Abstract:
Nanoparticles disclosed in the invention comprise a dextran-coated crystalline structure of cerium oxide wherein tetravalent Ce 4+  predominates over trivalent Ce 3+  and wherein said nanoparticles have a diameter of approximately from 3 to 5 nm. The nanoparticles exhibit both superoxide dismutase activity and catalase activity in an environment having a substantially neutral or acidic pH. The nanoparticles may be used to make and may be contained in a medication. The subject nanoparticles are useful in a method of promoting a cytotoxic anti-invasive effect on squamous tumor cells and inhibit tumor invasiveness.

Description:
CROSS-REFERENCE TO RELATED APPLICATION 
     This application is a continuation of application Ser. No. 12/834,302, filed Jul. 12, 2010, which claims the benefit of Provisional Application No. 61/224,602, filed on Jul. 10, 2009. Each of these applications is hereby incorporated by reference in its entirety. 
    
    
     STATEMENT REGARDING FEDERALLY SPONSORED RESEARCH OR DEVELOPMENT 
     This invention was made with government support by the National Science Foundation under award #CBET07081712. The government has certain rights in the invention. 
    
    
     SEQUENCE LISTING 
     This application contains a Sequence Listing electronically submitted via EFS-web to the United States Patent and Trademark Office as a text file named “Sequence_Listing.txt.” The electronically filed Sequence Listing serves as both the paper copy required by 37 C.F.R. §1.821(c) and the computer readable file required by 37 C.F.R. §1.821(c). The information contained in the Sequence Listing is incorporated herein by reference in its entirety. 
     FIELD OF THE INVENTION 
     The invention relates to the field of nanomedicine and, more particularly, to cerium oxide nanoparticles displaying redox functionality and useful for inhibiting tumor cells while not affecting normal cells, and associated methods. 
     BACKGROUND 
     Many studies on neoplastic transformation and tumor progression focused and still focus on tumor cells. However, one important aspect in tumor progression is the interaction between cancer cells and the stromal microenvironment [1]. The stroma was initially thought to have only supportive function in tumor development, but there is increasing evidence that stromal components actively take part in tumor progression and, therefore, are major players in tumor invasion [2-4]. Beside inflammatory and endothelial cells another crucial cellular component of the stroma is the myofibroblast (MF), a modulated fibroblast which has acquired the capacity to express the biomarker alpha-smooth muscle actin (αSMA) [5]. Myofibroblasts remodel the connective tissue during wound healing, but also interact with cancer cells at all stages of tumor progression and may thus control such phenomena as tumor invasion and angiogenesis [6]. 
     Although it is known that reactive oxygen species (ROS) can be key regulators at all stages of cancer development [7], the molecular mechanisms underlying the ROS-dependent tumor-stroma interaction in tumor progression and its potential therapeutic modulation to prevent tumor invasion have not been fully elucidated until recently. A better understanding of the ROS initiated molecular mechanisms mediating interaction between the tumor and the tumor microenvironment would be helpful for the development of novel therapeutic strategies, as invasion and metastases are the most common problems in cancer therapy. 
     Nanomedicine, the medical application of nanotechnology, deals with the application of structures of the size 100 nanometers or smaller in at least one dimension and seeks to deliver a valuable set of research tools and clinically helpful devices in the near future [8]. The small size of nanoparticles endows them with properties that can be very useful in carcinogenesis, particularly in imaging and anti-cancer therapy. A nanoparticle-based therapeutic approach may have the potential as supplementation therapy supporting the classical anticancer strategies such as radiation or the use of anticancer drugs. If future studies show that a nanoparticle-based anticancer therapy has less harmful effects, it is aimed for the application of nanoparticles as major anticancer approach. In both cases, the treatment with nanoparticles should result in killing tumor cells or in prevention of tumor invasion while leaving normal healthy cells intact. 
     In that context, nano-sized magnetic iron particles are increasingly being used in cancer therapy. Once uptaken by tumor cells, such particles can be magnetically heated leading to localized cell death while healthy cells remain alive [9,10]. Free oxygen radicals generated by exposure to cerium oxide nanoparticles (CNP) produced significant oxidative stress, which killed lung carcinoma cells [11]. However, the toxicity of CNP is still controversial as an antioxidant function of CNP is described as well. Vacancy engineered CNP exhibited superoxide dismutase mimetic activity in human epidermal keratinocytes [12] and in a cell-free test tube system [13]. 
     SUMMARY 
     With the foregoing in mind, the present invention advantageously provides cerium oxide nanoparticles which are capable of inhibiting tumor cancer cells while being inoffensive to normal cells. As it was described earlier that TGFβ1 increased the intracellular superoxide (O 2   − ) concentration via activation of NAD(P)H oxidase in human lung [14], and skin fibroblasts [4], the effect of CNP in context of prevention of myofibroblast formation and tumor invasion in tumor-stroma interaction was evaluated for skin-derived tumor cells. In an in-vitro cell culture model and dermis equivalent, nanoparticles of cerium oxide exhibit an inhibitory effect on the formation of myofibroblasts. Furthermore, concentrations of cerium oxide being non-toxic on normal cells showed an inhibitory, even cytotoxic and anti-invasive effect on squamous tumor cells. To our knowledge, this is the first report indicating a dual functionality of cerium oxide nanoparticles in tumor-stroma interaction. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
       Some of the features, advantages, and benefits of the present invention having been stated, others will become apparent as the description proceeds when taken in conjunction with the accompanying drawings, presented for solely for exemplary purposes and not with intent to limit the invention thereto, and in which: 
         FIG. 1A  shows the TGFβ1-mediated transition of fibroblasts to myofibroblasts; subconfluent human dermal fibroblasts (HDF) were cultured in control conditioned medium (CMHDF) and treated with rTGFβ1 (5 ng/ml) CMHDF for various periods of time; the amount of αSMA protein was determined by western blot analysis; experiments were performed in triplicate; the abbreviation CM stands for conditioned medium; 
         FIG. 1B  depicts that antioxidants downregulate the TGFβ1-mediated expression of αSMA; subconfluent HDF were cultured in CM HDF  and either untreated or pretreated for 4 h with NAC (5.0 mM) or for 24 h with Na 2 SeO 3  (0.5 μM) before addition of rTGFβ1 (5 ng/ml); TGFβ1 and the antioxidants were present for an additional 48 h; the amount of SMA protein was detected by western blotting; three independent experiments were performed; 
         FIG. 1C  illustrates that antioxidants increase invasion of tumor cells; subconfluent SCL-1 tumor cells were cultured in CM HDF  and either untreated or pretreated for 4 h with NAC (5.0 mM) or for 24 h with Na 2 SeO 3  (0.5 μM); the invasive capacity of these cells was tested with conditioned media of HDF (CM HDF ) and myofibroblasts (CM MF ) as described in Materials and Methods; 
         FIG. 2A  shows ultraviolet-visible spectra depicting the absorbance of cerium oxide nanoparticles synthesized in water and in dextran; the absorbance edge of Ce 3+  lies between 250-350 nm while the absorbance edge of Ce 4+  lies beyond 300 nm; the absorbance of freshly synthesized CNPs in water (open circle) and the CNPs freshly synthesized in dextran (closed circle) is beyond 350 nm signifying the predominance of tetravalent oxidation state in both; slow reduction of CNPs in water is confirmed by the absorbance of CNPs below 350 nm upon aging in water for 7 days (open boxes); the aging of dextran-coated nanoparticles at neutral pH (closed boxes) does not reduce CNPs as the absorbance remains beyond 350 nm post 7 days of aging; 
         FIG. 2B  provides HRTEM image(s) of CNPs; high resolution transmission electron micrographs of dextran stabilized cerium oxide nanoparticles: a) low magnification image depicting the distribution of nanoparticles; b) high magnification micrographs reveal the non agglomerated and uniformly dispersed 3-5 nm nanoparticles; c) and d) high magnification image depicting lattice fringes of CNPs from dispersed 3-5 nm particles; 
