Cascade autohydrolysis of Alzheimer's Aβ peptides

Protein/peptide self-assembly into amyloid structures associates with major neurodegenerative disorders such as Alzheimer's disease (AD). Soluble assemblies (oligomers) of the Aβ peptide and their aggregates are perceived as neurotoxic species in AD. While screening for synthetic cleavage agents that could break down such aberrant assemblies through hydrolysis, we observed that the assemblies of Aβ oligopeptides, containing the nucleation sequence Aβ(14–24) (H(14)QKLVFFAEDV(24)), could act as cleavage agents by themselves. Autohydrolysis showed a common fragment fingerprint among various mutated Aβ(14–24) oligopeptides, Aβ(12–25)-Gly and Aβ(1–28), and full-length Aβ(1–40/42), under physiologically relevant conditions. Primary endoproteolytic autocleavage at the Gln(15)–Lys(16), Lys(16)–Leu(17) and Phe(19)–Phe(20) positions was followed by subsequent exopeptidase self-processing of the fragments. Control experiments with homologous d-amino acid enantiomers Aβ(12–25)-Gly and Aβ(16–25)-Gly showed the same autocleavage pattern under similar reaction conditions. The autohydrolytic cascade reaction (ACR) was resilient to a broad range of conditions (20–37 °C, 10–150 μM peptide concentration at pH 7.0–7.8). Evidently, assemblies of the primary autocleavage fragments acted as structural/compositional templates (autocatalysts) for self-propagating autohydrolytic processing at the Aβ(16–21) nucleation site, showing the potential for cross-catalytic seeding of the ACR in larger Aβ isoforms (Aβ(1–28) and Aβ(1–40/42)). This result may shed new light on Aβ behaviour in solution and might be useful in the development of intervention strategies to decompose or inhibit neurotoxic Aβ assemblies in AD.