Genetic Characterization of the Galactitol Utilization Pathway of Salmonella enterica Serovar Typhimurium.

Galactitol degradation by salmonellae remains underinvestigated, although this metabolic capability contributes to growth in animals (R. R. Chaudhuri et al., PLoS Genet 9:e1003456, 2013, https://doi.org/10.1371/journal.pgen.1003456). The genes responsible for this metabolic capability are part of a 9.6-kb gene cluster that spans from gatY to gatR (STM3253 to STM3262) and encodes a phosphotransferase system, four enzymes, and a transporter of the major facilitator superfamily. Genome comparison revealed the presence of this genetic determinant in nearly all Salmonella strains. The generation time of Salmonella enterica serovar Typhimurium strain ST4/74 was higher in minimal medium with galactitol than with glucose. Knockout of STM3254 and gatC resulted in a growth-deficient phenotype of S Typhimurium, with galactitol as the sole carbon source. Partial deletion of gatR strongly reduced the lag phase of growth with galactitol, whereas strains overproducing GatR exhibited a near-zero growth phenotype. Luciferase reporter assays demonstrated strong induction of the gatY and gatZ promoters, which control all genes of this cluster except gatR, in the presence of galactitol but not glucose. Purified GatR bound to these two main gat gene cluster promoters as well as to its own promoter, demonstrating that this autoregulated repressor controls galactitol degradation. Surface plasmon resonance spectroscopy revealed distinct binding properties of GatR toward the three promoters, resulting in a model of differential gat gene expression. The cyclic AMP receptor protein (CRP) bound these promoters with similarly high affinities, and a mutant lacking crp showed severe growth attenuation, demonstrating that galactitol utilization is subject to catabolite repression. Here, we provide the first genetic characterization of galactitol degradation in Salmonella, revealing novel insights into the regulation of this dissimilatory pathway. IMPORTANCE: The knowledge of how pathogens adapt their metabolism to the compartments encountered in hosts is pivotal to our understanding of bacterial infections. Recent research revealed that enteropathogens have adapted specific metabolic pathways that contribute to their virulence properties, for example, by helping to overcome limitations in nutrient availability in the gut due to colonization resistance. The capability of Salmonella enterica serovar Typhimurium to degrade galactitol has already been demonstrated to play a role in vivo, but it has not been investigated so far on the genetic level. To our knowledge, this is the first molecular description of the galactitol degradation pathway of a pathogen.

The MazEF Toxin-Antitoxin System Alters the ß-Lactam Susceptibility of Staphylococcus aureus.

Toxin-antitoxin (TA) systems are genetic elements of prokaryotes which encode a stable toxin and an unstable antitoxin that can counteract toxicity. TA systems residing on plasmids are often involved in episomal maintenance whereas those on chromosomes can have multiple functions. The opportunistic pathogen Staphylococcus aureus possesses at least four different families of TA systems but their physiological roles are elusive. The chromosomal mazEF system encodes the RNase toxin MazF and the antitoxin MazE. In the light of ambiguity regarding the cleavage activity, we here verify that MazF specifically targets UACAU sequences in S. aureus in vivo. In a native strain background and under non-stress conditions, cleavage was observed in the absence or presence of mazE. Transcripts of spa (staphylococcal protein A) and rsbW (anti-σB factor) were cut, but translational reporter fusions indicated that protein levels of the encoded products were unaffected. Despite a comparable growth rate as the wild-type, an S. aureus mazEF deletion mutant was more susceptible to ß-lactam antibiotics, which suggests that further genes, putatively involved in the antibiotic stress response or cell wall synthesis or turnover, are controlled by this TA system.

Two paralogous yefM-yoeB loci from Staphylococcus equorum encode functional toxin-antitoxin systems.

Toxin-antitoxin (TA) systems are small genetic elements of prokaryotes associated with persister cell formation, phage defence, stress regulation and programmed cell arrest. In this study, we characterized two paralogues of the ribosome-dependent RNase YefM-YoeB TA system from the Gram-positive organism Staphylococcus equorum SE3. 5' Rapid amplification of cDNA ends confirmed transcriptional activity in the exponential growth phase and revealed an extended 5' untranslated region upstream of the yefM-seq1 gene. Inducible expression of the putative yoeB-seq1/2 toxins led to growth defects of Escherichia coli, which were counteracted by simultaneous induction of the cognate yefM-seq1/2 antitoxin candidates in a strictly pairwise manner. Bacterial two-hybrid assays revealed interaction between YoeB-seq1 and YefM-seq1 but not YoeB-seq1 and YefM-seq2, also indicating two independent systems. In vivo primer extensions demonstrated specific RNA cleavage adjacent to the start codons by YoeB-seq proteins, and YoeB-seq2 activity could be neutralized by the corresponding antitoxin YefM-seq2. Together, these results indicate that the two yefM-yoeB-seq1/2 paralogues from S. equorum encode functional TA systems.