are in good agreement with studies on breast carcinoma, showing the critical role of integrin-signaling in mechanosensing during tumorigenesis. CD98hc function as a co-receptor of integrins probably participates to integrin-signaling in mechanosensing in many cancer types. SCC is the second most common skin cancer (1) and its pathogenesis is tied to integrin expression (34),35). Elegant studies point to an important role for keratinocyte α5β1 integrin rather than α3β1 or α2β1 in SCCs formation (36). Most importantly, these studies show that the tumors arise from the underlying basal-layer cells (37). Newer studies point to dysfunction in environmental sensing, an integrin-dependent process, as a contributor to tumor formation and progression (19,38,39) . We now find that CD98hc loss drastically compromises environment stiffness sensing and conversely leads to a marked reduction in matrix stiffness. Importantly, the physiological elasticity of skin has been long evaluated, using other types of technologies, to range between 5 and 10 kPa (20,21,22), gel compliance we used in our in vitro studies. In the AFM settings we utilized, this value reaches 0.53 MPa on average. This apparent discrepancy can be explained by recent work from Akhtar et al. (40) showing that elastic modulus of the constituent ECM molecules is higher than the one of the connective tissues themselves. The dermis is of fibrillar nature, and the nanoscopic AFM probe we used in vivo is likely to find very distinct areas, such as fibers, upon which to indent. This leads to measurement of elastic modulus reaching values in the MPa range. Finally, in good agreement with the explanation above, our data suggest that, in the absence of CD98hc, the ECM components responsible for structural rigidity, such as collagen content, might be modulated, leading to an overall decrease in stiffness and altering the skin mechanical properties Integrin-mediated adhesions are intrinsically mechanosensitive and a large body of data implicates integrins in sensing mechanical forces (39,41). Piccolo’s laboratory pioneered the notion that mechanical signals and cell shape are converted into biochemical responses by two related transcription factors, YAP and TAZ (26,42). In particular, YAP and TAZ are nuclear relays of mechanical signals exerted by ECM rigidity (25) and mCTGF, a well characterized YAP/TAZ target, induces collagen deposition. CD98hc loss reduces ROCK activity in vivo resulting in decreased signaling of YAP/TAZ, and concomitantly a decrease of mCTGF expression, suggesting a role for CD98hc in collagen deposition. Importantly, cells deficient for CD98hc lose their capacity to ‘read’ physical and mechanical cues. The absence of CD98hc makes cells on a stiff ECM behave as if they were on a soft one. Thus, CD98hc tunes cellular stiffness sensing during tumorigenesis via the integrin/ROCK/YAP/TAZ pathway. In summary, our data establish a central role for CD98hc in chemically-induced tumor development and progression in skin and show that removal of CD98hc can induce tumor regression. We demonstrate that CD98hc mediates this process by acting as an amplifier of integrin-mediated mechanotransduction and that the gain in stiffness sensing provided by CD98hc forms the core of a positive feedback loop that increases the stiffness of the microenvironment and the cellular responses. Lastly, we implicate YAP/TAZ as a RhoA/ROCK regulated pathway that contributes to CD98hc-mediated tumorigenesis. These studies also highlight the potential synergic effect of blocking CD98hc, in an anti-cancer therapy, allowing targeting both tumor cell proliferation and tumor environment matrix stiffness. Supplementary Material Supplementary Data Supplementary Methods We thank the IRCAN core facilities (microscopy and animal facility) for technical help. This study was supported by grants from INSERM InCa/AVENIR (R08227AS), from Association pour la Recherche sur le Cancer (ARC R10159AA), and from Agence Nationale de la Recherche (ANR R09101AS), and through the “Investments for the Future” LABEX SIGNALIFE : program reference # ANR-11-LABX-0028-01. E. Boulter was the recipient of a postdoctoral fellowship from the Ligue Nationale Contre le Cancer (RAB 12007 ASA) and a Marie Curie IRG from the European Union FP7 (agreement 276945). Figure 1 CD98hc deficient epidermis is protected against tumor formation in vivo A. Number of papillomas per mouse is shown over the course of the experiment. Mice (8 weeks old) were treated 6 times with 4OHT before the start of the