         FIG. 2C  shows transmission electron microscopy (TEM) and fluorescence micrograph of CeO 2  nanoparticles; subconfluent fibroblasts (HDF) (a,c) and tumor cells (SCL-1) (b,d) were mock-treated or treated with 150 μM CeO 2 /dextran for 16 h to determine the cellular uptake of nanoceria; fluorescence microscopy to study the subcellular localization of FITC-labeled CNP; human dermal fibroblasts (e) and squamous tumor cells (f) were exposed to FITC-labeled cerium oxide nanoparticles (150 μM) for 24 h and photographed thereafter; 
         FIG. 2D  illustrates distribution of nanoceria (CeO 2 ) in murine skin; eight week CD-1 mice were treated with CeO 2 /dextran nanoparticles and the amount of CeO 2  in skin measured as described in Materials and Methods; the bar graphs represent mean and s.e.m.; 
         FIG. 2E  depicts line graphs showing that CNPs with predominant Ce3+ oxidation state and dextran coated CNPs were SOD active at both neutral and acidic pH while the CNPs with predominant Ce4+ oxidation state were not SOD active; 
         FIG. 2F  provides line graphs showing catalase activity of CNPs, which was tested using Amplex red assay (Invitrogen) as described previously (Chem Comm 2010); the nanoparticles were buffered to pH 3 and 7 to see the effect of pH change on the catalase activity of nanoparticles; as shown in this illustration; catalase activity of dextran coated nanoparticles was reduced by 40% or more in an acidic pH as compared to activity at pH 7; the same trend was observed for CNPs with predominant Ce 4+  oxidation state while CNPs with predominant Ce 3+  oxidation did not show any catalase activity; 
         FIG. 3A  depicts cytotoxicity of CeO 2  on fibroblasts; subconfluent human dermal fibroblasts were treated with different concentrations of CNP; the percentage of living cells was measured after 48 h; three independent experiments were performed; 
         FIG. 3B  shows that nanoceria particles downregulate TGFβ1-mediated mRNA expression of αSMA; total RNA was isolated from cells cultured in CM HDF  and either untreated or pretreated for 24 h with 50 μm or 150 μM CeO 2 /dextran before addition of rTGFβ1 (5 ng/ml); TGFβ1 and the cerium oxide particles were present for an additional 48 h; mRNA copy numbers were determined by quantitative real-time RT-PCR; values are given as ratios of target gene mRNA copy number compared to the housekeeping gene HPRT1 and represent means±s.e.m. from three independent experiments; CM, conditioned medium; 
         FIG. 3C  indicates that αSMA expression in human dermal fibroblasts is inhibited by CNP; subconfluent HDF were cultured in CM HDF  and either mock-treated or pretreated for 24 or 48 h with 150 μM CeO 2 /dextran before addition of rTGFβ1 (5 ng/ml); TGFβ1 and the cerium oxide particles were present for an additional 48 h.; α-tubulin was used as loading control; three independent experiments were performed; CM, conditioned medium; 
         FIG. 3D  shows that CNP inhibit TGFβ1-mediated transdifferentiation in collagen lattices; fibroblasts seeded for 2 d in the dermal equivalent (DE) were mock-treated or treated with 150 μM CNP prior to stimulation with rTGFβ1 (5 ng/ml); the diameter (in cm) of the contracted or non-contracted collagen lattices was used as a measure of the contractile force of the cells; three independent experiments were performed; bar equals 1 cm; 
         FIG. 3E  depicts that CNPs downregulate TGFβ1-mediated mRNA expression of αSMA in dermal equivalents; dermal equivalents were incubated for 2 d with rTGFβ1 (5 ng/ml) or in combination with 150 μM CNP; after collagenase treatment, the dermis was homogenized and 50 μl clear lysate was subjected to western blot analysis for αSMA; α-tubulin was used as a loading control; two independent experiments were performed; cc-GAG, collagen-chitosan-glycosaminoglycan; d, dermis; f, fibroblasts; k, Bar, 25 μm; 
         FIG. 4  shows oxidation of target structures; subconfluent HDF were cultured in CM HDF  and either mock-treated or pretreated for 40 h with 150 μM CeO 2 /dextran before addition of rTGFβ1 (5 ng/ml); TGFβ1 and the CNPs were present for an additional 8 h; H 2 O 2  was used as positive control at a concentration of 250 μM for 1 h; the level of protein oxidation was determined by western blot analysis; α-tubulin was used as loading control; three independent experiments were performed; 
         FIG. 5A  illustrates cytotoxicity of CeO 2  on squamous tumor cells; subconfluent squamous tumor cells (SCL-1) were treated with different concentrations of CeO 2 /dextran (CNP); the percentage of living cells after 48 h was measured; the experiments were performed in three independent experiments; Ct, control (mock-treated); 
         FIG. 5B  shows CNP-mediated inhibition of myofibroblast formation results in downregulation of tumor invasion; conditioned media of HDF (CM HDF ), myofibroblasts (CM MF ) and cells treated with rTGFβ1 and CNP CM HDF,TGF,CNP ) were used for the invasion assays based on matrigel-coated transwells; the total number of tumor cells migrating towards the chemoattractive media over a 48 h time period is a measure of the invasive capacity; the data represent the mean±s.e.m. of three independent experiments; **P&lt;0.01 versus CMMF (ANOVA, Dunnett&#39;s test); 
         FIG. 5C  presents the lowered invasive capacity of CNP-loaded tumor cells; subconfluent SCL-1 tumor cells were cultured in CM HDF  and either mock-treated or pretreated for 24 h with 50 μM or 150 μM CeO 2 ; the invasive capacity of these cells was tested with conditioned media of HDF (CM HDF ) and myofibroblasts (CM MF ); the total number of tumor cells migrating towards the chemoattractive media over a 48 h time period is a measure of the invasive capacity; the data represent the mean±s.e.m. of three independent experiments; **P&lt;0.1 versus CMMF (ANOVA, Dunnett&#39;s test). CM, conditioned medium; 
         FIG. 6A  depicts that nanoceria increase the level of reactive oxygen species (ROS) in tumor cells; subconfluent SCL-1 and HDF were preincubated with 50 μM and 150 μM CeO 2 /dextran for 24 h in CM SCL-1  or CM HDF ; increase of DCF fluorescence as a measure of increase in ROS was followed over 60 minutes versus untreated controls; the experiments were performed in triplicate; CM, conditioned medium; 
         FIG. 6B  shows oxidation of target structures; subconfluent SCL-1 cells were cultured in CM SCL-1  and either mock-treated or treated for 16 h with 150 μM CeO 2 /dextran before oxidized proteins were determined by western blot analysis; H 2 O 2  was used as positive control at a concentration of 250 μM for 1 h.; α-tubulin was used as loading control; three independent experiments were performed; CM, conditioned medium; and 
         FIG. 6C  shows expression of HIF-1 in human dermal fibroblasts HDF and squamous tumor cells SCL-1; representative Western blot demonstrates HIF-1α protein expression in HDF and SCL-1 cells either mock-treated or treated with 100 μM cobalt chloride for 4 h.; α-tubulin was used as loading control; two independent experiments were performed; CM, conditioned medium. 
     
    
    
     DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT 
     The present invention will now be described more fully hereinafter with reference to the accompanying drawings, in which preferred embodiments of the invention are shown. 
     Unless otherwise defined, all technical and scientific terms used herein are intended to have the same meaning as commonly understood in the art to which this invention pertains and at the time of its filing. Although various methods and materials similar or equivalent to those described herein can be used in the practice or testing of the present invention, suitable methods and materials are described below. However, the skilled should understand that the methods and materials used and described are examples and may not the only ones suitable for use in the invention. 
     Moreover, it should also be understood that any temperature, weight, volume, time interval, pH, salinity, molarity or molality, range, concentration and any other measurements, quantities or numerical expressions given herein are intended to be approximate and not exact or critical figures unless expressly stated to the contrary. Hence, where appropriate to the invention and as understood by those of skill in the art, it is proper to describe the various aspects of the invention using approximate or relative terms and terms of degree commonly employed in patent applications, such as: so dimensioned, about, approximately, substantially, essentially, consisting essentially of, comprising, and effective amount. 
