Structural insights into the mechanotransducing mechanism of FtsEX in cell division

Structural insights into the mechanotransducing mechanism of FtsEX in cell division

Abstract The filamentous temperature‐sensitive (Fts) protein FtsEX plays a pivotal role in Escherichia coli (E. coli) cell division by facilitating the activation of peptidoglycan hydrolysis through the adaptor EnvC. FtsEX belongs to the type VII ATP‐binding cassette (ABC) transporter superfamily, w...

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Main Authors: Yuejia Chen, Du Guo, Xin Wang, Changbin Zhang, Yatian Chen, Qinghua Luo, Yujiao Chen, Lili Yang, Zhibo Zhang, Tian Hong, Zhengyu Zhang, Haohao Dong, Shenghai Chang, Jianping Hu, Xiaodi Tang
Format: Article
Language:English
Published: Wiley 2024-11-01
Series:MedComm
Subjects:
ABC transporter
cell division
EnvC
FtsEX
mechanotransmission
Online Access:https://doi.org/10.1002/mco2.688
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Summary:Abstract The filamentous temperature‐sensitive (Fts) protein FtsEX plays a pivotal role in Escherichia coli (E. coli) cell division by facilitating the activation of peptidoglycan hydrolysis through the adaptor EnvC. FtsEX belongs to the type VII ATP‐binding cassette (ABC) transporter superfamily, which harnesses ATP energy to induce mechanical force, triggering a cascade of conformational changes that activate the pathway. However, the precise mechanism by which FtsEX initiates mechanotransmission remains elusive. Due to the inherent instability of this type of ABC transporter protein in vitro, the conformation of FtsEX has solely been determined in the stabilized ATP‐bound state. To elucidate the dynamics of FtsEX, we characterized FtsEX and EnvC of various functional structures through cryo‐electron microscopy (cryo‐EM) and homology modeling. We validated the structures by molecular dynamics simulations. By site‐directed mutagenesis and phenotype screening, we also identified the functional residues involved in allosteric communication between FtsE and FtsX as well as FtsX and EnvC. Additionally, we discovered a potential role of phospholipids in stabilizing the complex conformation during mechanotransmission. This comprehensive exploration significantly enhances our understanding of the intricate mechanisms governing bacterial cell division and unveils potential molecular targets for developing innovative antimicrobial drugs to combat antibiotic resistance.
ISSN:2688-2663

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