Project description:WalKR is an essential two component regulatory system in S. aureus, thought to control cell wall metabolism. Using genome sequencing of 5 paired clinical isolates of vancomycin-susceptible and vancomycin-intermediate S. aureus we found frequent, but unique, mutations in this locus. To investigate the contribution of these mutations to vancomycin resistance allelic replacement WalK (G223D) and WalR (K208R) mutants were generated and compared to the parent strains. Mutations in walk and walR led to increased vancomycin resistance, reduced biofilms formation and attenuation of virulence, demonstrating that minor genetic changes in this locus can lead to significant changes in bacterial resistance and virulence. Microarray transcriptional comparisons were performed to investigate the regulatory effects of the WalK (G223D) and WalR (K208R) mutations, and demonstrated that while changes in genes affecting cell wall metabolism were detected, more dramatic changes were found in regulation of cellular metabolism. Transcriptional profiling of laboratory derived S. aureus walKR mutants compared to the parent isolates. TPS3130 has a single point mutation in walK, and TPS3190 has a single point mutation in walR. Two condition experiment TPS3130 vs JKD6009 and TPS3190 vs JKD6004. 3 biological replicates per isolate pair, one replicate per slide.

Project description:WalKR is an essential two component regulatory system in S. aureus, thought to control cell wall metabolism. Using genome sequencing of 5 paired clinical isolates of vancomycin-susceptible and vancomycin-intermediate S. aureus we found frequent, but unique, mutations in this locus. To investigate the contribution of these mutations to vancomycin resistance allelic replacement WalK (G223D) and WalR (K208R) mutants were generated and compared to the parent strains. Mutations in walk and walR led to increased vancomycin resistance, reduced biofilms formation and attenuation of virulence, demonstrating that minor genetic changes in this locus can lead to significant changes in bacterial resistance and virulence. Microarray transcriptional comparisons were performed to investigate the regulatory effects of the WalK (G223D) and WalR (K208R) mutations, and demonstrated that while changes in genes affecting cell wall metabolism were detected, more dramatic changes were found in regulation of cellular metabolism.

Project description:Here, we use a panel of defined walKR mutants and functional genomics including ChIP-seq to confirm a high-resolution consensus WalR DNA-binding motif and characterise a 61-gene direct regulon

Project description:Here, we use a panel of defined walKR mutants and functional genomics including ChIP-seq to confirm a high-resolution consensus WalR DNA-binding motif and characterise a 61-gene direct regulon

Project description:The WalKR regulon was studied by comparing genes expression in a strain producing a constitutively active WalR regulator (WalRc) versus the wild type strain carrying the empty expression vector. Hybridizations were performed with three independent biological replicates. Our data allowed to identify 165 genes differentially expressed in the walRc expressing strain with a P-value ≤ 0.05 using Z-test and a threshold value of two-fold change in transcriptional levels. Among them, 108 genes are activated, and 57 genes are repressed. About 10% of these results were confirmed by quantitative real time PCR, revealing the high reliability of this overall study. Beyond the major effect of the WalKR system on genes expressing cell wall hydrolases, we have shown that it activates a large number of genes involved in virulence, and probably through its positive impact on the SaeRS two-component system, is a major activator of S. aureus virulence.

Project description:The WalKR regulon was studied by comparing genes expression in a strain producing a constitutively active WalR regulator (WalRc) versus the wild type strain carrying the empty expression vector. Hybridizations were performed with three independent biological replicates. Our data allowed to identify 165 genes differentially expressed in the walRc expressing strain with a P-value M-bM-^IM-$ 0.05 using Z-test and a threshold value of two-fold change in transcriptional levels. Among them, 108 genes are activated, and 57 genes are repressed. About 10% of these results were confirmed by quantitative real time PCR, revealing the high reliability of this overall study. Beyond the major effect of the WalKR system on genes expressing cell wall hydrolases, we have shown that it activates a large number of genes involved in virulence, and probably through its positive impact on the SaeRS two-component system, is a major activator of S. aureus virulence. Cells were grown in TSB rich medium added with 0.25 M-BM-5M CdCl2 to allow walRc expression until OD600nm of 1. Gene expression was compared between the HG001 wild type reference strain carrying the pCN51 empty vector (HG001/pCN51) and the HG001 strain carrying a pCN51 derivative with the walRc allele under the control of the Pcad inducible promoter (HG001/pSD3-12). Each condition was done in triplicate and the data were analyzed using the Arraystat software. Genes were considered as differentially expressed if their transcriptional level differed by at least two-fold with a Z-test P-value M-bM-^IM-$ 0.05 in at least two of the replicates.