     Further, any publications, patent applications, patents, and other references mentioned herein are incorporated by reference in their entirety as if they were part of this specification. However, in case of conflict, the present specification, including any definitions, will control. In addition, the materials, methods and examples given are illustrative in nature only and not intended to be limiting. 
     Accordingly, this invention may be embodied in many different forms and should not be construed as limited to the illustrated embodiments set forth herein. Rather, these illustrated embodiments are provided so that this disclosure will be thorough, complete, and will fully convey the scope of the invention to those skilled in the art. Other features and advantages of the invention will be apparent from the following detailed description, and from the claims. 
     Materials and Methods 
     Cell culture media (Dulbecco&#39;s modified Eagle&#39;s medium (DMEM) was purchased from Invitrogen (Karlsruhe, Germany) and the defined fetal calf serum (FCS gold) was from PAA Laboratories (Linz, Austria). All chemicals including protease as well as phosphatase inhibitor cocktails 1 and 2 were obtained from Sigma (Taufkirchen, Germany) or Merck Biosciences (Bad Soden, Germany) unless otherwise stated. The protein assay kit (Bio-Rad DC, detergent compatible) was from BioRad Laboratories (München, Germany), N-acetyl-L-cysteine (NAC) and sodium selenite were from Merck Biosciences. Matrigel and polycarbonate cell culture inserts (6.5 mm diameter, 8 μm pore size) were delivered from BD Biosciences (Heidelberg, Germany). The Oxyblot Protein Oxidation Detection kit was from Millipore (Schwalbach, Germany). The enhanced chemiluminescence system (SuperSignal West Pico/Femto Maximum Sensitivity Substrate) was supplied by Pierce (Bonn, Germany). Monoclonal mouse antibody raised against human-αSMA and α-tubulin were supplied by Sigma. Polyclonal rabbit antibody raised against human HIF-1 was supplied by New England Biolabs (Frankfurt a.M., Germany). The following secondary antibodies were used: polyclonal horseradish peroxidase (HRP)-conjugated goat anti-mouse IgG antibody (DAKO, Glostrup, Denmark) and anti-rabbit immunoglobulin G antibodies were from Dianova (Hamburg, Germany). Recombinant human TGFβ1 (rTGFβ1) was from R&amp;D Systems (Wiesbaden, Germany). 
     Cell Culture 
     Human dermal fibroblasts (HDF) were established by outgrowth from foreskin biopsies of healthy human donors with an age of 3-6 years. Cells were used in passages 2-12, corresponding to cumulative population doubling levels of 3-27 [15]. Dermal fibroblasts and the squamous carcinoma cell line SCL-1, originally derived from the face of a 74-year-old woman [16] (generously provided by Prof. Dr Norbert Fusenig, DKFZ Heidelberg, Germany), were cultured as described [17]. Myofibroblasts (MF) were generated by treatment of HDFs with different concentrations of recombinant TGFβ1 (5 ng/ml) for 48 h in HDF conditioned medium (CMHDF) [4]. 
     Preparation of Conditioned Medium 
     Conditioned medium was obtained from human dermal fibroblasts (CM HDF ) and myofibroblasts (CM MF ). For this, seeded 1.5×10 6  HDF cells were grown to subconfluence (˜70% confluence) in 175-cm 2  culture flasks. The serum-containing medium was removed, and after washing in phosphate-buffered saline (PBS) the cells were incubated in serum-free DMEM or treated with rTGFβ1 (5 ng/ml) in serum-free DMEM for 48 hours. This medium was removed, and after washing in PBS all cells were incubated in 15 ml serum-free DMEM for a further 48 hours before collection of the conditioned medium of HDF (CM HDF ) and myofibroblasts (CM MF ). 
     To prevent myofibroblast formation, HDF were treated with rTGFβ1 (5 ng/ml) in CM HDF  in combination with CNP for 48 h. The conditioned medium (CM HDF,TGF,CNP ) was collected as described above. Conditioned media were used fresh or stored at −20° C. for at the most 2 weeks before use. 
     Synthesis of Cerium Oxide Nanoparticles 
     Cerium oxide nanoparticles were synthesized in water and in dextran (molecular weight: 1000 Da) using previously described methods. Briefly, cerium nitrate hexahydrate was dissolved in deionized water and the pH of the solution was maintained between 3.5 to 4.0 for water based nanoparticles. Stoichiometric amounts of hydrogen peroxide and ammonium hydroxide were added to oxidize the dissolved cerium ions as cerium oxide nanoparticles (CNPs). The pH of the solution needs to be maintained below 4.0 to avoid precipitation of CNPs. For synthesis of dextran coated nanoparticles stoichiometric amounts of dextran was first dissolved in deionized water followed by cerium nitrate hexahydrate. The solution was stirred for 2 h followed by addition of ammonium hydroxide (30% w/w). The pH of the solution was kept below 9.5 to avoid precipitation of cerium hydroxide. The resulting cerium oxide nanoparticles were analyzed using UV-visible spectroscopy for determining the oxidation state of nanoparticles and transmission electron microscopy for particle size. 
     UV-Visible Spectrophotometry 
     The UV-visible spectral data were obtained using Varian Lambda 750 UV-VIS NIR instrument with a diffuse reflectance detector. The spectra were recorded immediately after the synthesis and after the complete aging treatment of nanoparticles. Deionized water and dextran solution was used as the control for water based CNPs and dextran-stabilized CNPs respectively. The reversal of oxidation state of nanoparticles confirms the presence of higher concentration of CNPs with trivalent oxidation states in water-synthesized nanoparticles. 
     High Resolution Transmission Electron Microscopy (HRTEM) 
     High resolution transmission electron micrographs were obtained using FEI Tecnai F 30 microscope operated at 300 kV with a point-to-point resolution of 0.2 nm. The samples were prepared by depositing a drop of CNP in water and dextran on a carbon coated copper grid. The grids were dried overnight in vacuum before imaging. 
     Cellular Uptake of Nanoparticles 
     Serum-starved human dermal fibroblasts in Dulbecco&#39;s Modified Eagle Medium (DMEM) were treated with 150 μM CeO 2 /dextran for 48 h. Thereafter, cells were harvested and washed with phosphate-buffered saline (PBS) to remove excess media. As CeO 2 /dextran is not detectable by phase contrast microscopy, transmission electron microscopy was used to determine the cellular uptake of nanoceria. For electronmicroscopy, pelleted samples of cerium oxide-treated cells were fixed for 2 h in 4% paraformaldehyde and 2.5% glutaraldehyde (Serva, Heidelberg, Germany) in 0.1 M phosphate buffer at pH 7.4 at room temperature. Next, the pellets were thoroughly washed with four changes of PBS, followed by a postfixation for 60 min in 1% osmium tetroxide (Serva) in the same buffer. The specimens were dehydrated in a graded series of acetone, and embedded in Spurr&#39;s medium (Serva) at 70° C. for 24 h. 
     Ultrathin sections were cut from the embedded tissue with a Reichert Ultracut (Vienna, Austria) using a diamond knife. The sections were collected on coated copper grids, and subsequently stained with uranyl acetate and lead citrate according to earlier published data [18]. The grids were analyzed using a Hitachi H 600 electron microscope. Documentation was carried out by using an optical system and the Digital Micrograph software (Gatan, Munich, Germany). For light microscopical controls semithin section were cut and stained with 1% Toluidine blue and 1% Borax. 
     Injection and Determining Cerium Oxide Nanoparticles in Skin 
     Eight-week-old, CD-1 mice were divided into two groups. Controls were given weekly doses of 100 μl sterile PBS only by intravenous (IV) administration. The nanoceria group received five doses (one dose a week) of 0.5 mg/kg of nanoceria suspended in 100 μl of sterile saline (IV). Both groups were sacrified on the sixth week. Skin tissue from the back of each animal was excised and hair removed. The tissue was patted dry, weighed and placed in 70% nitric acid overnight to start the digestion process. Samples were then microwave digested. The temperature was ramped to 200° C. over 20 min and held there for another 20 min. Samples were then boiled down to less than 1 ml each and reconstituted in water to an exact volume of 10 ml. Cerium levels were assessed using inductively coupled plasma mass spectroscopy (ICP-MS). 
