Project description:During infections, S. aureus has to cope with the oxidative burst of activated macrophages and neutrophils, including reactive oxygen and nitrogen species (RNS, ROS) and the strong oxidant hypochloric acid. We aimed to understand the global thiol-redox state in the major pathogen S. aureus and discover new NaOCl-sensitive proteins driven by thiol-switches. Thus, we performed a quantitative redox proteomics approach based on OxICAT and analyzed the percentages of thiol-oxidation levels in S.aureus before and after sub-lethal doses of 150 µM NaOCl stress. In parallel, we searched for protein S-bacillithiolation.

Project description:RNAseq of coding RNA in Staphylococcus aureus wildtype and ppGpp0 mutant shows transcription of the Fe-storage ferritin (ftnA) and miniferritin (dps) was elevated in the ppGpp0 mutant, while Fur-regulated iron transporters for uptake of heme or siderophores were repressed, including the isdABCDEFG, sirABC and sstADBCD-operons. Together these results indicate that (p)ppGpp confers tolerance to ROS and antibiotics during the stationary phase by down-regulation of internal iron levels to prevent ROS formation.

Project description:Pathogens that grow during infections must cope with the reactive oxygen species (ROS) released by host immune cells. Among the different strategies to prevent oxidative damage during infections, pathogenic bacteria have evolved mechanisms to reduce respiration and other cellular processes that are particularly sensitive to free radicals, obtaining energy preferentially by undergoing to fermentative metabolism. As fermentation produces fewer ATP per glucose than respiration, bacteria ensure an appropriate supply of energy by increasing the glycolytic flux. The opportunistic human pathogen Staphylococcus aureus is one such microbe but the underlying mechanism that enables S. aureus to induce fermentation during infections is still unclear. Here we show that the ComK-like regulator of natural competence that is present in many gram-positive bacteria is crucial to redirect S. aureus metabolism to fermentation during infection. ComK is cryptic in laboratory conditions but highly induced during infections or in response to infection-related cues, such as ROS. ComK induces the glycolytic flux and glucose consumption rate, a key step to redirect ATP production to fermentation. This licenses fermenting S. aureus to reduce oxidative damage while increasing DNA uptake by natural transformation. As a consequence, a comK-defective mutant shows an accumulation of ROS as well as DNA mutations that lower bacterial survival. This mutant shows no distinctive phenotype in laboratory conditions but is unable to cause infection in vertebrates or invertebrate infection models. ComK-mediated synchronization of natural transformation to fermentative metabolism may allow S. aureus, and probably other gram-positive bacteria, to use the fermentation acid end products to eliminate bacterial competitors while assimilating their DNA. Assimilated DNA may serve as a source of nucleotides for DNA repair or to promote genetic variability, thereby enabling a successful host colonization of this bacterium.

Project description:Staphylococcus aureus and Pseudomonas aeruginosa are the most prevalent pathogens that colonize structurally abnormal airways such as those in Cystic Fibrosis (CF) and other chronic obstructive lung diseases. Although these bacteria seem to succeed one another, CF patients acquire coinciding P. aeruginosa and S. aureus pulmonary infections, being co-infection usually associated with decreased lung function and increased frequency of pulmonary exacerbations. In addition, P. aeruginosa and S. aureus pathogens adopt a biofilm mode of growth, which contributes to high tolerance to antibiotic treatment and the recalcitrant nature of these chronic coinfections, leading to significant patient morbidity and mortality. Interactions between P. aeruginosa and S. aureus have been widely studied and it is commonly admitted that P. aeruginosa outcompetes S. aureus, perhaps outcompeting S. aureus for limited nutrients or producing anti-staphylococcal compounds, having S. aureus a minimal contribution to the overall course of the infection. However, the molecular mechanisms behind these interactions are largely unknown. Herein, we decided to characterize the full transcriptome of these dual-species biofilms, to unveil important molecular interactions that can occur between these two bacterial species that are relevant for the pathogenesis of the entire consortia. Our data provide novel insights into the role of interspecies interactions in the pathogenesis of P. aeruginosa and S. aureus co-infections and will contribute to future studies by the research community.

