Classical mammalian prions are assemblies of prion protein molecules that are extraordinarily transmissible, with a microgram of protein containing up to 10^8 lethal doses of infectivity1,2. Unlike most other pathogenic and amyloidogenic proteins, prions typically contain glycolipid anchors 3 and abundant asparagine-linked glycans4-6. The infectious nature, complexity, and biophysical properties of prions have complicated structural analyses and stymied any prior elucidation of 3D conformation at the polypeptide backbone level7. Here we have determined the structure of the core of a fully infectious, brain-derived prion by cryo-electron microscopy with ~3.1 angstrom resolution. The purified prions are amyloid fibrils comprised of monomers assembled with parallel in-register intermolecular beta sheets and connecting chains. Residues ~95-227 of each monomer provide one rung of the ordered fibril core, with the glycans and glycolipid anchor projecting from the lateral surfaces of the fibril. The fibril ends, where prion growth occurs, are formed by single monomers in an extended serpentine combination of β-arches, a Greek key, and loops that presumably template the refolding of incoming monomers. Our results describe an atomic model to underpin detailed molecular hypotheses of how pathologic prion proteins can propagate as infectious agents, and how such propagation and associated pathogenesis might be impeded.
Little is known about the structural basis of prion strains. Here we provide a high (3.0 Å) resolution cryo-electron microscopy-based structure of infectious brain-derived fibrils of the mouse anchorless RML scrapie strain which, like the recently determined hamster 263K strain, has a parallel in-register β-sheet-based core. Several structural motifs are shared between these ex vivo prion strains, including an amino-proximal steric zipper and three β-arches. However, detailed comparisons reveal variations in these shared structural topologies and other features. Unlike 263K and wildtype RML prions, the anchorless RML prions lack glycophosphatidylinositol anchors and are severely deficient in N-linked glycans. Nonetheless, the similarity of our anchorless RML structure to one reported for wildtype RML prion fibrils in an accompanying paper indicates that these post-translational modifications do not substantially alter the amyloid core conformation. This work demonstrates both common and divergent structural features of prion strains at the near-atomic level.
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