     Cell Viability 
     The cytotoxic effect of cerium oxide nanoparticles (CNP) was measured by the MTT (3-(4,5-Dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide) assay [19]. The activity of mitochondrial dehydrogenases, as indicator of cellular viability, results in formation of a purple formazan dye. Briefly, MTT solution (0.5 mg/ml) was added to the cell cultures treated for various times with the nanoparticles. The cells were incubated for an additional 1 hour. The medium was removed and the cells were lysed in dimethyl sulfoxide. Formazan formation was measured at 570 nm. The results were shown as a percentage of mock-treated control which was set at 100%. 
     RNA Isolation and Quantitative Real-Time RT-PCR 
     Total RNA was isolated and transcribed into cDNA as described [20]. Expression of mRNA was analyzed by real-time RT-PCR using a LightCycler system (Roche; Mannheim, Germany) as described [20]. Real-time RT-PCR was performed with 40 ng cDNA in glass capillaries containing LightCycler FastStart DNA Master SYBR Green I Reaction Mix (Roche), 2 mM MgCl2 and 1 μM of primers. Quantitation of the PCR amplicons was performed using the LightCycler Software. Hypoxanthine phosphoribosyltransferase (HPRT1) was used as internal normalization control [21]. Sequences of primer pairs are given in Table 1. 
     SDS-PAGE and Western Blotting 
     SDS-PAGE was performed according to the standard protocols published elsewhere [22] with minor modifications. Briefly, cells were lysed after incubation with rTGFβ1 in 1% SDS with 1:1000 protease inhibitor cocktail (Sigma; Taufkirchen, Germany). After sonication, the protein concentration was determined by using a modified Lowry method (Bio-Rad DC). 2×SDS-PAGE sample buffer (1.5 M Tris-HCl pH 6.8, 6 ml 20% SDS, 30 ml glycerol, 15 ml β-mercaptoethanol and 1.8 mg bromophenol blue was added, and after heating, the samples (10 μg total protein/lane) were applied to 10% (w/v) SDS-polyacrylamide gels. After electroblotting, immunodetection was carried out (1:1000 dilution of primary antibodies (mouse monoclonal anti-SMA and tubulin), 1:20000 dilution of anti-mouse antibody conjugated to HRP). Antigen-antibody complexes were visualized by an enhanced chemiluminescence system. Alpha-tubulin was used as internal control for equal loading. 
     Preparation of Collagen Lattices and Dermal Equivalents 
     Three-dimensional collagen lattices were prepared as described [23] with minor modifications. Briefly, type I collagen from rat tail tendon was redissolved at 3.2 mg/ml in sterile 0.2% acetic acid. Human dermal fibroblasts were seeded at 1.25×10 5  cells/ml into a NaOH-neutralized solution containing 0.8 mg collagen/ml 1×DMEM with 5% FCS and grown for 24 h at 37° C. in 3.5-cm-diameter uncoated bacterial culture dishes. Cells in that mechanically relaxed lattices were allowed to contract the gel matrix. The medium was replaced by serum-free medium or serum-free medium containing non-toxic concentrations of CNP, and the collagen lattices incubated for a further 24 h before addition of recombinant TGFβ1. After 48 h each collagen lattice was photographed and the diameter (in cm) used as a measure of the contractile force of the (myo)fibroblasts. 
     The dermal equivalents (DE) were prepared as previously described [24, 25]. Briefly, a suspension of 2×105 dermal fibroblasts/cm 2  was added in each well of a 24-well plate on top of a collagen-chitosan-glycosaminoglycan (cc-GAG) biopolymer and the DE was cultured for 14 d in DMEM plus 10% FCS containing 50 μg/ml ascorbic acid under submerged conditions in a humidified atmosphere. The medium was changed every 2 d. DE were fixed in 4% paraformaldehyde and embedded in paraffin. Sections of 6 μm thickness were stained using hematoxylin-eosin (HE). In addition, DE were incubated for 2 d with recombinant TGFβ1 or in combination with 150 μM CNP. Thereafter, the DE were washed in PBS and digested with 3 mg  Clostridium histolyticum  collagenase/ml PBS for 30-45 min at 37° C. After centrifugation, the cells were lysed with 1:1000 diluted protease and phosphatase inhibitors and subjected to western blot analysis. 
     Invasion Assay 
     Cell culture inserts (transwells) were overlaid with 125 μg/ml growth factor reduced Matrigel and placed in a 24-well plate. SCL-1 tumor cells (5×10 4  cells/insert) either mock-treated or pretreated with antioxidants (NAC, selenite) or CNP were seeded on top of the matrigel in serum-free DMEM. CM HDF , CM MF . or CM HDF,TGF,CNP  (see above) were used as chemoattractant in the lower chamber. After 72 h at 37° C., the tumor cells were rubbed off the upper side of the filter using cotton swabs, and the SCL-1 cells, which invaded to the lower side of the insert, were stained with Coomassie Blue solution (0.05% Coomassie Blue, 20% MeOH, 7.5% acetic acid). The number of invaded cells was estimated by counting 25 random microscopic fields/insert. 
     Determination of Oxidized (Carbonylated) Proteins Oxyblot Analysis 
     Dermal fibroblasts or tumor cells were grown to subconfluence on tissue culture dishes. After removal of serum-containing medium, HDF were cultured in CM HDF  and either mock-treated or pretreated for 40 h with 150 μM CeO 2  nanoparticles prior to addition of 10 ng rTGFβ1/ml for additional 8 h. Tumor cells were mock-treated or treated with 150 μM CNP for 16 h. As positive control, the cells were treated with 250 μM H 2 O 2  for 1 h. Thereafter, cells were lysed and carbonyl groups of oxidized proteins were detected with the OxyBlot™ Protein Oxidation Detection Kit, following the manufacturer&#39;s protocol. Briefly, the protein concentration was determined by using a modified Lowry method (Bio-Rad DC). The protein amounts of the samples were aligned. 5 μg of this cell lysate was incubated with 2,4-dinitrophenyl (DNP) hydrazine to form the DNP hydrazone derivatives. Labeled proteins were separated by SDS-PAGE and immunostained using rabbit anti-DNP antiserum (1:500) and goat anti-rabbit IgG conjugated to horseradish peroxidase (1:2000). Blots were developed by enhanced chemiluminescence. 
     Measurement of Intracellular ROS 
     Generation of ROS was determined using 2′,7′-Dichlorodihydrofluorescein diacetate (H 2 DCF-DA), a dye that diffuses across the lipid membranes into cells and is subsequently oxidized by intracellular ROS forming the highly fluorescent DCF. Subconfluent HDF and SCL-1 tumor cells were exposed to 50 μM or 150 μM CNP in serum-free DMEM in 24-well plates. Untreated subconfluent SCL-1 cells were used as negative controls. Medium was substituted after 24 h by 100 μM H2DCF-DA containing Hanks Balanced Salt Solution (HESS). DCF fluorescence was detected at an excitation wavelength of 485 nm and emission wavelength of 520 nm in 15 minutes intervals in a FLUOstar OPTIMA plate reader (BMG Labtech, Offenburg, Germany). Mean fluorescence intensities and standard error of mean were determined for each reading point by using the statistical software Prism 3.0 (GraphPad, San Diego, Calif., USA). 
     Statistical Analysis 
     Means were calculated from at least three independent experiments, and error bars represent standard error of the mean (s.e.m.). Analysis of statistical significance was done by Student t test or ANOVA with *P&lt;0.05, **P&lt;0.01, and ***P&lt;0.001 as levels of significance. 
