Function and Structure of FlaK, a Master Regulator of the Polar Flagellar Genes in Marine

Overview

Journal J Bacteriol

Publisher American Society for Microbiology

Specialty Microbiology

Date 2022 Oct 31

PMID 36314831

Authors

Michio Homma

Tomoya Kobayakawa

Yuxi Hao

Tatsuro Nishikino

Seiji Kojima

Affiliations

Soon will be listed here.

Abstract

Vibrio alginolyticus has a flagellum at the cell pole, and the genes, involved in its formation, are hierarchically regulated in several classes. FlaK (also called FlrA) is an ortholog of Pseudomonas aeruginosa FleQ, an AAA+ ATPase that functions as a master regulator for all later genes. In this study, we conducted mutational analysis of FlaK to examine its ATPase activity, ability to form a multimeric structure, and function in flagellation. We cloned and confirmed that its deletion caused a nonflagellated phenotype. We substituted amino acids at the ATP binding/hydrolysis site and at the putative subunit interfaces in a multimeric structure. Mutations in these sites abolished both ATPase activity and the ability of FlaK to induce downstream flagellar gene expression. The L371E mutation, at the putative subunit interface, abolished flagellar gene expression but retained ATPase activity, suggesting that ATP hydrolysis is not sufficient for flagellar gene expression. We also found that FlhG, a negative flagellar biogenesis regulator, suppressed the ATPase activity of FlaK. The 20 FlhG C-terminal residues are critical for reducing FlaK ATPase activity. Chemical cross-linking and size exclusion chromatography revealed that FlaK mostly exists as a dimer in solution and can form multimers, independent of ATP. However, ATP induced the interaction between FlhG and FlaK to form a large complex. The effects of FlhG on FlaK, such as multimer formation and/or DNA binding, are important for gene regulation. FlaK is an NtrC-type activator of the AAA+ ATPase subfamily of σ-dependent promoters of flagellar genes. FlhG, a MinD-like ATPase, negatively regulates the polar flagellar number by collaborating with FlhF, an FtsY-like GTPase. We found that FlaK and FlhG interact in the presence of ATP to form a large complex. Mutational analysis revealed the importance of FlaK ATPase activity in flagellar gene expression and provided a model of the molecular mechanism that regulates the flagellar number.

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