PMC 20201216 pmc.key 4831588 NO-CC CODE no 0 0 10.1021/jacs.6b01332 4831588 26967810 4634 13 This is an open access article published under an ACS AuthorChoice License, which permits copying and redistribution of the article or any adaptations for non-commercial purposes. 4642 surname:Kreutzer;given-names:Adam G. surname:Hamza;given-names:Imane L. surname:Spencer;given-names:Ryan K. surname:Nowick;given-names:James S. TITLE front 138 2017 0 X-ray Crystallographic Structures of a Trimer, Dodecamer, and Annular Pore Formed by an Aβ17–36 β-Hairpin 0.9994534 evidence cleaner0 2023-07-10T14:56:28Z DUMMY: X-ray Crystallographic Structures 0.9992366 oligomeric_state cleaner0 2023-07-10T09:57:04Z DUMMY: Trimer 0.9990484 oligomeric_state cleaner0 2023-07-10T10:07:15Z DUMMY: Dodecamer 0.92726004 site cleaner0 2023-07-10T14:08:21Z SO: Annular Pore protein PR: cleaner0 2023-07-10T10:08:53Z residue_range DUMMY: cleaner0 2023-07-10T10:09:12Z 17–36 0.998604 structure_element cleaner0 2023-07-10T10:09:18Z SO: β-Hairpin ABSTRACT abstract 112 High-resolution structures of oligomers formed by the β-amyloid peptide Aβ are needed to understand the molecular basis of Alzheimer’s disease and develop therapies. This paper presents the X-ray crystallographic structures of oligomers formed by a 20-residue peptide segment derived from Aβ. The development of a peptide in which Aβ17–36 is stabilized as a β-hairpin is described, and the X-ray crystallographic structures of oligomers it forms are reported. Two covalent constraints act in tandem to stabilize the Aβ17–36 peptide in a hairpin conformation: a δ-linked ornithine turn connecting positions 17 and 36 to create a macrocycle and an intramolecular disulfide linkage between positions 24 and 29. An N-methyl group at position 33 blocks uncontrolled aggregation. The peptide readily crystallizes as a folded β-hairpin, which assembles hierarchically in the crystal lattice. Three β-hairpin monomers assemble to form a triangular trimer, four trimers assemble in a tetrahedral arrangement to form a dodecamer, and five dodecamers pack together to form an annular pore. This hierarchical assembly provides a model, in which full-length Aβ transitions from an unfolded monomer to a folded β-hairpin, which assembles to form oligomers that further pack to form an annular pore. This model may provide a better understanding of the molecular basis of Alzheimer’s disease at atomic resolution. 0.9979809 evidence cleaner0 2023-07-10T14:56:36Z DUMMY: structures 0.97725874 oligomeric_state cleaner0 2023-07-10T09:57:13Z DUMMY: oligomers 0.86354554 protein cleaner0 2023-07-10T14:36:01Z PR: β-amyloid peptide 0.7519912 protein cleaner0 2023-07-10T10:08:54Z PR: 0.9995192 evidence cleaner0 2023-07-10T14:56:29Z DUMMY: X-ray crystallographic structures 0.9574868 oligomeric_state cleaner0 2023-07-10T09:57:14Z DUMMY: oligomers 0.8060632 residue_range cleaner0 2023-07-10T14:42:56Z DUMMY: 20-residue peptide segment 0.5019251 protein cleaner0 2023-07-10T10:08:54Z PR: protein PR: cleaner0 2023-07-10T14:38:49Z residue_range DUMMY: cleaner0 2023-07-10T14:39:01Z 17–36 0.99956745 structure_element cleaner0 2023-07-10T10:09:19Z SO: β-hairpin 0.9995325 evidence cleaner0 2023-07-10T14:56:29Z DUMMY: X-ray crystallographic structures 0.70311177 oligomeric_state cleaner0 2023-07-10T09:57:14Z DUMMY: oligomers protein PR: cleaner0 2023-07-10T14:39:36Z residue_range DUMMY: cleaner0 2023-07-10T14:39:47Z 17–36 structure_element SO: cleaner0 2023-07-10T14:40:06Z hairpin protein_state DUMMY: cleaner0 2023-07-10T10:26:42Z δ-linked residue_name SO: cleaner0 2023-07-10T10:26:21Z ornithine structure_element SO: cleaner0 2023-07-10T14:02:39Z turn 0.99510807 residue_number cleaner0 2023-07-10T14:43:03Z DUMMY: 17 0.9962352 residue_number cleaner0 2023-07-10T14:43:06Z DUMMY: 36 0.9945172 ptm cleaner0 2023-07-10T10:10:01Z MESH: disulfide linkage 0.9947225 residue_number cleaner0 2023-07-10T14:43:09Z DUMMY: 24 0.9957502 residue_number cleaner0 2023-07-10T14:43:14Z DUMMY: 29 0.9970932 residue_number cleaner0 2023-07-10T14:43:17Z DUMMY: 33 evidence DUMMY: cleaner0 2023-07-10T15:36:42Z readily crystallizes 0.9996369 protein_state cleaner0 2023-07-10T14:40:19Z DUMMY: folded 0.99950814 structure_element cleaner0 2023-07-10T10:09:19Z SO: β-hairpin 0.8951478 evidence cleaner0 2023-07-10T14:56:41Z DUMMY: crystal lattice 0.9995174 structure_element cleaner0 2023-07-10T10:09:19Z SO: β-hairpin 0.9990044 oligomeric_state cleaner0 2023-07-10T09:57:24Z DUMMY: monomers 0.94550765 protein_state cleaner0 2023-07-10T09:57:45Z DUMMY: triangular 0.9986405 oligomeric_state cleaner0 2023-07-10T09:57:06Z DUMMY: trimer 0.9976846 oligomeric_state cleaner0 2023-07-10T09:58:03Z DUMMY: trimers 0.80919456 oligomeric_state cleaner0 2023-07-10T10:07:47Z DUMMY: dodecamer 0.66039157 oligomeric_state cleaner0 2023-07-10T09:58:53Z DUMMY: dodecamers 0.9301689 site cleaner0 2023-07-10T14:08:22Z SO: annular pore 0.99956006 protein_state cleaner0 2023-07-10T14:29:13Z DUMMY: full-length 0.8096459 protein cleaner0 2023-07-10T10:08:54Z PR: 0.9996525 protein_state cleaner0 2023-07-10T14:40:26Z DUMMY: unfolded 0.99926764 oligomeric_state cleaner0 2023-07-10T09:58:16Z DUMMY: monomer 0.99964523 protein_state cleaner0 2023-07-10T14:40:20Z DUMMY: folded 0.99954224 structure_element cleaner0 2023-07-10T10:09:19Z SO: β-hairpin 0.998198 oligomeric_state cleaner0 2023-07-10T09:57:14Z DUMMY: oligomers 0.9254092 site cleaner0 2023-07-10T14:08:22Z SO: annular pore INTRO title_1 1545 Introduction INTRO paragraph 1558 High-resolution structures of oligomers formed by the β-amyloid peptide Aβ are desperately needed to understand the molecular basis of Alzheimer’s disease and ultimately develop preventions or treatments. In Alzheimer’s disease, monomeric Aβ aggregates to form soluble low molecular weight oligomers, such as dimers, trimers, tetramers, hexamers, nonamers, and dodecamers, as well as high molecular weight aggregates, such as annular protofibrils. Over the last two decades the role of Aβ oligomers in the pathophysiology of Alzheimer’s disease has begun to unfold. 0.99909747 evidence cleaner0 2023-07-10T14:56:46Z DUMMY: structures 0.99652416 oligomeric_state cleaner0 2023-07-10T09:57:14Z DUMMY: oligomers 0.94002265 protein cleaner0 2023-07-10T14:40:39Z PR: β-amyloid peptide 0.93936694 protein cleaner0 2023-07-10T10:08:54Z PR: 0.9981597 oligomeric_state cleaner0 2023-07-10T09:58:24Z DUMMY: monomeric 0.89636207 protein cleaner0 2023-07-10T10:08:54Z PR: 0.9967926 oligomeric_state cleaner0 2023-07-10T09:57:14Z DUMMY: oligomers 0.99898165 oligomeric_state cleaner0 2023-07-10T09:58:30Z DUMMY: dimers 0.9987111 oligomeric_state cleaner0 2023-07-10T09:58:05Z DUMMY: trimers 0.9987313 oligomeric_state cleaner0 2023-07-10T09:58:36Z DUMMY: tetramers 0.9982185 oligomeric_state cleaner0 2023-07-10T09:58:41Z DUMMY: hexamers 0.9954139 oligomeric_state cleaner0 2023-07-10T09:58:47Z DUMMY: nonamers 0.73250586 oligomeric_state cleaner0 2023-07-10T09:58:53Z DUMMY: dodecamers complex_assembly GO: cleaner0 2023-07-10T10:16:52Z annular protofibrils 0.871762 protein cleaner0 2023-07-10T10:08:54Z PR: 0.9886619 oligomeric_state cleaner0 2023-07-10T09:57:14Z DUMMY: oligomers INTRO paragraph 2136 Mouse models for Alzheimer’s disease have helped shape our current understanding about the Aβ oligomerization that precedes neurodegeneration. Aβ isolated from the brains of young plaque-free Tg2576 mice forms a mixture of low molecular weight oligomers. A 56 kDa soluble oligomer identified by SDS-PAGE was found to be especially important within this mixture. This oligomer was termed Aβ*56 and appears to be a dodecamer of Aβ. Purified Aβ*56 injected intercranially into healthy rats was found to impair memory, providing evidence that this Aβ oligomer may cause memory loss in Alzheimer’s disease. Smaller oligomers with molecular weights consistent with trimers, hexamers, and nonamers were also identified within the mixture of low molecular weight oligomers. Treatment of the mixture of low molecular weight oligomers with hexafluoroisopropanol resulted in the dissociation of the putative dodecamers, nonamers, and hexamers into trimers and monomers, suggesting that trimers may be the building block of the dodecamers, nonamers, and hexamers. Recently, Aβ trimers and Aβ*56 were identified in the brains of cognitively normal humans and were found to increase with age. taxonomy_domain DUMMY: cleaner0 2023-07-10T10:17:54Z Mouse 0.95153725 protein cleaner0 2023-07-10T10:08:54Z PR: 0.76898766 protein cleaner0 2023-07-10T10:08:54Z PR: taxonomy_domain DUMMY: cleaner0 2023-07-10T10:18:10Z mice 0.99578744 oligomeric_state cleaner0 2023-07-10T09:57:14Z DUMMY: oligomers 0.9961333 oligomeric_state cleaner0 2023-07-10T09:59:25Z DUMMY: oligomer 0.99951744 experimental_method cleaner0 2023-07-10T10:22:56Z MESH: SDS-PAGE 0.99662304 oligomeric_state cleaner0 2023-07-10T09:59:26Z DUMMY: oligomer 0.99874526 complex_assembly cleaner0 2023-07-10T10:16:25Z GO: Aβ*56 0.9969062 oligomeric_state cleaner0 2023-07-10T10:14:51Z DUMMY: dodecamer 0.524894 protein cleaner0 2023-07-10T10:08:54Z PR: 0.999077 complex_assembly cleaner0 2023-07-10T10:16:25Z GO: Aβ*56 0.930322 experimental_method cleaner0 2023-07-10T15:36:51Z MESH: injected intercranially 0.71981853 taxonomy_domain cleaner0 2023-07-10T14:41:27Z DUMMY: rats 0.7839674 protein cleaner0 2023-07-10T10:08:54Z PR: 0.99745375 oligomeric_state cleaner0 2023-07-10T09:59:26Z DUMMY: oligomer 0.9809374 oligomeric_state cleaner0 2023-07-10T09:57:14Z DUMMY: oligomers 0.99799526 oligomeric_state cleaner0 2023-07-10T09:58:05Z DUMMY: trimers 0.9979175 oligomeric_state cleaner0 2023-07-10T09:58:42Z DUMMY: hexamers 0.99625224 oligomeric_state cleaner0 2023-07-10T09:58:48Z DUMMY: nonamers 0.9794788 oligomeric_state cleaner0 2023-07-10T09:57:14Z DUMMY: oligomers 0.9043188 oligomeric_state cleaner0 2023-07-10T09:57:14Z DUMMY: oligomers 0.99964046 chemical cleaner0 2023-07-10T14:46:54Z CHEBI: hexafluoroisopropanol 0.7555674 oligomeric_state cleaner0 2023-07-10T09:58:53Z DUMMY: dodecamers 0.9777452 oligomeric_state cleaner0 2023-07-10T09:58:48Z DUMMY: nonamers 0.9961927 oligomeric_state cleaner0 2023-07-10T09:58:42Z DUMMY: hexamers 0.9981608 oligomeric_state cleaner0 2023-07-10T09:58:05Z DUMMY: trimers 0.9986059 oligomeric_state cleaner0 2023-07-10T09:57:24Z DUMMY: monomers 0.9974662 oligomeric_state cleaner0 2023-07-10T09:58:05Z DUMMY: trimers 0.9601586 oligomeric_state cleaner0 2023-07-10T09:58:53Z DUMMY: dodecamers 0.9466172 oligomeric_state cleaner0 2023-07-10T09:58:48Z DUMMY: nonamers 0.9969951 oligomeric_state cleaner0 2023-07-10T09:58:42Z DUMMY: hexamers 0.4964463 protein cleaner0 2023-07-10T10:08:54Z PR: 0.99813914 oligomeric_state cleaner0 2023-07-10T09:58:05Z DUMMY: trimers 0.9990856 complex_assembly cleaner0 2023-07-10T10:16:25Z GO: Aβ*56 0.9989365 species cleaner0 2023-07-10T14:41:36Z MESH: humans INTRO paragraph 3339 A type of large oligomers called annular protofibrils (APFs) have also been observed in the brains of transgenic mice and isolated from the brains of Alzheimer’s patients. APFs were first discovered in vitro using chemically synthesized Aβ that aggregated into porelike structures that could be observed by atomic force microscopy (AFM) and transmission electron microscopy (TEM). The sizes of APFs prepared in vitro vary among different studies. Lashuel et al. observed APFs with an outer diameter that ranged from 7–10 nm and an inner diameter that ranged from 1.5–2 nm, consistent with molecular weights of 150–250 kDa. Quist et al. observed APFs with an outer diameter of 16 nm embedded in a lipid bilayer. Kayed et al. observed APFs with an outer diameter that ranged from 8–25 nm, which were composed of small spherical Aβ oligomers, 3–5 nm in diameter. Although the APFs in these studies differ in size, they share a similar annular morphology and appear to be composed of smaller oligomers. 0.9700486 oligomeric_state cleaner0 2023-07-10T09:57:14Z DUMMY: oligomers 0.8665932 complex_assembly cleaner0 2023-07-10T10:16:51Z GO: annular protofibrils 0.7713709 complex_assembly cleaner0 2023-07-10T10:13:51Z GO: APFs taxonomy_domain DUMMY: cleaner0 2023-07-10T10:18:10Z mice 0.5791445 complex_assembly cleaner0 2023-07-10T10:13:52Z GO: APFs 0.9984447 protein_state cleaner0 2023-07-10T15:45:05Z DUMMY: chemically synthesized 0.63466835 protein cleaner0 2023-07-10T10:08:54Z PR: 0.8028501 structure_element cleaner0 2023-07-11T09:33:21Z SO: porelike structures 0.9995325 experimental_method cleaner0 2023-07-10T10:17:10Z MESH: atomic force microscopy 0.99963975 experimental_method cleaner0 2023-07-10T10:17:15Z MESH: AFM 0.99952656 experimental_method cleaner0 2023-07-10T10:17:20Z MESH: transmission electron microscopy 0.9996375 experimental_method cleaner0 2023-07-10T10:17:25Z MESH: TEM 0.95248115 complex_assembly cleaner0 2023-07-10T10:13:52Z GO: APFs 0.91114235 complex_assembly cleaner0 2023-07-10T10:13:52Z GO: APFs 0.9306856 complex_assembly cleaner0 2023-07-10T10:13:52Z GO: APFs 0.8881248 complex_assembly cleaner0 2023-07-10T10:13:52Z GO: APFs 0.97571397 protein_state cleaner0 2023-07-10T15:45:13Z DUMMY: small spherical 0.77268577 protein cleaner0 2023-07-10T10:08:54Z PR: 0.94128937 oligomeric_state cleaner0 2023-07-10T09:57:14Z DUMMY: oligomers 0.9496165 complex_assembly cleaner0 2023-07-10T10:13:52Z GO: APFs 0.99063766 oligomeric_state cleaner0 2023-07-10T09:57:14Z DUMMY: oligomers INTRO paragraph 4352 APFs have also been observed in the brains of APP23 transgenic mice by immunofluorescence with an anti-APF antibody and were found to accumulate in neuronal processes and synapses. In a subsequent study, APFs were isolated from the brains of Alzheimer’s patients by immunoprecipitation with an anti-APF antibody. These APFs had an outer diameter that ranged from 11–14 nm and an inner diameter that ranged from 2.5–4 nm. 0.98581684 complex_assembly cleaner0 2023-07-10T10:13:52Z GO: APFs taxonomy_domain DUMMY: cleaner0 2023-07-10T10:18:09Z mice 0.9995883 experimental_method cleaner0 2023-07-10T15:37:02Z MESH: immunofluorescence complex_assembly GO: cleaner0 2023-07-10T14:29:04Z APF 0.95454985 complex_assembly cleaner0 2023-07-10T10:13:52Z GO: APFs 0.99961036 experimental_method cleaner0 2023-07-10T15:37:06Z MESH: immunoprecipitation complex_assembly GO: cleaner0 2023-07-10T14:29:04Z APF 0.91438216 complex_assembly cleaner0 2023-07-10T10:13:52Z GO: APFs INTRO paragraph 4779 Dimers of Aβ have also been isolated from the brains of Alzheimer’s patients.− Aβ dimers inhibit long-term potentiation in mice and promote hyperphosphorylation of the microtubule-associated protein tau, leading to neuritic damage. Aβ dimers have only been isolated from human or transgenic mouse brains that contain the pathognomonic fibrillar Aβ plaques associated with Alzheimer’s disease. Furthermore, the endogenous rise of Aβ dimers in the brains of Tg2576 and J20 transgenic mice coincides with the deposition of Aβ plaques. These observations suggest that the Aβ trimers, hexamers, dodecamers, and related assemblies may be associated with presymptomatic neurodegeneration, while Aβ dimers are more closely associated with fibril formation and plaque deposition during symptomatic Alzheimer’s disease.