利用荧光各向异性评估大肠杆菌鞭毛马达 C 环的 CW 和 CCW 构象。

CW and CCW Conformations of the E. coli Flagellar Motor C-Ring Evaluated by Fluorescence Anisotropy.

机构信息

Rowland Institute at Harvard, Harvard University, Cambridge, Massachusetts; Department of Molecular and Cellular Biology, Harvard University, Cambridge, Massachusetts.

出版信息

Biophys J. 2018 Feb 6;114(3):641-649. doi: 10.1016/j.bpj.2017.12.001.

DOI:10.1016/j.bpj.2017.12.001

PMID:29414710

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC5985018/

Abstract

The molecular cascade that controls switching of the direction of rotation of Escherichia coli flagellar motors is well known, but the conformational changes that allow the rotor to switch are still unclear. The signaling molecule CheY, when phosphorylated, binds to the C-ring at the base of the rotor, raising the probability that the motor spins clockwise. When the concentration of CheY-P is so low that the motor rotates exclusively counterclockwise (CCW), the C-ring recruits more monomers of FliM and tetramers of FliN, the proteins to which CheY-P binds, thus increasing the motor's sensitivity to CheY-P and allowing it to switch once again. Motors that rotate exclusively CCW have more FliM and FliN subunits in their C-rings than motors that rotate exclusively clockwise. How are the new subunits accommodated? Does the diameter of the C-ring increase, or do FliM and FliN get packed in a different pattern, keeping the overall diameter of the C-ring constant? Here, by measuring fluorescence anisotropy of yellow fluorescent protein-labeled motors, we show that the CCW C-rings accommodate more FliM monomers without changing the spacing between them, and more FliN monomers at the same time as increasing their effective spacing and/or changing their orientation within the tetrameric structure.

摘要

控制大肠杆菌鞭毛马达旋转方向切换的分子级联反应众所周知，但允许转子切换的构象变化仍不清楚。当信号分子 CheY 磷酸化时，它会与转子底部的 C 环结合，从而增加马达顺时针旋转的概率。当 CheY-P 的浓度低到足以使马达仅逆时针旋转（CCW）时，C 环会招募更多的 FliM 单体和 CheY-P 结合的 FliN 四聚体，从而增加马达对 CheY-P 的敏感性，使其再次切换。仅逆时针旋转的马达的 C 环中的 FliM 和 FliN 亚基比仅顺时针旋转的马达多。新的亚基是如何适应的？C 环的直径会增加，还是 FliM 和 FliN 以不同的模式包装，保持 C 环的总直径不变？在这里，我们通过测量黄色荧光蛋白标记的马达的荧光各向异性，表明 CCW C 环在不改变它们之间间距的情况下容纳更多的 FliM 单体，同时在增加它们的有效间距和/或改变它们在四聚体结构中的方向的同时容纳更多的 FliN 单体。

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CW and CCW Conformations of the E. coli Flagellar Motor C-Ring Evaluated by Fluorescence Anisotropy.利用荧光各向异性评估大肠杆菌鞭毛马达 C 环的 CW 和 CCW 构象。

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