Project description:Staphylococcus aureus is a high-priority pathogen causing severe infections with high morbidity and mortality worldwide. Many S. aureus strains are methicillin-resistant (MRSA) or even multi-drug resistant. It is one of the most successful and prominent modern pathogens. An effective fight against S. aureus infections requires novel targets for antimicrobial and antistaphylococcal therapies. Recent advances in whole-genome sequencing and high-throughput techniques facilitate the generation of genome-scale metabolic models (GEMs). Among the multiple applications of GEMs is drug-targeting in pathogens. Hence, comprehensive and predictive metabolic reconstructions of S. aureus could facilitate the identification of novel targets for antimicrobial therapies. This review aims at giving an overview of all available GEMs of multiple S. aureus strains. We downloaded all 114 available GEMs of S. aureus for further analysis. The scope of each model was evaluated, including the number of reactions, metabolites, and genes. Furthermore, all models were quality-controlled using Mᴇᴍᴏᴛᴇ, an open-source application with standardized metabolic tests. Growth capabilities and model similarities were examined. This review should lead as a guide for choosing the appropriate GEM for a given research question. With the information about the availability, the format, and the strengths and potentials of each model, one can either choose an existing model or combine several models to create models with even higher predictive values. This facilitates model-driven discoveries of novel antimicrobial targets to fight multi-drug resistant S. aureus strains.

Project description:Staphylococcus aureus is a high-priority pathogen causing severe infections with high morbidity and mortality worldwide. Many S. aureus strains are methicillin-resistant (MRSA) or even multi-drug resistant. It is one of the most successful and prominent modern pathogens. An effective fight against S. aureus infections requires novel targets for antimicrobial and antistaphylococcal therapies. Recent advances in whole-genome sequencing and high-throughput techniques facilitate the generation of genome-scale metabolic models (GEMs). Among the multiple applications of GEMs is drug-targeting in pathogens. Hence, comprehensive and predictive metabolic reconstructions of S. aureus could facilitate the identification of novel targets for antimicrobial therapies. This review aims at giving an overview of all available GEMs of multiple S. aureus strains. We downloaded all 114 available GEMs of S. aureus for further analysis. The scope of each model was evaluated, including the number of reactions, metabolites, and genes.Furthermore, all models were quality-controlled using Mᴇᴍᴏᴛᴇ, an open-source application with standardized metabolic tests. Growth capabilities and model similarities were examined. This review should lead as a guide for choosing the appropriate GEM for a given research question. With the information about the availability, the format, and the strengths and potentials of each model, one can either choose an existing model or combine several models to create models with even higher predictive values. This facilitates model-driven discoveries of novel antimicrobial targets to fight multi-drug resistant S. aureus strains.

Project description:Staphylococcus aureus is a high-priority pathogen causing severe infections with high morbidity and mortality worldwide. Many S. aureus strains are methicillin-resistant (MRSA) or even multi-drug resistant. It is one of the most successful and prominent modern pathogens. An effective fight against S. aureus infections requires novel targets for antimicrobial and antistaphylococcal therapies. Recent advances in whole-genome sequencing and high-throughput techniques facilitate the generation of genome-scale metabolic models (GEMs). Among the multiple applications of GEMs is drug-targeting in pathogens. Hence, comprehensive and predictive metabolic reconstructions of S. aureus could facilitate the identification of novel targets for antimicrobial therapies. This review aims at giving an overview of all available GEMs of multiple S. aureus strains. We downloaded all 114 available GEMs of S. aureus for further analysis. The scope of each model was evaluated, including the number of reactions, metabolites, and genes.Furthermore, all models were quality-controlled using Mᴇᴍᴏᴛᴇ, an open-source application with standardized metabolic tests. Growth capabilities and model similarities were examined. This review should lead as a guide for choosing the appropriate GEM for a given research question. With the information about the availability, the format, and the strengths and potentials of each model, one can either choose an existing model or combine several models to create models with even higher predictive values. This facilitates model-driven discoveries of novel antimicrobial targets to fight multi-drug resistant S. aureus strains.