chemical carcinogenesis (DMBA/TPA) protocol. Data are mean (±SEM) of 2 independent experiments. (n=10 per group). B. Representative pictures at 16 weeks post initiation of mice from vehicle- (Ctrl) and 4OHT-treated group. C. Back skin sections, stained with H&E, isolated from vehicle- (Ctrl) or 4OHT-treated mice (as indicated) after 30 weeks of promotion, bearing or not tumors. Inserts are shown in D and E. Scale bar 200µm. D, E. Immunofluorescence analysis of skin samples from vehicle- (Ctrl) or 4OHT-treated mice (as indicated) with antibody against CD98hc. Dotted line indicates the dermis-epidermis junction. Scale bar 100µm. Figure 2 TPA-induced inflammatory response is preserved in absence of CD98hc A. Measurement of TPA-induced ear swelling. Ears of CD98hc- expressing or deficient mice were treated with TPA or vehicle alone. Seventy two hours after the first treatment, ears were collected. H&E stainings of representative ear cross sections are shown. Bar 100µm. B. Ear thickness of each mouse is shown (black dot represents value for each mouse). *** p<0.001 between TPA vs. vehicle. C. Time course of TPA-induced ear swelling. Extend of ear swelling was calculated as indicated in Mat. & Meth (n=3 per group). No significant difference was observed in the presence or absence of epidermal CD98hc. D. Quantification of the densities of infiltrated granulocytes of the ear of each mouse 72 hours after the first TPA treatment (each cross sections, as represented in A, were quantified), black dot represents value for each mouse). *** p<0.001 between TPA vs. vehicle. Figure 3 CD98hc loss induces tumor regression A. Number of papillomas per mouse is shown over the course of the experiment. Mice (8 weeks old) were subjected to the chemical carcinogenesis protocol DMBA/TPA. Six 4OHT-(or vehicle-) treatments were applied on the back skin of treated group 12 weeks after the DMBA application, corresponding to the first papillomas apparition. Data are mean (±SEM) of two independent experiments. n=6 per group. B. Number of tumors per mouse is shown over the course of the experiment. Mice (8 weeks old) were subjected to the chemical carcinogenesis protocol DMBA/TPA. Six 4OHT- (or vehicle-) treatments were applied on the back skin of treated group 22 weeks after the DMBA application, corresponding to papilloma conversion to malignant SCC. Only large papillomas, defined as a size of over 6mm, are shown. Data are mean ±SEM representative of n=10 for vehicle-treated (Ctrl) group and n=14 for 4OHT-treated group. C. Immunofluorescence analysis of SCC (upper panels) and normal skin (lower panels) samples from either murine or human origin with antibody against CD98hc, showing strong overexpression of CD98hc in SCC. Scale bars as indicated. D. Morphology of SCC tumor (left panel) and normal skin (right panel) sections shown by H&E staining. Scale bars as indicated. Figure 4 Loss of CD98hc increases tissue elasticity by modulating ECM organization A. AFM maps of the elastic moduli of vehicle- (Ctrl) and 4OHT-treated skin corresponding to the areas enclosed by yellow squares (left panels). Right panels show heat maps of the same 20 × 20 µm scanned areas. B. Representative force-separation curves of vehicle (Ctrl) and 4OHT -treated samples. C. Quantification of Young’s elastic Modulus in vehicle (n=3) and 4OHT (n=4) treated skin, expressed as mean ± SEM, ***p value<0.001). D. Defect in fibrillar collagen in 4OHT-treated skin shown by sirius red staining (right panel corresponds to polarized filter which highlights fibrillar collagen). Scale bars 100µm and 50 µm, respectively. E. Quantification of fibrillar collagen in 4OHT- vs. vehicle- (Ctrl) treated skin confirming a less organized collagen-rich dermis in CD98hc deficient skin. Figure 5 CD98hc loss reduces Rho Kinase (ROCK) activity in papillomas resulting in decreased YAP/TAZ Signaling A. Immunohistochemical analysis of murine papilloma sections from vehicle- (Ctrl) and 4OHT-treated mice with antibodies against MYPT1 and P-MYPT1, displaying strong expression across the epidermis, but decreased phosphorylation status in CD98hc deficient papillomas. Scale bar 200µm. B. Quantitative RT-PCR of YAP/TAZ signaling markers (mANKRD1 and mCTGF) from papilloma isolated from vehicle- (Ctrl) and 4OHT-treated mice. GAPDH is shown as control. Data shown are mean ±SEM (n=15 per group), *p< 0.01, **p≤0.001. C. Quantitative RT-PCR of CD98hc in vehicle- (Ctrl) vs. 4OHT-treated papillomas. (n=5 per group) Data are shown as mean ± SEM, ***p< 0.001. Figure 6 CD98hc is a central gain