Amyloid fibrils formed from different proteins, each associated with a particular disease, contain a common cross-beta spine. The atomic architecture of a spine, from the fibril-forming segment GNNQQNY of the yeast prion protein Sup35, was recently revealed by X-ray microcrystallography. It is a pair of beta-sheets, with the facing side chains of the two sheets interdigitated in a dry 'steric zipper'. Here we report some 30 other segments from fibril-forming proteins that form amyloid-like fibrils, microcrystals, or usually both. These include segments from the Alzheimer's amyloid-beta and tau proteins, the PrP prion protein, insulin, islet amyloid polypeptide (IAPP), lysozyme, myoglobin, alpha-synuclein and beta(2)-microglobulin, suggesting that common structural features are shared by amyloid diseases at the molecular level. Structures of 13 of these microcrystals all reveal steric zippers, but with variations that expand the range of atomic architectures for amyloid-like fibrils and offer an atomic-level hypothesis for the basis of prion strains.
Numerous soluble proteins convert to insoluble amyloid-like fibrils having common properties. Amyloid fibrils are associated with fatal diseases such as Alzheimer's, and amyloid-like fibrils can be formed in vitro. For the yeast protein Sup35, conversion to amyloid-like fibrils is associated with a transmissible infection akin to that caused by mammalian prions. A seven-residue peptide segment from Sup35 forms amyloid-like fibrils and closely related microcrystals, which here reveal the atomic structure of the cross-β spine. It is a double β-sheet, with each sheet formed from parallel segments stacked in-register. Sidechains protruding from the two sheets form a dry, tightly self-complementing steric zipper, bonding the sheets. Within each sheet, every segment is bound to its two neighbouring segments via stacks of both backbone and sidechain hydrogen bonds. The structure illuminates the stability of amyloid fibrils, their self-seeding characteristic, and their tendency to form polymorphic structures.Four decades of research have established that amyloid-like fibrils of different proteins have a common structural 'cross-β' spine 1 . In 1959 Cohen and Calkins 2 observed elongated, unbranched fibrils in electron micrographs of diseased tissues, and in 1968 Glenner and Eanes 3 discovered that the fibrils exhibit an X-ray diffraction signature known as the cross-β pattern. This pattern shows 4 that the strongest repeating feature of the fibril is a set of β-sheets that are parallel to the fibril axis with their strands perpendicular to this axis. The hypothesis of a common molecular organization was supported by the finding 5 that amyloid fibrils from 6 different proteins, each associated with its own clinical syndrome, showed similar cross-β diffraction patterns. The degree of similarity pointed to 'a common core molecular structure.'Revealing the atomic details of this cross-β spine has been impeded by the limited order of fibrils isolated from diseased tissues, infected cells, and in vitro conversions of proteins to fibrils. There is also evidence for a diversity of crystalline and fibril structures 6-8 . Nevertheless, an arsenal of biophysical tools has defined important features. These tools include solid-state NMR 9-11 , model-building constrained by X-ray fiber and powder diffraction 6,7,12,13 , site-directed spin labeling 14,15 , cryo-electron microscopy 16,17 , and proline-scanning mutagenesis 18 . Despite numerous models suggested by these studies, until now no refined, fully objective atomic model has been available for the common spine structure.Correspondence and requests for materials should be addressed to D.E. (david@mbi.ucla.edu). The structures of GNNQQNY and NNQQNY have been deposited in the Protein Data Bank with accession codes 1yjp and 1yjo, respectively.. Competing Interests StatementThe authors declare that they have no competing financial interests.Supplementary Information accompanies the paper on www.nature.com/nature. We selected the yeast protein Sup35 for X-ray diffraction analy...
