细菌鞭毛旋转速率和游动速度的同步测量。

Simultaneous measurement of bacterial flagellar rotation rate and swimming speed.

作者信息

Magariyama Y, Sugiyama S, Muramoto K, Kawagishi I, Imae Y, Kudo S

机构信息

Tsukuba Research Laboratory, Yaskawa Electric Corporation, Japan.

出版信息

Biophys J. 1995 Nov;69(5):2154-62. doi: 10.1016/S0006-3495(95)80089-5.

DOI:10.1016/S0006-3495(95)80089-5

PMID:8580359

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1236449/

Abstract

Swimming speeds and flagellar rotation rates of individual free-swimming Vibrio alginolyticus cells were measured simultaneously by laser dark-field microscopy at 25, 30, and 35 degrees C. A roughly linear relation between swimming speed and flagellar rotation rate was observed. The ratio of swimming speed to flagellar rotation rate was 0.113 microns, which indicated that a cell progressed by 7% of pitch of flagellar helix during one flagellar rotation. At each temperature, however, swimming speed had a tendency to saturate at high flagellar rotation rate. That is, the cell with a faster-rotating flagellum did not always swim faster. To analyze the bacterial motion, we proposed a model in which the torque characteristics of the flagellar motor were considered. The model could be analytically solved, and it qualitatively explained the experimental results. The discrepancy between the experimental and the calculated ratios of swimming speed to flagellar rotation rate was about 20%. The apparent saturation in swimming speed was considered to be caused by shorter flagella that rotated faster but produced less propelling force.

摘要

通过激光暗场显微镜在25、30和35摄氏度下同时测量了单个自由游动的溶藻弧菌细胞的游动速度和鞭毛旋转速率。观察到游动速度与鞭毛旋转速率之间大致呈线性关系。游动速度与鞭毛旋转速率的比值为0.113微米，这表明细胞在一次鞭毛旋转过程中前进了鞭毛螺旋节距的7%。然而，在每个温度下，游动速度在高鞭毛旋转速率时都有饱和的趋势。也就是说，鞭毛旋转较快的细胞并不总是游得更快。为了分析细菌的运动，我们提出了一个考虑鞭毛马达扭矩特性的模型。该模型可以进行解析求解，并定性地解释了实验结果。实验测得的游动速度与鞭毛旋转速率的比值与计算值之间的差异约为20%。游动速度的明显饱和被认为是由较短的鞭毛引起的，这些鞭毛旋转较快但产生的推进力较小。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/3ecb/1236449/c232ac1e1a71/biophysj00055-0527-a.jpg

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本文引用的文献

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细菌鞭毛旋转速率和游动速度的同步测量。

Simultaneous measurement of bacterial flagellar rotation rate and swimming speed.

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