Abstract
ABSTRACTThe transcriptional regulator SsrB acts as a switch between virulent and biofilm lifestyles of non-typhoidalSalmonella entericaserovar Typhimurium. During infection, phosphorylated SsrB activates genes onSalmonellaPathogenicity Island-2 (SPI-2) essential for survival and replication within the macrophage. Low pH inside the vacuole is a key inducer of expression and SsrB activation. Previous studies demonstrated an increase in SsrB protein levels and DNA-binding affinity at low pH; the molecular basis was unknown (Liew et al., 2019). This study elucidates its underlying mechanism andin vivosignificance. Employing single-molecule and transcriptional assays, we report that the SsrB DNA binding domain alone (SsrBc) is insufficient to induce acid pH sensitivity. Instead, His12, a conserved residue in the receiver domain, confers pH sensitivity to SsrB allosterically. Acid-dependent DNA binding was highly cooperative, suggesting a new configuration of SsrB oligomers at SPI-2-dependent promoters. His12 plays a role in SsrB phosphorylation; substituting His12 reduced phosphorylation at neutral pH and abolished pH-dependent differences. Failure to flip the switch in SsrB rendersSalmonellaavirulent and represents a potential means of controlling virulence.
Publisher
Cold Spring Harbor Laboratory