细菌鞭毛旋转机制及鞭毛数目调节的研究。

Seiji Kojima
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引用次数: 0

摘要

许多能运动的细菌都有运动器官——鞭毛。它由离子动力驱动的旋转马达旋转,嵌入细胞表面每根鞭毛细丝的基部。多年来,许多研究人员一直在研究它的旋转机制,但大部分的能量转换过程仍然是一个谜。我们重点研究了鞭毛定子,它在能量转换的核心过程中起作用,发现定子的质周区域改变了它的构象,只有当定子单元被并入马达并锚定在细胞壁上时才会被激活。同时,生理上重要的超分子复合物在适当的时间、适当的位置定位于细胞内。细胞如何实现这种适当的定位是生命科学的基本问题,我们通过分析溶藻弧菌单极鞭毛的生物发生机制来解决这个问题。在这里,我根据我们的研究,描述了鞭毛如何在特定的位置以适当的数量产生的分子机制,以及鞭毛定子如何被纳入电机以完成功能电机组装。
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Studies on the mechanism of bacterial flagellar rotation and the flagellar number regulation.

Many motile bacteria have the motility organ, the flagellum. It rotates by the rotary motor driven by the ion-motive force and is embedded in the cell surface at the base of each flagellar filament. Many researchers have been studying its rotary mechanism for years, but most of the energy conversion processes have been remained in mystery. We focused on the flagellar stator, which works at the core process of energy conversion, and found that the periplasmic region of the stator changes its conformation to be activated only when the stator units are incorporated into the motor and anchored at the cell wall. Meanwhile, the physiologically important supramolecular complex is localized in the cell at the right place and the right time with a proper amount. How the cell achieves such a proper localization is the fundamental question for life science, and we undertake this problem by analyzing the mechanism for biogenesis of a single polar flagellum of Vibrio alginolyticus. Here I describe the molecular mechanism of how the flagellum is generated at the specific place with a proper number, and also how the flagellar stator is incorporated into the motor to complete the functional motor assembly, based on our studies.

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[Study on biofilm formation and heterogeneity in Clostridium perfringens]. [Wakate Colosseum for Bacteriology]. [Award Lecture]. [Workshop]. [Luncheon Seminar].
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