The stoichiometry of minor-to-major pilins regulates the dynamic activity of the type IVa competence pilus in Vibrio cholerae

Type IVa pili (T4aP) are bacterial surface appendages that perform various functions including twitching motility, surface attachment, cell-cell interactions, and DNA uptake for natural transformation. Pivotal to each of these functions is the ability of T4aP to be dynamically extended and retracted from the cell surface. However, the factors that regulate this dynamic activity remain poorly understood. To address this question, we employ the competence T4aP from Vibrio cholerae as a model system. T4aP are composed of major and minor pilin subunits, named based on their relative abundance in the pilus filament. Prior work has established that minor pilins form a complex that initiates T4aP assembly. This allows for the subsequent addition of major pilins to the filament, which promotes T4aP extension. Here, we uncover that the stoichiometry of minor-to-major pilins is a crucial determinant of T4aP dynamic activity. Specifically, we show that either (1) overexpressing minor pilins or (2) underexpressing the major pilin results is a dramatic increase in the frequency of T4aP dynamics. These results indicate that the stoichiometry of major-to-minor pilins, not their absolute abundance, is one mechanism that regulates T4aP dynamic activity. AUTHOR SUMMARYType IVa pili (T4aP) are a broadly conserved family of filamentous bacterial appendages that help bacteria colonize surfaces, move towards or away from stimuli, and gain new traits through a mechanism of horizontal gene transfer called natural transformation. T4aP are primarily composed of protein subunits called major and minor pilins, named based on their relative abundance in the pilus filament. Bacteria can dynamically extend and retract pilus filaments from their surface through polymerization and depolymerization of these pilins. This dynamic activity is critical for the activities that T4aP carry out. However, the factors that regulate this dynamic activity remain incompletely understood. Here, we find that the ratio of minor-to-major pilins is one factor that regulates the frequency of dynamic activity. Minor pilins are a universally conserved feature of T4aP. So, the minor-to-major pilin ratio may be a broadly conserved mechanism for controlling dynamic T4aP activity in diverse bacterial species.