从结构角度看驱动蛋白马达的动力学。

A structural perspective on the dynamics of kinesin motors.

机构信息

School of Computational Sciences, Korea Institute for Advanced Study, Seoul, Republic of Korea.

出版信息

Biophys J. 2011 Dec 7;101(11):2749-59. doi: 10.1016/j.bpj.2011.10.037.

DOI:10.1016/j.bpj.2011.10.037

PMID:22261064

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3297800/

Abstract

Despite significant fluctuation under thermal noise, biological machines in cells perform their tasks with exquisite precision. Using molecular simulation of a coarse-grained model and theoretical arguments, we envisaged how kinesin, a prototype of biological machines, generates force and regulates its dynamics to sustain persistent motor action. A structure-based model, which can be versatile in adapting its structure to external stresses while maintaining its native fold, was employed to account for several features of kinesin dynamics along the biochemical cycle. This analysis complements our current understandings of kinesin dynamics and connections to experiments. We propose a thermodynamic cycle for kinesin that emphasizes the mechanical and regulatory role of the neck linker and clarify issues related to the motor directionality, and the difference between the external stalling force and the internal tension responsible for the head-head coordination. The comparison between the thermodynamic cycle of kinesin and macroscopic heat engines highlights the importance of structural change as the source of work production in biomolecular machines.

摘要

尽管在热噪声下会发生显著波动，但细胞中的生物机器仍能以极高的精度完成任务。我们使用粗粒化模型的分子模拟和理论论证，设想了生物机器的原型——驱动蛋白如何产生力并调节其动力学以维持持续的运动。我们采用了一种基于结构的模型，该模型可以灵活地适应外部应力，同时保持其天然折叠，以解释驱动蛋白沿着生化循环的动力学的几个特征。这种分析补充了我们对驱动蛋白动力学的现有理解，并与实验联系起来。我们提出了一个驱动蛋白的热力学循环，强调了颈域连接子的机械和调节作用，并澄清了与马达方向性、导致头部协调的外部停顿力和内部张力之间的区别有关的问题。将驱动蛋白的热力学循环与宏观热机进行比较，突出了结构变化作为生物分子机器产生功的来源的重要性。

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本文引用的文献

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A universal pathway for kinesin stepping.驱动蛋白行走的通用途径。

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Neck-linker docking coordinates the kinetics of kinesin's heads.颈连器对接协调了驱动蛋白头部的动力学。

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