Abstract

The pathogen <i>Staphylococcus aureus</i> colonizes and infects a variety of different sites within the human body. To adapt to these different environments, <i>S. aureus</i> relies on a complex and finely tuned regulatory network. While some of these networks have been well-elucidated, the functions of more than 50% of the transcriptional regulators in <i>S. aureus</i> remain unexplored. Here, we assess the contribution of the LacI family of metabolic regulators to staphylococcal virulence. We found that inactivating the purine biosynthesis regulator <i>purR</i> resulted in a strain that was acutely virulent in bloodstream infection models in mice and in ex vivo models using primary human neutrophils. Remarkably, these enhanced pathogenic traits are independent of purine biosynthesis, as the <i>purR</i> mutant was still highly virulent in the presence of mutations that disrupt PurR's canonical role. Through the use of transcriptomics coupled with proteomics, we revealed that a number of virulence factors are differentially regulated in the absence of <i>purR</i> Indeed, we demonstrate that PurR directly binds to the promoters of genes encoding virulence factors and to master regulators of virulence. These results guided us into further ex vivo and in vivo studies, where we discovered that <i>S. aureus</i> toxins drive the death of human phagocytes and mice, whereas the surface adhesin FnbA contributes to the increased bacterial burden observed in the <i>purR</i> mutant. Thus, <i>S. aureus</i> repurposes a metabolic regulator to directly control the expression of virulence factors, and by doing so, tempers its pathogenesis.