Structure and Energy-Conversion Mechanism of the Bacterial Na+-Driven Flagellar Motor

Takekawa Norihiro; Imada Katsumi; Homma Michio

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Structure and Energy-Conversion Mechanism of the Bacterial Na+-Driven Flagellar Motor

机译：细菌NA +驱动鞭毛电机的结构和能量转化机制

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Many bacteria swim by means of flagella that are rotated by a nanoscale motor embedded in the cell membrane. Torque is generated by the interaction between ion-conducting membrane proteins that comprise the stator and ring-shaped structures that form the rotor. Although the structure and function of the motor have been extensively studied, many mysteries remain, including the force-generation mechanism, the path of ion flow through the stator, the activation mechanism of the stator, and the mechanism of switching between clockwise (CW) and counterclockwise (CCW) rotation. We summarize recent knowledge of the Na+-driven flagellar motor, especially the Vibrio polar motor that rotates much faster than the H+-driven motor and provides a useful model system for examining comparative aspects of flagellar function.

机译：许多细菌通过嵌入在细胞膜中的纳米级电机旋转的鞭毛游泳。通过包括形成转子的定子和环形结构的离子导电膜蛋白之间的相互作用产生扭矩。虽然电机的结构和功能已经过广泛研究，但是许多谜团仍然存在，包括力发生机构，离子流过定子的路径，定子的激活机构，顺时针（CW）之间切换的机构逆时针（CCW）旋转。我们总结了最近对Na + -drive鞭毛电机的了解，特别是旋转的振动极性电动机比H + -drive马达更快，并提供了一种用于检查鞭毛功能的比较方面的有用模型系统。

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《Trends in Microbiology》 |2020年第9期|共13页
作者
Takekawa Norihiro; Imada Katsumi; Homma Michio;
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Osaka Univ Grad Sch Sci Dept Macromol Sci 1-1 Machikaneyama Cho Toyonaka Osaka 5600043 Japan;

Osaka Univ Grad Sch Sci Dept Macromol Sci 1-1 Machikaneyama Cho Toyonaka Osaka 5600043 Japan;

Nagoya Univ Grad Sch Sci Div Biol Sci Chikusa Ku Furo Cho Nagoya Aichi 4648602 Japan;

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1. Structure and Energy-Conversion Mechanism of the Bacterial Na+-Driven Flagellar Motor [J] . Takekawa Norihiro, Imada Katsumi, Homma Michio Trends in Microbiology . 2020,第9期

机译：细菌NA +驱动鞭毛电机的结构和能量转化机制
2. Assembly of motor proteins, PomA and PomB, in the Na+-driven stator of the flagellar motor [J] . Fukuoka H, Yakushi T, Kusurnoto A, Journal of Molecular Biology . 2005,第4期

机译：在鞭毛马达的Na +驱动定子中组装马达蛋白PomA和PomB
3. Requirements for Conversion of the Na+-Driven Flagellar Motor of Vibrio cholerae to the H+-Driven Motor of Escherichia coli [J] . Khoosheh K. Gosink, Claudia C. H?se Journal of bacteriology . 2000,第15期

机译：将霍乱弧菌的Na +驱动鞭毛马达转换为大肠杆菌的H +驱动马达的要求
4. Towards a biohybrid sensing platform built on impedance-based bacterial flagellar motor tachometry [C] . Tom J. Zajdel, Alexander N. Walczak, Debleena Sengupta, IEEE biomedical circuits and systems conference . 2017

机译：迈向基于阻抗细菌细菌鞭毛运动转速计的生物杂交传感平台
5. Study on the torque-generating mechanism of the sodium-driven bacterial flagellar motor [D] . Muramoto Kazumasa, 村本和優 1995

机译：钠驱动细菌鞭毛马达的转矩产生机理研究
6. A High-Throughput Screening Assay for Inhibitors of Bacterial Motility Identifies a Novel Inhibitor of the Na+-Driven Flagellar Motor and Virulence Gene Expression in Vibrio cholerae [O] . Lynn Rasmussen, E. Lucile White, Ashish Pathak, 2011

机译：细菌运动抑制剂的高通量筛选测定法鉴定了霍乱弧菌中Na +驱动的鞭毛运动和毒力基因表达的新型抑制剂。
7. 2S3-4 Modulation of the flagellar motor rotation by high-pressure microscopy(2S3 Structure and functional mechanism of the bacterial flagellar motor,The 46th Annual Meeting of the Biophysical Society of Japan) [O] . Masayoshi Nishiyama 2008

机译：2S3-4通过高压显微镜（2S3结构和细菌旗杆电机的2S3结构和功能机制，日本生物物理学学会第46次年会）的调制

Structure and Energy-Conversion Mechanism of the Bacterial Na+-Driven Flagellar Motor

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