Characterization of galactose catabolic pathways in Streptococcus agalactiae and identification of a major galactose: phosphotransferase importer.

We identified and characterized genomic regions of Streptococcus agalactiae that are involved in the Leloir and the tagatose-6-phosphate pathways for D-galactose catabolism. The accumulation of mutations in genes coding the Leloir pathway and the absence of these genes in a significant proportion of the strains suggest that this pathway may no longer be necessary for S. agalactiae and is heading toward extinction. In contrast, a genomic region containing genes coding for intermediates of the tagatose-6-phosphate pathway, a Gat family PTS transporter, and a DeoR/GlpR family regulator is present in the vast majority of strains. By deleting genes that code for intermediates of each of these two pathways in three selected strains, we demonstrated that the tagatose-6-phosphate pathway is their sole route for galactose catabolism. Furthermore, we showed that the Gat family PTS transporter acts as the primary importer of galactose in S. agalactiae. Finally, we proved that the DeoR/GlpR family regulator is a repressor of the tagatose-6-phosphate pathway and that galactose triggers the induction of this biochemical mechanism.IMPORTANCES. agalactiae, a significant pathogen for both humans and animals, encounters galactose and galactosylated components within its various ecological niches. We highlighted the capability of this bacterium to metabolize D-galactose and showed the role of the tagatose-6-phosphate pathway and of a PTS importer in this biochemical process. Since S. agalactiae relies on carbohydrate fermentation for energy production, its ability to uptake and metabolize D-galactose could enhance its persistence and its competitiveness within the microbiome.

The Role of Regulator Catabolite Control Protein A (CcpA) in Streptococcus agalactiae Physiology and Stress Response.

Streptococcus agalactiae is a leading cause of infections in neonates. This opportunistic pathogen colonizes the vagina, where it has to cope with acidic pH and hydrogen peroxide produced by lactobacilli. Thus, in the host, this bacterium possesses numerous adaptation mechanisms in which the pleiotropic regulators play a major role. The transcriptional regulator CcpA (catabolite control protein A) has previously been shown to be the major regulator involved in carbon catabolite repression in Gram-positive bacteria but is also involved in other functions. By transcriptomic analysis, we characterized the CcpA-dependent gene regulation in S. agalactiae. Approximately 13.5% of the genome of S. agalactiae depends on CcpA for regulation and comprises genes involved in sugar uptake and fermentation, confirming the role of CcpA in carbon metabolism. We confirmed by electrophoretic mobility shift assays (EMSAs) that the DNA binding site called cis-acting catabolite responsive element (cre) determined for other streptococci was effective in S. agalactiae. We also showed that CcpA is of capital importance for survival under acidic and oxidative stresses and is implicated in macrophage survival by regulating several genes putatively or already described as involved in stress response. Among them, we focused our study on SAK_1689, which codes a putative UspA protein. We demonstrated that SAK_1689, highly downregulated by CcpA, is overexpressed under oxidative stress conditions, this overexpression being harmful for the bacterium in a ΔccpA mutant. IMPORTANCE Streptococcus agalactiae is a major cause of disease burden leading to morbidity and mortality in neonates worldwide. Deciphering its adaptation mechanisms is essential to understand how this bacterium manages to colonize its host. Here, we determined the regulon of the pleiotropic regulator CcpA in S. agalactiae. Our findings reveal that CcpA is not only involved in carbon catabolite repression, but is also important for acidic and oxidative stress resistance and survival in macrophages.

Inductors and regulatory properties of the genomic island-associated fru2 metabolic operon of Streptococcus agalactiae.

The fru2 metabolic operon of Streptococcus agalactiae encodes the phosphoenolpyruvate:carbohydrate phosphotransferase system (PTS) enzyme II complex Fru2 (EIIBFru2 , EIIAFru2 , and EIICFru2 ); Fru2 R, a transcriptional activator with PTS regulatory domains (PRDs); a d-allulose-6-phosphate 3-epimerase; a transaldolase; and a transketolase. We showed that the transcription of fru2 is induced during the stationary phase of growth in complex media and during incubation in human cerebrospinal or amniotic fluids. d-allose and d-ribose are environmental signals governing this induction. PTSFru2 is involved in the activation of the fru2 promoter, and the histidine-67 of EIIAFru2 and the cysteine-9 of EIIBFru2 are important for this function. The activation of fru2 is also controlled by Fru2 R. The histidine-243 in the PRD1 domain, the histidine-323 in the PRD2 domain, the cysteine-400 in the EIIB-like domain, and the histidine-549 in the EIIA-like domain are important for the function of Fru2 R. Fru2 R binds to a DNA region containing palindromic sequences upstream of the identified transcriptional start site. EIIBFru2 interacts physically with the C-terminal part of Fru2 R (expressing the EIIB-like and EIIA-like motifs) and with EIIAFru2 . We propose a model of regulation of fru2 depending on the presence of an activatory carbohydrate in the growth medium.