− 0.99945194 oligomeric_state cleaner0 2023-07-10T09:58:31Z DUMMY: Dimers 0.8021377 protein cleaner0 2023-07-10T10:08:54Z PR: 0.5438175 protein cleaner0 2023-07-10T10:08:54Z PR: 0.99941444 oligomeric_state cleaner0 2023-07-10T09:58:31Z DUMMY: dimers taxonomy_domain DUMMY: cleaner0 2023-07-10T10:18:10Z mice 0.9493683 ptm cleaner0 2023-07-10T15:27:09Z MESH: hyperphosphorylation protein PR: cleaner0 2023-07-10T15:26:50Z microtubule-associated protein tau 0.6077137 protein cleaner0 2023-07-10T10:08:54Z PR: 0.99936277 oligomeric_state cleaner0 2023-07-10T09:58:31Z DUMMY: dimers 0.999215 species cleaner0 2023-07-10T14:41:54Z MESH: human 0.47958887 taxonomy_domain cleaner0 2023-07-10T10:17:54Z DUMMY: mouse protein_state DUMMY: cleaner0 2023-07-10T15:49:03Z fibrillar 0.5131039 protein cleaner0 2023-07-10T10:08:54Z PR: 0.7966062 protein cleaner0 2023-07-10T10:08:54Z PR: 0.99929655 oligomeric_state cleaner0 2023-07-10T09:58:31Z DUMMY: dimers taxonomy_domain DUMMY: cleaner0 2023-07-10T10:18:10Z mice protein PR: cleaner0 2023-07-10T10:08:54Z 0.72620815 protein cleaner0 2023-07-10T10:08:54Z PR: 0.9988053 oligomeric_state cleaner0 2023-07-10T09:58:05Z DUMMY: trimers 0.9966085 oligomeric_state cleaner0 2023-07-10T09:58:42Z DUMMY: hexamers 0.8557124 oligomeric_state cleaner0 2023-07-10T09:58:53Z DUMMY: dodecamers 0.646234 protein cleaner0 2023-07-10T10:08:54Z PR: 0.9993901 oligomeric_state cleaner0 2023-07-10T09:58:31Z DUMMY: dimers INTRO paragraph 5614 The approach of isolating and characterizing Aβ oligomers has not provided any high-resolution structures of Aβ oligomers. Techniques such as SDS-PAGE, TEM, and AFM have only provided information about the molecular weights, sizes, morphologies, and stoichiometry of Aβ oligomers. High-resolution structural studies of Aβ have primarily focused on Aβ fibrils and Aβ monomers. Solid-state NMR spectroscopy studies of Aβ fibrils revealed that Aβ fibrils are generally composed of extended networks of in-register parallel β-sheets.− X-ray crystallographic studies using fragments of Aβ have provided additional information about how Aβ fibrils pack. Solution-phase NMR and solid-state NMR have been used to study the structures of the Aβ monomers within oligomeric assemblies.− A major finding from these studies is that oligomeric assemblies of Aβ are primarily composed of antiparallel β-sheets. Many of these studies have reported the monomer subunit as adopting a β-hairpin conformation, in which the hydrophobic central and C-terminal regions form an antiparallel β-sheet. 0.5039002 protein cleaner0 2023-07-10T10:08:54Z PR: 0.99614125 oligomeric_state cleaner0 2023-07-10T09:57:14Z DUMMY: oligomers 0.99699545 evidence cleaner0 2023-07-10T14:42:04Z DUMMY: structures 0.7964468 protein cleaner0 2023-07-10T10:08:54Z PR: 0.9962723 oligomeric_state cleaner0 2023-07-10T09:57:14Z DUMMY: oligomers 0.99959564 experimental_method cleaner0 2023-07-10T10:22:55Z MESH: SDS-PAGE 0.9996464 experimental_method cleaner0 2023-07-10T10:17:25Z MESH: TEM 0.9996631 experimental_method cleaner0 2023-07-10T10:17:16Z MESH: AFM 0.60583735 protein cleaner0 2023-07-10T10:08:54Z PR: 0.99693775 oligomeric_state cleaner0 2023-07-10T09:57:15Z DUMMY: oligomers 0.7642248 experimental_method cleaner0 2023-07-10T15:37:11Z MESH: structural studies 0.9772439 protein cleaner0 2023-07-10T10:08:55Z PR: 0.693741 protein cleaner0 2023-07-10T10:08:55Z PR: 0.7077935 oligomeric_state cleaner0 2023-07-10T10:00:00Z DUMMY: fibrils 0.9717112 protein cleaner0 2023-07-10T10:08:55Z PR: 0.99897325 oligomeric_state cleaner0 2023-07-10T09:57:24Z DUMMY: monomers 0.99954873 experimental_method cleaner0 2023-07-10T10:23:01Z MESH: Solid-state NMR spectroscopy 0.82302004 protein cleaner0 2023-07-10T10:08:55Z PR: 0.47209287 oligomeric_state cleaner0 2023-07-10T10:00:00Z DUMMY: fibrils 0.65992016 protein cleaner0 2023-07-10T10:08:55Z PR: 0.39904255 oligomeric_state cleaner0 2023-07-10T10:00:01Z DUMMY: fibrils 0.9986865 structure_element cleaner0 2023-07-11T09:33:37Z SO: in-register parallel β-sheets 0.9992774 experimental_method cleaner0 2023-07-10T15:37:15Z MESH: X-ray crystallographic studies 0.8482603 protein cleaner0 2023-07-10T10:08:55Z PR: 0.5764966 protein cleaner0 2023-07-10T10:08:55Z PR: oligomeric_state DUMMY: cleaner0 2023-07-10T10:00:01Z fibrils 0.99956304 experimental_method cleaner0 2023-07-10T10:23:09Z MESH: Solution-phase NMR 0.9995558 experimental_method cleaner0 2023-07-10T10:23:13Z MESH: solid-state NMR 0.9957182 evidence cleaner0 2023-07-10T14:42:06Z DUMMY: structures 0.85935736 protein cleaner0 2023-07-10T10:08:55Z PR: 0.9992181 oligomeric_state cleaner0 2023-07-10T09:57:24Z DUMMY: monomers 0.99018073 protein cleaner0 2023-07-10T10:08:55Z PR: 0.9996321 structure_element cleaner0 2023-07-11T09:33:41Z SO: antiparallel β-sheets 0.9992317 oligomeric_state cleaner0 2023-07-10T09:58:17Z DUMMY: monomer 0.93509406 structure_element cleaner0 2023-07-10T10:00:19Z SO: subunit structure_element SO: cleaner0 2023-07-10T10:09:19Z β-hairpin 0.98106134 structure_element cleaner0 2023-07-11T09:33:44Z SO: central 0.95612884 structure_element cleaner0 2023-07-11T09:33:47Z SO: C-terminal regions 0.99963534 structure_element cleaner0 2023-07-11T09:33:50Z SO: antiparallel β-sheet INTRO paragraph 6738 In 2008, Hoyer et al. reported the NMR structure of an Aβ monomer bound to an artificial binding protein called an affibody (PDB 2OTK). The structure revealed that monomeric Aβ forms a β-hairpin when bound to the affibody. This Aβ β-hairpin encompasses residues 17–37 and contains two β-strands comprising Aβ17–24 and Aβ30–37 connected by an Aβ25–29 loop. Sequestering Aβ within the affibody prevents its fibrilization and reduces its neurotoxicity, providing evidence that the β-hairpin structure may contribute to the ability of Aβ to form neurotoxic oligomers. In a related study, Sandberg et al. constrained Aβ in a β-hairpin conformation by mutating residues A21 and A30 to cysteine and forming an intramolecular disulfide bond. Locking Aβ into a β-hairpin structure resulted in the formation Aβ oligomers, which were observed by size exclusion chromatography (SEC) and SDS-PAGE. The oligomers with a molecular weight of ∼100 kDa that were isolated by SEC were toxic toward neuronally derived SH-SY5Y cells. This study provides evidence for the role of β-hairpin structure in Aβ oligomerization and neurotoxicity. 0.99964845 experimental_method cleaner0 2023-07-10T15:37:25Z MESH: NMR 0.99663997 evidence cleaner0 2023-07-10T14:42:10Z DUMMY: structure 0.89516926 protein cleaner0 2023-07-10T10:08:55Z PR: 0.99936324 oligomeric_state cleaner0 2023-07-10T09:58:17Z DUMMY: monomer 0.9994837 protein_state cleaner0 2023-07-10T15:45:45Z DUMMY: bound to 0.98704666 chemical cleaner0 2023-07-10T15:29:47Z CHEBI: artificial binding protein 0.8710008 chemical cleaner0 2023-07-10T15:29:59Z CHEBI: affibody 0.99931574 evidence cleaner0 2023-07-10T14:42:13Z DUMMY: structure 0.9989262 oligomeric_state cleaner0 2023-07-10T09:58:25Z DUMMY: monomeric 0.57115346 protein cleaner0 2023-07-10T10:08:55Z PR: 0.9996558 structure_element cleaner0 2023-07-10T10:09:19Z SO: β-hairpin 0.9994358 protein_state cleaner0 2023-07-10T15:45:48Z DUMMY: bound to 0.4964339 chemical cleaner0 2023-07-10T15:29:59Z CHEBI: affibody 0.9803711 protein cleaner0 2023-07-10T10:08:55Z PR: 0.9994075 structure_element cleaner0 2023-07-10T10:09:19Z SO: β-hairpin 0.9986763 residue_range cleaner0 2023-07-10T14:42:52Z DUMMY: 17–37 0.9996045 structure_element cleaner0 2023-07-11T09:33:54Z SO: β-strands protein PR: cleaner0 2023-07-10T10:20:14Z residue_range DUMMY: cleaner0 2023-07-10T10:20:26Z 17–24 protein PR: cleaner0 2023-07-10T10:20:42Z residue_range DUMMY: cleaner0 2023-07-10T10:20:58Z 30–37 protein PR: cleaner0 2023-07-10T10:21:19Z residue_range DUMMY: cleaner0 2023-07-10T10:21:31Z 25–29 structure_element SO: cleaner0 2023-07-10T10:21:42Z loop 0.6987664 protein cleaner0 2023-07-10T10:08:55Z PR: 0.2828719 chemical cleaner0 2023-07-10T15:29:59Z CHEBI: affibody 0.99965763 structure_element cleaner0 2023-07-10T10:09:19Z SO: β-hairpin 0.92513806 protein cleaner0 2023-07-10T10:08:55Z PR: 0.9674943 oligomeric_state cleaner0 2023-07-10T09:57:15Z DUMMY: oligomers 0.63113844 protein cleaner0 2023-07-10T10:08:55Z PR: structure_element SO: cleaner0 2023-07-10T10:09:19Z β-hairpin 0.9923884 experimental_method cleaner0 2023-07-10T15:37:29Z MESH: mutating 0.9999056 residue_name_number cleaner0 2023-07-10T13:57:12Z DUMMY: A21 0.99990606 residue_name_number cleaner0 2023-07-10T10:49:30Z DUMMY: A30 0.9987962 residue_name cleaner0 2023-07-10T10:36:04Z SO: cysteine 0.8780202 ptm cleaner0 2023-07-10T10:22:21Z MESH: disulfide bond 0.47184205 protein cleaner0 2023-07-10T10:08:55Z PR: 0.99963254 structure_element cleaner0 2023-07-10T10:09:19Z SO: β-hairpin 0.4833778 protein cleaner0 2023-07-10T10:08:55Z PR: 0.99662304 oligomeric_state cleaner0 2023-07-10T09:57:15Z DUMMY: oligomers 0.99956506 experimental_method cleaner0 2023-07-10T15:37:32Z MESH: size exclusion chromatography 0.9996662 experimental_method cleaner0 2023-07-10T15:37:36Z MESH: SEC 0.9995844 experimental_method cleaner0 2023-07-10T10:22:56Z MESH: SDS-PAGE 0.99566936 oligomeric_state cleaner0 2023-07-10T09:57:15Z DUMMY: oligomers 0.99965584 experimental_method cleaner0 2023-07-10T15:37:36Z MESH: SEC 0.9996759 structure_element cleaner0 2023-07-10T10:09:19Z SO: β-hairpin 0.85829324 protein cleaner0 2023-07-10T10:08:55Z PR: INTRO paragraph 7914 Inspired by these β-hairpin structures, our laboratory developed a macrocyclic β-sheet peptide derived from Aβ17–36 designed to mimic an Aβ β-hairpin and reported its X-ray crystallographic structure. This peptide (peptide 1) consists of two β-strands comprising Aβ17–23 and Aβ30–36 covalently linked by two δ-linked ornithine (δOrn) β-turn mimics. The δOrn that connects residues D23 and A30 replaces the Aβ24–29 loop. The δOrn that connects residues L17 and V36 enforces β-hairpin structure. We incorporated an N-methyl group at position G33 to prevent uncontrolled aggregation and precipitation of the peptide. To improve the solubility of the peptide we replaced M35 with the hydrophilic isostere of methionine, ornithine (α-linked) (Figure 1B). The X-ray crystallographic structure of peptide 1 reveals that it folds to form a β-hairpin that assembles to form trimers and that the trimers further assemble to form hexamers and dodecamers. 0.99959207 structure_element cleaner0 2023-07-10T10:09:19Z SO: β-hairpin 0.83836514 evidence cleaner0 2023-07-10T14:42:23Z DUMMY: structures 0.8475345 structure_element cleaner0 2023-07-11T09:34:01Z SO: β-sheet protein PR: cleaner0 2023-07-10T10:24:08Z residue_range DUMMY: cleaner0 2023-07-10T10:24:19Z 17–36 0.7955069 protein cleaner0 2023-07-10T10:08:55Z PR: 0.9995086 structure_element cleaner0 2023-07-10T10:09:19Z SO: β-hairpin 0.9995098 evidence cleaner0 2023-07-10T10:23:28Z DUMMY: X-ray crystallographic structure 0.9646842 mutant cleaner0 2023-07-10T10:38:33Z MESH: peptide 1 0.99670887 structure_element cleaner0 2023-07-11T09:34:09Z SO: β-strands protein PR: cleaner0 2023-07-10T10:24:34Z residue_range DUMMY: cleaner0 2023-07-10T10:24:46Z 17–23 protein PR: cleaner0 2023-07-10T10:25:01Z residue_range DUMMY: cleaner0 2023-07-10T10:25:11Z 30–36 protein_state DUMMY: cleaner0 2023-07-10T10:26:41Z δ-linked residue_name SO: cleaner0 2023-07-10T10:26:21Z ornithine 0.8010554 structure_element cleaner0 2023-07-10T10:25:39Z SO: δOrn structure_element SO: cleaner0 2023-07-10T10:27:37Z β-turn 0.99973744 structure_element cleaner0 2023-07-10T14:03:39Z SO: δOrn 0.99988973 residue_name_number cleaner0 2023-07-10T10:49:38Z DUMMY: D23 0.99989367 residue_name_number cleaner0 2023-07-10T10:49:30Z DUMMY: A30 protein PR: cleaner0 2023-07-10T10:27:55Z residue_range DUMMY: cleaner0 2023-07-10T10:28:07Z 24–29 structure_element SO: cleaner0 2023-07-10T10:28:15Z loop 0.9997259 structure_element cleaner0 2023-07-10T14:03:39Z SO: δOrn 0.9998894 residue_name_number cleaner0 2023-07-10T13:57:03Z DUMMY: L17 0.99989426 residue_name_number cleaner0 2023-07-10T13:57:33Z DUMMY: V36 0.9995308 structure_element cleaner0 2023-07-10T10:09:19Z SO: β-hairpin 0.99989927 residue_name_number cleaner0 2023-07-10T13:58:11Z DUMMY: G33 0.9414554 experimental_method cleaner0 2023-07-10T15:37:42Z MESH: replaced 0.9999063 residue_name_number cleaner0 2023-07-10T13:58:16Z DUMMY: M35 0.8500073 residue_name cleaner0 2023-07-10T10:35:57Z SO: methionine 0.8644892 residue_name cleaner0 2023-07-10T10:26:21Z SO: ornithine protein_state DUMMY: cleaner0 2023-07-10T10:27:18Z α-linked 0.9995065 evidence cleaner0 2023-07-10T10:23:29Z DUMMY: X-ray crystallographic structure 0.85178244 mutant cleaner0 2023-07-10T10:38:33Z MESH: peptide 1 0.9996161 structure_element cleaner0 2023-07-10T10:09:19Z SO: β-hairpin 0.99884737 oligomeric_state cleaner0 2023-07-10T09:58:05Z DUMMY: trimers 0.9988152 oligomeric_state cleaner0 2023-07-10T09:58:06Z DUMMY: trimers 0.9988193 oligomeric_state cleaner0 2023-07-10T09:58:42Z DUMMY: hexamers 0.9941906 oligomeric_state cleaner0 2023-07-10T09:58:53Z DUMMY: dodecamers ja-2016-013325_0002.jpg fig1 FIG fig_caption 8914 (A) Cartoon illustrating the design of peptides 1 and 2 and their relationship to an Aβ17–36 β-hairpin. (B) Chemical structure of peptide 1 illustrating Aβ17–23 and Aβ30–36, M35Orn, the N-methyl group, and the δ-linked ornithine turns. (C) Chemical structure of peptide 2 illustrating Aβ17–36, the N-methyl group, the disulfide bond across positions 24 and 29, and the δ-linked ornithine turn. chemical CHEBI: cleaner0 2023-07-10T10:33:20Z peptides 1 and 2 protein PR: cleaner0 2023-07-10T10:33:04Z residue_range DUMMY: cleaner0 2023-07-10T10:37:44Z 17–36 0.999314 structure_element cleaner0 2023-07-10T10:09:19Z SO: β-hairpin mutant MESH: cleaner0 2023-07-10T10:38:32Z peptide 1 protein PR: cleaner0 2023-07-10T10:31:49Z residue_range DUMMY: cleaner0 2023-07-10T10:32:00Z 17–23 protein PR: cleaner0 2023-07-10T10:32:15Z residue_range DUMMY: cleaner0 2023-07-10T10:32:30Z 30–36 protein_state DUMMY: cleaner0 2023-07-10T10:26:42Z δ-linked 0.9810042 residue_name cleaner0 2023-07-10T10:26:21Z SO: ornithine structure_element SO: cleaner0 2023-07-10T10:34:22Z turns mutant MESH: cleaner0 2023-07-10T10:39:07Z peptide 2 protein PR: cleaner0 2023-07-10T10:33:54Z residue_range DUMMY: cleaner0 2023-07-10T10:34:07Z 17–36 0.9905417 ptm cleaner0 2023-07-10T10:22:22Z MESH: disulfide bond 0.99705064 residue_number cleaner0 2023-07-10T14:43:23Z DUMMY: 24 0.9969585 residue_number cleaner0 2023-07-10T14:43:26Z DUMMY: 29 protein_state DUMMY: cleaner0 2023-07-10T10:26:42Z δ-linked 0.9834495 residue_name cleaner0 2023-07-10T10:26:21Z SO: ornithine structure_element SO: cleaner0 2023-07-10T10:34:30Z turn INTRO paragraph 9331 Our design of peptide 1 omitted the Aβ24–29 loop. To visualize the Aβ24–29 loop, we performed replica-exchange molecular dynamics (REMD) simulations on Aβ17–36 using the X-ray crystallographic coordinates of Aβ17–23 and Aβ30–36 from peptide 1. These studies provided a working model for a trimer of Aβ17–36 β-hairpins and demonstrated that the trimer should be capable of accommodating the Aβ24–29 loop. mutant MESH: cleaner0 2023-07-10T10:38:33Z peptide 1 protein PR: cleaner0 2023-07-10T10:41:20Z residue_range DUMMY: cleaner0 2023-07-10T10:41:42Z 24–29 structure_element SO: cleaner0 2023-07-10T10:41:52Z loop protein PR: cleaner0 2023-07-10T10:43:00Z residue_range DUMMY: cleaner0 2023-07-10T10:43:10Z 24–29 structure_element SO: cleaner0 2023-07-10T10:44:39Z loop 0.999436 experimental_method cleaner0 2023-07-10T15:37:48Z MESH: replica-exchange molecular dynamics 0.999634 experimental_method cleaner0 2023-07-10T15:37:50Z MESH: REMD 0.9984914 experimental_method cleaner0 2023-07-10T15:37:52Z MESH: simulations protein PR: cleaner0 2023-07-10T10:42:10Z residue_range DUMMY: cleaner0 2023-07-10T10:42:23Z 17–36 0.9992975 evidence cleaner0 2023-07-10T14:56:54Z DUMMY: X-ray crystallographic coordinates protein PR: cleaner0 2023-07-10T10:42:37Z residue_range DUMMY: cleaner0 2023-07-10T10:42:47Z 17–23 protein PR: cleaner0 2023-07-10T10:43:37Z residue_range DUMMY: cleaner0 2023-07-10T10:43:49Z 30–36 mutant MESH: cleaner0 2023-07-10T10:38:33Z peptide 1 0.9994091 oligomeric_state cleaner0 2023-07-10T09:57:06Z DUMMY: trimer protein PR: cleaner0 2023-07-10T10:44:15Z residue_range DUMMY: cleaner0 2023-07-10T10:44:26Z 17–36 0.9996304 structure_element cleaner0 2023-07-10T10:51:04Z SO: β-hairpins 0.9994087 oligomeric_state cleaner0 2023-07-10T09:57:06Z DUMMY: trimer protein PR: cleaner0 2023-07-10T10:45:53Z residue_range DUMMY: cleaner0 2023-07-10T10:46:04Z 24–29 structure_element SO: cleaner0 2023-07-10T10:44:40Z loop INTRO paragraph 9759 In the current study we set out to restore the Aβ24–29 loop, reintroduce the methionine residue at position 35, and determine the X-ray crystallographic structures of oligomers that form. We designed peptide 2 as a homologue of peptide 1 that embodies these ideas. Peptide 2 contains a methionine residue at position 35 and an Aβ24–29 loop with residues 24 and 29 (Val and Gly) mutated to cysteine and linked by a disulfide bond (Figure 1C). Here, we describe the development of peptide 2 and report the X-ray crystallographic structures of the trimer, dodecamer, and annular pore observed within the crystal structure. 