Project description:The nucleotide (p)ppGpp is crucial for viability during amino acid limitation in bacteria, yet how it accomplishes this remains unknown. We found that the absence of (p)ppGpp in Bacillus subtilis cells leads to multiple amino acid auxotrophy, and that (p)ppGpp allows for prototrophy by reducing GTP levels. We provide evidence that reduction of GTP levels relieves the requirements for branched-chain amino acids primarily by preventing hyperactivity of the GTP-dependent transcriptional regulator CodY, but that GTP levels can also play an important role in regulating transcription of many amino acid biosynthesis genes independently of CodY. Thus, CodY-dependent and independent regulation of transcription by GTP levels plays overlapping yet distinct physiological roles in allowing amino acid prototrophy. Finally, supplementing these required amino acids does not protect against cell death upon nutrient downshift, but allows for sustained growth following this transition. We conclude that regulation of GTP levels by (p)ppGpp allows cells to adapt to conditions of amino acid limitation by first allowing survival during shifting nutrient conditions, and then allowing amino acid prototrophy by transcriptionally regulating amino acid biosynthesis. This strategy may be used to ensure viability during amino acid limitation in evolutionarily divergent bacteria. Twelve-condition experiment: wt, wt+RHX, wt+Guo, (p)ppGpp0, (p)ppGpp0+RHX, (p)ppGpp0+Guo, M-NM-^TcodY (p)ppGpp0, M-NM-^TcodY (p)ppGpp0+RHX, M-NM-^TcodY (p)ppGpp0+Guo, guaB- (p)ppGpp0, guaB- (p)ppGpp0+RHX, guaB- (p)ppGpp0+Guo. Biological replicates: 3 for each sample. Reference: a mixture of wt RNA from different growth phases and wt backgrounds.

Project description:Growth curves and (p)ppGpp accumulation assays showed that RelA inactivation could influence S. suis growth and led to incapacity of (p)ppGpp synthesis during glucose starvation. To identify the roles of RelA/(p)ppGpp in global gene regulation in S. suis, we compared the transcriptional profiles of SC-19 [a (p)ppGpp+ strain] and ΔrelA [a (p)ppGpp0 strain during glucose starvation] in both glucose-abundant and -deficient CDM in exponential phase by microarray analysis. A less stringent cut-off limit, 2-fold change, was used. qRT-PCR validation displayed the same trends observed in the microarrays

Project description:The stringent response is initiated by rapid (p)ppGpp synthesis, which leads to a profound reprogramming of gene expression in most bacteria. The stringent phenotype seems to be species specific and may be mediated by fundamentally different molecular mechanisms. In Staphylococcus aureus, (p)ppGpp synthesis upon amino acid deprivation is achieved through the synthase domain of the bifunctional enzyme RSH (RelA/SpoT homolog). In several firmicutes, a direct link between stringent response and the CodY regulon was proposed. Wild-type strain HG001, rshSyn, codY and rshSyn, codY double mutants were analyzed by transcriptome analysis to delineate different consequences of RSH-dependent (p)ppGpp synthesis after induction of the stringent response by amino-acid deprivation. Under these conditions genes coding for major components of the protein synthesis machinery and nucleotide metabolism were down-regulated only in rsh positive strains. Genes which became activated upon (p)ppGpp induction are mostly regulated indirectly via de-repression of the GTP-responsive repressor CodY. Only seven genes, including those coding for the cytotoxic phenol-soluble modulins (PSMs), were found to be up-regulated via RSH independently of CodY. qtRT-PCR analyses of hallmark genes of the stringent response indicate that an RSH activating stringent condition is induced after uptake of S. aureus in human polymorphonuclear neutrophils (PMNs). The RSH activity in turn is crucial for intracellular expression of psms. Accordingly, rshSyn and rshSyn, codY mutants were less able to survive after phagocytosis similar to psm mutants. Intraphagosomal induction of psma1-4 and/or psmM-CM-^_1,2 could complement the survival of the rshSyn mutant. Thus, an active RSH synthase is required for intracellular psm expression which contributes to survival after phagocytosis. Microarray was used to evaluate alteration in the transcriptome of codY and rsh mutants and compared to the wild type

Project description:The stringent response is initiated by rapid (p)ppGpp synthesis, which leads to a profound reprogramming of gene expression in most bacteria. The stringent phenotype seems to be species specific and may be mediated by fundamentally different molecular mechanisms. In Staphylococcus aureus, (p)ppGpp synthesis upon amino acid deprivation is achieved through the synthase domain of the bifunctional enzyme RSH (RelA/SpoT homolog). In several firmicutes, a direct link between stringent response and the CodY regulon was proposed. Wild-type strain HG001, rshSyn, codY and rshSyn, codY double mutants were analyzed by transcriptome analysis to delineate different consequences of RSH-dependent (p)ppGpp synthesis after induction of the stringent response by amino-acid deprivation. Under these conditions genes coding for major components of the protein synthesis machinery and nucleotide metabolism were down-regulated only in rsh positive strains. Genes which became activated upon (p)ppGpp induction are mostly regulated indirectly via de-repression of the GTP-responsive repressor CodY. Only seven genes, including those coding for the cytotoxic phenol-soluble modulins (PSMs), were found to be up-regulated via RSH independently of CodY. qtRT-PCR analyses of hallmark genes of the stringent response indicate that an RSH activating stringent condition is induced after uptake of S. aureus in human polymorphonuclear neutrophils (PMNs). The RSH activity in turn is crucial for intracellular expression of psms. Accordingly, rshSyn and rshSyn, codY mutants were less able to survive after phagocytosis similar to psm mutants. Intraphagosomal induction of psma1-4 and/or psmß1,2 could complement the survival of the rshSyn mutant. Thus, an active RSH synthase is required for intracellular psm expression which contributes to survival after phagocytosis.

