The P3 Peptides (Aβ) Rapidly Form Amyloid Fibrils That Cross-seed with Full-length Aβ

Overview

Journal Nat Commun

Specialty Biology

Date 2025 Feb 27

PMID 40016209

Authors

Yao Tian

Andrea P Torres-Flores

Qi Shang

Hui Zhang

Anum Khursheed

Bogachan Tahirbegi

Patrick N Pallier

John H Viles

Affiliations

Soon will be listed here.

Abstract

The p3 peptides, Aβ, are a common alternative cleavage product of the amyloid precursor protein, and are found in diffuse amyloid deposits of Alzheimer's and Down Syndrome brains. The p3 peptides have been mis-named 'non-amyloidogenic'. Here we show p3 peptides rapidly form amyloid fibrils, with kinetics dominated by secondary nucleation. Importantly, cross-seeding experiments, with full-length Aβ induces a strong nucleation between p3 and Aβ peptides. The cross-seeding interaction is highly specific, and occurs only when the C-terminal residues are matched. We have imaged membrane interactions with p3, and monitored Ca influx and cell viability with p3 peptide. Together this data suggests the N-terminal residues influence, but are not essential for, membrane disruption. Single particle analysis of TEM images indicates p3 peptides can form ring-like annular oligomers. Patch-clamp electrophysiology, shows p3 oligomers are capable of forming large ion-channels across cellular membranes. A role for p3 peptides in disease pathology should be considered as p3 peptides are cytotoxic and cross-seed Aβ fibril formation in vitro.

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