Mechanical resistance in unstructured proteins
Abstract
Single-molecule pulling experiments on unstructured proteins linked to neurodegenerative diseases have measured rupture forces comparable to those for stable folded proteins. To investigate the structural mechanisms of this unexpected force resistance, we perform pulling simulations of the amyloid {\beta}-peptide (A{\beta}) and {\alpha}-synuclein ({\alpha}S), starting from simulated conformational ensembles for the free monomers. For both proteins, the simulations yield a set of rupture events that agree well with the experimental data. By analyzing the conformations right before rupture in each event, we find that the mechanically resistant structures share a common architecture, with similarities to the folds adopted by A{\beta} and {\alpha}S in amyloid fibrils. The disease-linked Arctic mutation of A{\beta} is found to increase the occurrence of highly force-resistant structures. Our study suggests that the high rupture forces observed in A{\beta} and {\alpha}S pulling experiments are caused by structures that might have a key role in amyloid formation.
Cite
@article{arxiv.1304.7991,
title = {Mechanical resistance in unstructured proteins},
author = {S. Æ. Jónsson and S. Mitternacht and A. Irbäck},
journal= {arXiv preprint arXiv:1304.7991},
year = {2013}
}
Comments
v3: Added correct journal reference plus minor corrections