0.9742589 experimental_method cleaner0 2023-07-10T15:37:57Z MESH: restore protein PR: cleaner0 2023-07-10T10:46:20Z residue_range DUMMY: cleaner0 2023-07-10T10:46:36Z 24–29 structure_element SO: cleaner0 2023-07-10T10:44:40Z loop 0.9987637 experimental_method cleaner0 2023-07-10T15:37:59Z MESH: reintroduce 0.99891746 residue_name cleaner0 2023-07-10T10:35:56Z SO: methionine 0.9964091 residue_number cleaner0 2023-07-10T14:43:31Z DUMMY: 35 0.9995488 evidence cleaner0 2023-07-10T14:56:29Z DUMMY: X-ray crystallographic structures 0.96816325 oligomeric_state cleaner0 2023-07-10T09:57:15Z DUMMY: oligomers 0.9973719 mutant cleaner0 2023-07-10T10:39:08Z MESH: peptide 2 0.98622614 mutant cleaner0 2023-07-10T10:38:33Z MESH: peptide 1 0.9961827 mutant cleaner0 2023-07-10T10:39:08Z MESH: Peptide 2 0.99892515 residue_name cleaner0 2023-07-10T10:35:57Z SO: methionine 0.9962081 residue_number cleaner0 2023-07-10T14:43:33Z DUMMY: 35 protein PR: cleaner0 2023-07-10T10:47:13Z residue_range DUMMY: cleaner0 2023-07-10T10:47:25Z 24–29 structure_element SO: cleaner0 2023-07-10T10:44:40Z loop 0.99221075 residue_number cleaner0 2023-07-10T14:43:36Z DUMMY: 24 0.9959067 residue_number cleaner0 2023-07-10T14:43:39Z DUMMY: 29 0.99940336 residue_name cleaner0 2023-07-10T14:44:57Z SO: Val 0.99938273 residue_name cleaner0 2023-07-10T14:45:00Z SO: Gly 0.9951917 experimental_method cleaner0 2023-07-10T15:38:06Z MESH: mutated 0.9989937 residue_name cleaner0 2023-07-10T10:36:03Z SO: cysteine 0.99533427 ptm cleaner0 2023-07-10T10:22:22Z MESH: disulfide bond 0.9937948 mutant cleaner0 2023-07-10T10:39:08Z MESH: peptide 2 0.99953794 evidence cleaner0 2023-07-10T14:56:29Z DUMMY: X-ray crystallographic structures 0.99918133 oligomeric_state cleaner0 2023-07-10T09:57:06Z DUMMY: trimer 0.99606377 oligomeric_state cleaner0 2023-07-10T14:43:47Z DUMMY: dodecamer 0.98689055 site cleaner0 2023-07-10T14:08:22Z SO: annular pore 0.99962056 evidence cleaner0 2023-07-10T14:42:40Z DUMMY: crystal structure RESULTS title_1 10385 Results RESULTS title_2 10393 Development of Peptide 2 0.99923146 mutant cleaner0 2023-07-10T10:39:08Z MESH: Peptide 2 RESULTS paragraph 10418 We developed peptide 2 from peptide 1 by an iterative process, in which we first attempted to restore the Aβ24–29 loop without a disulfide linkage. We envisioned peptide 3 as a homologue of peptide 1 with the Aβ24–29 loop in place of the δOrn that connects D23 and A30 and p-iodophenylalanine (FI) in place of F19. We routinely use p-iodophenylalanine to determine the X-ray crystallographic phases. After determining the X-ray crystallographic structure of the p-iodophenylalanine variant we attempt to determine the structure of the native phenylalanine compound by isomorphous replacement. Upon synthesizing peptide 3, we found that it formed an amorphous precipitate in most crystallization conditions screened and failed to afford crystals in any condition. 0.9892849 mutant cleaner0 2023-07-10T10:39:08Z MESH: peptide 2 0.9937219 mutant cleaner0 2023-07-10T10:38:33Z MESH: peptide 1 protein PR: cleaner0 2023-07-10T10:48:36Z residue_range DUMMY: cleaner0 2023-07-10T10:48:46Z 24–29 structure_element SO: cleaner0 2023-07-10T10:44:40Z loop 0.9951011 ptm cleaner0 2023-07-10T10:10:02Z MESH: disulfide linkage 0.9922428 mutant cleaner0 2023-07-10T10:48:10Z MESH: peptide 3 0.97108465 mutant cleaner0 2023-07-10T10:38:33Z MESH: peptide 1 protein PR: cleaner0 2023-07-10T10:49:01Z residue_range DUMMY: cleaner0 2023-07-10T10:49:11Z 24–29 structure_element SO: cleaner0 2023-07-10T10:44:40Z loop 0.9992563 structure_element cleaner0 2023-07-10T14:03:39Z SO: δOrn 0.9998549 residue_name_number cleaner0 2023-07-10T10:49:38Z DUMMY: D23 0.99987125 residue_name_number cleaner0 2023-07-10T10:49:29Z DUMMY: A30 0.9996927 chemical cleaner0 2023-07-10T10:49:17Z CHEBI: p-iodophenylalanine 0.99924856 chemical cleaner0 2023-07-10T10:49:22Z CHEBI: FI 0.9998852 residue_name_number cleaner0 2023-07-10T10:49:33Z DUMMY: F19 0.99968237 chemical cleaner0 2023-07-10T10:49:18Z CHEBI: p-iodophenylalanine 0.999561 evidence cleaner0 2023-07-10T14:57:01Z DUMMY: X-ray crystallographic phases 0.99957705 evidence cleaner0 2023-07-10T10:23:29Z DUMMY: X-ray crystallographic structure 0.99928826 chemical cleaner0 2023-07-10T10:49:18Z CHEBI: p-iodophenylalanine 0.9989945 evidence cleaner0 2023-07-10T14:57:05Z DUMMY: structure 0.98784876 residue_name cleaner0 2023-07-10T10:49:44Z SO: phenylalanine 0.9995549 experimental_method cleaner0 2023-07-10T15:38:10Z MESH: isomorphous replacement 0.99354255 mutant cleaner0 2023-07-10T10:48:17Z MESH: peptide 3 0.9983418 evidence cleaner0 2023-07-10T14:57:08Z DUMMY: crystals RESULTS paragraph 11191 We postulate that the loss of the δOrn constraint leads to conformational heterogeneity that prevents peptide 3 from crystallizing. To address this issue, we next incorporated a disulfide bond between residues 24 and 29 as a conformational constraint that serves as a surrogate for δOrn. We designed peptide 4 to embody this idea, mutating Val24 and Gly29 to cysteine and forming an interstrand disulfide linkage. We mutated these residues because they occupy the same position as the δOrn that connects D23 and A30 in peptide 1. Residues V24 and G29 form a non-hydrogen-bonded pair, which can readily accommodate disulfide linkages in antiparallel β-sheets. Disulfide bonds across non-hydrogen-bonded pairs stabilize β-hairpins, while disulfide bonds across hydrogen-bonded pairs do not. Although the disulfide bond between positions 24 and 29 helps stabilize the β-hairpin, it does not alter the charge or substantially change the hydrophobicity of the Aβ17–36 β-hairpin. We were gratified to find that peptide 4 afforded crystals suitable for X-ray crystallography. As the next step in the iterative process, we determined the X-ray crystallographic structure of this peptide (PDB 5HOW). 0.999203 structure_element cleaner0 2023-07-10T14:03:39Z SO: δOrn 0.9848524 mutant cleaner0 2023-07-10T10:48:17Z MESH: peptide 3 0.9961566 ptm cleaner0 2023-07-10T10:22:22Z MESH: disulfide bond 0.9908619 residue_number cleaner0 2023-07-10T14:43:54Z DUMMY: 24 0.99191636 residue_number cleaner0 2023-07-10T14:43:56Z DUMMY: 29 0.99907047 structure_element cleaner0 2023-07-10T14:03:39Z SO: δOrn 0.9774096 mutant cleaner0 2023-07-10T10:50:20Z MESH: peptide 4 0.96276623 experimental_method cleaner0 2023-07-10T15:38:19Z MESH: mutating 0.99990726 residue_name_number cleaner0 2023-07-10T10:51:45Z DUMMY: Val24 0.9999074 residue_name_number cleaner0 2023-07-10T10:51:49Z DUMMY: Gly29 0.99879634 residue_name cleaner0 2023-07-10T10:36:04Z SO: cysteine 0.84402835 ptm cleaner0 2023-07-10T10:10:02Z MESH: disulfide linkage 0.96369773 experimental_method cleaner0 2023-07-10T15:38:33Z MESH: mutated 0.9994572 structure_element cleaner0 2023-07-10T14:03:39Z SO: δOrn 0.99991214 residue_name_number cleaner0 2023-07-10T10:49:38Z DUMMY: D23 0.999912 residue_name_number cleaner0 2023-07-10T10:49:30Z DUMMY: A30 0.9778849 mutant cleaner0 2023-07-10T10:38:33Z MESH: peptide 1 0.99990845 residue_name_number cleaner0 2023-07-10T10:52:02Z DUMMY: V24 0.9999087 residue_name_number cleaner0 2023-07-10T10:52:07Z DUMMY: G29 0.9766631 bond_interaction melaniev@ebi.ac.uk 2023-07-28T14:18:41Z MESH: non-hydrogen-bonded pair 0.99633384 ptm cleaner0 2023-07-10T13:58:29Z MESH: disulfide linkages 0.999683 structure_element cleaner0 2023-07-11T09:34:23Z SO: antiparallel β-sheets 0.99575865 ptm cleaner0 2023-07-10T15:28:01Z MESH: Disulfide bonds 0.96280503 bond_interaction melaniev@ebi.ac.uk 2023-07-28T14:18:41Z MESH: non-hydrogen-bonded pairs 0.99969673 structure_element cleaner0 2023-07-10T10:51:04Z SO: β-hairpins 0.995991 ptm cleaner0 2023-07-10T15:28:01Z MESH: disulfide bonds 0.9655484 bond_interaction melaniev@ebi.ac.uk 2023-07-28T14:18:41Z MESH: hydrogen-bonded pairs 0.9962245 ptm cleaner0 2023-07-10T10:22:22Z MESH: disulfide bond 0.9932238 residue_number cleaner0 2023-07-10T14:43:59Z DUMMY: 24 0.99372065 residue_number cleaner0 2023-07-10T14:44:01Z DUMMY: 29 0.99970675 structure_element cleaner0 2023-07-10T10:09:19Z SO: β-hairpin protein PR: cleaner0 2023-07-10T10:52:24Z residue_range DUMMY: cleaner0 2023-07-10T10:52:34Z 17–36 0.9996972 structure_element cleaner0 2023-07-10T10:09:19Z SO: β-hairpin 0.9822699 mutant cleaner0 2023-07-10T10:50:26Z MESH: peptide 4 0.99896896 evidence cleaner0 2023-07-10T14:57:11Z DUMMY: crystals 0.9995647 experimental_method cleaner0 2023-07-10T15:38:26Z MESH: X-ray crystallography 0.9332236 experimental_method cleaner0 2023-07-10T15:38:28Z MESH: determined 0.9994993 evidence cleaner0 2023-07-10T10:23:29Z DUMMY: X-ray crystallographic structure RESULTS paragraph 12409 After determining the X-ray crystallographic structure of peptide 4 we reintroduced the native phenylalanine at position 19 and the methionine at position 35 to afford peptide 2. We completed the iterative process—from 1 to 3 to 4 to 2—by successfully determining the X-ray crystallographic structure of peptide 2 (PDB 5HOX and 5HOY). The following sections describe the synthesis of peptides 2–4 and the X-ray crystallographic structure of peptide 2. 0.999524 evidence cleaner0 2023-07-10T10:23:29Z DUMMY: X-ray crystallographic structure mutant MESH: cleaner0 2023-07-10T10:50:26Z peptide 4 0.99385285 experimental_method cleaner0 2023-07-10T15:38:37Z MESH: reintroduced 0.99925715 residue_name cleaner0 2023-07-10T10:49:45Z SO: phenylalanine 0.99681 residue_number cleaner0 2023-07-10T14:44:06Z DUMMY: 19 0.99917006 residue_name cleaner0 2023-07-10T10:35:57Z SO: methionine 0.996888 residue_number cleaner0 2023-07-10T14:44:09Z DUMMY: 35 0.90846217 mutant cleaner0 2023-07-10T10:39:08Z MESH: peptide 2 0.9995273 evidence cleaner0 2023-07-10T10:23:29Z DUMMY: X-ray crystallographic structure 0.90822935 mutant cleaner0 2023-07-10T10:39:08Z MESH: peptide 2 mutant MESH: cleaner0 2023-07-10T10:54:05Z peptides 2–4 0.99954253 evidence cleaner0 2023-07-10T10:23:29Z DUMMY: X-ray crystallographic structure 0.9377295 mutant cleaner0 2023-07-10T10:39:08Z MESH: peptide 2 RESULTS title_2 12867 Synthesis of Peptides 2–4 mutant MESH: cleaner0 2023-07-10T10:54:06Z Peptides 2–4 RESULTS paragraph 12895 We synthesized peptides 2–4 by similar procedures to those we have developed for other macrocyclic peptides. Our laboratory routinely prepares macrocyclic peptides by solid-phase synthesis of the corresponding linear peptide on 2-chlorotrityl resin, followed by cleavage of the protected linear peptide from the resin, solution-phase macrolactamization, and deprotection of the resulting macrocyclic peptide. In synthesizing peptides 2 and 4 we formed the disulfide linkage after macrolactamization and deprotection of the acid-labile side chain protecting groups. We used acid-stable Acm-protected cysteine residues at positions 24 and 29 and removed the Acm groups by oxidation with I2 in aqueous acetic acid to afford the disulfide linkage. Peptides 2–4 were purified by RP-HPLC. 0.76412606 mutant cleaner0 2023-07-10T10:54:06Z MESH: peptides 2–4 mutant MESH: cleaner0 2023-07-10T13:56:23Z peptides 2 and 4 0.93680143 ptm cleaner0 2023-07-10T10:10:02Z MESH: disulfide linkage 0.7893932 protein_state cleaner0 2023-07-10T15:46:41Z DUMMY: acid-stable 0.9989392 protein_state cleaner0 2023-07-10T15:46:44Z DUMMY: Acm-protected 0.99904937 residue_name cleaner0 2023-07-10T10:36:04Z SO: cysteine 0.9967083 residue_number cleaner0 2023-07-10T14:44:14Z DUMMY: 24 0.99653554 residue_number cleaner0 2023-07-10T14:44:16Z DUMMY: 29 0.80693245 chemical cleaner0 2023-07-10T15:33:50Z CHEBI: acetic acid 0.9724722 ptm cleaner0 2023-07-10T10:10:02Z MESH: disulfide linkage mutant MESH: cleaner0 2023-07-10T10:54:06Z Peptides 2–4 0.99951 experimental_method cleaner0 2023-07-10T15:38:42Z MESH: RP-HPLC RESULTS title_2 13682 Crystallization, X-ray Crystallographic Data Collection, Data Processing, and Structure Determination of Peptides 2 and 4 0.99958974 experimental_method cleaner0 2023-07-10T15:38:45Z MESH: Crystallization 0.99932367 experimental_method cleaner0 2023-07-10T15:38:51Z MESH: X-ray Crystallographic Data Collection 0.9984472 experimental_method cleaner0 2023-07-10T15:38:54Z MESH: Structure Determination mutant MESH: cleaner0 2023-07-10T13:56:23Z Peptides 2 and 4 RESULTS paragraph 13804 We screened crystallization conditions for peptide 4 in a 96-well-plate format using three different Hampton Research crystallization kits (Crystal Screen, Index, and PEG/Ion) with three ratios of peptide and mother liquor per condition (864 experiments). Peptide 4 afforded crystals in a single set of conditions containing HEPES buffer and Jeffamine M-600—the same crystallization conditions that afforded crystals of peptide 1. Peptide 2 also afforded crystals in these conditions. We further optimized these conditions to rapidly (∼72 h) yield crystals suitable for X-ray crystallography. The optimized conditions consist of 0.1 M HEPES at pH 6.4 with 31% Jeffamine M-600 for peptide 4 and 0.1 M HEPES pH 7.1 with 29% Jeffamine M-600 for peptide 2. experimental_method MESH: cleaner0 2023-07-10T15:39:20Z screened crystallization conditions 0.85154676 mutant cleaner0 2023-07-10T10:50:26Z MESH: peptide 4 0.76433134 mutant cleaner0 2023-07-10T10:50:26Z MESH: Peptide 4 0.99602854 evidence cleaner0 2023-07-10T14:44:20Z DUMMY: crystals 0.9996301 chemical cleaner0 2023-07-10T14:44:29Z CHEBI: Jeffamine M-600 0.9981212 evidence cleaner0 2023-07-10T14:44:22Z DUMMY: crystals 0.9948926 mutant cleaner0 2023-07-10T10:38:33Z MESH: peptide 1 0.9947971 mutant cleaner0 2023-07-10T10:39:08Z MESH: Peptide 2 0.99759406 evidence cleaner0 2023-07-10T14:44:26Z DUMMY: crystals 0.99853027 evidence cleaner0 2023-07-10T14:44:24Z DUMMY: crystals 0.99957484 experimental_method cleaner0 2023-07-10T15:39:35Z MESH: X-ray crystallography 0.92050093 chemical cleaner0 2023-07-10T14:44:31Z CHEBI: HEPES 0.9996245 chemical cleaner0 2023-07-10T14:44:33Z CHEBI: Jeffamine M-600 0.77729464 mutant cleaner0 2023-07-10T10:50:26Z MESH: peptide 4 0.9420801 chemical cleaner0 2023-07-10T15:33:54Z CHEBI: HEPES 0.9996414 chemical cleaner0 2023-07-10T14:44:36Z CHEBI: Jeffamine M-600 0.9898722 mutant cleaner0 2023-07-10T10:39:08Z MESH: peptide 2 RESULTS paragraph 14561 Crystal diffraction data for peptides 4 and 2 were collected in-house with a Rigaku MicroMax 007HF X-ray diffractometer at 1.54 Å wavelength. Crystal diffraction data for peptide 2 were also collected at the Advanced Light Source at Lawrence Berkeley National Laboratory with a synchrotron source at 1.00 Å wavelength to achieve higher resolution. Data from peptides 4 and 2 suitable for refinement at 2.30 Å were obtained from the diffractometer; data from peptide 2 suitable for refinement at 1.90 Å were obtained from the synchrotron. 