Formation of multiple flagella caused by a mutation of the flagellar rotor protein FliM in Vibrio alginolyticus

Abstract

AbstractThe marine bacterium Vibrio alginolyticus forms only a single flagellum at the cell pole. In Vibrio, two proteins (GTPase FlhF and ATPase FlhG) regulate flagellar number at the cell pole. We previously isolated a mutant strain characterized as NMB155 that forms multiple flagella despite the absence of mutations in flhF and flhG. NMB155 also exhibited straight swimming without a directional change in flagellar rotation. Whole-genome sequencing of NMB155 identified an E9K mutation in FliM that is a component of the C-ring in the flagellar rotor. Mutations in FliM result in defects in flagellar formation (fla) and flagellar rotation (che or mot); however, there are few reports indicating that FliM mutations increase the number of flagella. Here, we determined that the E9K mutation confers the multi-flagellar phenotype and also the che phenotype. The co-expression of wild-type FliM and FliM-E9K indicated that they were competitive in regard to determining the flagellar number. It had been shown that the ATPase activity of FlhG corresponds to the flagellar number. We observed that the ATPase activity of FlhG was increased by the addition of FliM but not by the addition of FliM-E9K. This indicates that the N-terminal region of FliM that includes the E9 residue interacts with FlhG to increase its ATPase activity, and the E9K mutation may inhibit this interaction. We concluded that FliM downregulate FlhG activity to inhibit the formation of additional flagella.ImportanceThe flagellar rotor generates a driving force to rotate the flagellum and is not involved in controlling the number of flagella in Vibrio. However, we observed that the E9K mutation in the rotor protein FliM confers multiple flagella. Our findings reveal a novel regulatory mechanism controlling flagellar number.