Structural Resolution of Switchable States of a De Novo Peptide Assembly

Overview

Journal Nat Commun

Specialty Biology

Date 2021 Mar 22

PMID 33750792

Citations 11

Authors

William M Dawson

Eric J M Lang

Guto G Rhys

Kathryn L Shelley

Christopher Williams

R Leo Brady

Matthew P Crump

Adrian J Mulholland

Derek N Woolfson

Affiliations

Soon will be listed here.

Abstract

De novo protein design is advancing rapidly. However, most designs are for single states. Here we report a de novo designed peptide that forms multiple α-helical-bundle states that are accessible and interconvertible under the same conditions. Usually in such designs amphipathic α helices associate to form compact structures with consolidated hydrophobic cores. However, recent rational and computational designs have delivered open α-helical barrels with functionalisable cavities. By placing glycine judiciously in the helical interfaces of an α-helical barrel, we obtain both open and compact states in a single protein crystal. Molecular dynamics simulations indicate a free-energy landscape with multiple and interconverting states. Together, these findings suggest a frustrated system in which steric interactions that maintain the open barrel and the hydrophobic effect that drives complete collapse are traded-off. Indeed, addition of a hydrophobic co-solvent that can bind within the barrel affects the switch between the states both in silico and experimentally.

Citing Articles

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