0.999041 evidence cleaner0 2023-07-10T14:44:38Z DUMMY: Crystal diffraction data mutant MESH: cleaner0 2023-07-10T10:57:10Z peptides 4 and 2 0.9987157 evidence cleaner0 2023-07-10T14:44:40Z DUMMY: Crystal diffraction data 0.6537781 mutant cleaner0 2023-07-10T10:39:08Z MESH: peptide 2 mutant MESH: cleaner0 2023-07-10T10:57:11Z peptides 4 and 2 mutant MESH: cleaner0 2023-07-10T10:39:08Z peptide 2 RESULTS paragraph 15103 Data for peptides 4 and 2 were scaled and merged using XDS. Phases for peptide 4 were determined by single-wavelength anomalous diffraction (SAD) phasing by using the coordinates of the iodine anomalous signal from p-iodophenylalanine. Phases for peptide 2 were determined by isomorphous replacement of peptide 4. The structures of peptides 2 and 4 were solved and refined in the P6122 space group. Coordinates for hydrogens were generated by phenix.refine during refinement. The asymmetric unit of each peptide consists of six monomers, arranged as two trimers. Peptides 2 and 4 form morphologically identical structures and assemblies in the crystal lattice. mutant MESH: cleaner0 2023-07-10T10:57:11Z peptides 4 and 2 0.9662267 evidence cleaner0 2023-07-10T14:57:16Z DUMMY: Phases mutant MESH: cleaner0 2023-07-10T10:50:26Z peptide 4 0.9994998 experimental_method cleaner0 2023-07-10T15:40:11Z MESH: single-wavelength anomalous diffraction 0.9996172 experimental_method cleaner0 2023-07-10T15:40:13Z MESH: SAD 0.87384784 experimental_method cleaner0 2023-07-10T15:40:16Z MESH: phasing 0.95816034 evidence cleaner0 2023-07-10T14:57:23Z DUMMY: iodine anomalous signal 0.99971867 chemical cleaner0 2023-07-10T10:49:18Z CHEBI: p-iodophenylalanine 0.96701795 evidence cleaner0 2023-07-10T14:57:27Z DUMMY: Phases mutant MESH: cleaner0 2023-07-10T10:39:08Z peptide 2 0.99955964 experimental_method cleaner0 2023-07-10T15:40:18Z MESH: isomorphous replacement mutant MESH: cleaner0 2023-07-10T10:50:26Z peptide 4 0.99867237 evidence cleaner0 2023-07-10T14:57:30Z DUMMY: structures mutant MESH: cleaner0 2023-07-10T13:56:23Z peptides 2 and 4 0.607354 experimental_method cleaner0 2023-07-10T15:40:20Z MESH: solved chemical CHEBI: cleaner0 2023-07-10T10:31:20Z peptide 0.99909973 oligomeric_state cleaner0 2023-07-10T09:57:24Z DUMMY: monomers 0.99905604 oligomeric_state cleaner0 2023-07-10T09:58:06Z DUMMY: trimers mutant MESH: cleaner0 2023-07-10T13:56:22Z Peptides 2 and 4 0.9846275 evidence cleaner0 2023-07-10T14:57:33Z DUMMY: crystal lattice RESULTS title_2 15764 X-ray Crystallographic Structure of Peptide 2 and the Oligomers It Forms 0.9994813 evidence cleaner0 2023-07-10T10:23:29Z DUMMY: X-ray Crystallographic Structure 0.9979197 mutant cleaner0 2023-07-10T10:39:08Z MESH: Peptide 2 0.9978307 oligomeric_state cleaner0 2023-07-10T09:57:15Z DUMMY: Oligomers RESULTS paragraph 15837 The X-ray crystallographic structure of peptide 2 reveals that it folds to form a twisted β-hairpin comprising two β-strands connected by a loop (Figure 2A). Eight residues make up each surface of the β-hairpin: L17, F19, A21, D23, A30, I32, L34, and V36 make up one surface; V18, F20, E22, C24, C29, I31, G33, and M35 make up the other surface. The β-strands of the monomers in the asymmetric unit are virtually identical, differing primarily in rotamers of F20, E22, C24, C29, I31, and M35 (Figure S1). The disulfide linkages suffered radiation damage under synchrotron radiation. We refined three of the β-hairpins with intact disulfide linkages and three with thiols to represent cleaved disulfide linkages in the synchrotron data set (PDB 5HOX). No evidence for cleavage of the disulfides was observed in the refinement of the data set collected on the X-ray diffractometer, and we refined all disulfide linkages as intact (PDB 5HOY). 0.99944 evidence cleaner0 2023-07-10T10:23:29Z DUMMY: X-ray crystallographic structure 0.99803936 mutant cleaner0 2023-07-10T10:39:08Z MESH: peptide 2 0.995728 structure_element cleaner0 2023-07-11T09:34:28Z SO: twisted β-hairpin 0.9995902 structure_element cleaner0 2023-07-11T09:34:31Z SO: β-strands 0.99972075 structure_element cleaner0 2023-07-10T10:44:40Z SO: loop 0.99963075 structure_element cleaner0 2023-07-10T10:09:19Z SO: β-hairpin 0.99987936 residue_name_number cleaner0 2023-07-10T13:57:03Z DUMMY: L17 0.99988186 residue_name_number cleaner0 2023-07-10T10:49:34Z DUMMY: F19 0.9998845 residue_name_number cleaner0 2023-07-10T13:57:11Z DUMMY: A21 0.9998822 residue_name_number cleaner0 2023-07-10T10:49:38Z DUMMY: D23 0.9998852 residue_name_number cleaner0 2023-07-10T10:49:30Z DUMMY: A30 0.9998814 residue_name_number cleaner0 2023-07-10T13:57:22Z DUMMY: I32 0.9998826 residue_name_number cleaner0 2023-07-10T13:57:27Z DUMMY: L34 0.9998826 residue_name_number cleaner0 2023-07-10T13:57:32Z DUMMY: V36 0.99988556 residue_name_number cleaner0 2023-07-10T13:57:38Z DUMMY: V18 0.9998834 residue_name_number cleaner0 2023-07-10T13:57:43Z DUMMY: F20 0.9998845 residue_name_number cleaner0 2023-07-10T13:57:48Z DUMMY: E22 0.9998807 residue_name_number cleaner0 2023-07-10T13:57:53Z DUMMY: C24 0.9998834 residue_name_number cleaner0 2023-07-10T13:57:59Z DUMMY: C29 0.9998833 residue_name_number cleaner0 2023-07-10T13:58:04Z DUMMY: I31 0.9998894 residue_name_number cleaner0 2023-07-10T13:58:10Z DUMMY: G33 0.9998834 residue_name_number cleaner0 2023-07-10T13:58:15Z DUMMY: M35 0.9996355 structure_element cleaner0 2023-07-11T09:34:35Z SO: β-strands 0.9992638 oligomeric_state cleaner0 2023-07-10T09:57:24Z DUMMY: monomers 0.99987507 residue_name_number cleaner0 2023-07-10T13:57:43Z DUMMY: F20 0.9998801 residue_name_number cleaner0 2023-07-10T13:57:49Z DUMMY: E22 0.99987435 residue_name_number cleaner0 2023-07-10T13:57:54Z DUMMY: C24 0.9998753 residue_name_number cleaner0 2023-07-10T13:57:59Z DUMMY: C29 0.99987805 residue_name_number cleaner0 2023-07-10T13:58:04Z DUMMY: I31 0.99987507 residue_name_number cleaner0 2023-07-10T13:58:16Z DUMMY: M35 0.9944804 ptm cleaner0 2023-07-10T13:58:29Z MESH: disulfide linkages 0.98165166 experimental_method cleaner0 2023-07-10T15:40:28Z MESH: refined 0.9996164 structure_element cleaner0 2023-07-10T10:51:04Z SO: β-hairpins 0.99951124 protein_state cleaner0 2023-07-10T14:46:11Z DUMMY: intact 0.98381037 ptm cleaner0 2023-07-10T13:58:29Z MESH: disulfide linkages 0.9994874 protein_state cleaner0 2023-07-10T14:46:15Z DUMMY: cleaved 0.9916744 ptm cleaner0 2023-07-10T13:58:29Z MESH: disulfide linkages 0.9787425 ptm cleaner0 2023-07-10T15:28:10Z MESH: disulfides 0.9752783 experimental_method cleaner0 2023-07-10T15:40:30Z MESH: refinement 0.90610075 experimental_method cleaner0 2023-07-10T15:40:39Z MESH: refined 0.9930679 ptm cleaner0 2023-07-10T13:58:29Z MESH: disulfide linkages 0.9995315 protein_state cleaner0 2023-07-10T14:46:11Z DUMMY: intact ja-2016-013325_0003.jpg fig2 FIG fig_caption 16792 X-ray crystallographic structure of peptide 2 (PDB 5HOX, synchrotron data set). (A) X-ray crystallographic structure of a representative β-hairpin monomer formed by peptide 2. (B) Overlay of the six β-hairpin monomers in the asymmetric unit. The β-hairpins are shown as cartoons to illustrate the differences in the Aβ25–28 loops. 0.9995028 evidence cleaner0 2023-07-10T14:57:44Z DUMMY: X-ray crystallographic structure 0.97852206 mutant cleaner0 2023-07-10T10:39:08Z MESH: peptide 2 0.9995206 evidence cleaner0 2023-07-10T10:23:29Z DUMMY: X-ray crystallographic structure 0.9994331 structure_element cleaner0 2023-07-10T10:09:19Z SO: β-hairpin 0.999218 oligomeric_state cleaner0 2023-07-10T09:58:17Z DUMMY: monomer 0.9582621 mutant cleaner0 2023-07-10T10:39:08Z MESH: peptide 2 0.99906534 experimental_method cleaner0 2023-07-10T15:40:45Z MESH: Overlay 0.9994893 structure_element cleaner0 2023-07-10T10:09:19Z SO: β-hairpin 0.9991929 oligomeric_state cleaner0 2023-07-10T09:57:24Z DUMMY: monomers 0.999655 structure_element cleaner0 2023-07-10T10:51:04Z SO: β-hairpins protein PR: cleaner0 2023-07-10T14:21:43Z residue_range DUMMY: cleaner0 2023-07-10T14:21:55Z 25–28 structure_element SO: cleaner0 2023-07-10T14:22:05Z loops RESULTS paragraph 17135 The Aβ25–28 loops of the six monomers within the asymmetric unit vary substantially in backbone geometry and side chain rotamers (Figures 2B and S1). The electron density for the loops is weak and diffuse compared to the electron density for the β-strands. The B values for the loops are large, indicating that the loops are dynamic and not well ordered. Thus, the differences in backbone geometry and side chain rotamers among the loops are likely of little significance and should be interpreted with caution. protein PR: cleaner0 2023-07-10T14:00:00Z residue_range DUMMY: cleaner0 2023-07-10T14:00:11Z 25–28 0.9992186 structure_element cleaner0 2023-07-11T09:34:40Z SO: loops 0.99915147 oligomeric_state cleaner0 2023-07-10T09:57:24Z DUMMY: monomers 0.999589 evidence cleaner0 2023-07-10T14:57:50Z DUMMY: electron density 0.9990503 structure_element cleaner0 2023-07-11T09:34:45Z SO: loops 0.9995669 evidence cleaner0 2023-07-10T14:57:51Z DUMMY: electron density 0.99967366 structure_element cleaner0 2023-07-11T09:34:48Z SO: β-strands 0.9993787 evidence cleaner0 2023-07-10T14:57:55Z DUMMY: B values 0.99822277 structure_element cleaner0 2023-07-11T09:34:51Z SO: loops 0.9990182 structure_element cleaner0 2023-07-11T09:34:54Z SO: loops 0.99886763 structure_element cleaner0 2023-07-11T09:34:56Z SO: loops RESULTS paragraph 17653 Peptide 2 assembles into oligomers similar in morphology to those formed by peptide 1. Like peptide 1, peptide 2 forms a triangular trimer, and four trimers assemble to form a dodecamer. In the higher-order assembly of the dodecamers formed by peptide 2 a new structure emerges, not seen in peptide 1, an annular pore consisting of five dodecamers. 0.99781215 mutant cleaner0 2023-07-10T10:39:08Z MESH: Peptide 2 0.99908066 oligomeric_state cleaner0 2023-07-10T09:57:15Z DUMMY: oligomers 0.99880075 mutant cleaner0 2023-07-10T10:38:33Z MESH: peptide 1 0.9989558 mutant cleaner0 2023-07-10T10:38:33Z MESH: peptide 1 0.99889326 mutant cleaner0 2023-07-10T10:39:08Z MESH: peptide 2 0.98909026 protein_state cleaner0 2023-07-10T09:57:46Z DUMMY: triangular 0.99917245 oligomeric_state cleaner0 2023-07-10T09:57:07Z DUMMY: trimer 0.9990213 oligomeric_state cleaner0 2023-07-10T09:58:06Z DUMMY: trimers 0.99811757 oligomeric_state cleaner0 2023-07-10T15:22:02Z DUMMY: dodecamer 0.9985569 oligomeric_state cleaner0 2023-07-10T09:58:53Z DUMMY: dodecamers 0.9981346 mutant cleaner0 2023-07-10T10:39:08Z MESH: peptide 2 0.6090316 evidence cleaner0 2023-07-10T15:21:46Z DUMMY: structure 0.9986092 mutant cleaner0 2023-07-10T10:38:33Z MESH: peptide 1 0.83510053 site cleaner0 2023-07-10T14:08:22Z SO: annular pore 0.9990969 oligomeric_state cleaner0 2023-07-10T09:58:53Z DUMMY: dodecamers RESULTS title_3 18002 Trimer 0.99737906 oligomeric_state cleaner0 2023-07-10T09:57:07Z DUMMY: Trimer RESULTS paragraph 18009 Peptide 2 forms a trimer, much like that which we observed previously for peptide 1, in which three β-hairpins assemble to form an equilateral triangle (Figure 3A). The trimer maintains all of the same stabilizing contacts as those of peptide 1. Hydrogen bonding and hydrophobic interactions between residues on the β-strands comprising Aβ17–23 and Aβ30–36 stabilize the core of the trimer. The disulfide bonds between residues 24 and 29 are adjacent to the structural core of the trimer and do not make any substantial intermolecular contacts. Two crystallographically distinct trimers comprise the peptide portion of the asymmetric unit. The two trimers are almost identical in structure, differing slightly among side chain rotamers and loop conformations. 0.9708526 mutant cleaner0 2023-07-10T10:39:08Z MESH: Peptide 2 0.999243 oligomeric_state cleaner0 2023-07-10T09:57:07Z DUMMY: trimer 0.98338246 mutant cleaner0 2023-07-10T10:38:33Z MESH: peptide 1 0.9996609 structure_element cleaner0 2023-07-10T10:51:04Z SO: β-hairpins 0.6800581 structure_element cleaner0 2023-07-11T09:35:01Z SO: equilateral triangle 0.9992054 oligomeric_state cleaner0 2023-07-10T09:57:07Z DUMMY: trimer 0.8864662 mutant cleaner0 2023-07-10T10:38:33Z MESH: peptide 1 bond_interaction MESH: melaniev@ebi.ac.uk 2023-07-28T14:18:41Z Hydrogen bonding bond_interaction MESH: melaniev@ebi.ac.uk 2023-07-28T14:18:41Z hydrophobic interactions 0.99971074 structure_element cleaner0 2023-07-11T09:35:04Z SO: β-strands protein PR: cleaner0 2023-07-10T14:00:50Z residue_range DUMMY: cleaner0 2023-07-10T14:01:02Z 17–23 protein PR: cleaner0 2023-07-10T14:01:16Z residue_range DUMMY: cleaner0 2023-07-10T14:01:33Z 30–36 0.80977035 structure_element cleaner0 2023-07-11T09:35:16Z SO: core 0.9992182 oligomeric_state cleaner0 2023-07-10T09:57:07Z DUMMY: trimer 0.9961841 ptm cleaner0 2023-07-10T15:28:01Z MESH: disulfide bonds 0.9793444 residue_number cleaner0 2023-07-10T14:44:47Z DUMMY: 24 0.9923781 residue_number cleaner0 2023-07-10T14:44:51Z DUMMY: 29 0.7002436 structure_element cleaner0 2023-07-11T09:35:18Z SO: structural core 0.9992055 oligomeric_state cleaner0 2023-07-10T09:57:07Z DUMMY: trimer 0.9988949 oligomeric_state cleaner0 2023-07-10T09:58:06Z DUMMY: trimers chemical CHEBI: cleaner0 2023-07-10T10:31:21Z peptide 0.9986878 oligomeric_state cleaner0 2023-07-10T09:58:06Z DUMMY: trimers 0.99829334 structure_element cleaner0 2023-07-10T10:44:40Z SO: loop ja-2016-013325_0004.jpg fig3 FIG fig_caption 18781 X-ray crystallographic structure of the trimer formed by peptide 2. (A) Triangular trimer. The three water molecules in the center hole of the trimer are shown as spheres. (B) Detailed view of the intermolecular hydrogen bonds between the main chains of V18 and E22 and δOrn and C24, at the three corners of the triangular trimer. (C) The F19 face of the trimer, with key side chains shown as spheres. (D) The F20 face of the trimer, with key side chains as spheres. 0.9992159 evidence cleaner0 2023-07-10T10:23:29Z DUMMY: X-ray crystallographic structure 0.99929285 oligomeric_state cleaner0 2023-07-10T09:57:07Z DUMMY: trimer mutant MESH: cleaner0 2023-07-10T10:39:08Z peptide 2 0.9195634 protein_state cleaner0 2023-07-10T09:57:46Z DUMMY: Triangular 0.9992619 oligomeric_state cleaner0 2023-07-10T09:57:07Z DUMMY: trimer 0.9997776 chemical cleaner0 2023-07-10T15:34:00Z CHEBI: water 0.9992895 oligomeric_state cleaner0 2023-07-10T09:57:07Z DUMMY: trimer bond_interaction MESH: melaniev@ebi.ac.uk 2023-07-28T14:18:41Z hydrogen bonds 0.9998975 residue_name_number cleaner0 2023-07-10T13:57:38Z DUMMY: V18 0.99990034 residue_name_number cleaner0 2023-07-10T13:57:49Z DUMMY: E22 0.9998609 structure_element cleaner0 2023-07-10T14:03:39Z SO: δOrn 0.9998971 residue_name_number cleaner0 2023-07-10T13:57:54Z DUMMY: C24 0.8647282 protein_state cleaner0 2023-07-10T09:57:46Z DUMMY: triangular 0.9991831 oligomeric_state cleaner0 2023-07-10T09:57:07Z DUMMY: trimer 0.99988556 residue_name_number cleaner0 2023-07-10T10:49:34Z DUMMY: F19 0.999286 oligomeric_state cleaner0 2023-07-10T09:57:07Z DUMMY: trimer 0.9998834 residue_name_number cleaner0 2023-07-10T13:57:43Z DUMMY: F20 0.99926513 oligomeric_state cleaner0 2023-07-10T09:57:07Z DUMMY: trimer RESULTS paragraph 19252 A network of 18 intermolecular hydrogen bonds helps stabilize the trimer. At the corners of the trimer, the pairs of β-hairpin monomers form four hydrogen bonds: two between the main chains of V18 and E22 and two between δOrn and the main chain of C24 (Figure 3B). Three ordered water molecules fill the hole in the center of the trimer, hydrogen bonding to each other and to the main chain of F20 (Figure 3A). bond_interaction MESH: melaniev@ebi.ac.uk 2023-07-28T14:18:41Z hydrogen bonds 0.999288 oligomeric_state cleaner0 2023-07-10T09:57:07Z DUMMY: trimer 0.9992549 oligomeric_state cleaner0 2023-07-10T09:57:07Z DUMMY: trimer 0.9994802 structure_element cleaner0 2023-07-10T10:09:19Z SO: β-hairpin 0.99830544 oligomeric_state cleaner0 2023-07-10T09:57:24Z DUMMY: monomers bond_interaction MESH: melaniev@ebi.ac.uk 2023-07-28T14:18:41Z hydrogen bonds 0.99987984 residue_name_number cleaner0 2023-07-10T13:57:38Z DUMMY: V18 0.9998851 residue_name_number cleaner0 2023-07-10T13:57:49Z DUMMY: E22 0.9997837 structure_element cleaner0 2023-07-10T14:03:39Z SO: δOrn 0.9998801 residue_name_number cleaner0 2023-07-10T13:57:54Z DUMMY: C24 0.9997751 chemical cleaner0 2023-07-10T15:34:03Z CHEBI: water 0.9992343 oligomeric_state cleaner0 2023-07-10T09:57:07Z DUMMY: trimer bond_interaction MESH: melaniev@ebi.ac.uk 2023-07-28T14:18:41Z hydrogen bonding 0.9998777 residue_name_number cleaner0 2023-07-10T13:57:43Z DUMMY: F20 RESULTS paragraph 19670 Hydrophobic contacts