Physical mechanism reveals bacterial slowdown above a critical number of flagella

Maria Tătulea-Codrean, Eric Lauga
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Abstract

Numerous studies have explored the link between bacterial swimming and the number of flagella, a distinguishing feature of motile multiflagellated bacteria. We revisit this open question using augmented slender-body theory simulations, in which we resolve the full hydrodynamic interactions within a bundle of helical filaments rotating and translating in synchrony. Unlike previous studies, our model considers the full torque-speed relationship of the bacterial flagellar motor, revealing its significant impact on multiflagellated swimming. Because the viscous load per motor decreases with flagellar number, the bacterial flagellar motor (BFM) transitions from the high-load to the low-load regime at a critical number of filaments, leading to bacterial slowdown as further flagella are added to the bundle. We explain the physical mechanism behind the observed slowdown as an interplay between the load-dependent generation of torque by the motor, and the load-reducing cooperativity between flagella, which consists of both hydrodynamic and non-hydrodynamic components. The theoretically predicted critical number of flagella is remarkably close to the values reported for the model organism \textit{Escherichia coli}. Our model further predicts that the critical number of flagella increases with viscosity, suggesting that bacteria can enhance their swimming capacity by growing more flagella in more viscous environments, consistent with empirical observations.
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物理机制揭示了细菌在鞭毛数量超过临界值时速度减慢的原因
许多研究探讨了细菌游动与鞭毛数量之间的联系,鞭毛数量是多鞭毛运动细菌的一个显著特征。我们利用增强细长体理论模拟重新探讨了这一悬而未决的问题,在模拟中,我们解决了同步旋转和平移的螺旋丝束内的全部流体动力学相互作用。与以前的研究不同,我们的模型考虑了细菌鞭毛马达的全部扭矩-速度关系,揭示了它对多鞭毛虫游泳的重大影响。由于每个马达的粘性负荷随着鞭毛数量的增加而减少,细菌鞭毛马达(BFM)在鞭毛数量达到临界值时会从高负荷状态过渡到低负荷状态,从而导致细菌在鞭毛束中增加鞭毛时速度减慢。我们将所观察到的减速现象背后的物理机制解释为马达产生的转矩与鞭毛之间的减载协同作用之间的相互作用。理论预测的鞭毛临界数量与模式生物(大肠杆菌)的报告值非常接近。我们的模型进一步预测,鞭毛的临界数量会随着粘度的增加而增加,这表明细菌可以通过在粘度更高的环境中生长更多的鞭毛来增强其游泳能力,这与经验观察是一致的。
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