amplifier of stiffness sensing A. Actin staining of WT (CD98hcfl/fl) or CD98hc-deficient (CD98hc−/−) cells seeded on silicone gels displaying variable stiffness. Scale bar 20 µm. B. Quantification of cell area according to matrix stiffness. Data represented are mean of 3 independent experiments. Error Bars are SEM. C. Western blot analysis of FAK and Akt level of phosphorylation in WT or CD98hc-deficient cells according to matrix stiffness. Total FAK, Akt, and α -tubulin are shown as controls. D. Western blot analysis of FAK and Akt level of phosphorylation in CD98hc-deficient cells reconstituted with full length human CD98hc (hCD98hc) or CD69 (control). Total FAK, Akt, and α-tubulin are shown as controls. Figure 7 CD98hc capacity to stiffness sensing is mediated through integrin signaling A. CD98hc-deficient cells reconstituted with different chimeras (GFP positive) were seeded on 30 kPa stiffness silicone gels. Model of chimeras of CD98hc and another type II transmembrane protein (CD69), is shown. CD98hc protein is depicted in gray, and CD69 is depicted in black. Each chimera is defined by its cytoplasmic (C), transmembrane (T), and extracellular (E) domain derived from either CD98hc (98) or CD69 (69). CD98hc extracellular domain is necessary and sufficient for amino acid transport, whereas the intracellular and transmembrane domains are required for interactions with integrins. Actin cytoskeleton was observed using phalloidin staining. Quantification of cell surface area of transfected cells (GFP+) vs. Mock (GFP-), according to the matrix stiffness, is shown. Data represented are mean of 3 independent experiments. Error Bars are SEM. Scale bar 10 µm. B. Western blot analysis of FAK and Akt level of phosphorylation in CD98hc-deficient cells (CD98hc−/−) reconstituted with chimeras and seeded on 30 kPa silicone gels. The authors disclose no potential conflicts of interest. 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PMC005xxxxxx/PMC5120727.txt
LICENSE: This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. 101692909 45744 J Rare Dis Res Treat Journal of rare diseases research & treatment 27891535 5120727 NIHMS825771 Article Gene therapy for hemoglobin disorders - a mini-review Rai Parul 1 Malik Punam 12* 1 Cincinnati Children’s Hospital Medical Center, Cincinnati, OH, USA 2 Department of Pediatrics, University of Cincinnati College of Medicine, Cincinnati, OH 45229, USA * Correspondence: Punam Malik, MD, Cincinnati Children’s Hospital Medical Center, Division of Experimental Hematology and Cancer Biology and the Division of Hematology, Cancer and Blood Disease Institute, Cincinnati Children’s Hospital Medical Center 3333 Burnet Ave, Cincinnati OH 45229, USA, punam.malik@cchmc.org 10 11 2016 2016 23 11 2016 1 2 2531 This file is available for text mining. It may also be used consistent with the principles of fair use under the copyright law. Gene therapy by either gene insertion or editing is an exciting curative therapeutic option for monogenic hemoglobin disorders like sickle cell disease and β-thalassemia. The safety and efficacy of gene transfer techniques has markedly improved with the use of lentivirus vectors. The clinical translation of this technology has met with good success, although key limitations include number of engraftable transduced hematopoietic stem cells and adequate transgene expression that results in complete correction of β0 thalassemia major. This highlights the need to identify and address factors that might be contributing to the in-vivo survival of the transduced hematopoietic stem cells or find means to improve expression from current vectors. In this review, we briefly discuss the gene therapy strategies specific to hemoglobinopathies, the success of the preclinical models and the current status of gene therapy clinical trials. Gene Hemoglobinopathies Sickle cell anemia Thalassemia Hemoglobin Therapy Review Disorders Introduction Sickle cell disease (SCD) and β-thalassemia are autosomal recessive disorders that result in qualitative and quantitative defects in β-globin protein production; and are highly prevalent worldwide, with approximately 7% of the global population estimated to be carriers of hemoglobin gene-variants, and over 330,000 affected infants born annually with SCD alone1. Despite improved medical supportive therapies, significant long-term mortality and morbidity associated with hemoglobinopathies remains2,3. Hematopoietic stem cell transplant (HSCT) provides the only definitive cure, with a disease free survival exceeding 