between residues at the three corners of the trimer, where the β-hairpins meet, further stabilize the trimer. At each corner, the side chains of residues L17, F19, and V36 of one β-hairpin pack against the side chains of residues A21, I32, L34, and also D23 of the adjacent β-hairpin to create a hydrophobic cluster (Figure 3C). The three hydrophobic clusters create a large hydrophobic surface on one face of the trimer. The other face of the trimer displays a smaller hydrophobic surface, which includes the side chains of residues V18, F20, and I31 of the three β-hairpins (Figure 3D). In subsequent discussion, we designate the former surface the “F19 face” and the latter surface the “F20 face”. bond_interaction MESH: melaniev@ebi.ac.uk 2023-07-28T14:18:41Z Hydrophobic contacts 0.99907696 oligomeric_state cleaner0 2023-07-10T09:57:07Z DUMMY: trimer 0.9996171 structure_element cleaner0 2023-07-10T10:51:04Z SO: β-hairpins 0.9992318 oligomeric_state cleaner0 2023-07-10T09:57:07Z DUMMY: trimer 0.9999 residue_name_number cleaner0 2023-07-10T13:57:03Z DUMMY: L17 0.99989927 residue_name_number cleaner0 2023-07-10T10:49:34Z DUMMY: F19 0.9999001 residue_name_number cleaner0 2023-07-10T13:57:33Z DUMMY: V36 0.99961406 structure_element cleaner0 2023-07-10T10:09:19Z SO: β-hairpin 0.9999045 residue_name_number cleaner0 2023-07-10T13:57:12Z DUMMY: A21 0.9999031 residue_name_number cleaner0 2023-07-10T13:57:22Z DUMMY: I32 0.99990225 residue_name_number cleaner0 2023-07-10T13:57:27Z DUMMY: L34 0.999902 residue_name_number cleaner0 2023-07-10T10:49:38Z DUMMY: D23 0.99961996 structure_element cleaner0 2023-07-10T10:09:19Z SO: β-hairpin 0.99905705 site cleaner0 2023-07-10T14:54:17Z SO: hydrophobic cluster 0.99815303 site cleaner0 2023-07-10T14:04:47Z SO: hydrophobic clusters 0.99938655 site cleaner0 2023-07-10T14:04:53Z SO: hydrophobic surface 0.99910957 oligomeric_state cleaner0 2023-07-10T09:57:07Z DUMMY: trimer 0.9990772 oligomeric_state cleaner0 2023-07-10T09:57:07Z DUMMY: trimer 0.99921834 site cleaner0 2023-07-10T14:04:53Z SO: hydrophobic surface 0.9999033 residue_name_number cleaner0 2023-07-10T13:57:38Z DUMMY: V18 0.99990296 residue_name_number cleaner0 2023-07-10T13:57:43Z DUMMY: F20 0.99990034 residue_name_number cleaner0 2023-07-10T13:58:04Z DUMMY: I31 0.9995834 structure_element cleaner0 2023-07-10T10:51:04Z SO: β-hairpins 0.99988294 residue_name_number cleaner0 2023-07-10T10:49:34Z DUMMY: F19 0.99988115 residue_name_number cleaner0 2023-07-10T13:57:43Z DUMMY: F20 RESULTS title_3 20404 Dodecamer 0.9991642 oligomeric_state cleaner0 2023-07-11T09:35:39Z DUMMY: Dodecamer RESULTS paragraph 20414 Four trimers assemble to form a dodecamer. The four trimers arrange in a tetrahedral fashion, creating a central cavity inside the dodecamer. Because each trimer is triangular, the resulting arrangement resembles an octahedron. Each of the 12 β-hairpins constitutes an edge of the octahedron, and the triangular trimers occupy four of the eight faces of the octahedron. Figure 4A illustrates the octahedral shape of the dodecamer. Figure 4B illustrates the tetrahedral arrangement of the four trimers. 0.92943406 oligomeric_state cleaner0 2023-07-10T09:58:06Z DUMMY: trimers 0.9883305 oligomeric_state cleaner0 2023-07-11T09:35:47Z DUMMY: dodecamer 0.9677702 oligomeric_state cleaner0 2023-07-10T09:58:06Z DUMMY: trimers 0.68210614 protein_state cleaner0 2023-07-10T15:46:55Z DUMMY: tetrahedral 0.94942534 site cleaner0 2023-07-10T14:06:25Z SO: central cavity 0.987146 oligomeric_state cleaner0 2023-07-11T09:35:56Z DUMMY: dodecamer 0.99367625 oligomeric_state cleaner0 2023-07-10T09:57:07Z DUMMY: trimer 0.89434457 protein_state cleaner0 2023-07-10T09:57:46Z DUMMY: triangular 0.9869421 protein_state cleaner0 2023-07-10T10:01:19Z DUMMY: octahedron 0.9996304 structure_element cleaner0 2023-07-10T10:51:04Z SO: β-hairpins 0.6038043 protein_state cleaner0 2023-07-10T10:01:20Z DUMMY: octahedron 0.9887107 protein_state cleaner0 2023-07-10T09:57:46Z DUMMY: triangular 0.97976136 oligomeric_state cleaner0 2023-07-10T09:58:06Z DUMMY: trimers 0.6768757 protein_state cleaner0 2023-07-10T10:01:20Z DUMMY: octahedron protein_state DUMMY: cleaner0 2023-07-11T09:36:15Z octahedral 0.97393256 oligomeric_state cleaner0 2023-07-11T09:36:05Z DUMMY: dodecamer 0.99546045 protein_state cleaner0 2023-07-10T15:47:25Z DUMMY: tetrahedral 0.9308589 oligomeric_state cleaner0 2023-07-10T09:58:06Z DUMMY: trimers ja-2016-013325_0005.jpg fig4 FIG fig_caption 20919 X-ray crystallographic structure of the dodecamer formed by peptide 2. (A) View of the dodecamer that illustrates the octahedral shape. (B) View of the dodecamer that illustrates the tetrahedral arrangement of the four trimers that comprise the dodecamer. (C) View of two trimer subunits from inside the cavity of the dodecamer. Residues L17, L34, and V36 are shown as spheres, illustrating the hydrophobic packing that occurs at the six vertices of the dodecamer. (D) Detailed view of one of the six vertices of the dodecamer. 0.99948007 evidence cleaner0 2023-07-10T15:22:14Z DUMMY: X-ray crystallographic structure 0.9991375 oligomeric_state cleaner0 2023-07-10T14:22:51Z DUMMY: dodecamer 0.9928001 mutant cleaner0 2023-07-10T10:39:08Z MESH: peptide 2 0.99905556 oligomeric_state cleaner0 2023-07-10T14:23:00Z DUMMY: dodecamer protein_state DUMMY: cleaner0 2023-07-10T15:47:46Z octahedral 0.99870574 oligomeric_state cleaner0 2023-07-10T14:23:06Z DUMMY: dodecamer protein_state DUMMY: cleaner0 2023-07-10T15:48:02Z tetrahedral 0.9834343 oligomeric_state cleaner0 2023-07-10T09:58:06Z DUMMY: trimers 0.9980312 oligomeric_state cleaner0 2023-07-10T14:23:14Z DUMMY: dodecamer 0.9939126 oligomeric_state cleaner0 2023-07-10T09:57:07Z DUMMY: trimer 0.6427129 structure_element cleaner0 2023-07-10T14:28:53Z SO: subunits 0.96798074 site cleaner0 2023-07-10T14:54:30Z SO: cavity 0.99848217 oligomeric_state cleaner0 2023-07-10T14:23:20Z DUMMY: dodecamer 0.999864 residue_name_number cleaner0 2023-07-10T13:57:03Z DUMMY: L17 0.9998683 residue_name_number cleaner0 2023-07-10T13:57:27Z DUMMY: L34 0.99987245 residue_name_number cleaner0 2023-07-10T13:57:33Z DUMMY: V36 bond_interaction MESH: melaniev@ebi.ac.uk 2023-07-28T14:18:41Z hydrophobic packing 0.9971776 oligomeric_state cleaner0 2023-07-10T14:23:25Z DUMMY: dodecamer 0.9980862 oligomeric_state cleaner0 2023-07-10T14:23:32Z DUMMY: dodecamer RESULTS paragraph 21447 The F19 faces of the trimers line the interior of the dodecamer. At the six vertices, hydrophobic packing between the side chains of L17, L34, and V36 helps stabilize the dodecamer (Figures 4C and D). Salt bridges between the side chains of D23 and δOrn at the vertices further stabilize the dodecamer. Each of the six vertices includes two Aβ25–28 loops that extend past the core of the dodecamer without making any substantial intermolecular contacts. The exterior of the dodecamer displays four F20 faces (Figure S3). In the crystal lattice, each F20 face of one dodecamer packs against an F20 face of another dodecamer. Although the asymmetric unit comprises half a dodecamer, the crystal lattice may be thought of as being built of dodecamers. 0.99988055 residue_name_number cleaner0 2023-07-10T10:49:34Z DUMMY: F19 0.9881462 oligomeric_state cleaner0 2023-07-10T09:58:06Z DUMMY: trimers 0.9855783 oligomeric_state cleaner0 2023-07-10T14:23:53Z DUMMY: dodecamer bond_interaction MESH: melaniev@ebi.ac.uk 2023-07-28T14:18:41Z hydrophobic packing 0.99987864 residue_name_number cleaner0 2023-07-10T13:57:03Z DUMMY: L17 0.99987817 residue_name_number cleaner0 2023-07-10T13:57:27Z DUMMY: L34 0.9998815 residue_name_number cleaner0 2023-07-10T13:57:33Z DUMMY: V36 0.9894287 oligomeric_state cleaner0 2023-07-10T14:24:01Z DUMMY: dodecamer 0.99987495 residue_name_number cleaner0 2023-07-10T10:49:38Z DUMMY: D23 0.9998466 structure_element cleaner0 2023-07-10T14:03:39Z SO: δOrn 0.98633343 oligomeric_state cleaner0 2023-07-10T14:24:12Z DUMMY: dodecamer protein PR: cleaner0 2023-07-10T14:05:44Z residue_range DUMMY: cleaner0 2023-07-10T14:05:55Z 25–28 structure_element SO: cleaner0 2023-07-10T14:06:05Z loops 0.99597794 structure_element cleaner0 2023-07-11T09:36:22Z SO: core 0.99218833 oligomeric_state cleaner0 2023-07-10T14:24:22Z DUMMY: dodecamer 0.9943877 oligomeric_state cleaner0 2023-07-10T14:24:30Z DUMMY: dodecamer 0.70828927 residue_name_number cleaner0 2023-07-10T13:57:43Z DUMMY: F20 0.9666192 evidence cleaner0 2023-07-10T15:22:19Z DUMMY: crystal lattice 0.9916802 residue_name_number cleaner0 2023-07-10T13:57:43Z DUMMY: F20 0.9694082 oligomeric_state cleaner0 2023-07-10T14:24:40Z DUMMY: dodecamer 0.98894006 residue_name_number cleaner0 2023-07-10T13:57:43Z DUMMY: F20 0.9841942 oligomeric_state cleaner0 2023-07-10T14:24:51Z DUMMY: dodecamer 0.9857307 oligomeric_state cleaner0 2023-07-10T14:25:02Z DUMMY: dodecamer 0.856898 evidence cleaner0 2023-07-10T15:22:21Z DUMMY: crystal lattice 0.9417257 oligomeric_state cleaner0 2023-07-10T09:58:53Z DUMMY: dodecamers RESULTS paragraph 22203 The electron density map for the X-ray crystallographic structure of peptide 2 has long tubes of electron density inside the central cavity of the dodecamer. The shape and length of the electron density is consistent with the structure of Jeffamine M-600, which is an essential component of the crystallization conditions. Jeffamine M-600 is a polypropylene glycol derivative with a 2-methoxyethoxy unit at one end and a 2-aminopropyl unit at the other end. Its average molecular weight is about 600 Da, which corresponds to nine propylene glycol units. Although Jeffamine M-600 is a heterogeneous mixture with varying chain lengths and stereochemistry, we modeled a single stereoisomer with nine propylene glycol units (n = 9) to fit the electron density. The Jeffamine M-600 appears to stabilize the dodecamer by occupying the central cavity and making hydrophobic contacts with residues lining the cavity (Figure S3). In a dodecamer formed by full-length Aβ, the hydrophobic C-terminal residues (Aβ37–40 or Aβ37–42) might play a similar role in filling the dodecamer and thus create a packed hydrophobic core within the central cavity of the dodecamer. 0.99958426 evidence cleaner0 2023-07-10T15:22:29Z DUMMY: electron density map 0.9995545 evidence cleaner0 2023-07-10T10:23:29Z DUMMY: X-ray crystallographic structure 0.97934306 mutant cleaner0 2023-07-10T10:39:09Z MESH: peptide 2 0.9995809 evidence cleaner0 2023-07-10T14:57:51Z DUMMY: electron density 0.99335635 site cleaner0 2023-07-10T14:06:25Z SO: central cavity 0.9986966 oligomeric_state cleaner0 2023-07-10T14:16:52Z DUMMY: dodecamer 0.9995684 evidence cleaner0 2023-07-10T14:57:51Z DUMMY: electron density 0.99932253 evidence cleaner0 2023-07-10T15:22:42Z DUMMY: structure 0.9993839 chemical cleaner0 2023-07-10T15:34:09Z CHEBI: Jeffamine M-600 0.999519 chemical cleaner0 2023-07-10T15:34:12Z CHEBI: Jeffamine M-600 0.99952114 chemical cleaner0 2023-07-10T15:34:50Z CHEBI: Jeffamine M-600 0.99959373 evidence cleaner0 2023-07-10T14:57:51Z DUMMY: electron density 0.9994647 chemical cleaner0 2023-07-10T15:34:52Z CHEBI: Jeffamine M-600 0.99720436 oligomeric_state cleaner0 2023-07-10T14:17:02Z DUMMY: dodecamer 0.9966955 site cleaner0 2023-07-10T14:06:24Z SO: central cavity bond_interaction MESH: melaniev@ebi.ac.uk 2023-07-28T14:18:41Z hydrophobic contacts 0.975463 site cleaner0 2023-07-10T14:54:47Z SO: cavity 0.9955487 oligomeric_state cleaner0 2023-07-10T14:17:12Z DUMMY: dodecamer 0.9995497 protein_state cleaner0 2023-07-10T14:29:13Z DUMMY: full-length 0.4306851 protein cleaner0 2023-07-10T10:08:55Z PR: protein PR: cleaner0 2023-07-10T14:06:48Z residue_range DUMMY: cleaner0 2023-07-10T14:07:02Z 37–40 protein PR: cleaner0 2023-07-10T14:07:18Z residue_range DUMMY: cleaner0 2023-07-10T14:07:38Z 37–42 0.99829847 oligomeric_state cleaner0 2023-07-10T14:17:22Z DUMMY: dodecamer 0.9977617 site cleaner0 2023-07-10T14:54:50Z SO: hydrophobic core 0.9987234 site cleaner0 2023-07-10T14:06:25Z SO: central cavity 0.9980034 oligomeric_state cleaner0 2023-07-10T14:17:30Z DUMMY: dodecamer RESULTS title_3 23368 Annular Pore 0.55672383 site cleaner0 2023-07-10T14:08:22Z SO: Annular Pore RESULTS paragraph 23381 Five dodecamers assemble to form an annular porelike structure (Figure 5A). Hydrophobic packing between the F20 faces of trimers displayed on the outer surface of each dodecamer stabilizes the porelike assembly. Two morphologically distinct interactions between trimers occur at the interfaces of the five dodecamers: one in which the trimers are eclipsed (Figure 5B), and one in which the trimers are staggered (Figure 5C). Hydrophobic packing between the side chains of F20, I31, and E22 stabilizes these interfaces (Figure 5D and E). The annular pore contains three eclipsed interfaces and two staggered interfaces. The eclipsed interfaces occur between dodecamers 1 and 2, 1 and 5, and 3 and 4, as shown in Figure 5A. The staggered interfaces occur between dodecamers 2 and 3 and 4 and 5. The annular pore is not completely flat, instead, adopting a slightly puckered shape, which accommodates the eclipsed and staggered interfaces. Ten Aβ25–28 loops from the vertices of the five dodecamers line the hole in the center of the pore. The hydrophilic side chains of S26, N27, and K28 decorate the hole. 0.9947389 oligomeric_state cleaner0 2023-07-10T09:58:53Z DUMMY: dodecamers 0.46617872 structure_element cleaner0 2023-07-11T09:36:26Z SO: porelike bond_interaction MESH: melaniev@ebi.ac.uk 2023-07-28T14:18:41Z Hydrophobic packing 0.9994198 residue_name_number cleaner0 2023-07-10T13:57:43Z DUMMY: F20 0.9937476 oligomeric_state cleaner0 2023-07-10T09:58:06Z DUMMY: trimers 0.99768627 oligomeric_state cleaner0 2023-07-10T14:16:35Z DUMMY: dodecamer 0.98369724 oligomeric_state cleaner0 2023-07-10T09:58:06Z DUMMY: trimers 0.99890244 site cleaner0 2023-07-10T14:09:34Z SO: interfaces 0.9975661 oligomeric_state cleaner0 2023-07-10T09:58:53Z DUMMY: dodecamers 0.9835196 oligomeric_state cleaner0 2023-07-10T09:58:06Z DUMMY: trimers protein_state DUMMY: cleaner0 2023-07-10T15:48:24Z eclipsed 0.98756206 oligomeric_state cleaner0 2023-07-10T09:58:06Z DUMMY: trimers 0.9984919 protein_state cleaner0 2023-07-10T15:48:30Z DUMMY: staggered bond_interaction MESH: melaniev@ebi.ac.uk 2023-07-28T14:18:41Z Hydrophobic packing 0.999902 residue_name_number cleaner0 2023-07-10T13:57:43Z DUMMY: F20 0.9998994 residue_name_number cleaner0 2023-07-10T13:58:05Z DUMMY: I31 0.9999013 residue_name_number cleaner0 2023-07-10T13:57:49Z DUMMY: E22 0.99853134 site cleaner0 2023-07-10T14:09:35Z SO: interfaces site SO: cleaner0 2023-07-10T14:08:21Z annular pore 0.98955053 protein_state cleaner0 2023-07-10T15:48:24Z DUMMY: eclipsed 0.9773628 site cleaner0 2023-07-10T14:09:33Z SO: interfaces 0.9603877 protein_state cleaner0 2023-07-10T15:48:30Z DUMMY: staggered 0.9564764 site cleaner0 2023-07-10T14:09:35Z SO: interfaces 0.99811506 protein_state cleaner0 2023-07-10T15:48:24Z DUMMY: eclipsed 0.98816967 site cleaner0 2023-07-10T14:09:35Z SO: interfaces 0.9447598 structure_element cleaner0 2023-07-10T10:06:34Z SO: dodecamers 1 and 2 0.8105362 structure_element cleaner0 2023-07-11T09:36:31Z SO: 1 and 5 0.7737394 structure_element cleaner0 2023-07-11T09:36:35Z SO: 3 and 4 0.99496907 protein_state cleaner0 2023-07-10T15:48:30Z DUMMY: staggered 0.9717439 site cleaner0 2023-07-10T14:09:35Z SO: interfaces structure_element SO: cleaner0 2023-07-10T10:06:51Z dodecamers 2 and 3 0.9016544 structure_element cleaner0 2023-07-11T09:36:38Z SO: 4 and 5 site SO: cleaner0 2023-07-10T14:08:22Z annular pore 0.99846435 protein_state cleaner0 2023-07-10T15:48:24Z DUMMY: eclipsed 0.9233372 protein_state cleaner0 2023-07-10T15:48:30Z DUMMY: staggered 0.9233138 site cleaner0 2023-07-10T14:09:35Z SO: interfaces protein PR: cleaner0 2023-07-10T14:09:53Z residue_range DUMMY: cleaner0 2023-07-10T14:10:10Z 25–28 0.9773431 structure_element cleaner0 2023-07-11T09:36:41Z SO: loops 0.9940684 oligomeric_state cleaner0 2023-07-10T09:58:53Z DUMMY: dodecamers 0.9651338 site cleaner0 2023-07-10T14:54:57Z SO: pore 0.9999002 residue_name_number cleaner0 2023-07-10T14:10:48Z DUMMY: S26 0.99989796 residue_name_number cleaner0 2023-07-10T14:10:43Z DUMMY: N27 0.9998975 residue_name_number cleaner0 2023-07-10T14:10:38Z DUMMY: K28 ja-2016-013325_0006.jpg fig5 FIG fig_caption 24489 X-ray crystallographic structure of the annular pore formed by peptide 2. (A) Annular porelike structure illustrating the relationship of the five dodecamers that form the pore (top view). (B) Eclipsed interface between dodecamers 1 and 2 (side view). The same eclipsed interface also occurs between dodecamers 1 and 5 and 3 and 4. (C) Staggered interface between dodecamers 2 and 3 (side view). The same staggered interface also occurs between dodecamers 4 and 5. (D) Eclipsed interface between dodecamers 1 and 5 (top view). Residues F20, I31, and E22 are shown as spheres to detail the hydrophobic packing. (E) Staggered interface between dodecamers 2 and 3 (top view). Residues F20, I31, and E22 are shown as spheres to detail the hydrophobic packing. 