Variation of swimming speed enhances the chemotactic migration of Escherichia coli.

Systems and Synthetic Biology Pub Date : 2015-09-01 Epub Date: 2015-07-09 DOI:10.1007/s11693-015-9174-x
R V S Uday Bhaskar, Richa Karmakar, Deepti Deepika, Mahesh S Tirumkudulu, K V Venkatesh
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Abstract

Studies on chemotaxis of Escherichia coli have shown that modulation of tumble frequency causes a net drift up the gradient of attractants. Recently, it has been demonstrated that the bacteria is also capable of varying its runs speed in uniform concentration of attractant. In this study, we investigate the role of swimming speed on the chemotactic migration of bacteria. To this end, cells are exposed to gradients of a non-metabolizable analogue of glucose which are sensed via the Trg sensor. When exposed to a gradient, the cells modulate their tumble duration, which is accompanied with variation in swimming speed leading to drift velocities that are much higher than those achieved through the modulation of the tumble duration alone. We use an existing intra-cellular model developed for the Tar receptor and incorporate the variation of the swimming speed along with modulation of tumble frequency to predict drift velocities close to the measured values. The main implication of our study is that E. coli not only modulates the tumble frequency, but may also vary the swimming speed to affect chemotaxis and thereby efficiently sample its nutritionally rich environment.

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游泳速度的变化可增强大肠杆菌的趋化迁移。
对大肠杆菌趋化性的研究表明,调节翻滚频率会导致吸引物梯度上的净漂移。最近的研究表明,细菌还能在均匀浓度的引诱剂中改变其运行速度。在本研究中,我们研究了游泳速度对细菌趋化迁移的作用。为此,我们将细胞暴露于不可代谢的葡萄糖类似物的梯度中,并通过 Trg 传感器对其进行感应。当暴露于梯度时,细胞会调节其翻滚持续时间,同时伴随着游动速度的变化,导致漂移速度远高于仅通过调节翻滚持续时间所达到的漂移速度。我们利用现有的为焦油受体开发的细胞内模型,将游泳速度的变化与翻滚频率的调节结合起来,预测出了接近测量值的漂移速度。我们研究的主要意义在于,大肠杆菌不仅会调节翻滚频率,还可能会改变游动速度以影响趋化性,从而有效地采样营养丰富的环境。
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