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.     

The Mga virulence regulon: infection where the grass is greener

Co-ordinate regulation of virulence gene expression in response to different host environments is central to the success of the group A streptococcus (GAS, Streptococcus pyogenes) as an important human pathogen. Mga represents a ubiquitous stand-alone virulence regulator that controls genes (Mga regulon) whose products are necessary for adherence, internalization and host immune evasion. Mga highly activates a core set of virulence genes, including its own gene, by directly binding to their promoters. Yet, Mga also influences expression of over 10% of the GAS genome, primarily genes and operons involved in metabolism and sugar utilization. Expression of the Mga regulon is influenced by conditions that signify favourable growth conditions, presumably allowing GAS to take advantage of promising new niches in the host. The ability of Mga to respond to growth signals clearly involves regulation of mga expression via global regulatory networks such as RALPs, Rgg/RopB and the catabolite control protein CcpA. However, the presence of predicted PTS regulatory domains (PRDs) within Mga suggests an intriguing model whereby phosphorylation of Mga by the PTS phosphorelay might link growth and sugar utilization with virulence in GAS. As Mga homologues have been found in several important Gram-positive pathogens, the Mga regulon could provide a valuable paradigm for increasing our understanding of global virulence networks in bacteria.     

Quantification of the influence of HPrSer46P on CcpA-cre interaction

Carbon catabolite repression (CCR) of the Bacillus megateriumxyl operon is dependent on the catabolite responsive element cre, the catabolite control protein (CcpA) and the histidine-containing phosphocarrier protein phosphorylated at the serine 46 residue (HPrSer46P). The latter is formed in the presence of glucose and mediates CCR via CcpA. We present evidence for the presence of HPrSer46P in a ternary complex with CcpA and cre. We also demonstrate increased stability of this complex compared to the CcpA-cre complex by electrophoretic mobility shift analysis (EMSA). This stabilization by HPrSer46P is the same for the xyl cre and an improved cre. Thus, HPrSer46P is a co-repressor for CcpA. In addition, surface plasmon resonance (SPR) experiments yielded binding constants of CcpA and the CcpA-HPrSer46P complex with cre. HPrSer46P stimulated CcpA binding to cre 50-fold. The binding constant is 4.9(+/- 0.5) x 10(6) M(-1). Non-phosphorylated HPr did not affect the complex formation between CcpA and cre. Previously proposed effects by glucose-6-phosphate, fructose-1,6-diphosphate and NADP on CcpA-cre or CcpA-HPrSer46P-cre formation were not found in EMSA and SPR experiments.     

Phosphorylation of HPr and Crh by HprK, early steps in the catabolite repression signalling pathway for the Bacillus subtilis levanase operon

Carbon catabolite repression (CCR) of Bacillus subtilis catabolic genes is mediated by CcpA and in part by P-Ser-HPr. For certain operons, Crh, an HPr-like protein, is also implicated in CCR. In this study we demonstrated that in ptsH1 crh1 and hprK mutants, expression of the lev operon was completely relieved from CCR and that both P-Ser-HPr and P-Ser-Crh stimulated the binding of CcpA to the cre sequence of the lev operon.     

CcpA-mediated repression of Clostridium difficile toxin gene expression

The presence of glucose or other rapidly metabolizable carbon sources in the bacterial growth medium strongly represses Clostridium difficile toxin synthesis independently of strain origin. In Gram-positive bacteria, carbon catabolite repression (CCR) is generally regarded as a regulatory mechanism that responds to carbohydrate availability. In the C. difficile genome all elements involved in CCR are present. To elucidate in vivo the role of CCR in C. difficile toxin synthesis, we used the ClosTron gene knockout system to construct mutants of strain JIR8094 that were unable to produce the major components of the CCR signal transduction pathway: the phosphotransferase system (PTS) proteins (Enzyme I and HPr), the HPr kinase/phosphorylase (HprK/P) and the catabolite control protein A, CcpA. Inactivation of the ptsI, ptsH and ccpA genes resulted in derepression of toxin gene expression in the presence of glucose, whereas repression of toxin production was still observed in the hprK mutant, indicating that uptake of glucose is required for repression but that phosphorylation of HPr by HprK is not. C. difficile CcpA was found to bind to the regulatory regions of the tcdA and tcdB genes but not through a consensus cre site motif. Moreover in vivo and in vitro results confirmed that HPr-Ser45-P does not stimulate CcpA-dependent binding to DNA targets. However, fructose-1,6-biphosphate (FBP) alone did increase CcpA binding affinity in the absence of HPr-Ser45-P. These results showed that CcpA represses toxin expression in response to PTS sugar availability, thus linking carbon source utilization to virulence gene expression in C. difficile.     

Regulators of the Bacillus subtilis cydABCD operon: identification of a negative regulator, CcpA, and a positive regulator, ResD

The cydABCD operon of Bacillus subtilis encodes products required for the production of cytochrome bd oxidase. Previous work has shown that one regulatory protein, YdiH (Rex), is involved in the repression of this operon. The work reported here confirms the role of Rex in the negative regulation of the cydABCD operon. Two additional regulatory proteins for the cydABCD operon were identified, namely, ResD, a response regulator involved in the regulation of respiration genes, and CcpA, the carbon catabolite regulator protein. ResD, but not ResE, was required for full expression of the cydA promoter in vivo. ResD binding to the cydA promoter between positions -58 and -107, a region which includes ResD consensus binding sequences, was not enhanced by phosphorylation. A ccpA mutant had increased expression from the full-length cydA promoter during stationary growth compared to the wild-type strain. Maximal expression in a ccpA mutant was observed from a 3'-deleted cydA promoter fusion that lacked the Rex binding region, suggesting that the effect of the two repressors, Rex and CcpA, was cumulative. CcpA binds directly to the cydA promoter, protecting the region from positions -4 to -33, which contains sequences similar to the CcpA consensus binding sequence, the cre box. CcpA binding was enhanced upon addition of glucose-6-phosphate, a putative cofactor for CcpA. Mutation of a conserved residue in the cre box reduced CcpA binding 10-fold in vitro and increased cydA expression in vivo. Thus, CcpA and ResD, along with the previously identified cydA regulator Rex (YdiH), affect the expression of the cydABCD operon. Low-level induction of the cydA promoter was observed in vivo in the absence of its regulatory proteins, Rex, CcpA, and ResD. This complex regulation suggests that the cydA promoter is tightly regulated to allow its expression only at the appropriate time and under the appropriate conditions.