0.99919903 evidence cleaner0 2023-07-10T10:23:29Z DUMMY: X-ray crystallographic structure 0.7619935 site cleaner0 2023-07-10T14:08:22Z SO: annular pore 0.9839363 mutant cleaner0 2023-07-10T10:39:09Z MESH: peptide 2 0.9952337 structure_element cleaner0 2023-07-11T09:36:50Z SO: Annular porelike 0.76622033 evidence cleaner0 2023-07-10T15:22:49Z DUMMY: structure 0.99862015 oligomeric_state cleaner0 2023-07-10T09:58:53Z DUMMY: dodecamers 0.99661726 site cleaner0 2023-07-10T14:55:02Z SO: pore 0.99857295 site cleaner0 2023-07-10T14:55:12Z SO: Eclipsed interface structure_element SO: cleaner0 2023-07-10T10:04:45Z dodecamers 1 and 2 0.99860144 site cleaner0 2023-07-10T14:55:13Z SO: eclipsed interface structure_element SO: cleaner0 2023-07-10T10:05:01Z dodecamers 1 and 5 structure_element SO: cleaner0 2023-07-10T10:03:23Z 3 and 4 0.9986403 site cleaner0 2023-07-10T14:55:19Z SO: Staggered interface structure_element SO: cleaner0 2023-07-10T10:05:16Z dodecamers 2 and 3 0.9983357 site cleaner0 2023-07-10T14:55:19Z SO: staggered interface structure_element SO: cleaner0 2023-07-10T10:05:31Z dodecamers 4 and 5 0.9980626 site cleaner0 2023-07-10T14:55:13Z SO: Eclipsed interface structure_element SO: cleaner0 2023-07-10T10:05:46Z dodecamers 1 and 5 0.9998859 residue_name_number cleaner0 2023-07-10T13:57:43Z DUMMY: F20 0.9998832 residue_name_number cleaner0 2023-07-10T13:58:05Z DUMMY: I31 0.99988735 residue_name_number cleaner0 2023-07-10T13:57:49Z DUMMY: E22 bond_interaction MESH: melaniev@ebi.ac.uk 2023-07-28T14:18:41Z hydrophobic packing 0.9983897 site cleaner0 2023-07-10T14:55:19Z SO: Staggered interface structure_element SO: cleaner0 2023-07-10T10:06:01Z dodecamers 2 and 3 0.9998871 residue_name_number cleaner0 2023-07-10T13:57:43Z DUMMY: F20 0.9998814 residue_name_number cleaner0 2023-07-10T13:58:05Z DUMMY: I31 0.99988616 residue_name_number cleaner0 2023-07-10T13:57:49Z DUMMY: E22 bond_interaction MESH: melaniev@ebi.ac.uk 2023-07-28T14:18:41Z hydrophobic packing RESULTS paragraph 25245 The annular pore is comparable in size to other large protein assemblies. The outer diameter is ∼11–12 nm. The diameter of the hole in the center of the pore is ∼2 nm. The thickness of the pore is ∼5 nm, which is comparable to that of a lipid bilayer membrane. It is important to note that the annular pore formed by peptide 2 is not a discrete unit in the crystal lattice. Rather, the crystal lattice is composed of conjoined annular pores in which all four F20 faces on the surface of each dodecamer contact F20 faces on other dodecamers (Figure S4). The crystal lattice shows how the dodecamers can further assemble to form larger structures. Each dodecamer may be thought of as a tetravalent building block with the potential to assemble on all four faces to form higher-order supramolecular assemblies. 0.6856659 site cleaner0 2023-07-10T14:08:22Z SO: annular pore 0.9704287 site cleaner0 2023-07-10T14:55:26Z SO: pore 0.9694308 site cleaner0 2023-07-10T14:55:29Z SO: pore 0.67850506 site cleaner0 2023-07-10T14:08:22Z SO: annular pore 0.994282 mutant cleaner0 2023-07-10T10:39:09Z MESH: peptide 2 0.99795693 evidence cleaner0 2023-07-10T15:22:54Z DUMMY: crystal lattice 0.9919589 evidence cleaner0 2023-07-10T15:22:56Z DUMMY: crystal lattice site SO: cleaner0 2023-07-10T14:25:54Z annular pores 0.88399476 residue_name_number cleaner0 2023-07-10T13:57:43Z DUMMY: F20 0.99921536 oligomeric_state cleaner0 2023-07-10T14:16:05Z DUMMY: dodecamer 0.92644376 residue_name_number cleaner0 2023-07-10T13:57:43Z DUMMY: F20 0.99911577 oligomeric_state cleaner0 2023-07-10T09:58:54Z DUMMY: dodecamers 0.9943179 evidence cleaner0 2023-07-10T15:22:58Z DUMMY: crystal lattice 0.99896383 oligomeric_state cleaner0 2023-07-10T09:58:54Z DUMMY: dodecamers 0.99923635 oligomeric_state cleaner0 2023-07-10T14:16:15Z DUMMY: dodecamer DISCUSS title_1 26061 Discussion DISCUSS paragraph 26072 The X-ray crystallographic study of peptide 2 described here provides high-resolution structures of oligomers formed by an Aβ17–36 β-hairpin. The crystallographic assembly of peptide 2 into a trimer, dodecamer, and annular pore provides a model for the assembly of the full-length Aβ peptide to form oligomers. In this model Aβ folds to form a β-hairpin comprising the hydrophobic central and C-terminal regions. Three β-hairpins assemble to form a trimer, and four trimers assemble to form a dodecamer. The dodecamers further assemble to form an annular pore (Figure 6). 0.99939936 experimental_method cleaner0 2023-07-10T15:40:51Z MESH: X-ray crystallographic study 0.99834687 mutant cleaner0 2023-07-10T10:39:09Z MESH: peptide 2 0.9981528 evidence cleaner0 2023-07-10T15:23:06Z DUMMY: structures 0.99295276 oligomeric_state cleaner0 2023-07-10T09:57:15Z DUMMY: oligomers protein PR: cleaner0 2023-07-10T14:14:44Z residue_range DUMMY: cleaner0 2023-07-10T14:14:58Z 17–36 0.99963754 structure_element cleaner0 2023-07-10T10:09:19Z SO: β-hairpin 0.8816129 evidence cleaner0 2023-07-10T15:41:09Z DUMMY: crystallographic assembly 0.9982991 mutant cleaner0 2023-07-10T10:39:09Z MESH: peptide 2 0.9985261 oligomeric_state cleaner0 2023-07-10T09:57:07Z DUMMY: trimer 0.9975731 oligomeric_state cleaner0 2023-07-10T14:15:26Z DUMMY: dodecamer site SO: cleaner0 2023-07-10T14:08:22Z annular pore 0.9995305 protein_state cleaner0 2023-07-10T14:29:13Z DUMMY: full-length protein PR: cleaner0 2023-07-10T10:08:55Z 0.99453884 oligomeric_state cleaner0 2023-07-10T09:57:15Z DUMMY: oligomers 0.9411563 protein cleaner0 2023-07-10T10:08:55Z PR: 0.9996684 structure_element cleaner0 2023-07-10T10:09:19Z SO: β-hairpin 0.9953944 structure_element cleaner0 2023-07-11T09:36:57Z SO: central and C-terminal regions 0.99965125 structure_element cleaner0 2023-07-10T10:51:04Z SO: β-hairpins 0.9991762 oligomeric_state cleaner0 2023-07-10T09:57:07Z DUMMY: trimer 0.9989819 oligomeric_state cleaner0 2023-07-10T09:58:06Z DUMMY: trimers 0.9929763 oligomeric_state cleaner0 2023-07-10T14:15:35Z DUMMY: dodecamer 0.9912322 oligomeric_state cleaner0 2023-07-10T09:58:54Z DUMMY: dodecamers site SO: cleaner0 2023-07-10T14:08:22Z annular pore ja-2016-013325_0007.jpg fig6 FIG fig_caption 26662 Model for the hierarchical assembly of an Aβ β-hairpin into a trimer, dodecamer, and annular pore based on the crystallographic assembly of peptide 2. Monomeric Aβ folds to form a β-hairpin in which the hydrophobic central and C-terminal regions form an antiparallel β-sheet. Three β-hairpin monomers assemble to form a triangular trimer. Four triangular trimers assemble to form a dodecamer. Five dodecamers assemble to form an annular pore. The molecular weights shown correspond to an Aβ42 monomer (∼4.5 kDa), an Aβ42 trimer (∼13.5 kDa), an Aβ42 dodecamer (∼54 kDa), and an Aβ42 annular pore composed of five dodecamers (∼270 kDa). 0.46425954 protein cleaner0 2023-07-10T10:08:55Z PR: 0.99969107 structure_element cleaner0 2023-07-10T10:09:19Z SO: β-hairpin 0.9990308 oligomeric_state cleaner0 2023-07-10T09:57:07Z DUMMY: trimer 0.879043 oligomeric_state cleaner0 2023-07-10T15:23:21Z DUMMY: dodecamer 0.8754952 site cleaner0 2023-07-10T14:08:22Z SO: annular pore 0.8207643 evidence cleaner0 2023-07-10T15:41:22Z DUMMY: crystallographic assembly 0.99860716 mutant cleaner0 2023-07-10T10:39:09Z MESH: peptide 2 0.9989329 oligomeric_state cleaner0 2023-07-10T09:58:25Z DUMMY: Monomeric 0.4228502 protein cleaner0 2023-07-10T10:08:55Z PR: 0.99969894 structure_element cleaner0 2023-07-10T10:09:19Z SO: β-hairpin 0.8335692 structure_element cleaner0 2023-07-11T09:37:00Z SO: central 0.96587986 structure_element cleaner0 2023-07-11T09:37:04Z SO: C-terminal regions 0.99966925 structure_element cleaner0 2023-07-11T09:37:10Z SO: antiparallel β-sheet 0.999692 structure_element cleaner0 2023-07-10T10:09:19Z SO: β-hairpin 0.9991974 oligomeric_state cleaner0 2023-07-10T09:57:24Z DUMMY: monomers 0.9414926 protein_state cleaner0 2023-07-10T09:57:46Z DUMMY: triangular 0.99896777 oligomeric_state cleaner0 2023-07-10T09:57:07Z DUMMY: trimer 0.79635763 protein_state cleaner0 2023-07-10T09:57:46Z DUMMY: triangular 0.9984816 oligomeric_state cleaner0 2023-07-10T09:58:06Z DUMMY: trimers 0.8916394 oligomeric_state cleaner0 2023-07-10T14:26:46Z DUMMY: dodecamer 0.89428616 oligomeric_state cleaner0 2023-07-10T09:58:54Z DUMMY: dodecamers 0.8921617 site cleaner0 2023-07-10T14:08:22Z SO: annular pore 0.99917895 protein cleaner0 2023-07-10T15:30:12Z PR: Aβ42 0.99933344 oligomeric_state cleaner0 2023-07-10T09:58:17Z DUMMY: monomer 0.9991387 protein cleaner0 2023-07-10T15:30:15Z PR: Aβ42 0.999338 oligomeric_state cleaner0 2023-07-10T09:57:07Z DUMMY: trimer 0.99744 protein cleaner0 2023-07-10T15:30:18Z PR: Aβ42 0.99199814 oligomeric_state cleaner0 2023-07-10T14:26:53Z DUMMY: dodecamer 0.9983273 protein cleaner0 2023-07-10T15:30:24Z PR: Aβ42 0.9344156 site cleaner0 2023-07-10T14:08:22Z SO: annular pore 0.99022186 oligomeric_state cleaner0 2023-07-10T09:58:54Z DUMMY: dodecamers DISCUSS paragraph 27327 The model put forth in Figure 6 is consistent with the current understanding of endogenous Aβ oligomerization and explains at atomic resolution many key observations about Aβ oligomers. Two general types of endogenous Aβ oligomers have been observed: Aβ oligomers that occur on a pathway to fibrils, or “fibrillar oligomers”, and Aβ oligomers that evade a fibrillar fate, or “nonfibrillar oligomers”.− Fibrillar oligomers accumulate in Alzheimer’s disease later than nonfibrillar oligomers and coincide with the deposition of plaques. Nonfibrillar oligomers accumulate early in Alzheimer’s disease before plaque deposition. 0.98362213 protein cleaner0 2023-07-10T10:08:55Z PR: 0.69500244 protein cleaner0 2023-07-10T10:08:55Z PR: 0.9968413 oligomeric_state cleaner0 2023-07-10T09:57:15Z DUMMY: oligomers 0.69728047 protein cleaner0 2023-07-10T10:08:55Z PR: 0.9842993 oligomeric_state cleaner0 2023-07-10T09:57:15Z DUMMY: oligomers 0.4827744 protein cleaner0 2023-07-10T10:08:55Z PR: 0.97100955 oligomeric_state cleaner0 2023-07-10T09:57:15Z DUMMY: oligomers 0.9607778 oligomeric_state cleaner0 2023-07-10T10:00:01Z DUMMY: fibrils 0.99556965 protein_state cleaner0 2023-07-10T15:49:02Z DUMMY: fibrillar 0.90404606 oligomeric_state cleaner0 2023-07-10T09:57:15Z DUMMY: oligomers 0.59141874 protein cleaner0 2023-07-10T10:08:55Z PR: 0.90367794 oligomeric_state cleaner0 2023-07-10T09:57:15Z DUMMY: oligomers protein_state DUMMY: cleaner0 2023-07-10T15:49:03Z fibrillar 0.99723345 protein_state cleaner0 2023-07-10T15:49:08Z DUMMY: nonfibrillar 0.93664545 oligomeric_state cleaner0 2023-07-10T09:57:15Z DUMMY: oligomers 0.99050224 protein_state cleaner0 2023-07-10T15:49:03Z DUMMY: Fibrillar 0.97474265 oligomeric_state cleaner0 2023-07-10T09:57:15Z DUMMY: oligomers 0.99849355 protein_state cleaner0 2023-07-10T15:49:08Z DUMMY: nonfibrillar 0.98835844 oligomeric_state cleaner0 2023-07-10T09:57:15Z DUMMY: oligomers 0.99834716 protein_state cleaner0 2023-07-10T15:49:08Z DUMMY: Nonfibrillar 0.9744353 oligomeric_state cleaner0 2023-07-10T09:57:15Z DUMMY: oligomers DISCUSS paragraph 27970 Fibrillar and nonfibrillar oligomers have structurally distinct characteristics, which are reflected in their reactivity with the fibril-specific OC antibody and the oligomer-specific A11 antibody. Fibrillar oligomers are recognized by the OC antibody but not the A11 antibody, whereas nonfibrillar oligomers are recognized by the A11 antibody but not the OC antibody. These criteria have been used to classify the Aβ oligomers that accumulate in vivo. Aβ dimers have been classified as fibrillar oligomers, whereas Aβ trimers, Aβ*56, and APFs have been classified as nonfibrillar oligomers. 0.99884295 protein_state cleaner0 2023-07-10T15:49:03Z DUMMY: Fibrillar 0.99918383 protein_state cleaner0 2023-07-10T15:49:08Z DUMMY: nonfibrillar 0.9958556 oligomeric_state cleaner0 2023-07-10T09:57:15Z DUMMY: oligomers oligomeric_state DUMMY: cleaner0 2023-07-10T09:59:26Z oligomer 0.9987214 protein_state cleaner0 2023-07-10T15:49:03Z DUMMY: Fibrillar 0.9927113 oligomeric_state cleaner0 2023-07-10T09:57:15Z DUMMY: oligomers 0.99916637 protein_state cleaner0 2023-07-10T15:49:08Z DUMMY: nonfibrillar 0.9938916 oligomeric_state cleaner0 2023-07-10T09:57:15Z DUMMY: oligomers 0.7839367 protein cleaner0 2023-07-10T10:08:55Z PR: 0.99323857 oligomeric_state cleaner0 2023-07-10T09:57:15Z DUMMY: oligomers 0.7455043 protein cleaner0 2023-07-10T10:08:56Z PR: 0.9992397 oligomeric_state cleaner0 2023-07-10T09:58:31Z DUMMY: dimers 0.99877805 protein_state cleaner0 2023-07-10T15:49:03Z DUMMY: fibrillar 0.9936293 oligomeric_state cleaner0 2023-07-10T09:57:15Z DUMMY: oligomers 0.8332771 protein cleaner0 2023-07-10T10:08:56Z PR: 0.99881977 oligomeric_state cleaner0 2023-07-10T09:58:06Z DUMMY: trimers 0.999163 complex_assembly cleaner0 2023-07-10T10:16:25Z GO: Aβ*56 0.7249561 complex_assembly cleaner0 2023-07-10T10:13:52Z GO: APFs 0.99906164 protein_state cleaner0 2023-07-10T15:49:08Z DUMMY: nonfibrillar 0.9969014 oligomeric_state cleaner0 2023-07-10T09:57:15Z DUMMY: oligomers DISCUSS paragraph 28574 Larson and Lesné proposed a model for the endogenous production of nonfibrillar oligomers that explains these observations. In this model, folded Aβ monomer assembles into a trimer, the trimer further assembles into hexamers and dodecamers, and the dodecamers further assemble to form annular protofibrils. The hierarchical assembly of peptide 2 is consistent with this model; and the trimer, dodecamer, and annular pore formed by peptide 2 may share similarities to the trimers, Aβ*56, and APFs observed in vivo. At this point, we can only speculate whether the trimer and dodecamer formed by peptide 2 share structural similarities to Aβ trimers and Aβ*56, as little is known about the structure of Aβ trimers and Aβ*56. 