Abstract
The bacterial flagellar motor is a reversible rotary molecular nanomachine, which couples ion flux across the cytoplasmic membrane to torque generation. It comprises a rotor and multiple stator complexes, and each stator complex functions as an ion channel and determines the ion specificity of the motor. Although coupling ions for the motor rotation were presumed to be only monovalent cations, such as H+ and Na+, the stator complex MotA1/MotB1 of Paenibacillus sp. TCA20 (MotA1TCA/MotB1TCA) was reported to use divalent cations as coupling ions, such as Ca2+ and Mg2+. In this study, we initially aimed to measure the motor torque generated by MotA1TCA/MotB1TCA under the control of divalent cation motive force; however, we identified that the coupling ion of MotA1TCAMotB1TCA is very likely to be a monovalent ion. We engineered a series of functional chimeric stator proteins between MotB1TCA and Escherichia coli MotB. E. coli ΔmotAB cells expressing MotA1TCA and the chimeric MotB presented significant motility in the absence of divalent cations. Moreover, we confirmed that MotA1TCA/MotB1TCA in Bacillus subtilis ΔmotABΔmotPS cells generates torque without divalent cations. Based on two independent experimental results, we conclude that the MotA1TCA/MotB1TCA complex directly converts the energy released from monovalent cation flux to motor rotation.
Highlights
Most swimming bacteria can swim towards their favorable environments by rotating their helical flagella [1,2]
Imazawa et al reported that the flagellar motor of Paenibacillus sp
TCA20 is driven by the flux of divalent ions and MotA1TCA/MotB1TCA, which acts as a stator in the motor, couples the divalent ion flow to motor rotation [20]
Summary
Most swimming bacteria can swim towards their favorable environments by rotating their helical flagella [1,2]. Previous studies reported that various Mot complexes work in a wide range of bacterial species, such as MotA/MotB in H+-driven motors of Escherichia coli, PomA/PomB in Na+-driven motors of Vibrio alginolyticus, MotP/MotS in Na+-driven motors of Bacillus subtilis, and MotP/MotS in Na+, K+, and Rb+-driven motors of Bacillus alcalophilus [4,5,6,7]. All these Mot complexes share a common structure and function; a peptidoglycan (PG) binding domain to anchor the stator unit to the PG layer, a transmembrane (TM). Spizizen salts contained 85 mM K2HPO4, 40 mM KH2PO4, 15 mM (NH4)2SO4, 6 mM sodium citrate, and 0.8 mM MgSO4
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