Eukaryotic cells contain assemblies of RNAs and proteins termed RNA granules. Many proteins within these bodies contain KH or RRM RNA-binding domains as well as low complexity (LC) sequences of unknown function. We discovered that exposure of cell or tissue lysates to a biotinylated isoxazole (b-isox) chemical precipitated hundreds of RNA-binding proteins with significant overlap to the constituents of RNA granules. The LC sequences within these proteins are both necessary and sufficient for b-isox-mediated aggregation, and these domains can undergo a concentration-dependent phase transition to a hydrogel-like state in the absence of the chemical. X-ray diffraction and EM studies revealed the hydrogels to be composed of uniformly polymerized amyloid-like fibers. Unlike pathogenic fibers, the LC sequence-based polymers described here are dynamic and accommodate heterotypic polymerization. These observations offer a framework for understanding the function of LC sequences as well as an organizing principle for cellular structures that are not membrane bound.
Loop and Subdomain Movements in the Mechanism of Escherichia coli Dihydrofolate Reductase: Crystallographic Evidence,
The reaction catalyzed by Escherichia coli dihydrofolate reductase (ecDHFR) cycles through five detectable kinetic intermediates: holoenzyme, Michaelis complex, ternary product complex, tetrahydrofolate (THF) binary complex, and THF.NADPH complex. Isomorphous crystal structures analogous to these five intermediates and to the transition state (as represented by the methotrexate-NADPH complex) have been used to assemble a 2.1 A resolution movie depicting loop and subdomain movements during the catalytic cycle (see Supporting Information). The structures suggest that the M20 loop is predominantly closed over the reactants in the holoenzyme, Michaelis, and transition state complexes. But, during the remainder of the cycle, when nicotinamide is not bound, the loop occludes (protrudes into) the nicotinamide-ribose binding pocket. Upon changing from the closed to the occluded conformation, the central portion of the loop rearranges from beta-sheet to 3(10) helix. The change may occur by way of an irregularly structured open loop conformation, which could transiently admit a water molecule into position to protonate N5 of dihydrofolate. From the Michaelis to the transition state analogue complex, rotation between two halves of ecDHFR, the adenosine binding subdomain and loop subdomain, closes the (p-aminobenzoyl)glutamate (pABG) binding crevice by approximately 0.5 A. Resulting enhancement of contacts with the pABG moiety may stabilize puckering at C6 of the pteridine ring in the transition state. The subdomain rotation is further adjusted by cofactor-induced movements (approximately 0.5 A) of helices B and C, producing a larger pABG cleft in the THF.NADPH analogue complex than in the THF analogue complex. Such movements may explain how THF release is assisted by NADPH binding. Subdomain rotation is not observed in vertebrate DHFR structures, but an analogous loop movement (residues 59-70) appears to similarly adjust the pABG cleft width, suggesting that these movements are important for catalysis. Loop movement, also unobserved in vertebrate DHFR structures, may preferentially weaken NADP+ vs NADPH binding in ecDHFR, an evolutionary adaptation to reduce product inhibition in the NADP+ rich environment of prokaryotes.
DNA polymerase beta (pol beta) fills single nucleotide (nt) gaps in DNA produced by the base excision repair pathway of mammalian cells. Crystal structures have been determined representing intermediates in the 1 nt gap-filling reaction of pol beta: the binary complex with a gapped DNA substrate (2.4 A resolution), the ternary complex including ddCTP (2.2 A), and the binary product complex containing only nicked DNA (2.6 A). Upon binding ddCTP to the binary gap complex, the thumb subdomain rotates into the closed conformation to contact the otherwise solvent-exposed ddCTP-template base pair. Thumb movement triggers further conformational changes which poise catalytic residue Asp192, dNTP, and template for nucleotidyl transfer, effectively assembling the active site. In the product nicked DNA complex, the thumb returns to the open conformation as in the gapped binary DNA complex, facilitating dissociation of the product. These findings suggest that pol beta may enhance fidelity by an induced fit mechanism in which correct base pairing between template and incoming dNTP induces alignment of catalytic groups for catalysis (via thumb closure), but incorrect base pairing will not. The structures also reveal that pol beta binds both gapped and nicked DNA with a 90 degrees kink occurring precisely at the 5'-phosphodiester linkage of the templating residue. If the DNA were not kinked in this way, contact between the thumb and dNTP-template base pair, presumably important for the checking mechanism, would be impossible, especially when the gap is but a single nucleotide. Such a 90 degrees kink may be a mechanistic feature employed by any polymerase involved in filling gaps to completion.
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