Project description:Transcriptional profiling to define the stringent response regulon and significance of basal (p)ppGpp levels in E. faecalis OG1RF.

Project description:Growth curves and (p)ppGpp accumulation assays showed that RelA inactivation could influence S. suis growth and led to incapacity of (p)ppGpp synthesis during glucose starvation. To identify the roles of RelA/(p)ppGpp in global gene regulation in S. suis, we compared the transcriptional profiles of SC-19 [a (p)ppGpp+ strain] and ΔrelA [a (p)ppGpp0 strain during glucose starvation] in both glucose-abundant and -deficient CDM in exponential phase by microarray analysis. A less stringent cut-off limit, 2-fold change, was used. qRT-PCR validation displayed the same trends observed in the microarrays relA mutant strain and its parents strain SC-19 were cultured in both glucose-abundant CDM (CDM containing 1% glucose) and glucose-deficient CDM (CDM containing 2% glucose) respectively. The bacteriain in exponential phase were collected for microarray analysis. Three independent experiments were performed.

Project description:Transcriptional profiling to define the stringent response regulon and significance of basal (p)ppGpp levels in E. faecalis OG1RF. RNA was extracted from four replicate samples of each strain of interest and labeled with Cy3. For each replicate, labeled RNA was hybridized to slides along with Cy5-labeled reference RNA, extracted from E. faecalis OG1RF cells grown to mid-log.

Project description:Transcriptional profiling of E. faecalis E99 WT and an isogenic ΔperA strain grown in THB + 1% glucose. Pathogenic E. faecalis are enriched for a pathogenicity island (PAI). This 150-kb island harbors a number of well characterized virulence genes plus a number of determinants of unknown function including one encoding a transcriptional regulator, designated PerA. In this work, we show that PerA coordinately regulates both metabolic and virulence genes, and influences the platelet binding ability of E. faecalis. Finally, we show that PerA responds to bicarbonate, an intestinal ion frequently used by pathogens to determine the site of infection. Together, these results indicate that PerA is a global transcriptional regulator that coordinately regulates genes responsible for enterococcal pathogenicity. These findings highlight a novel feature of PAI-mediated virulence regulation, namely the coordinate regulation of metabolic and virulence factors in the core genome by a horizontally acquired PAI-encoded transcriptional regulator. RNA was obtained from E. faecalis E99 ΔperA from mid-log (OD600 0.05), late log (OD600 0.5) and stationary phase (OD600 1.0) and compared to E. faecalis E99 WT RNA extracted from the same growth phases. Cultures were grown in THB + 1% glucose.

Project description:Staphylococcus aureus is a medically important pathogen that exhibit high metabolic versatility allowing it to infect various niches within a host. S. aureus utilizes two major transcriptional regulators, CodY and CcpA, to remodel metabolic and virulence gene expression in response to changing environmental conditions. Previous studies revealed that inactivation of either codY or ccpA has a pronounced impact on different aspects of staphylococcal physiology and pathogenesis. To determine the contribution and interplay of these two regulators in modulating central metabolism, virulence, and biofilm development we constructed and characterized codY ccpA double mutant in S. aureus UAMS-1. In line with previous studies, we found that CcpA and CodY control cellular metabolic status by altering carbon flow through the central and overflow metabolic pathways. Our results demonstrate that ccpA inactivation impairs biofilm formation and decreases incorporation of eDNA into the biofilm matrix while disrupting codY resulted in a robust structured biofilm tethered together with eDNA and PIA. Interestingly, inactivation of both codY and ccpA decreases biofilm biomass and neglects eDNA release in the double mutant. Compared to inactivation of codY, the codY ccpA mutant did not overexpress toxins but maintained overexpression of amino acid metabolism pathways. Furthermore, codY ccpA mutant produced higher amounts of PIA, in contrast to the wild-type strain and ccpA mutant. Overall, results of this study suggest that interplay between CodY and CcpA modulates central metabolism to optimize growth on preferred carbon sources while repressing virulence gene expression until nutrient limitation requires scavenging nutrients from the host.

Project description:Transcriptional profiles of wildtype and mutant strains bt0700 and bt0700 bt3998 (ppGpp0) of human gut commensal B. thetaiotaomicron were collected to investigate the relevance of the stringent response mediated by the alarmone (p)ppGpp for growth and survival in three different conditions. RNAseq samples were taken during growth in glucose minimal medium, after 1h of carbon starvation, and after 6 days of monocolonizing germ-free mice (from cecum material).