MutS和MSH同源物中通过动态通信途径切换实现的长程信号传导。

Long-Range Signaling in MutS and MSH Homologs via Switching of Dynamic Communication Pathways.

作者信息

Wang Beibei, Francis Joshua, Sharma Monika, Law Sean M, Predeus Alexander V, Feig Michael

机构信息

Department of Biochemistry & Molecular Biology, Michigan State University, East Lansing, MI, United States.

出版信息

PLoS Comput Biol. 2016 Oct 21;12(10):e1005159. doi: 10.1371/journal.pcbi.1005159. eCollection 2016 Oct.

DOI:10.1371/journal.pcbi.1005159

PMID:27768684

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC5074593/

Abstract

Allostery is conformation regulation by propagating a signal from one site to another distal site. This study focuses on the long-range communication in DNA mismatch repair proteins MutS and its homologs where intramolecular signaling has to travel over 70 Å to couple lesion detection to ATPase activity and eventual downstream repair. Using dynamic network analysis based on extensive molecular dynamics simulations, multiple preserved communication pathways were identified that would allow such long-range signaling. The pathways appear to depend on the nucleotides bound to the ATPase domain as well as the type of DNA substrate consistent with previously proposed functional cycles of mismatch recognition and repair initiation by MutS and homologs. A mechanism is proposed where pathways are switched without major conformational rearrangements allowing for efficient long-range signaling and allostery.

摘要

变构是通过将信号从一个位点传播到另一个远端位点来进行构象调节。本研究聚焦于DNA错配修复蛋白MutS及其同源物中的长程通信，其中分子内信号必须传播超过70 Å才能将损伤检测与ATP酶活性及最终的下游修复相耦合。基于广泛的分子动力学模拟，通过动态网络分析确定了多条能够实现这种长程信号传递的保留通信途径。这些途径似乎依赖于与ATP酶结构域结合的核苷酸以及DNA底物的类型，这与之前提出的MutS及其同源物错配识别和修复起始的功能循环一致。我们提出了一种机制，即途径在没有重大构象重排的情况下进行切换，从而实现高效的长程信号传递和变构。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/4c51/5074593/b8f026ae28da/pcbi.1005159.g001.jpg

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MutS和MSH同源物中通过动态通信途径切换实现的长程信号传导。

Long-Range Signaling in MutS and MSH Homologs via Switching of Dynamic Communication Pathways.

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