Structural and Computational Study of the GroEL-Prion Protein Complex

Overview

Journal Biomedicines

Specialty Biomedical Engineering

Date 2021 Nov 27

PMID 34829878

Citations 3

Authors

Aleksandra A Mamchur

Andrei V Moiseenko

Irina S Panina

Igor A Yaroshevich

Sofia S Kudryavtseva

Evgeny B Pichkur

Olga S Sokolova

Vladimir I Muronetz

Tatiana B Stanishneva-Konovalova

Affiliations

Soon will be listed here.

Abstract

The molecular chaperone GroEL is designed to promote protein folding and prevent aggregation. However, the interaction between GroEL and the prion protein, PrP, could lead to pathogenic transformation of the latter to the aggregation-prone PrP form. Here, the molecular basis of the interactions in the GroEL-PrP complex is studied with cryo-EM and molecular dynamics approaches. The obtained cryo-EM structure shows PrP to be bound to several subunits of GroEL at the level of their apical domains. According to MD simulations, the disordered N-domain of PrP forms much more intermolecular contacts with GroEL. Upon binding to the GroEL, the N-domain of PrP begins to form short helices, while the C-domain of PrP exhibits a tendency to unfold its α2-helix. In the absence of the nucleotides in the system, these processes are manifested at the hundred nanoseconds to microsecond timescale.

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