Load-dependent adaptation near zero load in the bacterial flagellar motor.

The bacterial flagellar motor is an ion-powered transmembrane protein complex which drives swimming in many bacterial species. The motor consists of a cytoplasmic 'rotor' ring and a number of 'stator' units, which are rooted to the cell wall of the bacterium. Recently, it has been shown that the number of engaged torque-generating 'stator' units in the motor varies depending on the external load the motor experiences, and suggested that mechanosensing in the flagellar motor is driven via a 'catch bond' mechanism in the motor's stator units. Here, we present a method that allows us to measure stator dynamics across a large range of external loads, including near the zero-torque limit: By attaching superparamagnetic beads to the flagellar hook, we can control the motor's speed via a rotating magnetic field. Here, we manipulate the motor to three different speed levels in two different ion-motive force (IMF) conditions. Our results suggest that stator dynamics are affected by the torque that each stator unit experiences, manifested as a function of the energy available to it in the form of IMF and the speed at which the rotor is driven.