The Streptococcus pyogenes orphan protein tyrosine phosphatase,SP‐PTP,possesses dual specificity and essential virulence regulatory functions

Group A Streptococcus (GAS) is a human pathogen that causes high morbidity and mortality. GAS lacks a gene encoding tyrosine kinase but contains one encoding tyrosine phosphatase (SP‐PTP). Thus, GAS is thought to lack tyrosine phosphorylation, and the physiological significance of SP‐PTP is, therefore, questionable. Here, we demonstrate that SP‐PTP possesses dual phosphatase specificity for Tyr‐ and Ser/Thr‐phosphorylated GAS proteins, such as Ser/Thr kinase (SP‐STK) and the SP‐STK‐phosphorylated CovR and WalR proteins. Phenotypic analysis of GAS mutants lacking SP‐PTP revealed that the phosphatase activity per se positively regulates growth, cell division and the ability to adhere to and invade host cells. Furthermore, A549 human lung cells infected with GAS mutants lacking SP‐PTP displayed increased Ser‐/Thr‐/Tyr‐phosphorylation. SP‐PTP also differentially regulates the expression of ～50% of the total GAS genes, including several virulence genes potentially through the two‐component regulators, CovR, WalR and PTS/HPr regulation of Mga. Although these mutants exhibit attenuated virulence, a GAS mutant overexpressing SP‐PTP is hypervirulent. Our study provides the first definitive evidence for the presence and importance of Tyr‐phosphorylation in GAS and the relevance of SP‐PTP as an important therapeutic target.     

Two DNA-binding domains of Mga are required for virulence gene activation in the group A streptococcus

Mga is a DNA-binding protein that activates expression of several important virulence genes in the group A streptococcus (GAS), including those encoding M protein (emm), C5a peptidase (scpA) and Mga (mga). To determine the functionality of four potential helix-turn-helix DNA-binding motifs (HTH1-HTH4) identified within the amino-terminus of Mga, alanine substitutions were introduced within each domain in a MBP-Mga fusion allele and purified proteins were assayed for binding to Mga-specific promoter fragments (Pmga, PscpA and Pemm) in vitro. Although HTH-1 and HTH-2 mutations showed wild type DNA-binding activity, an altered HTH-3 domain resulted in reduced binding to the three promoters and an HTH-4 mutant was devoid of detectable binding activity. Plasmid-encoded expression of the HTH-3 and HTH-4 alleles from a constitutive promoter (Pspac) in the mga-deleted GAS strain JRS519 demonstrated that Mga-regulated emm expression correlated directly to the DNA-binding activity observed for each mutant protein in vitro. Single-copy expression of HTH-3 and HTH-4 from their native Pmga resulted in a dramatic reduction in autoregulated mga expression in both mutant strains. Thus, Mga appears to contain two DNA-binding domains (HTH-3 and HTH-4) that are required for direct activation of the Mga virulence regulon in vivo.     

A PTS EII mutant library in Group A Streptococcus identifies a promiscuous man‐family PTS transporter influencing SLS‐mediated hemolysis

The Group A Streptococcus (GAS, Streptococcus pyogenes) is a Gram‐positive human pathogen that must adapt to unique host environments in order to survive. Links between sugar metabolism and virulence have been demonstrated in GAS, where mutants in the phosphoenolpyruvate‐dependent phosphotransferase system (PTS) exhibited Streptolysin S (SLS)‐mediated hemolysis during exponential growth. This early onset hemolysis correlated with an increased lesion size and severity in a murine soft tissue infection model when compared with parental M1T1 MGAS5005. To identify the PTS components responsible for this phenotype, we insertionally inactivated the 14 annotated PTS EIIC‐encoding genes in the GAS MGAS5005 genome and subjected this library to metabolic and hemolysis assays to functionally characterize each EIIC. It was found that a few EIIs had a very limited influence on PTS sugar metabolism, whereas others were fairly promiscuous. The mannose‐specific EII locus, encoded by manLMN, was expressed as a mannose‐inducible operon that exhibited the most influence on PTS sugar metabolism, including mannose. Importantly, components of the mannose‐specific EII also acted to prevent the early onset of SLS‐mediated hemolysis. Interestingly, these roles were not identical in two different M1T1 GAS strains, highlighting the possible versatility of the PTS to adapt to strain‐specific needs.