Mechanosensitive remodeling of the bacterial flagellar motor is independent of direction of rotation

N. Wadhwa, Y. Tu, H. Berg
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引用次数: 21

Abstract

Significance Macromolecular machines carry out most of the biological functions in living organisms. Despite their significance, we do not yet understand the rules that govern the self-assembly of large multiprotein complexes. The bacterial flagellar motor tunes the assembly of its torque-generating stator complex with changes in external load. Here, we report that clockwise and counterclockwise rotating motors have identical remodeling responses to changes in the external load, suggesting a purely mechanical mechanism for this regulation. Autonomous control of self-assembly may be a general strategy for tuning the functional output of protein complexes. The flagellar motor is a prime example of a macromolecular machine in which the functional regulation of assembly can be rigorously studied. Motility is important for the survival and dispersal of many bacteria, and it often plays a role during infections. Regulation of bacterial motility by chemical stimuli is well studied, but recent work has added a new dimension to the problem of motility control. The bidirectional flagellar motor of the bacterium Escherichia coli recruits or releases torque-generating units (stator units) in response to changes in load. Here, we show that this mechanosensitive remodeling of the flagellar motor is independent of direction of rotation. Remodeling rate constants in clockwise rotating motors and in counterclockwise rotating motors, measured previously, fall on the same curve if plotted against torque. Increased torque decreases the off rate of stator units from the motor, thereby increasing the number of active stator units at steady state. A simple mathematical model based on observed dynamics provides quantitative insight into the underlying molecular interactions. The torque-dependent remodeling mechanism represents a robust strategy to quickly regulate output (torque) in response to changes in demand (load).
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细菌鞭毛马达的机械敏感性重塑与旋转方向无关
意义大分子机器在生物体中执行大部分生物功能。尽管它们意义重大,但我们还不了解控制大型多蛋白复合物自组装的规则。细菌鞭毛马达根据外部负载的变化调整其产生扭矩的定子复合体的组装。在这里,我们报道顺时针和逆时针旋转的电机对外部负载的变化有相同的重塑响应,表明这种调节的纯机械机制。自我组装的自主控制可能是调节蛋白质复合物功能输出的一般策略。鞭毛马达是大分子机器的一个主要例子,其中组装的功能调节可以被严格地研究。运动性对许多细菌的生存和传播很重要,并且在感染过程中经常起作用。化学刺激对细菌运动的调节已经得到了很好的研究,但最近的工作为运动控制问题增加了一个新的维度。大肠杆菌的双向鞭毛马达根据负载的变化招募或释放扭矩产生单元(定子单元)。在这里,我们发现鞭毛马达的机械敏感性重塑与旋转方向无关。先前测量的顺时针旋转电机和逆时针旋转电机的重塑速率常数,如果与转矩绘制,则落在同一曲线上。增加的转矩降低了电机定子单元的断开率,从而增加了稳定状态下活跃定子单元的数量。基于观察到的动力学的简单数学模型提供了对潜在分子相互作用的定量洞察。扭矩依赖的重塑机制代表了一种强大的策略,可以根据需求(负载)的变化快速调节输出(扭矩)。
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