     Table 1 Sequences of Primers for real-time RT-PCR 
     Genes Primer (5′-3′) 
     αSMA Forward: CTGTTCCAGCCATCCTTCAT (SEQ ID NO: 1) 
     Reverse: TCATGATGCTGCTGTTGTAGGTGGT (SEQ ID NO: 2) 
     HPRT1 Forward: ATTCTTTGCTGACCTGCTGGATT (SEQ ID NO: 3) 
     Reverse: CTTAGGCTTTGTATTTTGCTTTTC (SEQ ID NO: 4) 
     Results 
     This study focused on the progression of tumors and the importance of invasion during tumor-stroma interaction. Tumor cells continuously modulate the stromal microenvironment, which is important for tumor invasion [2]. Fibroblasts are basically involved in the process leading to invasion of tumor cells in the skin [1,4]. 
     TGFβ1-Mediated Formation of Myofibroblasts 
     It is described that reactive oxygen species are important for many pathological processes like tumor invasion and inflammation. It is known that TGFβ1 initiates a ROS-triggered mesenchymal-mesenchymal transition (MMT) of human dermal fibroblasts to myofibroblasts [4]. Antioxidants downregulate the TGFβ1-dependent expression of αSMA. A time course analysis of TGFβ1-mediated αSMA expression in human dermal fibroblasts was performed. αSMA protein levels were measured in subconfluent fibroblast monolayer cultures in control conditioned medium (CM HDF ) or after treatment with recombinant TGFβ1 for 8 to 48 h. Treatment of HDF with recombinant TGFβ1 resulted in a significant time-dependent increase in the αSMA protein amount starting at 16 h post treatment compared with mock-treated control cells ( FIG. 1A ). 
     TGFβ1 increased the intracellular concentration of reactive oxygen species [26]. Therefore, we addressed the question of whether ROS modulate induction of αSMA. Again, a significant increase in TGFβ1-initiated αSMA protein levels was detected compared with mock-treated controls ( FIG. 1B ). By contrast, N-acetyl-L-cysteine and selenite either completely prevented (NAC) or significantly lowered (selenite) the TGFβ1-triggered upregulation of αSMA protein levels at 48 h after treatment with the growth factor. Incubation of HDF with the antioxidants alone did not affect αSMA expression compared with mock-treated controls (data not shown). 
     Antioxidants Increase Invasive Capacity of Tumor Cells 
     As classical antioxidants and the micronutrient selenium prevent tumor cell-mediated formation of myofibroblasts which support the invasion of tumor cells [4], the question was addressed of whether the direct treatment of tumor cells with that antioxidants affect tumor invasion. Therefore, cells of the squamous tumor cell line SCL-1 (or the melanoma cell line A375; data not shown) were incubated with antioxidants like N-acetyl-L-cysteine or selenite. The invasive capacity of treated cells and mock-treated cells was tested after a 48 h incubation period. The conditioned medium of myofibroblasts (CM MF ) resulted in a 2-fold increase in the number of invading tumor cells compared to CM HDF -treated cells. Interestingly, the invasive capacity of SCL-1 cells was further increased by NAC and selenite. A 2.5- to 3.5-fold increase in the number of invading tumor cells was observed compared to CM MF  ( FIG. 1C ). In conclusion, the antioxidant NAC and the micronutrient selenite promote tumor invasion, if the tumor cells are in direct contact with the antioxidants. Even though antioxidants are beneficial in context of prevention of myofibroblast formation, they appear to be harmful in context of tumor cell migration and invasion, respectively. As in tumor-stroma interaction in vivo the stromal cell and cancer cell are not available separately, alternative substances protecting stromal cells and preventing tumor cell invasion or even kill tumor cells would be a valuable tool for a therapeutical approach. 
     Characterization of CeO 2  Nanoparticles 
     As cerium oxide based nanoparticles (CNP) have been shown to have prooxidant or antioxidant activity depending on the environmental pH [27], the effect of CNP on stromal and tumor cells was investigated herein. The absorbance edge of Ce 3+  lies between 250-350 nm while the absorbance edge of Ce 4+  lies beyond 350 nm. The absorbance of freshly synthesized CNP in water (open circle) and in dextran (closed circle) is beyond 350 nm indicating the predominance of tetravalent oxidation state (Ce 4+ ) in both preparations ( FIG. 2A ). Slow reduction of CNP in water (open boxes) is confirmed by the absorbance of CNP below 350 nm (dotted line) upon aging in water for 7 d reflecting a change in the ratio of Ce 3+ /Ce 4+  towards Ce 3+ . The aging of nanoparticles in dextran does not reduce CNP as the absorbance remains beyond 350 nm post 7 d of aging (closed boxes), indicating a stable Ce 3+ /Ce 4+  ratio at neutral pH. Therefore, for further studies the stable dextran-coated cerium oxide nanoparticles were used. 
       FIG. 2B  shows a representative low magnification image depicting the distribution of nanoparticles (a). The high magnification micrographs reveal the non agglomerated and uniformly dispersed 3-5 nm nanoparticles (b) while (c) and (d) depict the high magnification lattices from dispersed 3-5 nm CNP. 
     Superoxide Dismutase and Catalase Activity of Cerium Oxide Nanoparticles 
     The SOD mimetic activity of CNPs was tested as described previously (Chem Comm 2007, Biomaterials 2008). In addition the nanoparticles were buffered to pH 3 and 7 to determine the effect of change in pH on the SOD activity of nanoparticles. Three different sets of nanoparticles were tested: viz. CNPs with predominant Ce 3+  oxidation state, with predominant Ce 4+  oxidation state and dextran-coated nanoparticles (mixed oxidation state). It can be observed from  FIG. 2E  that CNPs with predominant Ce 3+  oxidation state and dextran coated CNPs were SOD active at both neutral and acidic pH while the CNPs with predominant Ce 4+  oxidation state were not SOD active. 
     The catalase activity of CNPs was tested using Amplex red assay (Invitrogen) as described previously (Chem Comm 2010). Additionally the nanoparticles were buffered to pH 3 and 7 to observe any effect in the catalase activity of nanoparticles. As seen from  FIG. 2F  the catalase activity of dextran coated nanoparticles was reduced by 40% or more in acidic pH as compared to the activity at pH 7. The same trend was observed for CNPs with predominant Ce 4+  oxidation state while CNPs with predominant Ce 3+  oxidation did not show any catalase activity consistent with our previously obtained results (Chem Comm 2007, Chem Comm 2010 and Biomaterials 2008). 
     CNP Distribution in Cell Culture and In Vivo 
     Transmission electron microscopy (TEM) was used to follow the cellular uptake of CNP. The TEM micrographs of human dermal fibroblasts (a, c) and SCL-1 tumor cells (b, d) show an uptake of the CeO 2  nanoparticles at 16 h upon treatment (c, d) compared to mock-treated controls (a, b) ( FIG. 2C ). However, the size of the incorporated CNP was measured to be 50 nm based on the scale of the micrographs. As the size of the added CNP primarily was about 5 nm ( FIG. 28 ), the nanoparticles at least in part agglomerated in the cells. CNP smaller than 50 nm could not be seen under commonly used experimental conditions. In order to follow more precisely the distribution of the intracellular particles, fluorescent dye-labeled CNP were used. After incubation of fibroblasts and tumor cells with fluorescein-isothiocyanate (FITC)-labeled CNP, a broad fluorescent staining of the cells was observed. The CNP were ubiquitously distributed in the cytosol ( FIG. 2C ; E, F). To ensure that the FITC fluorescence really reflected incorporated CNP and was not due to absorption on the cell surface, the cells were washed and passaged. The nanoparticles were still detectable (data not shown). 
     In another set of experiments the distribution of cerium oxide nanoparticles in the skin of a murine model was established.  FIG. 2D  shows an increased CeO 2  amount in the skin of the mice after six weeks of supplementation. In comparison to mock-treated mice, an up to 8-fold increase in the amount of CeO 2  per gram skin tissue was detected in CNP-treated mice. 