Project description:Tunicamycin sensitivity sequencing

Project description:Methicillin resistance in Staphylococcus aureus depends on the production of mecA, which encodes penicillin-binding protein 2A (PBP2A), an acquired peptidoglycan transpeptidase with reduced susceptibility to beta-lactam antibiotics. Here, we show that preventing the expression of wall teichoic acids (WTAs) genetically or with a TarO inhibitor sensitizes MRSA strains to beta-lactams although PBP2A is still expressed. Using S. aureus microarrays and array data analysis protocols (NIAID's Pathogen Functional Genomics Resource Center) we have characterized the transcriptomes of S. aureus COL. in order to further understand the sensitization of strain COL to methicillin by tunicamycin we determined the tunicamycin and methicillin transcriptomes alone and in combination. Methicillin treatment of COL at 500 µg/mL had almost no effect on cell growth rate and, remarkably, the only gene in the transcriptome that showed a more than two-fold change in expression was lytM, which was downregulated. The tunicamycin transcriptome of COL, acquired at 0.4 µg/mL, shows modest changes compared to the untreated control both in terms of the total numbers of affected genes and in the degree of up- or downregulation. Several of the genes upregulated upon tunicamycin treatment are part of the cell wall stress stimulon.COL was grown with methicillin to an OD600 ~0.4, and challenged with tunicamycin for 2 hrs whereas the control culture contained methicillin alone. transcriptome for COL growing in the presence of both agents showed extensive changes in gene expression. , the cell wall stress stimulon, which was not induced by methicillin when tunicamycin was absent, was clearly induced in its presence and the changes were far more dramatic than observed with tunicamycin alone. ). vraS and vraR, which encode a two component signaling system dedicated to the cell wall regulon, were upregulated 3.8 and 3.7 fold, respectively. Other upregulated cell wall stress stimulon genes include pbp2, fmtA, mvaD (mevalonate diphosphate decarboxylase), crtN (dehydrosqualene desaturase) mvak1 (mevalonate kinase), recU, SAV1424 (methionine sulfoxide reductase A), prsA (peptidyl-prolyl cis/trans isomerase), tcaA (Tca protein) and cwrA. A considerable number of genes were also downregulated upon challenge of COL with the combination of tunicamycin and methicillin. These included sspB, lrgA, dltA, capL, SAS0988, sspA, pflB, and spa. Several of these genes have been found to be downregulated in previous studies of cell wall-active antibiotic challenge of S. aureus.

Project description:Neutrophils have an important role in rapid antimicrobial defenses against and resolution of urinary tract infections (UTIs). We show that a mechanism known as neutrophil extracellular trap (NET) formation is a strategy to combat pathogens in the urinary tract. Viscous aggregates that were present in human urine sediments revealed high extracellular DNA content. The DNA formed a scaffold to which antimicrobial effector proteins derived from different neutrophil subcellular compartments bound. Treatment with deoxyribonuclease I solubilized these structures. We observed massive proteolytic degradation in the NETs with apparently dominant roles for the neutrophil granule proteases elastase, proteinase 3, and cathepsin G. In a UTI case with Staphylococcus aureus as the infectious agent, high abundance of autolysins and immune evasion factors in a cell-free NET extract suggested that controlled cell wall autolysis plays a role in derailing the host immune response and allows some bacterial cells to survive following entrapment in NETs.

Project description:We reported the RNA-Seq results of Staphylococcus aureus Newman wild-type, walKD119A, walKV149A and DHBP-treated wild-type strains. We found that mutations of the potential signal transduction residues of WalK attenuate the activity of walKR two-component system, whereas DHBP supplementation activates this two-component system.