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依赖信号的细菌鞭毛开关蛋白 FliM 的周转。

Signal-dependent turnover of the bacterial flagellar switch protein FliM.

机构信息

Clarendon Laboratory, Department of Physics, University of Oxford, Parks Road, Oxford OX1 3PU, United Kingdom.

出版信息

Proc Natl Acad Sci U S A. 2010 Jun 22;107(25):11347-51. doi: 10.1073/pnas.1000284107. Epub 2010 May 24.

DOI:10.1073/pnas.1000284107
PMID:20498085
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC2895113/
Abstract

Most biological processes are performed by multiprotein complexes. Traditionally described as static entities, evidence is now emerging that their components can be highly dynamic, exchanging constantly with cellular pools. The bacterial flagellar motor contains approximately 13 different proteins and provides an ideal system to study functional molecular complexes. It is powered by transmembrane ion flux through a ring of stator complexes that push on a central rotor. The Escherichia coli motor switches direction stochastically in response to binding of the response regulator CheY to the rotor switch component FliM. Much is known of the static motor structure, but we are just beginning to understand the dynamics of its individual components. Here we measure the stoichiometry and turnover of FliM in functioning flagellar motors, by using high-resolution fluorescence microscopy of E. coli expressing genomically encoded YPet derivatives of FliM at physiological levels. We show that the approximately 30 FliM molecules per motor exist in two discrete populations, one tightly associated with the motor and the other undergoing stochastic turnover. This turnover of FliM molecules depends on the presence of active CheY, suggesting a potential role in the process of motor switching. In many ways the bacterial flagellar motor is as an archetype macromolecular assembly, and our results may have further implications for the functional relevance of protein turnover in other large molecular complexes.

摘要

大多数生物过程都是由多蛋白复合物执行的。这些复合物传统上被描述为静态实体,但现在有证据表明,它们的组成部分可以高度动态,不断与细胞库进行交换。细菌鞭毛马达包含大约 13 种不同的蛋白质,是研究功能分子复合物的理想系统。它由跨膜离子流驱动,通过定子复合物环推动中央转子。大肠杆菌的马达随机切换方向,响应于响应调节剂 CheY 与转子开关组件 FliM 的结合。马达的静态结构已经有了很多了解,但我们才刚刚开始了解其各个组件的动态。在这里,我们通过使用高分辨率荧光显微镜观察生理水平下表达基因组编码 YPet 衍生 FliM 的大肠杆菌,测量了功能鞭毛马达中 FliM 的化学计量和周转率。我们表明,每个马达中约有 30 个 FliM 分子存在于两个离散的群体中,一个与马达紧密结合,另一个则随机进行周转。FliM 分子的这种周转取决于活性 CheY 的存在,这表明它在马达切换过程中可能具有潜在的作用。在许多方面,细菌鞭毛马达都是一种典范的大分子组装体,我们的结果可能对其他大型分子复合物中蛋白质周转的功能相关性有进一步的影响。

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