Abstract
AbstractSmall single-strand DNA/RNA phages that infect gram-negative bacteria encode lysis proteins that induce cell lysis without directly degrading the cell wall. One such protein, the 37-residue LysMprotein derived from a lysis gene ofLevivirusphage M (lysM), completely blocks the lipid II transport activity mediated byEscherichia coliMurJ, which is essential for peptidoglycan biosynthesis. LysMwas proposed to be a single α-helical transmembrane protein that binds to MurJ and prevents its conformational transition during lipid II transport. Although LysMpossibly interacts with MurJ, the inhibition mechanism remains unclear. Here, we identified the crucial residues for LysMfunction via comprehensive alanine-scanning mutagenesis. These residues were located on two surfaces in an α-helix model, probably providing surfaces interacting with MurJ in the membrane. This study provides fundamental information regarding the mechanism of LysMinhibition.
Publisher
Cold Spring Harbor Laboratory
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