Regulator-derived growth and fitness costs of Salmonella SPI-2 expression are environment specific and T3SS independent

Bacterial pathogens must evolve regulatory mechanisms that balance the necessity of virulence genes with the costs associated with their expression. Salmonella Pathogenicity Island-2 (SPI-2) is a genomic locus that encodes a Type 3 Secretion System (T3SS) and secreted effectors necessary for intracellular survival and replication. Recent work has shown that SPI-2 is expressed heterogeneously, suggesting uniform or aberrant expression of the system carries fitness costs. Here, we report a negative correlation between microcolony growth and SPI-2 expression, suggesting a growth cost to expression of SPI-2. To quantify and mechanistically evaluate this cost, we employ knockout and synthetic expression of the SPI-2 master regulator ssrB to eliminate or force the expression of SPI-2 genes. We find that ssrB expression causes deficits throughout the growth curve and puts cells at a competitive disadvantage in acidic, nutrient limited media. We further show that these deficits are environment specific, and not observed until stationary phase in neutral, rich media. We also observe unexpected cell morphology effects of ssrB expression, suggesting its effects on the cell extend beyond its regulation of SPI-2 genes. Using known ssrB mutations we find that DNA-binding activity, but not phosphorylation, of SsrB is necessary for growth costs. Lastly, we show that this growth cost is incurred even in the absence of the SPI-2 genetic locus, indicating that it is inherent to expression of ssrB , rather than its primary downstream virulence gene targets. These results demonstrate that SPI-2 expression is coupled to context specific cell growth and fitness deficits induced by its master regulator, offering a potential benefit to heterogeneous expression.