80% with HLA-matched sibling donor transplants4,5. Improvements in management of graft versus host disease (GVHD) and better means of inducing graft tolerance have encouraged the use of an extended donor pool comprising of unrelated donors and umbilical cord blood as the hematopoietic stem cell (HSC) source for patients lacking a matched sibling donor6. However, matched-unrelated HSCT for thalassemia have an overall survival of 65% in the high risk patients7. In addition, a 5–10% mortality from transplant-conditioning, GVHD and graft failure continues to limit the acceptability of this treatment modality8. Gene therapy, using genetically-modified autologous HSCs is an attractive alternative to allogeneic HSCT, and specifically unrelated-donor HSCT, since it eliminates the need for a matched donor and the risk of GVHD/graft rejection. Successful gene therapy for monogenic immune disorders like chronic granulomatous disease and severe combined immunodeficiency9–13 has encouraged development of this technology for hemoglobinopathies. Whereas in immunodeficiency disorders, the genetically modified hematopoietic progenitors and T cells have a selective survival advantage and a tremendous expansion potential, respectively, requiring a minimal (0.1–1%) gene corrected HSC engraftment for sustained correction of lymphoid dysfunction14; in hemoglobinopathies, no such survival advantage of genetically modified HSCs/progenitors is present, and selective advantage is limited to the terminal erythroid cells15. Post-transplant follow-up studies16 and murine models17,18 show that a 20% donor chimerism is essential for improving the clinical manifestations in SCD and thalassemia, a level requiring substantial pre-transplant chemotherapy conditioning. Furthermore, in order for globin gene transfer to affect a cure, high level erythroid lineage specific expression is necessary. Despite these hurdles, improved vector potency and safety have significantly advanced the field, resulting in cures in patients with Hemoglobin E-β-thalassemia and considerable disease amelioration in some patients with β0 thalassemia and SCD. The lessons learnt from these early gene therapy trials suggest that engraftment of sufficient transduced HSC, or their in-vivo selection could play a crucial role to extend the curative capacity of gene therapy. Vector development for hemoglobin disorders Correction of hemoglobin disorders by vector-mediated gene transfer requires utilization of a safe delivery vehicle/vector to efficiently transfer the complex β-transgene cassette to HSCs and result in sustained high expression of the transferred globin gene. The vectors commonly used have been bioengineered from different retroviruses, mainly murine Moloney leukemia virus (retrovirus vectors; RV), HIV-1 (lentivirus vectors; LV) and foamy virus, after removing the genetic elements responsible for their pathogenicity and virulence, and adding the β-globin gene and its locus control region (LCR) elements. Of these, LV have been most successful at correcting hemoglobinopathy animal models, and have resulted in their clinical translation. The β-globin LCR is a cis-regulatory element composed of five DNAase-1 hypersensitivity sites, four of which are formed in the erythroid cells19. When linked to the globin genes LCR leads to position-independent, erythroid lineage-specific enhancement of globin gene expression. The enhancer activity of LCR resides in three of its hypersensitivity sites HS 2, 3 and 4, which contain an array of binding sites for ubiquitous and erythroid specific transcription factors20. An intact LCR (5’HS 1–5) is involved in maintaining an open chromatin conformation that is needed for position independent expression of the globin genes. The LCR also results in developmental regulation of globin expression and interacts with the ε, γ and β globin gene promoters in the embryonic, fetal and adult stage, respectively21. Gamma-retrovirus (RV) vectors Initial studies looking at RV-mediated human β-globin gene transfer without inclusion of the LCR elements, showed variable and low levels of gene expression (<1% of endogenous β- globin expression)22. Following this study, nearly one decade of efforts to develop RV for expressing sufficient globin gene expression were futile23,24. RVs utilizing the enhancer/promoter sequences of the LTR (long terminal repeat) to drive transgene expression of genes other than globin genes, were the first ones to be used in clinical trials. Despite their initial clinical success in gene therapy of