Project description:Candida albicansis a commensal yeast that has important impacts on host metabolism and immune function, and can establish life-threatening infections in immunocompromised individuals. Previously,C. albicanscolonization has been shown to contribute to the progression and severity of alcoholic liver disease. However, relatively little is known about howC. albicansresponds to changing environmental conditions in the GI tract of individuals with alcohol use disorder, namely repeated exposure to ethanol. In this study, we repeatedly exposedC. albicansto high concentrations (10% vol/vol) of ethanol—a concentration that can be observed in the upper GI tract of humans following consumption of alcohol. Following this repeated exposure protocol, ethanol small colony (Esc) variants ofC. albicansisolated from these populations exhibited increased ethanol tolerance, altered transcriptional responses to ethanol, and cross-resistance/tolerance to the frontline antifungal fluconazole. These Esc strains exhibited chromosomal copy number variations and carried polymorphisms in genes previously associated with the acquisition of fluconazole resistance during human infection. This study identifies a selective pressure that can result in evolution of fluconazole tolerance and resistance without previous exposure to the drug.

Project description:Multi-drug resistant Staphylococcus aureus (S. aureus) infections continously threaten public health. The rapid escalation in morbidity and mortality rates associated with methicillin-resistant S. aureus (MRSA) infections necessitates the urgent development of novel antimicrobial agents. Our study reveals that the FDA-approved drug cinacalcet (CNA) effectively functions as an antibacterial and anti-biofilm agent against S. aureus without detectable resistance. It evidently improved survival rate of mice infected with clinical multi-resistant S. aureus in a pneumonia model. Subsequent proteomic and biochemical experiments suggest that the primary antibacterial mechanism involves membrane structure disruption, ATP content reduction, and reactive oxygen species (ROS) production. Concurrently, LiP-SMap combined with biochemical validation indicates that CNA inhibits biofilm formation by targeting IcaR, a negative regulator of icaADBC, thereby enhancing its binding capacity to the ica operator DNA and subsequently suppressing extracellular polysaccharide formation. Importantly, compared to vancomycin, CNA demonstrates stronger biofilm bacterial clearance in a mouse thigh infection model. Collectively, our findings propose that CNA can be repurposed as a potential therapeutic agent for treating multidrug-resistant S. aureus infections and their associated biofilms.

Project description:Interactions between Macrophages and T-lymphocytes: Tumor Sneaking Through Intrinsic to Helper T cell Dynamics ROB J. DE BOER AND PAULINE HOGEWEG Bioinformatics Group, University of Utrecht, Padualaan 8, 3584 CH Utrecht, The Netherlands Abstract In a mathematical model of the cellular immune response we investigate immune reactions to tumors that are introduced in various doses. The model represents macrophage T-lymphocyte interactions that generate cytotoxic macrophages and cytotoxic T-lymphocytes. In this model antigens (tumors) can induce infinitely large T-lymphocyte effector populations because (a) effector T-lymphocytes are capable of repeated proliferation and (b) we have omitted immunosuppression. In this (proliferative) model small doses of weakly antigenic tumors grow infinitely large (i.e. sneak through) eliciting an immune response of limited magnitude. Intermediate doses of the same tumor induce larger immune responses and are hence rejected. Large doses of the tumor break through, but their progressive growth is accompanied by a strong immune response involving extensive lymphocyte proliferation. Similarly a more antigenic tumor is rejected in intermediate doses and breaks through in large doses. Initially small doses however lead to tumor dormancy. Thus although the model is devoid of explicit regulatory mechanisms that limit the magnitude of its response (immunosuppression is such a mechanism), the immune response to large increasing tumors may either be (a) a stable reaction of limited magnitude (experimentally known as tolerance or unresponsiveness) or (b) a strong and ever increasing reaction. Unresponsiveness can evolve because in this model net T-lymphocyte proliferation requires the presence of a minimum number of helper T cells (i.e. a proliferation threshold). Unresponsiveness is caused by depletion of helper T cell precursors.