The PilT retraction ATPase promotes both extension and retraction of the MSHA type IVa pilus inVibrio cholerae

Abstract

ABSTRACTDiverse bacterial species use type IVa pili (T4aP) to interact with their environments. The dynamic extension and retraction of T4aP is critical for their function, but the mechanisms that regulate this dynamic activity remain poorly understood. T4aP are typically extended via the activity of a dedicated extension motor ATPase and retracted via the action of an antagonistic retraction motor ATPase called PilT. These motors are generally functionally independent, and loss of PilT commonly results in T4aP hyperpiliation due to undeterred pilus extension.However, for the mannose-sensitive hemagglutinin (MSHA) T4aP ofVibrio cholerae, the loss of PilT results in a loss of surface piliation, which is unexpected based on our current understanding of T4aP dynamics. Here, we employ a combination of genetic and cell biological approaches to dissect the underlying mechanism. Our results demonstrate that PilT is necessary for MSHA pilus extension in addition to its well-established role in promoting MSHA pilus retraction. Through a suppressor screen, we also provide genetic evidence that the MshA major pilin impacts pilus extension. Together, these findings contribute to our understanding of the factors that regulate pilus extension and describe a previously uncharacterized function for the PilT motor ATPase.AUTHOR SUMMARYMany bacteria use filamentous appendages called type IVa pili to interact with their environment. These fibers dynamically extend and retract through the activity of ATPase motor proteins. In most pilus systems, deletion of the retraction motor results in uninterrupted pilus extension, leading to hyperpiliation. However, in the MSHA pilus system ofV. cholerae, deletion of the retraction motor,pilT, results in a decrease in the number of surface pili. Here, we show that PilT is unexpectedly required for MSHA pilus extension in addition to its defined role in promoting pilus retraction. These results extend our understanding of the complex mechanisms underlying the dynamic activity of these broadly conserved filamentous appendages.