Control over the Fibrillization Yield by Varying the Oligomeric Nucleation Propensities of Self-assembling Peptides

Overview

Journal Commun Chem

Publisher Springer Nature

Specialty Chemistry

Date 2023 Jan 27

PMID 36703336

Authors

Chun Yin Jerry Lau

Federico Fontana

Laurens D B Mandemaker

Dennie Wezendonk

Benjamin Vermeer

Alexandre M J J Bonvin

Renko de Vries

Heyang Zhang

Katrien Remaut

Joep van den Dikkenberg

Joao Medeiros-Silva

Alia Hassan

Barbara Perrone

Rainer Kuemmerle

Fabrizio Gelain

Wim E Hennink

Markus Weingarth

Enrico Mastrobattista

Affiliations

Soon will be listed here.

Abstract

Self-assembling peptides are an exemplary class of supramolecular biomaterials of broad biomedical utility. Mechanistic studies on the peptide self-assembly demonstrated the importance of the oligomeric intermediates towards the properties of the supramolecular biomaterials being formed. In this study, we demonstrate how the overall yield of the supramolecular assemblies are moderated through subtle molecular changes in the peptide monomers. This strategy is exemplified with a set of surfactant-like peptides (SLPs) with different β-sheet propensities and charged residues flanking the aggregation domains. By integrating different techniques, we show that these molecular changes can alter both the nucleation propensity of the oligomeric intermediates and the thermodynamic stability of the fibril structures. We demonstrate that the amount of assembled nanofibers are critically defined by the oligomeric nucleation propensities. Our findings offer guidance on designing self-assembling peptides for different biomedical applications, as well as insights into the role of protein gatekeeper sequences in preventing amyloidosis.

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