The Intersection of the Staphylococcus aureus Rex and SrrAB Regulons: an Example of Metabolic Evolution That Maximizes Resistance to Immune Radicals

Staphylococcus aureus is the most pathogenic member of the Staphylococcaceae. While it acquired an arsenal of canonical virulence determinants that mediate pathogenicity, it has also metabolically adapted to thrive at sites of inflammation. Notably, it has evolved to grow in the presence of nitric oxide (NO·). To this end, we note that the Rex regulon, composed of genes encoding dehydrogenases, metabolite transporters, and regulators, is much larger in S. aureus than other Staphylococcus species. Here, we demonstrate that this expanded Rex regulon is necessary and sufficient for NO· resistance. Preventing its expression results in NO· sensitivity, and the closely related species, Staphylococcus simiae, also possesses an expanded Rex regulon and exhibits NO· resistance. We hypothesize that the expanded Rex regulon initially evolved to provide efficient anaerobic metabolism but that S. aureus has co-opted this feature to thrive at sites of inflammation where respiration is limited. One distinguishing feature of the Rex regulon in S. aureus is that it contains the srrAB two-component system. Here, we show that Rex blocks the ability of SrrA to auto-induce the operon, thereby preventing maximal SrrAB expression. This results in NO·-responsive srrAB expression in S. aureus but not in other staphylococci. Consequently, higher expression of cytochromes and NO· detoxification are also observed in S. aureus alone, allowing for continued respiration at NO· concentrations beyond that of S. simiae. We therefore contend that the intersection of the Rex and SrrAB regulons represents an evolutionary event that allowed S. aureus to metabolically adapt to host inflammatory radicals during infection.