     Results 
     Cytotoxicity of Cerium Oxide Nanoparticles on Fibroblasts 
     Recent studies deal with a free radical scavenging mechanism of CNP in mammalian cells. CeO 2  particles of less than 20 nm have been shown to increase cellular survival [28]. Herein, the MTT assay was used to determine optimal concentrations at which more than 80% of dermal fibroblasts survived at least 48 h after incubation with no change in morphology. Concentrations up to 300 μM did not show any cytotoxic effect at 48 h after CNP incubation ( FIG. 3A ). No change in morphology was observed (data not shown). Compared to mock-treated cells, significant toxicity of the CeO 2  particles was not detected (p&lt;0.5, ANOVA). 
     Cerium Oxide Nanoparticles Prevent Myofibroblast Formation. 
     It has previously been suggested that CeO 2  nanoparticles may exert cytoprotective effects based on the chemical properties of that material [29-31]. we performed real-time RT-PCR to study the effect of CNP on levels of αSMA mRNA in human dermal fibroblasts. The ‘housekeeping’ gene HPRT was used as internal control. TGFβ1 caused a 10-fold increase in αSMA steady-state mRNA levels at 24 h after treatment compared to mock-treated controls. Preincubation with non-toxic concentrations of CNP significantly counteracted the TGFβ1-initiated transcription of αSMA mRNA ( FIG. 3B ). These data correlated with the αSMA protein amount ( FIG. 3C ). The increase in the TGFβ1-triggered αSMA protein levels at 24 or 48 h upon treatment was almost completely abrogated by the application of CNP compared to TGFβ1 or TGFβ1 plus dextran treated cells ( FIG. 3C ). 
     Three-dimensional free-floating collagen gels [32,33] were used to exclude an artificial effect of TGFβ1 and CNP due to cells in monolayer cultures. Cells in that mechanically released lattices were allowed to contract them. The occurrence of myofibroblasts is characterized by their capability to contract the free-floating collagen gel ( FIG. 3D ). A decrease in the area and diameter of the collagen gel is inversely proportional to the increase in the number of myofibroblasts [34,35]. Compared to the collagen lattices of untreated (a) or CNP-treated fibroblasts (b), the diameter of the lattices treated with TGFβ1 (c) was significantly lowered after 4 d of contraction, reflecting the existence of myofibroblasts. Treatment of the fibroblasts located in the collagen gels with CNP prior to TGFβ1 application (d) resulted in a marginal contraction of the collagen lattices compared to untreated controls, which corresponded with a significantly lowered expression of αSMA. 
     These data were confirmed by preincubation of the fibroblasts with CNP in a 3-dimensional dermal equivalent (DE) [26] ( FIG. 3E ). The contraction in that model is prohibited by the used extracellular matrix. Therefore, the DE resembles the dermis under physiological conditions in vivo. Normal human skin characteristics were apparent in paraffin sections of dermal equivalents stained with hematoxylin-eosin (HE) ( FIG. 3E ), which is in line with previously published data [26]. Treatment of fibroblasts with TGFβ1 in conditioned medium (CMHDF) resulted in a significant increase in αSMA protein levels compared to mock-treated cells ( FIG. 3E ). Furthermore, the DE was incubated with CNP prior to TGFβ1 treatment. CNP prevented the increase in αSMA protein amount by about 60%. The data obtained with the dermis equivalents agree with data from the monolayer cell cultures, indicating the prevention of TGFβ1-mediated fibroblast to myofibroblast transition by CNP in a more complex system resembling the human dermis. 
     Oxidation of Proteins by TGFβ1-Mediated Reactive Oxygen Species 
     ROS can directly generate damage in DNA, lipids and proteins. As TGFβ1 initiates the reactive oxygen species-dependend expression of αSMA [4], the effect of CNP on ROS production was studied. An increase in the concentration of intracellular ROS leads to oxidized (carbonylated) proteins, a hallmark of oxidative stress [36]. The question was addressed of whether CNP prevent TGFβ1-mediated production of ROS and consequently avoid the oxidation of proteins. In mock-treated fibroblasts (CM HDF ) a low amount of oxidized proteins was detected whereas in TGFβ1-treated cells the amount of oxidized proteins was significantly increased ( FIG. 4 ). Treatment of CNP significantly lowered the TGFβ1-mediated protein oxidation. Hydrogen peroxide was used as positive control ( FIG. 4 ). 
     Cytotoxicity of Cerium Oxide Nanoparticles on Squamous Tumor Cells 
     As tumor progression is associated with activation of the stroma via molecular crosstalk between tumor cells and stromal cells, we studied the effect of CNP on the squamous tumor cell line SCL-1. The MTT assay was used to determine concentrations at which SCL-1 tumor cells show cytotoxicity.  FIG. 5A  shows the viability of the SCL-1 cells after incubation with different concentrations of CNP after 48 h. Treatment of the tumor cells with CNP at a concentration of 150 μM, resulting in no loss of viability of dermal fibroblasts (see  FIG. 3A ), led to a significant toxicity for tumor cells. More than 50% of the tumor cells were sensitive to cell killing at that concentration ( FIG. 5A ). Similar data were obtained by A375 melanoma cells (data not shown). A concentration of 250 μM CeO2 nanoparticles did not increase the cytotoxicity at 48 h post treatment. However, a fraction of 50% of the tumor cells still survived at that experimental conditions. These cells were used for invasion studies. 
     Involvement of CNP in Tumor Invasion 
     Prevention of transdifferentiation by antioxidants inhibits the myofibroblast-mediated increase in tumor invasion [4]. Myofibroblasts were found at the invasion front of some tumors [37], suggesting that myofibroblasts are involved in processes of tumor invasion and metastasis. In this study we tested whether the invasive capacity of tumor cells may be modulated by CNP-dependent inhibition of myofibroblast formation. The formation of myofibroblasts was prevented by treatment of subconfluent HDF cultures in CM HDF,TGF  with CNP. After treatment of HDF with different concentrations of CNP and TGFβ1, the medium was replaced by serum-free DMEM for an additional 48 hours. These media (CM HDF,TGF,CNP ) were used for invasion assays ( FIG. 5B ). Compared with the medium from mock-treated cells (CM HDF ) conditioned medium from myofibroblasts (CM HDF,TGF ) led to a 2.2-fold increase in the invasive capacity of SCL-1 tumor cells. CM HDF,TGF,CNP  resulted in a 70% lowered invasive capacity of the squamous tumor cells compared with CM HDF,TGF , suggesting that CNP play a role in lowering the invasive capacity of tumor cells. 
     Furthermore, the question was addressed whether the direct treatment of tumor cells with CNP affects tumor invasion. Therefore, squamous tumor cells SCL-1 were incubated with different concentrations of CNPs. Fourty-eight hafter treatment the invasive capacity of these SCL-1 cells and mock-treated control cells were tested with conditioned media from HDF (CM HDF ) and from myofibroblasts (CM MF ) ( FIG. 5  C). The invasive capacity of tumor cells is modulated by CNPs. Compared to mock-treated cells, the invasive capacity of CNP-preincubated SCL-1 cells was significantly lowered. In conclusion, CNP inhibit tumor invasion, if either the tumor cells are in direct contact with the nanoparticles ( FIG. 5C ) or the formation of myofibroblasts is prevented by CNP ( FIG. 5B ). 
     Oxidation of Proteins by CNP-Initiated Reactive Oxygen Species in Tumor Cells. 
     As a modulation of intracellular ROS levels by nanoparticles is suggested, we studied the effect of CNP on ROS production in the squamous SCL-1 cell line and human dermal fibroblasts (HDF). Therefore, time-course analysis of ROS generation after treatment with CNP of subconfluent HDF or SCL-1 cells was performed ( FIG. 6A ). Incubation of the tumor cells with CNP resulted in a significant increase in dichlorofluorescein (DCF) staining compared to mock-treated cells which was maintained over the studied time range. This suggests that CNP increases intracellular ROS level in SCL-1 cells. By contrast, no increase in ROS levels was measured in HDF after CNP treatment compared to untreated controls. Interestingly, the mock-treated HDF had a significant lower level of intracellular ROS compared to mock-treated SCL-1 tumor cells. A non-toxic concentration of 250 μM H 2 O 2  which was used as technical control, further increased the intracellular ROS level (data not shown). Furthermore, a CNP-initiated and ROS-mediated oxidation of proteins was studied. Indeed, the amount of oxidized proteins was significantly increased in CNP-treated cells ( FIG. 6B ) compared to mock-treated SCL-1 cells. Hydrogen peroxide was used as positive control resulting in an increase in oxidized proteins. These data support the hypothesis that CNP has a prooxidant effect in tumor cells. 
