Ring formation byVibriofusion protein composed of FliF and FliG, MS-ring and C-ring component of bacterial flagellar motor in membrane

Abstract

ABSTRACTThe marine bacteriumVibrio alginolyticushas a single flagellum as a locomotory organ at the cell pole, which is rotated by the Na+-motive force to swim in a liquid. The base of the flagella has a motor composed of a stator and rotor, which serves as a power engine to generate torque through the rotor–stator interaction coupled to Na+influx through the stator channel. The MS-ring, which is embedded in the membrane at the base of the flagella as part of the rotor, is the initial structure required for flagellum assembly. It comprises 34 molecules of the two-transmembrane protein FliF. FliG, FliM, and FliN form a C-ring just below the MS-ring. FliG is an important rotor protein that interacts with the stator PomA and directly contributes to force generation. We previously found that FliG promotes MS-ring formation inE. coli. In the present study, we constructed afliF–fliGfusion gene, which encodes an approximately 100 kDa protein, and the successfully production of this protein effectively formed the MS-ring inE. colicells. We observed fuzzy structures around the ring using either electron microscopy or high-speed atomic force microscopy (HS-AFM), suggesting that FliM and FliN are necessary for the formation of a stable ring structure. The HS-AFM movies revealed flexible movements at the FliG region. We speculate that this flexibility plays a crucial role in facilitating the interaction between the cytoplasmic region of PomA and FliG to generate force.IMPORTANCEMS-ring is the initial structure to be assembled in flagellar motors. It comprises a complex two-ring (M and S) structure composed of 34 FliF molecules. We prepared a FliF–FliG fusion protein, which is directly involved in force generation. We observed it enabled the efficient formation of the MS-ring. The FliG portion that usually comprises the C-ring along with FliM and FliN displayed high flexibility likely due to the lack of FliM and FliN in the fusion protein. This study represents a significant milestone in thein vitroreconstruction of Na+-driven motor complexes.