Abstract
Enterobacteriaceae use the periplasmic domain of the conserved inner membrane protein, PbgA/YejM, to regulate lipopolysaccharide (LPS) biogenesis. Salmonella enterica serovar Typhimurium (S. Typhimurium) relies on PbgA to cause systemic disease in mice and this involves functional interactions with LapB/YciM, FtsH, and LpxC. Escherichia coli PbgA interacts with LapB, an adaptor for the FtsH protease, via the transmembrane segments. LapB and FtsH control proteolysis of LpxC, the rate-limiting LPS biosynthesis enzyme. Lipid A-core, the hydrophobic anchor of LPS molecules, co-crystallizes with PbgA and interacts with residues in the basic region. The model predicts that PbgA-LapB detects periplasmic LPS molecules and prompts FtsH to degrade LpxC. However, the key residues and critical interactions are not defined. We establish that S. Typhimurium uses PbgA to regulate LpxC and define the contribution of two pairs of arginines within the basic region. PbgA R215 R216 form contacts with lipid A-core in the structure, and R231 R232 exist in an adjacent alpha helix. PbgA R215 R216 are necessary for S. Typhimurium to regulate LpxC, control lipid-A core biogenesis, promote survival in macrophages, and enhance virulence in mice. In contrast, PbgA R231 R232 are not necessary to regulate LpxC or to control lipid A-core levels, nor are they necessary to promote survival in macrophages or mice. However, residues R231 R232 are critical for infection lethality, and the persistent infection phenotype requires mouse Toll-like receptor four, which detects lipid A. Therefore, S. Typhimurium relies on PbgA's tandem arginines for multiple interconnected mechanisms of LPS regulation that enhance pathogenesis.