[细菌运动机制]。

Shuichi Nakamura
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引用次数: 5

摘要

细菌,这种生活在微观尺度上的生物,只能通过热波动来传播。然而,定向运动的能力,如通过旋转鞭毛游泳,通过移动细胞表面粘附素在表面上滑行,以及肌动蛋白依赖的运动,可能有助于通过寻找更有利的环境来茁壮成长,并且这种运动性已知与致病性有关。在多种迁移机制中,可能大多数物种会使用鞭毛依赖的迁移机制。细菌鞭毛是一种分子纳米机器,由螺旋细丝和基础马达组成,由细胞膜上的阳离子电化学梯度(离子动力)提供动力。许多物种,如大肠杆菌,鞭毛位于细胞体的外部,而螺旋体的鞭毛位于质周空间内。鞭毛细丝或螺旋螺旋体像螺旋桨一样旋转,产生推进力。本文综述了细菌鞭毛的结构和工作机制,以及鞭毛在高粘性环境中的依赖运动。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
[Mechanism of bacterial motility].
Bacteria, life living at microscale, can spread only by thermal fluctuation. However, the ability of directional movement, such as swimming by rotating flagella, gliding over surfaces via mobile cell-surface adhesins, and actin-dependent movement, could be useful for thriving through searching more favorable environments, and such motility is known to be related to pathogenicity. Among diverse migration mechanisms, perhaps flagella-dependent motility would be used by most species. The bacterial flagellum is a molecular nanomachine comprising a helical filament and a basal motor, which is fueled by an electrochemical gradient of cation across the cell membrane (ion motive force). Many species, such as Escherichia coli, possess flagella on the outside of the cell body, whereas flagella of spirochetes reside within the periplasmic space. Flagellar filaments or helical spirochete bodies rotate like a screw propeller, generating propulsive force. This review article describes the current knowledge of the structure and operation mechanism of the bacterial flagellum, and flagella-dependent motility in highly viscous environments.
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