RocA Regulates Phosphatase Activity of Virulence Sensor CovS of Group A <i>Streptococcus</i> in Growth Phase- and pH-Dependent Manners
Chuan Chiang-Ni, He-Jing Chiou, H. J. Tseng, Chih‐Yun Hsu, Cheng‐Hsun Chiu
Abstract
The emergence of invasive group A streptococcal infections has been reported worldwide. Clinical isolates that have spontaneous mutations or a truncated allele of the rocA gene (e.g., emm 3-type isolates) are considered to be more virulent than isolates with the intact rocA gene (e.g., emm 1-type isolates). RocA is a positive regulator of covR and has been shown to enhance the phosphorylation level of intracellular CovR regulator through the functional CovS protein. CovS is the membrane-embedded sensor and modulates the phosphorylation level of CovR by its kinase and phosphatase activities. The present study shows that the enhancement of CovR phosphorylation is mediated via the repression of CovS’s phosphatase activity by RocA. In addition, we found that RocA acts dominantly on modulating CovR phosphorylation under neutral pH conditions and in the exponential phase of growth. The phosphorylation level of CovR is crucial for group A Streptococcus species to regulate virulence factor expression and is highly related to bacterial invasiveness; therefore, growth phase- and pH-dependent RocA activity and the sequence polymorphisms of rocA gene would contribute significantly to bacterial phenotype variations and pathogenesis.