immune-deficiencies, concerns about their safety emerged following reports of vector-mediated insertional mutagenesis9–12. Integration site analysis revealed that the RVs have a tendency to integrate near cellular promoters, retroviral common integration sites (CIS) and cancer genes, independent of the vector design, and enhance their expression via the LTR promoter/enhancer. The RV vector insertions increase immortalization of primary hematopoietic progenitor cells25. While the RV LTR is a strong enhancer and upregulates transgene expression to very high levels compared to relatively weaker enhancers from the HIV LTR and cytomegalovirus26, it also simultaneously activates cellular proto- oncogenes flanking insertion sites27. Additionally, methylation of the LTR can lead to inactivation of the integrated transgene promoter and prevent long-term transgene expression28. The construction of a self-inactivating [SIN] vector design deletes the LTR promoter/enhancer and allows the transgene expression to be driven by internal cellular promoters, reduce LTR enhancer-mediated genotoxicity27 and its methylation-induced inactivation29. Inclusion of the chicken β-globin hypersensitive site-4 (cHS4) insulator element to the SIN vector further improved its safety by reducing position dependent variablility in gene expression30. However the inability of RV to transduce non-diving cells, along with vector instability seen with incorporation of large LCR sequences greatly limited their use in gene therapy for hemoglobin disorders31. Lentivirus vectors The interest in LV was generated with the increasing knowledge of the basic structure and properties of HIV-1 virus. HIV-1 can efficiently translocate the intact nuclear membrane and thus, has the ability to transduce non-dividing/quiescent cells and can carry larger expression cassettes. These features enabled the HIV-1 based LVs to be developed for hemoglobinopathies, and efficiently transfer the β-transgene/LCR to HSCs for sustained correction of the hemoglobin defect. The major safety concerns with the use of LVs initially were risk of generating a replication-competent lentivirus (RCL) and insertional mutagenesis. The former risk has been eliminated by removal of HIV regulatory and accessory genes from vector plasmids and constructing the vector with 3–4 separate packaging plasmids, with minimal overlapping sequences between and within them31. The preference for intragenic integration of LV vectors, coupled with the SIN design considerably reduces their genotoxicity potential; Indeed, recent LV clinical trials with a follow up of nearly 10 years have shown no genotoxicity resulting from LV vectors, even though, preclinical studies have reported vector integration in known oncogenes (MLL, NUP214)32 and suggested that transcriptionally active enhancers like the LCR can lead to gene dysregulation, independent of the vector type (RV or LV) or design (LTR-based or SIN)26,33. Our group explored the genotoxicity potential of LCR enhancer elements and showed that the LCR-containing LVs have approximately 200-fold lower immortalization potential than RVs. Though gene dysregulation was seen in the vicinity of the integrated vector, no proto-oncogene upregulation was noted34. Use of cHS4 insulators decreased the transforming potential further, along with decreasing position dependent variable gene expression and methylation-associated silencing35. Preclinical studies Gene Therapy for β-Thalassemia LV-mediated human β-gene transfer was shown to rescue mouse models of β-thalassemia intermedia and β-thalassemia major. May and colleagues demonstrated the use of a LV vector carrying the human β-globin gene fragment and β-globin LCR spanning the HS2, HS3, and HS4 regions to correct thalassemia intermedia in mice with increase in hemoglobin levels by 3–4 g/dl36. The same group developed an adult β0-thalassemia major mouse model using mice engrafted with beta-globin-null Hbb(th3/th3) fetal liver cells and rescued their severe phenotype using the same vector with an average vector copy number (VCN) of 1.0– 2.418. Imren and coworkers thereafter showed correction of β-thalassemia mice using a vector carrying the βT87Q gene, where a point mutation in the β-globin gene also confers it with anti-sickling properties. However, multiple copies were required for adequate correction of the mouse thalassemia phenotype32. Our group showed complete correction of the human β0 thalassemia phenotype in vitro and in a xenograft model with approximately 2 vector copies/cell37. Miccio