Involvement of the N Domain Residues E34, K35, and R38 in the Functionally Active Structure of Escherichia Coli Lon Protease

Overview

Journal Acta Naturae

Specialty Biology

Date 2021 Jan 18

PMID 33456980

Citations 3

Authors

A G Andrianova

A M Kudzhaev

V A Abrikosova

A E Gustchina

I V Smirnov

T V Rotanova

Affiliations

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Abstract

ATP-dependent Lon protease of (Lon), which belongs to the superfamily of AAA proteins, is a key component of the cellular proteome quality control system. It is responsible for the cleavage of mutant, damaged, and short-lived regulatory proteins that are potentially dangerous for the cell. Lon functions as a homooligomer whose subunits contain a central characteristic AAA module, a C-terminal protease domain, and an N-terminal non-catalytic region composed of the actual N-terminal domain and the inserted α-helical domain. An analysis of the N domain crystal structure suggested a potential involvement of residues E34, K35, and R38 in the formation of stable and active Lon. We prepared and studied a triple mutant LonEKR in which these residues were replaced with alanine. The introduced substitutions were shown to affect the conformational stability and nucleotide-induced intercenter allosteric interactions, as well as the formation of the proper protein binding site.

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