     Accumulation of Hypoxia-Inducible Factor 1 (HIF-1) 
     Hypoxia-inducible factor 1 (HIF-1) is a heterodimeric transcription factor playing a critical role in tumor cells [38]. HIF-1 is highly expressed in tumor cells but having a high turnover rate as well. The factor is rapidly degraded by the proteasomal pathway. Hypoxic conditions or chemical inhibitors of the hydroxylases, such as cobalt, inhibit HIF-1 degradation and stabilize its expression. Treatment of SCL-1 cells with a non-toxic concentration of 100 μM cobalt chloride for 4 h resulted in a significant increase in HIF-1 protein levels compared to mock-treated cells ( FIG. 6C ). HDF showed no HIF-1 protein expression and were not affected by cobalt chloride. 
     Discussion 
     With the rapidly increasing number of publications on the health effects of nanomaterials, nanoparticles have drawn attention to their potential harmful effects [39]. The unique properties of these materials such as large specific area and greater reactivity resulted in questions regarding potential toxicological effects [40]. Even though the potential cytotoxic effects of nanoparticles on human health are controversially discussed, a few preliminary studies have demonstrated toxic effects [41,42]. On the other hand, some types of nanoparticles, for example cerium oxide based nanoparticles (CNP, nanoceria), seem to have more beneficial effects. Due to the valence and oxygen defect properties and their unique ability to switch oxidation states between III (Ce 3+ ) and IV (Ce 4+ ), CNP are described to have antioxidant activity (12,43]. As other data postulate a prooxidant mechanism of CNP in human cells depending on the structure as well as exogenous and endogenous conditions [11,44], the question was addressed in our study of whether that discussed bifunctional character may be used as a therapeutical tool in tumor-stroma interaction. In skin cancer, tumor cells interact with their cellular microenvironment, such as (stromal) fibroblasts [1,2,4]. The data herein showed that non-toxic concentrations of dextran-coated CNP with a size of 3-5 nm in diameter prevent the TGF 1-initiated and ROS-triggered expression of αSMA, a biomarker of myofibroblasts. Furthermore, the invasive capacity of tumor cells was dramatically lowered by inhibition of myofibroblast formation via CNP. That finding is in line with the prevention of myofibroblast formation by classical antioxidants and subsequent inhibition of tumor invasion [4,37]. Therefore, our data indicate an antioxidant mechanism of CNP in fibroblasts which is underlined by a CNP-dependent lowering of oxidized proteins. As TGF 1 increases the intracellular superoxide (O 2− ) level [4,14] and CNP exerts a superoxide dismutase (SOD) mimetic activity under a neutral pH, the conclusion seems likely that the ROS-triggered formation of myofibroblasts is inhibited by CNP. In that context, the intracellular production of O 2−  by incubation of dermal fibroblasts with the redox cycling agent paraquat (Pe) was prevented by pretreatment of the cells with CNP (data not shown). Recently, it was shown that CNP with a size &gt;300 nm in diameter and a &gt;10-fold higher concentration induced ROS-dependent DNA damage towards human dermal fibroblasts in vitro [44]. In conclusion, a non-toxic and even protective antioxidant effect of CNP from the dominating influence of tumor cell-derived soluble factors (e.g. TGF 1) depends on particle size, concentration, and oxidation state. The oxidation state IV was demonstrated to detoxify O 2−  [43,45] resulting in a shift of the Ce 3+ /Ce 4+ -ratio towards oxidation state III. 
     In this study, the direct treatment of tumor cells with concentrations of CNP which are non-toxic for (stromal) fibroblasts increased the intracellular ROS level leading to cellular toxicity and lowered invasive capacity. The elevated amount of ROS is mediated by the mixed valence states of Ce 3+  and Ce 4+  on the surface of the nanoceria and depends on the pH value. Earlier published data [27, 46] convincingly showed that the cerium oxide nanoparticles trigger a Fenton-like reaction, if O 2−  or H 2 O 2  are available which was described for tumor cells [7, 38] and showed herein. As a result, more aggressive ROS types such as hydroxyl (HO.) and hydroperoxyl (HO 2 .) radicals are generated which damage the cells. The autocatalytic and autoregenerative capacity of CNP (Ce 3+             Ce 4+           Ce 3+ ) given under physiological pH conditions is abrogated under an acidic pH. Here, the ratio of Ce 3+ /Ce 4+  is rapidly shifted to an irreversible higher concentration of Ce 3+ . Transmittance curves underline that hypothesis [46]. As a result, less Ce 4+  is available per time for a potential antioxidant and detoxifying reaction and a prooxidant reaction is boosted in tumor cells.
     What is the reason for a lowered pH in tumor cells? More than 50 years ago, the Nobel prize laureate Otto Warburg described that cancer cells greedily consume glucose and produce lactic acid even under aerobic conditions resulting in an acidic cytosolic pH. This phenomenon is called the ‘Warburg effect’ [47,48]. Recently, the Warburg effect, which is part of the concept of metabolic remodelling in tumor cells, returns to the cancer stage [49, 50]. A continuously elevated concentration of reactive oxygen species in tumor cells (see  FIG. 6 ) may be the trigger for HIF1α expression and stabilization. HIF1α was recently described as key regulator of the metabolic remodelling resulting, for example resulting in enhanced glycolysis and lactate production [38,50]. An elevated HIF1α level was detected in our study herein which fits to earlier published data and may explain the prooxidant mechanism of CNP in tumor cells. 
     In summary, this study is the first to show that cerium oxide nanoparticles have a dual function in tumor-stroma interaction, namely beneficial for stromal cells and harmful for tumor cells, based on the Warburg effect. Nanoceria reveal an inhibitory effect on the formation of myofibroblasts. Furthermore, concentrations of cerium oxide being non-toxic on normal (stromal) cells (e.g. fibroblasts) showed an inhibitory, even ROS-dependent cytotoxic and anti-invasive effect on squamous tumor cells. The understanding of the interaction between tumor cells, its surrounding stroma and engineered nanoparticles could result in novel therapeutic strategies to combat metastatic spread more efficiently in the future. 
     Accordingly, in the drawings and the above specification there have been disclosed typical preferred embodiments of the invention and although specific terms may have been employed, the terms are used in a descriptive sense only and not for purposes of limitation. The invention has been described in considerable detail with specific reference to these illustrated embodiments. It will be apparent, however, that various modifications and changes can be made within the spirit and scope of the invention as described in the foregoing specification and as defined in the appended claims. 
     REFERENCES CITED 
     
         
         [1] de Wever, O. &amp; Mareel, M. Role of tissue stroma in cancer cell invasion. J. Pathol. 200, 429-447 (2003). 
         [2] Liotta, L. A. &amp; Kohn, E. C. The microenvironment of the tumour-host interface. Nature 411, 375-379 (2001). 
         [3] Pupa, S. M. et al. New insights into the role of extracellular matrix during tumor onset and progression. J. Cell. Physiol. 192, 259-267 (2002). 
         [4] Cat, B, et al. Enhancement of tumor invasion depends on transdifferentiation of skin fibroblasts mediated by reactive oxygen species. J. Cell Sci. 119, 2727-2738 (2006). 
         [5] Kunz-Schughart, L. A. Knuechel R. Tumor-associated fibroblasts (part II): functional impact on tumor tissue. Histol. Histopathol. 17, 623-637 (2002). 
         [6] Desmouliere, A. et al. The stroma reaction myofibroblast: a key player in the control of tumor cell behavior. Int. J. Dev. Biol. 48: 509-517 (2004). 
