Brett K.-Y. Chu scite author profile

Prion protein amyloid aggregates are associated with infectious neurodegenerative diseases, known as transmissible spongiform encephalopathies. Self-replication of amyloid structures by refolding of native protein molecules is the probable mechanism of disease transmission. Amyloid fibril formation and self-replication can be affected by many different factors, including other amyloid proteins and peptides. Mouse prion protein fragments 107-143 (PrP(107-143)) and 89-230 (PrP(89-230)) can form amyloid fibrils. β-sheet core in PrP(89-230) amyloid fibrils is limited to residues ∼160–220 with unstructured N-terminus. We employed chemical kinetics tools, atomic force microscopy and Fourier-transform infrared spectroscopy, to investigate the effects of mouse prion protein fragment 107-143 fibrils on the aggregation of PrP(89-230). The data suggest that amyloid aggregates of a short prion-derived peptide are not able to seed PrP(89-230) aggregation; however, they accelerate the self-replication of PrP(89-230) amyloid fibrils. We conclude that PrP(107-143) fibrils could facilitate the self-replication of PrP(89-230) amyloid fibrils in several possible ways, and that this process deserves more attention as it may play an important role in amyloid propagation.

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Segments in the Amyloid Core that Distinguish Hamster from Mouse Prion Fibrils

Shen

Chen

Lin

et al. 2019

Neurochem Res

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Location of the cross‐β structure in prion fibrils: A search by seeding and electron spin resonance spectroscopy

et al. 2022

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Prion diseases are transmissible fatal neurodegenerative disorders spreading between humans and other mammals. The pathogenic agent, prion, is a protease-resistant, β-sheet-rich protein aggregate, converted from a membrane protein called PrP C . PrP Sc is the misfolded form of PrP C and undergoes selfpropagation to form the infectious amyloids. Since the key hallmark of prion disease is amyloid formation, identifying and studying which segments are involved in the amyloid core can provide molecular details about prion diseases. It has been known that the prion protein could also form non-infectious fibrils in the presence of denaturants. In this study, we employed a combination of site-directed nitroxide spin-labeling, fibril seeding, and electron spin resonance (ESR) spectroscopy to identify the structure of the in vitro-prepared full-length mouse prion fibrils. It is shown that in the in vitro amyloidogenesis, the formation of the amyloid core is linked to an α-to-β structural transformation involving the segment 160-224, which contains strand 2, helix 2, and helix 3. This method is particularly suitable for examining the hetero-seeded amyloid fibril structure, as the unlabeled seeds are invisible by ESR spectroscopy.It can be applied to study the structures of different strains of infectious prions or other amyloid fibrils in the future.

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Brett K.-Y. Chu

Self-Replication of Prion Protein Fragment 89-230 Amyloid Fibrils Accelerated by Prion Protein Fragment 107-143 Aggregates

Segments in the Amyloid Core that Distinguish Hamster from Mouse Prion Fibrils

Location of the cross‐β structure in prion fibrils: A search by seeding and electron spin resonance spectroscopy

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