and colleagues used a LV vector carrying the β-globin gene linked to a minimized LCR HS2/HS3. They showed that a frequency of 30–50% of transduced hematopoietic cells harboring an average VCN of 1 was sufficient to fully correct the thalassemia phenotype in th3/+ mice15. In addition they also demonstrated that the genetically corrected erythroblasts had an in vivo survival advantage, thus encouraging the need to explore the utility of reduced intensity transplant regimens for clinical gene therapy trials. Gene Therapy for SCD The efficacy of LV-mediated transfer of γ-globin gene/mutated β-globin genes (βT87Q and βAS3) for correcting SCD was explored using transgenic and humanized xenograft sickle cell murine models. Pawliuk and colleagues showed improvement in hematological parameters, splenomegaly and hyposthenuria in BERK and SAD mice using the βT87Q LV38. Levasseur on the other hand used a βAS3 (a human β-globin gene with 3 anti-sickling mutations) in a LV to successfully transduce murine HSC without cytokine stimulation39. Romero et al used the same βAS3 LV to successfully transduce bone marrow CD34 progenitor cells from patients with SCD, and produce sufficient levels of anti-sickling hemoglobin40. Persons et al41, and Pestina et al42 showed improvement in SCD phenotype by increasing the expression of fetal hemoglobin (HbF) using γ-globin LV. Our group showed an 18–20% engraftment of HSCs containing γ-globin gene-LV, following a non-myeloablative conditioning regimen. This donor chimerism was sufficient to result in approximately 60% circulating RBC containing HbF (F cells) with an improvement in the SCD manifestations43. Clinical trials The success in preclinical models, supported by safety studies on LV vectors led to the design of clinical gene therapy trials. Cavazzana-Calvo et al. enrolled a hemoglobin E/β (βE/β0)-thalassemia major patient in 2007 who received genetically modified autologous HSCs expressing βT87Q-globin following myeloablative busulfan conditioning. This subject became transfusion independent 1–2 years later44 with a hemoglobin maintained at 9–10 gm/dl. This therapeutic benefit was initially due to a clonal expansion observed following vector insertion in the HMGA2 gene. However this clone has eventually subsided. The trial was subsequently extended to include 18 patients with thalassemia (transfusion-dependent βEβ0 n=10, β0β0 n=5, β+thalassemia n= 3) and 4 patients with SCA45–47. All patients with βEβ0-thalassemia and β+thalassemia became transfusion independent within a year of transplant, with a median increase in hemoglobin by 4.9-g/dl, while patients with β0β0-thalassemia with a similar hemoglobin increase experienced a significant reduction in their transfusion requirement, but were not transfusion independent, since the baseline hemoglobin levels in β0β0thalassemia are much lower than in individuals with β+/βE thalassemia. One of four patients with SCD who received a high dose of transduced CD34 cells had remarkable improvement in their SCD phenotype. Two other trials are using the β-globin LV vectors for β-thalassemia. In the trial led by Boulad et al (NCT01639690), the preconditioning regimen had to be switched from a reduced-intensity busulfan to myeloablative doses following modest engraftment and β-globin expression with the lower dose48; the trial led by Ferrari et al (NCT02453477) is using a myeloablative regimen consisting of treosulfan and thiotepa with initial success48. The NCT02247843 trial led by Kohn et al. for SCD is investigating the efficacy of βAS3LV, and the trial led by our group (Malik et al.; NCT02186418) is using a γ-globin LV following reduced intensity conditioning. The results of these studies are eagerly awaited. Recent Advances in Genetic Manipulation Technology The emergence of gene editing technology, which enables precise genome manipulation, offers a new approach for treating β-hemoglobinopathies49. Site specific double strand breaks (DSB) can be induced with zinc finger nucleases, transcription activator-like effector nucleases (TALENS), meganucleases and more recently with Clustered regularly interspaced short palindromic repeats (CRISPR)/Cas9 system. CRISPR/Cas9 has revolutionized gene targeting. Unlike other nucleases which use a protein dimer for target sequence recognition and require a novel protein to be engineered for each new target site, CRISPR/Cas9 technology uses a short guide RNA (gRNA) with a 20bp sequence complementary to the DNA sequence to be targeted50. In addition targeting/knockdown of multiple genes can be achieved by using multiple gRNAs with a common Cas9 protein51. DSB is then followed by DNA repair through one of the two major pathways: 1) Non-homologous end joining (NHEJ) with direct fusion of the nuclease cleaved ends. This repair mechanism is error-prone, leading to indels, and is cell-cycle stage independent52. 