0.82338506 protein_state cleaner0 2023-07-10T15:49:08Z DUMMY: nonfibrillar 0.46907452 oligomeric_state cleaner0 2023-07-10T09:57:15Z DUMMY: oligomers 0.99957055 protein_state cleaner0 2023-07-10T14:40:20Z DUMMY: folded 0.8741774 protein cleaner0 2023-07-10T10:08:56Z PR: 0.99933285 oligomeric_state cleaner0 2023-07-10T09:58:17Z DUMMY: monomer 0.9993048 oligomeric_state cleaner0 2023-07-10T09:57:07Z DUMMY: trimer 0.99879164 oligomeric_state cleaner0 2023-07-10T09:57:07Z DUMMY: trimer 0.9681349 oligomeric_state cleaner0 2023-07-10T09:58:42Z DUMMY: hexamers 0.99741024 oligomeric_state cleaner0 2023-07-10T09:58:54Z DUMMY: dodecamers 0.9988606 oligomeric_state cleaner0 2023-07-10T09:58:54Z DUMMY: dodecamers complex_assembly GO: cleaner0 2023-07-10T10:16:52Z annular protofibrils 0.9990848 mutant cleaner0 2023-07-10T10:39:09Z MESH: peptide 2 0.9990043 oligomeric_state cleaner0 2023-07-10T09:57:07Z DUMMY: trimer 0.99851674 oligomeric_state cleaner0 2023-07-10T14:27:45Z DUMMY: dodecamer 0.93985254 site cleaner0 2023-07-10T14:08:22Z SO: annular pore 0.9988367 mutant cleaner0 2023-07-10T10:39:09Z MESH: peptide 2 0.9990896 oligomeric_state cleaner0 2023-07-10T09:58:06Z DUMMY: trimers 0.9994509 complex_assembly cleaner0 2023-07-10T10:16:25Z GO: Aβ*56 0.67791164 complex_assembly cleaner0 2023-07-10T10:13:52Z GO: APFs 0.99890137 oligomeric_state cleaner0 2023-07-10T09:57:07Z DUMMY: trimer 0.99848807 oligomeric_state cleaner0 2023-07-10T14:27:52Z DUMMY: dodecamer 0.99874556 mutant cleaner0 2023-07-10T10:39:09Z MESH: peptide 2 0.61046284 protein cleaner0 2023-07-10T10:08:56Z PR: 0.9991455 oligomeric_state cleaner0 2023-07-10T09:58:06Z DUMMY: trimers 0.9994221 complex_assembly cleaner0 2023-07-10T10:16:25Z GO: Aβ*56 0.9986656 evidence cleaner0 2023-07-10T15:23:29Z DUMMY: structure 0.5242032 protein cleaner0 2023-07-10T10:08:56Z PR: 0.99914396 oligomeric_state cleaner0 2023-07-10T09:58:06Z DUMMY: trimers 0.9994405 complex_assembly cleaner0 2023-07-10T10:16:25Z GO: Aβ*56 DISCUSS paragraph 29315 The crystallographically observed annular pore formed by peptide 2 is morphologically similar to the APFs formed by full-length Aβ. The annular pore formed by peptide 2 is comparable in size to the APFs prepared in vitro or isolated from Alzheimer’s brains (Figure 7 and Table 1). The varying sizes of APFs formed by full-length Aβ might result from differences in the number of oligomer subunits comprising each APF. Although the annular pore formed by peptide 2 contains five dodecamer subunits, pores containing fewer or more subunits can easily be envisioned. The dodecamers that comprise the annular pore exhibit two modes of assembly—eclipsed interactions and staggered interactions between the F20 faces of trimers within dodecamers. These two modes of assembly might reflect a dynamic interaction between dodecamers, which could permit assemblies of more dodecamers into larger annular pores. evidence DUMMY: cleaner0 2023-07-10T15:43:20Z crystallographically observed 0.74659073 site cleaner0 2023-07-10T14:08:22Z SO: annular pore 0.99914885 mutant cleaner0 2023-07-10T10:39:09Z MESH: peptide 2 0.9904997 complex_assembly cleaner0 2023-07-10T10:13:52Z GO: APFs 0.9995325 protein_state cleaner0 2023-07-10T14:29:12Z DUMMY: full-length 0.8696307 protein cleaner0 2023-07-10T10:08:56Z PR: 0.8513384 site cleaner0 2023-07-10T14:08:22Z SO: annular pore 0.9992081 mutant cleaner0 2023-07-10T10:39:09Z MESH: peptide 2 0.9876654 complex_assembly cleaner0 2023-07-10T10:13:52Z GO: APFs 0.99124134 complex_assembly cleaner0 2023-07-10T10:13:52Z GO: APFs 0.9995335 protein_state cleaner0 2023-07-10T14:29:13Z DUMMY: full-length 0.7001555 protein cleaner0 2023-07-10T10:08:56Z PR: 0.99407035 oligomeric_state cleaner0 2023-07-10T09:59:26Z DUMMY: oligomer 0.6554335 structure_element cleaner0 2023-07-10T14:28:52Z SO: subunits 0.9955497 complex_assembly cleaner0 2023-07-10T14:29:03Z GO: APF 0.818646 site cleaner0 2023-07-10T14:08:22Z SO: annular pore 0.9992809 mutant cleaner0 2023-07-10T10:39:09Z MESH: peptide 2 0.99894255 oligomeric_state cleaner0 2023-07-10T14:55:46Z DUMMY: dodecamer 0.9971551 structure_element cleaner0 2023-07-10T14:28:53Z SO: subunits 0.83031535 site cleaner0 2023-07-10T14:55:36Z SO: pores 0.9976739 structure_element cleaner0 2023-07-10T14:28:53Z SO: subunits 0.99886453 oligomeric_state cleaner0 2023-07-10T09:58:54Z DUMMY: dodecamers 0.7511022 site cleaner0 2023-07-10T14:08:22Z SO: annular pore protein_state DUMMY: cleaner0 2023-07-10T15:48:24Z eclipsed protein_state DUMMY: cleaner0 2023-07-10T15:48:30Z staggered 0.9966365 residue_name_number cleaner0 2023-07-10T13:57:43Z DUMMY: F20 0.9572813 oligomeric_state cleaner0 2023-07-10T09:58:06Z DUMMY: trimers 0.9883255 oligomeric_state cleaner0 2023-07-10T09:58:54Z DUMMY: dodecamers 0.99812466 oligomeric_state cleaner0 2023-07-10T09:58:54Z DUMMY: dodecamers 0.9975942 oligomeric_state cleaner0 2023-07-10T09:58:54Z DUMMY: dodecamers 0.7614624 site cleaner0 2023-07-10T14:55:50Z SO: annular pores ja-2016-013325_0008.jpg fig7 FIG fig_caption 30222 Surface views of the annular pore formed by peptide 2. (A) Top view. (B) Side view. 0.9367285 site cleaner0 2023-07-10T14:08:22Z SO: annular pore 0.9604572 mutant cleaner0 2023-07-10T10:39:09Z MESH: peptide 2 tbl1.xml tbl1 TABLE table_title_caption 30306 Annular Pores Formed by Aβ and Peptide 2 site SO: cleaner0 2023-07-10T14:29:49Z Annular Pores 0.49635306 protein cleaner0 2023-07-10T10:08:56Z PR: 0.9986495 mutant cleaner0 2023-07-10T10:39:09Z MESH: Peptide 2 tbl1.xml tbl1 TABLE table <?xml version="1.0" encoding="UTF-8"?> <table frame="hsides" rules="groups" border="0"><colgroup><col align="left"/><col align="center"/><col align="center"/><col align="left"/></colgroup><thead><tr><th style="border:none;" align="center">annular pore source</th><th style="border:none;" align="center">outer diameter</th><th style="border:none;" align="center">inner diameter</th><th style="border:none;" align="center">observation method</th></tr></thead><tbody><tr><td style="border:none;" align="left">peptide <bold>2</bold></td><td style="border:none;" align="center"> ∼11–12 nm</td><td style="border:none;" align="center">∼2 nm</td><td style="border:none;" align="left">X-ray crystallography</td></tr><tr><td style="border:none;" align="left">synthetic Aβ<sup><xref ref-type="bibr" rid="ref6">6</xref></sup></td><td style="border:none;" align="center">7–10 nm</td><td style="border:none;" align="center">1.5–2 nm</td><td style="border:none;" align="left">TEM</td></tr><tr><td style="border:none;" align="left">synthetic Aβ<sup><xref ref-type="bibr" rid="ref7">7</xref></sup></td><td style="border:none;" align="center">16 nm</td><td style="border:none;" align="center">not reported</td><td style="border:none;" align="left">AFM</td></tr><tr><td style="border:none;" align="left">synthetic Aβ<sup><xref ref-type="bibr" rid="ref8">8</xref></sup></td><td style="border:none;" align="center">8–25 nm</td><td style="border:none;" align="center">not reported</td><td style="border:none;" align="left">TEM</td></tr><tr><td style="border:none;" align="left">Alzheimer’s brain<sup><xref ref-type="bibr" rid="ref10">10</xref></sup></td><td style="border:none;" align="center">11–14 nm</td><td style="border:none;" align="center">2.5–4 nm</td><td style="border:none;" align="left">TEM</td></tr></tbody></table> 30350 annular pore source outer diameter inner diameter observation method peptide 2 ∼11–12 nm ∼2 nm X-ray crystallography synthetic Aβ 7–10 nm 1.5–2 nm TEM synthetic Aβ 16 nm not reported AFM synthetic Aβ 8–25 nm not reported TEM Alzheimer’s brain 11–14 nm 2.5–4 nm TEM site SO: cleaner0 2023-07-10T14:08:22Z annular pore chemical CHEBI: cleaner0 2023-07-10T10:31:21Z peptide 0.9993832 experimental_method cleaner0 2023-07-10T15:43:27Z MESH: X-ray crystallography 0.50929236 protein_state cleaner0 2023-07-10T15:49:22Z DUMMY: synthetic 0.72633183 protein cleaner0 2023-07-10T10:08:56Z PR: experimental_method MESH: cleaner0 2023-07-10T10:17:25Z TEM 0.68735087 protein cleaner0 2023-07-10T10:08:56Z PR: experimental_method MESH: cleaner0 2023-07-10T10:17:16Z AFM 0.725103 protein cleaner0 2023-07-10T10:08:56Z PR: experimental_method MESH: cleaner0 2023-07-10T10:17:25Z TEM experimental_method MESH: cleaner0 2023-07-10T10:17:25Z TEM DISCUSS paragraph 30663 Dot blot analysis shows that peptide 2 is reactive toward the A11 antibody (Figure S5). This reactivity suggests that peptide 2 forms oligomers in solution that share structural similarities to the nonfibrillar oligomers formed by full-length Aβ. Further studies are needed to elucidate the species that peptide 2 forms in solution and to study their biological properties. This is an active area of research in our laboratory. Preliminary attempts to study these species by SEC and SDS-PAGE have not provided a clear measure of the structures formed in solution. The difficulty in studying the oligomers formed in solution may reflect the propensity of the dodecamer to assemble on all four F20 faces. 0.9996084 experimental_method cleaner0 2023-07-10T15:43:34Z MESH: Dot blot 0.9719767 mutant cleaner0 2023-07-10T10:39:09Z MESH: peptide 2 0.9831927 mutant cleaner0 2023-07-10T10:39:09Z MESH: peptide 2 0.9981207 oligomeric_state cleaner0 2023-07-10T09:57:15Z DUMMY: oligomers 0.98931164 protein_state cleaner0 2023-07-10T15:49:08Z DUMMY: nonfibrillar 0.99711084 oligomeric_state cleaner0 2023-07-10T09:57:15Z DUMMY: oligomers 0.9995144 protein_state cleaner0 2023-07-10T14:29:13Z DUMMY: full-length 0.8415795 protein cleaner0 2023-07-10T10:08:56Z PR: 0.9940018 mutant cleaner0 2023-07-10T10:39:09Z MESH: peptide 2 0.9996823 experimental_method cleaner0 2023-07-10T15:37:37Z MESH: SEC 0.9995587 experimental_method cleaner0 2023-07-10T10:22:56Z MESH: SDS-PAGE 0.7605614 evidence cleaner0 2023-07-10T15:23:34Z DUMMY: structures 0.99833256 oligomeric_state cleaner0 2023-07-10T09:57:15Z DUMMY: oligomers 0.9996724 oligomeric_state cleaner0 2023-07-10T15:23:43Z DUMMY: dodecamer 0.99944156 residue_name_number cleaner0 2023-07-10T13:57:43Z DUMMY: F20 DISCUSS paragraph 31369 The X-ray crystallographic structure and A11 reactivity of peptide 2 support the model proposed by Larsen and Lesné and suggest that β-hairpins constitute a fundamental building block for nonfibrillar oligomers. What makes β-hairpins special is that three β-hairpins can nestle together to form trimers, stabilized by a network of hydrogen bonds and hydrophobic interactions. This mode of assembly is not unique to Aβ. The foldon domain of bacteriophage T4 fibritin is composed of three β-hairpins that assemble into a triangular trimer similar to the triangular trimer formed by peptide 2. Additionally, our research group has observed a similar assembly of a β-hairpin peptide derived from β2-microglobulin. 0.99950874 evidence cleaner0 2023-07-10T10:23:30Z DUMMY: X-ray crystallographic structure 0.99778897 mutant cleaner0 2023-07-10T10:39:09Z MESH: peptide 2 0.99964684 structure_element cleaner0 2023-07-10T10:51:04Z SO: β-hairpins 0.9959486 protein_state cleaner0 2023-07-10T15:49:08Z DUMMY: nonfibrillar 0.9490833 oligomeric_state cleaner0 2023-07-10T09:57:15Z DUMMY: oligomers 0.99963474 structure_element cleaner0 2023-07-10T10:51:04Z SO: β-hairpins 0.99953574 structure_element cleaner0 2023-07-10T10:51:05Z SO: β-hairpins 0.99923205 oligomeric_state cleaner0 2023-07-10T09:58:06Z DUMMY: trimers bond_interaction MESH: melaniev@ebi.ac.uk 2023-07-28T14:18:41Z hydrogen bonds bond_interaction MESH: melaniev@ebi.ac.uk 2023-07-28T14:18:41Z hydrophobic interactions 0.9831617 protein cleaner0 2023-07-10T10:08:56Z PR: 0.9996187 structure_element cleaner0 2023-07-11T09:37:39Z SO: foldon domain species MESH: cleaner0 2023-07-10T14:32:13Z bacteriophage T4 0.8102835 protein cleaner0 2023-07-10T14:31:00Z PR: fibritin 0.99958324 structure_element cleaner0 2023-07-10T10:51:05Z SO: β-hairpins 0.80067027 protein_state cleaner0 2023-07-10T09:57:46Z DUMMY: triangular 0.9992448 oligomeric_state cleaner0 2023-07-10T09:57:07Z DUMMY: trimer 0.8109537 protein_state cleaner0 2023-07-10T09:57:46Z DUMMY: triangular 0.99926907 oligomeric_state cleaner0 2023-07-10T09:57:07Z DUMMY: trimer 0.9844508 mutant cleaner0 2023-07-10T10:39:09Z MESH: peptide 2 0.99943477 structure_element cleaner0 2023-07-10T10:09:19Z SO: β-hairpin 0.97846574 protein cleaner0 2023-07-10T15:32:24Z PR: β2-microglobulin CONCL title_1 32100 Conclusion CONCL paragraph 32111 Although we began these studies with a relatively simple hypothesis—that the trimers and dodecamers formed by peptide 1 could accommodate the Aβ24–29 loop—an even more exciting finding has emerged—that the dodecamers can assemble to form annular pores. This finding could not have been anticipated from the X-ray crystallographic structure of peptide 1 and reveals a new level of hierarchical assembly that recapitulates micrographic observations of annular protofibrils. The crystallographically observed dodecamer, in turn, recapitulates the observation of Aβ*56, which appears to be a dodecamer of Aβ. The crystallographically observed trimer recapitulates the Aβ trimers that are observed even before the onset of symptoms in Alzheimer’s disease. 0.9979778 oligomeric_state cleaner0 2023-07-10T09:58:06Z DUMMY: trimers 0.96598125 oligomeric_state cleaner0 2023-07-10T09:58:54Z DUMMY: dodecamers 0.99939597 mutant cleaner0 2023-07-10T10:38:33Z MESH: peptide 1 protein PR: cleaner0 2023-07-10T14:32:48Z residue_range DUMMY: cleaner0 2023-07-10T14:32:59Z 24–29 structure_element SO: cleaner0 2023-07-10T10:44:40Z loop 0.9943329 oligomeric_state cleaner0 2023-07-10T09:58:54Z DUMMY: dodecamers site SO: cleaner0 2023-07-10T14:56:18Z annular pores 0.99947774 evidence cleaner0 2023-07-10T10:23:30Z DUMMY: X-ray crystallographic structure 0.99930394 mutant cleaner0 2023-07-10T10:38:33Z MESH: peptide 1 complex_assembly GO: cleaner0 2023-07-10T10:16:52Z annular protofibrils evidence DUMMY: cleaner0 2023-07-10T15:24:14Z crystallographically observed 0.996816 oligomeric_state cleaner0 2023-07-10T14:33:42Z DUMMY: dodecamer 0.99949056 complex_assembly cleaner0 2023-07-10T10:16:25Z GO: Aβ*56 0.9902602 oligomeric_state cleaner0 2023-07-10T14:33:51Z DUMMY: dodecamer 0.9434316 protein cleaner0 2023-07-10T10:08:56Z PR: evidence DUMMY: cleaner0 2023-07-10T15:43:49Z crystallographically observed 0.9990804 oligomeric_state cleaner0 2023-07-10T09:57:07Z DUMMY: trimer 0.74936247 protein cleaner0 2023-07-10T10:08:56Z PR: 0.9990004 oligomeric_state cleaner0 2023-07-10T09:58:06Z DUMMY: trimers CONCL paragraph 32876 Our approach of constraining Aβ17–36 into a β-hairpin conformation and blocking aggregation with an N-methyl group has allowed us to crystallize a large fragment of what is generally considered to be an uncrystallizable peptide. We believe this iterative, “bottom up” approach of identifying the minimal modification required to crystallize Aβ peptides will ultimately allow larger fragments of Aβ to be crystallized, thus providing greater insights into the structures of Aβ oligomers. protein PR: cleaner0 2023-07-11T09:38:52Z residue_range DUMMY: cleaner0 2023-07-11T09:39:09Z 17–36 structure_element SO: cleaner0 2023-07-10T10:09:19Z β-hairpin 0.9996012 experimental_method cleaner0 2023-07-10T15:44:11Z MESH: crystallize 0.9995086 experimental_method cleaner0 2023-07-10T15:44:15Z MESH: crystallize 0.9806091 protein cleaner0 2023-07-10T10:08:56Z PR: 0.98060685 protein cleaner0 2023-07-10T10:08:56Z PR: 0.9995915 experimental_method cleaner0 2023-07-10T15:44:18Z MESH: crystallized 0.735821 evidence cleaner0 2023-07-10T15:24:26Z DUMMY: structures 0.9897104 protein cleaner0 2023-07-10T10:08:56Z PR: 0.6001843 oligomeric_state cleaner0 2023-07-10T09:57:15Z DUMMY: oligomers SUPPL title 33378 Supporting Information Available SUPPL paragraph 33411 Procedures for the synthesis and crystallization of peptides 2–4; details of X-ray crystallographic data collection, processing, and refinement; procedure and data for dot blot analysis (PDF) SUPPL paragraph 33605 Crystallographic coordinates of peptide 2 deposited into the Protein Data Bank (PDB) with code 5HOX (data collected on a synchrotron at 1.00 Å wavelength) (PDB) SUPPL paragraph 33767 Crystallographic coordinates of peptide 2 deposited into the Protein Data Bank (PDB) with code 5HOY (data collected on an X-ray diffractometer at 1.54 Å wavelength) (PDB) SUPPL paragraph 33939 Crystallographic coordinates of peptide 4 deposited into the Protein Data Bank (PDB) with code 5HOW (PDB) SUPPL paragraph 34045 Crystallographic coordinates of the dodecamer formed by peptide 2 (PDB) SUPPL paragraph 34117 Crystallographic coordinates of the annular pore formed by peptide 2 (PDB) SUPPL paragraph 34192 Crystallographic data for 5HOW (CIF) SUPPL paragraph 34229 Crystallographic data for 5HOX (CIF) SUPPL paragraph 34266 Crystallographic data for 5HOY (CIF) SUPPL paragraph 34303 The Supporting Information is available free of charge on the ACS Publications website at DOI: 10.1021/jacs.6b01332. SUPPL title_1 34420 Supplementary Material SUPPL paragraph 34443 The authors declare no competing financial