         [7] Cerutti, P. et al. The role of the cellular antioxidant defense in oxidant carcinogenesis. Environ. Health Perspect. 102, 123-129 (1994). 
         [8] Freitas, R. A. What is nanomedicine? Nanomedicine 1, 2-9 (2005) 
         [9] Barry, S. E. Challenges in the development of magnetic particles for therapeutic applications. Int. J. Hyperth. 24, 451-466 (2008). 
         [10] Corchero, J. L. Villaverde, A. (2009) Biomedical applications of distally controlled magnetic nanoparticles. Trends Biotechnol. 27, 468-476 (2009). 
         [11] Lin, W. et al. Toxicity of Cerium Oxide Nanoparticles in Human Lung Cancer Cells. Int. J. of Toxicol. 25, 451-457 (2006). 
         [12] Karakoti, A. S. et al. Nanoceria as Antioxidant: Synthesis and Biomedical Applications. JOM 60, 33-37 (2008). 
         [13] Karakoti, A. S. et al. PEGylated Nanoceria as Radical Scavenger with Tunable Redox Chemistry. J. Am. Chem. Soc. 131, 14144-14145 (2009). 
         [14] Thannickal, V. J. Fanburg, B. L. Reactive oxygen species in cell signaling. Am. J. Physiol. Lung Cell Mol. Physiol. 279, L1005-L1028 (2000). 
         [15] Bayreuther K. et al. Terminal differentiation, aging, apoptosis, and spontaneous transformation in fibroblast stem cell systems in vivo and in vitro. Ann. N. Y. Acad. Sci. 663, 167-179 (1992). 
         [16] Boukamp, P. et al. Phenotypic and genotypic characteristics of a cell line from a squamous cell carcinoma of human skin. J. Natl. Cancer Inst. 68, 415-427 (1982). 
         [17] Stuhlmann, D. et al. Modulation of homologous gap junctional intercellular communication of human dermal fibroblasts via a paracrine factors generated by squamous tumor cells. Carcinogenesis 24, 1737-1748 (2003). 
         [18] Reynolds, E. S. The use of lead citrate at high pH as electron opaque stain in electron microscopy. J. Cell Biol. 17, 208-212 (1963). 
         [19] MoαSMAnn, T. Rapid colorimetric assay for cellular growth and survival: application to proliferation and cytotoxicity assays. J. Immunol. Methods 65, 55-63 (1983). 
         [20] Speckmann, B. et al. Selenoprotein P expression is controlled through interaction of the coactivator PGC-1alpha with FoxO1a and hepatocyte nuclear factor 4alpha transcription factors. Hepatology 48, 1998-2006 (2008). 
         [21] Nishimura, M. et al. Effects of prototypical drug-metabolizing enzyme inducers on mRNA expression of housekeeping genes in primary cultures of human and rat hepatocytes. Biochem. Biophys. Res. Commun. 346, 1033-1039 (2006). 
         [22] Laemmli, U K. Cleavage of structural proteins during the assembly of the head of bacteriophage T4. Nature 227, 680-685 (1970). 
         [23] Mauch, C. et al. Regulation of collagen synthesis in fibroblasts within a three-dimensional collagen gel. Exp. Cell Res. 178, 493-503 (1988). 
         [24] Damour, O. et al. A dermal substrate made of collagen-GAG-chitosan for deep burn coverage: first clinical uses. Clin. Mater. 15, 273-276 (1994). 
         [25] Schlotmann, K. et al. Cosmetic efficacy claims in vitro using a three-dimensional human skin model. Int. J. Cosmet. Sci. 23, 309-318 (2001). 
         [26] Stuhlmann, D. et al. Paracrine effect of TGF-beta1 on downregulation of gap junctional intercellular communication between human dermal fibroblasts. Biochem. Biophys. Res. Commun. 319, 321-326 (2004). 
         [27] Heckert, E. G. et al. Fenton-like reaction catalyzed by rare earth inner transition metal cerium. Environ. Sci. Technol. 42, 5014-5019 (2008). 
         [28] Rzigalinski, B. A. et al. Radical nanomedicine. Nanomedicine 1, 399-412 (2006). 
         [29] Chen, J. et al. Rare earth nanoparticles prevent retinal degeneration induced by intracellular peroxides. Nat. Nanotechnol. 1:142-150 (2006) 
         [30] Schubert, D. et al. Cerium and yttrium oxide nanoparticles are neuroprotective. Biochem. Biophys. Res. Commun. 342, 86-91 (2006). 
         [31] Tarnuzzer, R. W. et al. Vacancy Engineered Ceria Nanostructures for Protection from Radiation-Induced Cellular Damage. Nano Lett. 5, 2573-2577 (2005). 
         [32] Treiber, N. et al. Overexpression of manganese superoxide dismutase in human dermal fibroblasts enhances the contraction of free floating collagen lattice: implications for ageing and hyperplastic scar formation. Arch. Dermatol. Res. 301, 273-287 (2009) 
         [33] Kessler, D. et al. Fibroblasts in mechanically stressed collagen lattices assume a “synthetic” phenotype. J. Biol. Chem. 276, 36575-36585 (2001). 
         [34] Arora, P. D. McCulloch, C. A. Dependence of collagen remodelling on alpha-smooth muscle actin expression by fibroblasts. J. Cell. Physiol. 159, 161-175 (1994). 
         [35] Ljinen, P. et al. Transforming growth factor-beta 1 promotes contraction of collagen gel by cardiac fibroblasts through their differentiation into myofibroblats. Methods Find. Exp. Clin. Pharmacol. 25, 79-86 (2003). 
         [36] Levine, R. L. et al. Carbonyl assays for determination of oxidatively modified proteins. Methods Enzymol. 233, 346-357 (1994). 
         [37] de Wever, O. Mareel, M. Role of myofibroblasts at the invasion front. Biol. Chem. 383, 55-67 (2002). 
         [38] Nadege, D. et al. Mitochondria: from bioenergetics to the metabolic regulation of carcinogenesis. Front. Biosci. 14, 4015-4034 (2009). 
         [39] Moller, P. et al. Role of oxidative damage in toxicity of particulates. Free Radic. Res. 44, 1-46 (2010). 
         [40] Oberdörster, G. et al. Nanotoxicology: an emerging discipline evolving from studies of ultrafine particles. Environ. Health Perspect. 113, 823-829 (2005). 
         [41] Shvedova, A. A. et al. Exposure to carbon nanotube material: assessment of nanotube cytotoxicity using human keratinocyte cells. J. Toxicol. Environ. Health A 66, 1909-1926 (2003). 
         [42] Warheit, D. B. Nanoparticles: Health impacts ? Mater. Today 7, 32-35 (2004) 
         [43] Heckert, E. et al. The role of cerium redox state in the SOD mimetic activity of nanoceria. Biomaterials 29, 2705-2709 (2008). 
         [44] Auffan, M. et al. CeO2 nanoparticles induce DNA damage towards human dermal fibroblasts in vitro. Nanotoxicol. 3, 161-171 (2009). 
         [45] Korsvik, C. et al. Superoxide dismutase mimetic properties exhibited by vacancy engineered ceria nanoparticles. Chem. Commun. 14, 1056-1058 (2007). 
         [46] Perez, J. M. et al. Synthesis of biocompatible dextran-coated nanoceria with pH-dependent antioxidant properties. ASMAll 4, 552-556 (2008). 
         [47] Ristow, M. Oxidative metabolism in cancer growth. Curr. Opin. Clin. Nutr. Metab. Care. 9, 339-345 (2006). 
         [48] Warburg, O. On the origin of cancer cells. Science 123, 309-314 (1956). 
         [49] Zhivotovsky, B. Orrenius, S. The Warburg effect returns to the cancer stage. Sem. Cancer Biol. 19, 1-3 (2009). 
         [50] Semenza, G. L. Tumor metabolism: cancer cells give and take lactate. J. Clin. Invest. 118, 3835-3837 (2008).