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Abstract

A large number of small membrane proteins have been discovered in bacteria, but their mechanism of action has remained mostly elusive. Here, we investigate the mechanism of a physiologically important small protein, MgrB, which represses the activity of the sensor kinase PhoQ and is widely distributed among enterobacteria. The PhoQ/PhoP two-component system is a master regulator of the bacterial virulence program and interacts with MgrB to modulate bacterial virulence, fitness, and drug resistance. A combination of crosslinking approaches with functional assays and protein dynamic simulations revealed structural rearrangements due to interactions between MgrB and PhoQ near the membrane/periplasm interface and along the transmembrane helices. These interactions induce the movement of the PhoQ catalytic domain and the repression of its activity. In the absence of MgrB, PhoQ appears to be insensitive to antimicrobial peptides, including the commonly used C18G. MgrB mediates the sensing of C18G by dissociating from and thus derepressing PhoQ. Our findings reveal the inhibitory mechanism of the small protein MgrB and uncover its importance in antimicrobial peptide sensing.Significance Statement Small proteins have been shown to have high prevalence, vast diversity and predominant regulatory functions in biological processes across all domains of life. However, their mechanisms of action remain largely elusive. In this study, we investigate the mechanism of the small protein, MgrB. It interacts with PhoQ sensor kinase, rearranges its conformation, represses its kinase activity and regulates bacterial response to environmental changes. Particularly for antimicrobial peptides, MgrB is required for bacteria to have a selective response to this host-exclusive stimulus. Our findings underline the importance of a small protein in bacterial fitness and drug resistance, provide a molecular basis for engineering novel peptide-based regulators, and present a framework for studying other small proteins.Competing Interest StatementThe authors have declared no competing interest.