Allosteric communication mediated by protein contact clusters: A dynamical model

arXiv - PHYS - Biological Physics Pub Date : 2024-08-27 DOI:arxiv-2408.15110

Ahmed A. A. I. Ali, Emanuel Dorbath, Gerhard Stock

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Abstract

Allostery refers to the puzzling phenomenon of long-range communication between distant sites in proteins. Despite its importance in biomolecular regulation and signal transduction, the underlying dynamical process is not well understood. This study introduces a dynamical model of allosteric communication based on "contact clusters"-localized groups of highly correlated contacts that facilitate interactions between secondary structures. The model shows that allostery involves a multi-step process with cooperative contact changes within clusters and communication between distant clusters mediated by rigid secondary structures. Considering time-dependent experiments on a photoswitchable PDZ3 domain, extensive (in total $\sim 500\,\mu$s) molecular dynamics simulations are conducted that directly monitor the photoinduced allosteric transition. The structural reorganization is illustrated by the time evolution of the contact clusters and the ligand, which affects the nonlocal coupling between distant clusters. A timescale analysis reveals dynamics from nano- to microseconds, which are in excellent agreement with the experimentally measured timescales.

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由蛋白质接触簇介导的异构通讯：动力学模型

异构指的是蛋白质中遥远位点之间的长程通讯这一令人费解的现象。尽管这种现象在生物分子调控和信号转导中非常重要，但人们对其背后的动态过程却不甚了解。本研究介绍了一种基于 "接触集群 "的异构通讯动力学模型--高度相关的接触的局部集群可促进二级结构之间的相互作用。该模型显示，异构涉及一个多步骤过程，其中包括簇内的合作性接触变化和由刚性二级结构介导的远距离簇间的交流。考虑到对可光照开关的 PDZ3 结构域进行的时间依赖性实验，我们进行了大量（总计 500 次）分子动力学模拟，直接监测光照诱导的异质转变。接触簇和配体的时间演变说明了结构重组，这影响了远距离簇之间的非局部耦合。时间尺度分析显示了从纳秒到微秒的动态变化，这与实验测量的时间尺度非常吻合。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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arXiv - PHYS - Biological Physics

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