2) Homologous directed repair (HDR) uses an exogenous donor template53 delivered via single-stranded oligonucleotides, plasmids, or viral vectors like integrase deficient lentivirus or adeno-associated virus54, for gene correction with targeted insertion. For hemoglobinopathies, gene editing strategizes shown to be successful include either induction of endogenous fetal hemoglobin55,56, modification of the causal β-globin gene mutation by targeted nucleases57 or therapeutic transgene integration58, or a combined approach59,60. Inactivation of an erythroid specific enhancer of BCL11A by gene editing leads to suppression of BCL11A and up-regulation of γ-globin in erythroid lineage cells61,62. These gene editing strategizes are being performed in CD34+ stem and progenitor cells63 or in induced pluripotent stem cells (iPSCs) capable of differentiating into any somatic cell type64–66. Patient-specific iPSCs are generated by the genetic reprogramming of their somatic cells, and provide an unlimited source of stem cells which can be genetically manipulated, differentiated along a specific tissue type and returned back to the patient. Currently, active research in differentiating iPSC towards definitive hematopoietic stem cells with long term engraftment potential is underway. In addition to their therapeutic potential, iPSCs can also be used as in-vitro disease models67. Off-target nuclease binding activity68, efficient means of delivering the genome editing tools to target stem cell populations without loss of ‘stemness’, genomic variation occurring with somatic reprogramming, efficient gene targeting by homology directed repair69, and developing functional HSCs from these genetically modified iPSC70,71 are some of the challenges in the field. Conclusions and future directions Gene therapy for hemoglobinopathies is now a reality, with several patients cured of their β0/βE thalassemia or with significant amelioration from β0/β0 thalassemia and one patient with SCD, while others are showing modest transgene expression. The current curative capacity of gene transfer technology is limited by the severity of the underlying disease. The increase in hemoglobin to 8–9 gm/dl seen in β0β0 thalassemia is still not sufficient to prevent ineffective erythropoiesis, and hence these subjects are still intermittently transfused. However the overall transfusion burden in this patient population has decreased dramatically. Cohen et al showed that the success of chelation therapy in achieving a neutral or negative iron balance (assessed by liver iron concentration) had a significant correlation to the transfusion iron intake72. Thus decreasing the transfusion burden is advantageous, as it not only might affect the dose of chelation therapy used but also affects its outcome. The challenges to efficacious clinical translation in hemoglobinopathies include the dose of engraftable transduced HSCs, the intensity of the preconditioning transplant regimen, and expression of the transgene. In-vivo selection strategies can ensure expansion of the few genetically-modified engrafted HSCs. Improving vector potency will augment gene expression. Efforts to promote differentiation of iPSC technology to produce engraftable HSC can expand the HSC source, and gene editing can circumvent the need for high transgene expressing-LV and potential, albeit low, insertional genotoxicities of LV. New technologies that can reshape the future of gene therapy are gene editing using CRISPR/CaS9 and development of hematopoietic stem cells from iPSCs with long term repopulating potential, although much work is needed to make this a reality. With scientific advancements in stem cell biology and genetic manipulation, we envision a future where a child prenatally diagnosed with hemoglobinopathy can have his/her genetically modified cord blood stem cells transfused even before the fetal to adult hemoglobin switch, thus preventing the occurrence of any disease manifestations. This study is supported by the Doris Duke Foundation Innovations in Clinical Research Award to PM, and the NIH-NHLBI Excellence in Hemoglobinopathy Research Award (EHRA) program (U01HL117709). 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