interest. REF title 34496 References 349 357 surname:Benilova;given-names:I. surname:Karran;given-names:E. surname:De Strooper;given-names:B. 10.1038/nn.3028 22286176 REF Nat. Neurosci. ref 15 2012 34507 352 357 surname:Lesné;given-names:S. surname:Koh;given-names:M. T. surname:Kotilinek;given-names:L. surname:Kayed;given-names:R. surname:Glabe;given-names:C. G. surname:Yang;given-names:A. surname:Gallagher;given-names:M. surname:Ashe;given-names:K. H. 10.1038/nature04533 16541076 REF Nature ref 440 2006 34508 1383 1398 surname:Lesné;given-names:S. E. surname:Sherman;given-names:M. A. surname:Grant;given-names:M. surname:Kuskowski;given-names:M. surname:Schneider;given-names:J. A. surname:Bennett;given-names:D. A. surname:Ashe;given-names:K. H. 10.1093/brain/awt062 23576130 REF Brain ref 136 2013 34509 73 110 surname:Hafner;given-names:J. H. surname:Cheung;given-names:C. L. surname:Woolley;given-names:A. T. surname:Lieber;given-names:C. M. 10.1016/B978-008044031-6/50037-9 11473787 REF Prog. Biophys. Mol. Biol. ref 77 2001 34510 2433 2444 surname:Lin;given-names:H. surname:Bhatia;given-names:R. surname:Lal;given-names:R. 10.1096/fj.01-0377com 11689468 REF FASEB J. ref 15 2001 34511 291 292 surname:Lashuel;given-names:H. A. surname:Hartley;given-names:D. surname:Petre;given-names:B. M. surname:Walz;given-names:T. surname:Lansbury;given-names:P. T.;suffix:Jr. 10.1038/418291a REF Nature ref 418 2002 34512 10427 10432 surname:Quist;given-names:A. surname:Doudevski;given-names:I. surname:Lin;given-names:H. surname:Azimova;given-names:R. surname:Ng;given-names:D. surname:Frangione;given-names:B. surname:Kagan;given-names:B. surname:Ghiso;given-names:J. surname:Lal;given-names:R. 10.1073/pnas.0502066102 16020533 REF Proc. Natl. Acad. Sci. U. S. A. ref 102 2005 34513 4230 4237 surname:Kayed;given-names:R. surname:Pensalfini;given-names:A. surname:Margol;given-names:L. surname:Sokolov;given-names:Y. surname:Sarsoza;given-names:F. surname:Head;given-names:E. surname:Hall;given-names:J. surname:Glabe;given-names:C. 10.1074/jbc.M808591200 19098006 REF J. Biol. Chem. ref 284 2009 34514 689285 surname:Kokubo;given-names:H. surname:Kayed;given-names:R. surname:Glabe;given-names:C. G. surname:Staufenbiel;given-names:M. surname:Saido;given-names:T. C. surname:Iwata;given-names:N. surname:Yamaguchi;given-names:H. 10.4061/2009/689285 20798763 REF Int. J. Alzheimer's Dis. ref 2009 2009 34515 22122 22130 surname:Lasagna-Reeves;given-names:C. A. surname:Glabe;given-names:C. G. surname:Kayed;given-names:R. 10.1074/jbc.M111.236257 21507938 REF J. Biol. Chem. ref 286 2011 34516 20631 20635 surname:Roher;given-names:A. E. surname:Chaney;given-names:M. O. surname:Bonnell;given-names:B. S. surname:Emmerling;given-names:M. R. surname:Kuo;given-names:Y. M. surname:Webster;given-names:S. D. surname:Stine;given-names:W. B. surname:Haverkamp;given-names:L. J. surname:Woods;given-names:A. S. surname:Cotter;given-names:R. J. surname:Tuohy;given-names:J. M. surname:Krafft;given-names:G. A. 10.1074/jbc.271.34.20631 8702810 REF J. Biol. Chem. ref 271 1996 34517 860 866 surname:McLean;given-names:C. A. surname:Cherny;given-names:R. A. surname:Fraser;given-names:F. W. surname:Fuller;given-names:S. J. surname:Smith;given-names:M. J. surname:Beyreuther;given-names:K. surname:Bush;given-names:A. I. surname:Masters;given-names:C. L. 10.1002/1531-8249(199912)46:6<860::AID-ANA8>3.0.CO;2-M 10589538 REF Ann. Neurol. ref 46 1999 34518 1328 1341 surname:McDonald;given-names:J. M. surname:Savva;given-names:G. M. surname:Brayne;given-names:C. surname:Welzel;given-names:A. T. surname:Forster;given-names:G. surname:Shankar;given-names:G. M. surname:Selkoe;given-names:D. J. surname:Ince;given-names:P. G. surname:Walsh;given-names:D. M. 10.1093/brain/awq065 20403962 REF Brain ref 133 2010 34519 837 842 surname:Shankar;given-names:G. M. surname:Li;given-names:S. surname:Regan;given-names:C. M. surname:Walsh;given-names:D. M. surname:Sabatini;given-names:B. L. surname:Selkoe;given-names:D. J. surname:Mehta;given-names:T. H. surname:Garcia-Munoz;given-names:A. surname:Shepardson;given-names:N. E. surname:Smith;given-names:I. surname:Brett;given-names:F. M. surname:Farrell;given-names:M. A. surname:Rowan;given-names:M. J. surname:Lemere;given-names:C. A. 10.1038/nm1782 18568035 REF Nat. Med. ref 14 2008 34520 5819 5824 surname:Jin;given-names:M. surname:Shepardson;given-names:N. surname:Yang;given-names:T. surname:Chen;given-names:G. surname:Walsh;given-names:D. surname:Selkoe;given-names:D. J. 10.1073/pnas.1017033108 21421841 REF Proc. Natl. Acad. Sci. U. S. A. ref 108 2011 34521 4050 4058 surname:Mucke;given-names:L. surname:Masliah;given-names:E. surname:Yu;given-names:G. Q. surname:Mallory;given-names:M. surname:Rockenstein;given-names:E. M. surname:Tatsuno;given-names:G. surname:Hu;given-names:K. surname:Kholodenko;given-names:D. surname:Johnson-Wood;given-names:K. surname:McConlogue;given-names:L. 10818140 REF J. Neurosci. ref 20 2000 34522 372 381 surname:Kawarabayashi;given-names:T. surname:Younkin;given-names:L. H. surname:Saido;given-names:T. C. surname:Shoji;given-names:M. surname:Ashe;given-names:K. H. surname:Younkin;given-names:S. G. 11160418 REF J. Neurosci. ref 21 2001 34523 3801 3809 surname:Kawarabayashi;given-names:T. surname:Shoji;given-names:M. surname:Younkin;given-names:L. H. surname:Wen-Lang;given-names:L. surname:Dickson;given-names:D. W. surname:Murakami;given-names:T. surname:Matsubara;given-names:E. surname:Abe;given-names:K. surname:Ashe;given-names:K. H. surname:Younkin;given-names:S. G. 10.1523/JNEUROSCI.5543-03.2004 15084661 REF J. Neurosci. ref 24 2004 34524 1977 1986 surname:Meilandt;given-names:W. J. surname:Cisse;given-names:M. surname:Ho;given-names:K. surname:Wu;given-names:T. surname:Esposito;given-names:L. A. surname:Scearce-Levie;given-names:K. surname:Cheng;given-names:I. H. surname:Yu;given-names:G. Q. surname:Mucke;given-names:L. 10.1523/JNEUROSCI.2984-08.2009 19228952 REF J. Neurosci. ref 29 2009 34525 293 302 surname:Shankar;given-names:G. M. surname:Leissring;given-names:M. A. surname:Adame;given-names:A. surname:Sun;given-names:X. surname:Spooner;given-names:E. surname:Masliah;given-names:E. surname:Selkoe;given-names:D. J. surname:Lemere;given-names:C. A. surname:Walsh;given-names:D. M. 10.1016/j.nbd.2009.07.021 19660551 REF Neurobiol. Dis. ref 36 2009 34526 13407 13412 surname:Benzinger;given-names:T. L. surname:Gregory;given-names:D. M. surname:Burkoth;given-names:T. S. surname:Miller-Auer;given-names:H. surname:Lynn;given-names:D. G. surname:Botto;given-names:R. E. surname:Meredith;given-names:S. C. 10.1073/pnas.95.23.13407 9811813 REF Proc. Natl. Acad. Sci. U. S. A. ref 95 1998 34527 262 265 surname:Petkova;given-names:A. T. surname:Leapman;given-names:R. D. surname:Guo;given-names:Z. surname:Yau;given-names:W. M. surname:Mattson;given-names:M. P. surname:Tycko;given-names:R. 10.1126/science.1105850 15653506 REF Science ref 307 2005 34528 17342 17347 surname:Lührs;given-names:T. surname:Ritter;given-names:C. surname:Adrian;given-names:M. surname:Riek-Loher;given-names:D. surname:Bohrmann;given-names:B. surname:Döbeli;given-names:H. surname:Schubert;given-names:D. surname:Riek;given-names:R. 10.1073/pnas.0506723102 16293696 REF Proc. Natl. Acad. Sci. U. S. A. ref 102 2005 34529 498 512 surname:Petkova;given-names:A. T. surname:Yau;given-names:W. M. surname:Tycko;given-names:R. 10.1021/bi051952q 16401079 REF Biochemistry ref 45 2006 34530 4618 4629 surname:Paravastu;given-names:A. K. surname:Petkova;given-names:A. T. surname:Tycko;given-names:R. 10.1529/biophysj.105.076927 16565054 REF Biophys. J. ref 90 2006 34531 1257 1268 surname:Lu;given-names:J. X. surname:Qiang;given-names:W. surname:Yau;given-names:W. M. surname:Schwieters;given-names:C. D. surname:Meredith;given-names:S. C. surname:Tycko;given-names:R. 10.1016/j.cell.2013.08.035 24034249 REF Cell ref 154 2013 34532 499 505 surname:Xiao;given-names:Y. surname:Ma;given-names:B. surname:McElheny;given-names:D. surname:Parthasarathy;given-names:S. surname:Long;given-names:F. surname:Hoshi;given-names:M. surname:Nussinov;given-names:R. surname:Ishii;given-names:Y. 10.1038/nsmb.2991 25938662 REF Nat. Struct. Mol. Biol. ref 22 2015 34533 453 457 surname:Sawaya;given-names:M. R. surname:Sambashivan;given-names:S. surname:Madsen;given-names:A. Ø. surname:Riekel;given-names:C. surname:Eisenberg;given-names:D. surname:Nelson;given-names:R. surname:Ivanova;given-names:M. I. surname:Sievers;given-names:S. A. surname:Apostol;given-names:M. I. surname:Thompson;given-names:M. J. surname:Balbirnie;given-names:M. surname:Wiltzius;given-names:J. J. surname:McFarlane;given-names:H. T. 10.1038/nature05695 17468747 REF Nature ref 447 2007 34534 16938 16943 surname:Colletier;given-names:J. P. surname:Laganowsky;given-names:A. surname:Landau;given-names:M. surname:Zhao;given-names:M. surname:Soriaga;given-names:A. B. surname:Goldschmidt;given-names:L. surname:Flot;given-names:D. surname:Cascio;given-names:D. surname:Sawaya;given-names:M. R. surname:Eisenberg;given-names:D. 10.1073/pnas.1112600108 21949245 REF Proc. Natl. Acad. Sci. U. S. A. ref 108 2011 34535 1870 1877 surname:Yu;given-names:L. surname:Edalji;given-names:R. surname:Miesbauer;given-names:L. surname:Solomon;given-names:L. surname:Bartley;given-names:D. surname:Walter;given-names:K. surname:Johnson;given-names:R. W. surname:Hajduk;given-names:P. J. surname:Olejniczak;given-names:E. T. surname:Harlan;given-names:J. E. surname:Holzman;given-names:T. F. surname:Lopez;given-names:A. P. surname:Labkovsky;given-names:B. surname:Hillen;given-names:H. surname:Barghorn;given-names:S. surname:Ebert;given-names:U. surname:Richardson;given-names:P. L. 10.1021/bi802046n 19216516 REF Biochemistry ref 48 2009 34536 22822 22826 surname:Scheidt;given-names:H. A. surname:Morgado;given-names:I. surname:Huster;given-names:D. 10.1074/jbc.M112.367474 22589542 REF J. Biol. Chem. ref 287 2012 34537 458 462 surname:Doi;given-names:T. surname:Masuda;given-names:Y. surname:Irie;given-names:K. surname:Akagi;given-names:K. surname:Monobe;given-names:Y. surname:Imazawa;given-names:T. surname:Takegoshi;given-names:K. 10.1016/j.bbrc.2012.10.096 23131555 REF Biochem. Biophys. Res. Commun. ref 428 2012 34538 18673 18683 surname:Gu;given-names:L. surname:Liu;given-names:C. surname:Guo;given-names:Z. 10.1074/jbc.M113.457739 23687299 REF J. Biol. Chem. ref 288 2013 34539 2494 2508 surname:Tay;given-names:W. M. surname:Huang;given-names:D. surname:Rosenberry;given-names:T. L. surname:Paravastu;given-names:A. K. 10.1016/j.jmb.2013.04.003 23583777 REF J. Mol. Biol. ref 425 2013 34540 8294 8307 surname:Potapov;given-names:A. surname:Yau;given-names:W.-M. surname:Ghirlando;given-names:R. surname:Thurber;given-names:K. R. surname:Tycko;given-names:R. 10.1021/jacs.5b04843 26068174 REF J. Am. Chem. Soc. ref 137 2015 34541 5099 6104 surname:Hoyer;given-names:W. surname:Grönwall;given-names:C. surname:Jonsson;given-names:A. surname:Ståhl;given-names:S. surname:Härd;given-names:T. 10.1073/pnas.0711731105 18375754 REF Proc. Natl. Acad. Sci. U. S. A. ref 105 2008 34542 15595 15600 surname:Sandberg;given-names:A. surname:Luheshi;given-names:L. M. surname:Lannfelt;given-names:L. surname:Dobson;given-names:C. M. surname:Härd;given-names:T. surname:Söllvander;given-names:S. surname:Pereira de Barros;given-names:T. surname:Macao;given-names:B. surname:Knowles;given-names:T. P. surname:Biverstål;given-names:H. surname:Lendel;given-names:C. surname:Ekholm-Petterson;given-names:F. surname:Dubnovitsky;given-names:A. 10.1073/pnas.1001740107 20713699 REF Proc. Natl. Acad. Sci. U. S. A. ref 107 2010 34543 12756 12760 surname:Lendel 10.1002/anie.201406357 REF Angew. Chem., Int. Ed. ref 53 2014 34544 recently reported the NMR structure of a hexameric peptide barrel formed by this disulfide constrained Aβ: Lendel, C.; Bjerring, M.; Dubnovitsky, A.; Kelly, R. T.; Filippov, A.; Antzutkin, O. N.; Nielsen, N. C.; Härd, T 5595 5598 surname:Spencer;given-names:R. K. surname:Li;given-names:H. surname:Nowick;given-names:J. S. 10.1021/ja5017409 24669800 REF J. Am. Chem. Soc. ref 136 2014 34767 4972 4973 surname:Nowick;given-names:J. S. surname:Lam;given-names:K. S. surname:Khasanova;given-names:T. V. surname:Kemnitzer;given-names:W. E. surname:Maitra;given-names:S. surname:Mee;given-names:H. T. surname:Liu;given-names:R. 10.1021/ja025699i 11982357 REF J. Am. Chem. Soc. ref 124 2002 34768 We also created a peptide with an N-methyl group at position F20. This peptide forms oligomers with structures similar to those formed by peptide 1. REF ref 34769 698 710 surname:Spencer;given-names:R. K. surname:Nowick;given-names:J. S. 10.1002/ijch.201400179 26213415 REF Isr. J. Chem. ref 55 2015 34770 488 499 surname:Santiveri;given-names:C. M. surname:León;given-names:E. surname:Rico;given-names:M. surname:Jiménez;given-names:M. A. 10.1002/chem.200700845 17943702 REF Chem. - Eur. J. ref 14 2008 34771 6304 6311 surname:Spencer;given-names:R. K. surname:Kreutzer;given-names:A. G. surname:Salveson;given-names:P. J. surname:Li;given-names:H. surname:Nowick;given-names:J. S. 10.1021/jacs.5b01673 25915729 REF J. Am. Chem. Soc. ref 137 2015 34772 3523 3528 surname:Spencer;given-names:R. surname:Chen;given-names:K. H. surname:Manuel;given-names:G. surname:Nowick;given-names:J. S. 10.1002/ejoc.201300221 REF Eur. J. Org. Chem. ref 2013 2013 34773 125 132 surname:Kabsch;given-names:W. 10.1107/S0907444909047337 20124692 REF Acta Crystallogr., Sect. D: Biol. Crystallogr. ref 66 2010 34774 623 628 surname:Weik;given-names:M. surname:Ravelli;given-names:R. B. surname:Kryger;given-names:G. surname:McSweeney;given-names:S. surname:Raves;given-names:M. L. surname:Harel;given-names:M. surname:Gros;given-names:P. surname:Silman;given-names:I. surname:Kroon;given-names:J. surname:Sussman;given-names:J. L. 10.1073/pnas.97.2.623 10639129 REF Proc. Natl. Acad. Sci. U. S. A. ref 97 2000 34775 488 497 surname:Leiros;given-names:H. K. surname:McSweeney;given-names:S. M. surname:Smalås;given-names:A. O. 10.1107/S0907444901000646 11264577 REF Acta Crystallogr., Sect. D: Biol. Crystallogr. ref 57 2001 34776 The δOrn in peptide 2 replaces K16 in Aβ. In a dodecamer of full-length Aβ, the side chain of K16 could form a salt bridge with the side chain of D23. REF ref 34777 24 39 surname:Pieters;given-names:B. J. surname:van Eldijk;given-names:M. B. surname:Nolte;given-names:R. J. surname:Mecinović;given-names:J. 10.1039/C5CS00157A 26497225 REF Chem. Soc. Rev. ref 45 2016 34778 5628 5654 surname:Butterfield;given-names:S. M. surname:Lashuel;given-names:H. A. 10.1002/anie.200906670 REF Angew. Chem., Int. Ed. ref 49 2010 34779 29639 29643 surname:Glabe;given-names:C. G. 10.1074/jbc.R800016200 18723507 REF J. Biol. Chem. ref 283 2008 34780 125 139 surname:Larson;given-names:M. E. surname:Lesné;given-names:S. E. 10.1111/j.1471-4159.2011.07478.x REF J. Neurochem. ref 120 2012 34781 1760 1771 surname:Liu;given-names:P. surname:Reed;given-names:M. N. surname:Wilmot;given-names:C. M. surname:Cleary;given-names:J. P. surname:Zahs;given-names:K. R. surname:Ashe;given-names:K. H. surname:Kotilinek;given-names:L. A. surname:Grant;given-names:M. K. surname:Forster;given-names:C. L. surname:Qiang;given-names:W. surname:Shapiro;given-names:S. L. surname:Reichl;given-names:J. H. surname:Chiang;given-names:A. C. surname:Jankowsky;given-names:J. L. 10.1016/j.celrep.2015.05.021 26051935 REF Cell Rep. ref 11 2015 34782 486 489 surname:Kayed;given-names:R. surname:Head;given-names:E. surname:Thompson;given-names:J. L. surname:McIntire;given-names:T. M. surname:Milton;given-names:S. C. surname:Cotman;given-names:C. W. surname:Glabe;given-names:C. G. 10.1126/science.1079469 12702875 REF Science ref 300 2003 34783 789 798 surname:Tao;given-names:Y. surname:Strelkov;given-names:S. V. surname:Mesyanzhinov;given-names:V. V. surname:Rossmann;given-names:M. G. 10.1016/S0969-2126(97)00233-5 9261070 REF Structure ref 5 1997 34784