Project description:Various mutations in the rpoB gene, which encodes the RNA polymerase beta subunit, are associated with increased vancomycin (VAN) resistance in vancomycin-intermediate S. aureus (VISA) and hetero-VISA (hVISA) strains. We reported that rpoB mutations are also linked to the expression of the recently found slow VISA (sVISA) phenotype (Saito et al 2014 AAC). Because RpoC and RpoB are components of RNA polymerase, we examined the effect of rpoC(P440L) mutation on the expression of the sVISA phenotype in the Mu3fdh2*V6-5 strain (V6-5), which was derived from a previously reported hVISA strain with the VISA phenotype. V6-5 had an extremely prolonged doubling time (72.2 min) and high vncomycin MIC (16 mg/L). However, the phenotype of V6-5 was unstable, and the strain frequently reverted to hVISA with concomitant loss of slow growth rate, cell wall thickness, and reduced autolysis. Whole genome sequencing of phenotypic revertant strain V6-5-L1 and comparison with V6-5 revealed a second mutation F562L in rpoC. Introduction of the wild-type rpoC gene using multi-copy plasmid resolved the sVISA phenotype of V6-5, indicating that rpoC(P440L) mutation expressed the sVISA phenotype in hVISA. To investigate the mechanisms of resistance in the sVISA strain, we independently isolated additional 10 revertants to hVISA and VISA. In subsequent whole genome analysis, we identified compensatory mutations in the genes of three distinct functional categories; rpoC gene itself as regulatory mutations, peptidoglycan biosynthesis genes, and relQ which is involved in stringent response. It appears that rpoC(P440L) mutation causes sVISA phenotype by augmenting cell-wall peptidoglycan synthesis, and through the control of stringent response. 9 analysis using 60 mer-oligo microarray, 4 rpoC mutant, 2 relQ mutant, 2 mutations associated with the peptidoglycan, 1 wild-type strain

Project description:Various mutations in the rpoB gene, which encodes the RNA polymerase beta subunit, are associated with increased vancomycin (VAN) resistance in vancomycin-intermediate S. aureus (VISA) and hetero-VISA (hVISA) strains. We reported that rpoB mutations are also linked to the expression of the recently found slow VISA (sVISA) phenotype (Saito et al 2014 AAC). Because RpoC and RpoB are components of RNA polymerase, we examined the effect of rpoC(P440L) mutation on the expression of the sVISA phenotype in the Mu3fdh2*V6-5 strain (V6-5), which was derived from a previously reported hVISA strain with the VISA phenotype. V6-5 had an extremely prolonged doubling time (72.2 min) and high vncomycin MIC (16 mg/L). However, the phenotype of V6-5 was unstable, and the strain frequently reverted to hVISA with concomitant loss of slow growth rate, cell wall thickness, and reduced autolysis. Whole genome sequencing of phenotypic revertant strain V6-5-L1 and comparison with V6-5 revealed a second mutation F562L in rpoC. Introduction of the wild-type rpoC gene using multi-copy plasmid resolved the sVISA phenotype of V6-5, indicating that rpoC(P440L) mutation expressed the sVISA phenotype in hVISA. To investigate the mechanisms of resistance in the sVISA strain, we independently isolated additional 10 revertants to hVISA and VISA. In subsequent whole genome analysis, we identified compensatory mutations in the genes of three distinct functional categories; rpoC gene itself as regulatory mutations, peptidoglycan biosynthesis genes, and relQ which is involved in stringent response. It appears that rpoC(P440L) mutation causes sVISA phenotype by augmenting cell-wall peptidoglycan synthesis, and through the control of stringent response.

Project description:hVISA clinical strain Mu3 spontaneously generates VISA at an extremely high frequency (1x10-6 or greater) within its cell population. The VISA-converted mutant strains generally grow slower than their parent hVISA strain, but they usually form colonies on vancomycin-containing agar plates after 48 hours of incubation on population analysis. However, we noticed a curious group of VISA mutants whose colony formation is much more delayed and observed as discrete colonies only after 96 hours incubation. They have extremely prolonged lag-phase and doubling-times, but recorded vancomycin MICs of 8 to 24 mg/L when determined after 48 to 96 hours of incubation. We established strain Mu3-6RS having vancomycin MIC of 12 mg/L (at 72h) as a representative of the ‘slow VISA’ (sVISA) strains. Its cell wall was thickened, and autolytic activity was decreased as compared with those of the parent strain Mu3. Whole genome sequencing of Mu3-6RS revealed only one mutation, which substituted the 512th amino-acid sequence of RNA polymerase ß-subunit from Arg of Mu3 to Proline. Its VISA phenotype was unstable, and the strain frequently reverted to hVISA with concomitant loss of small colony morphology, cell-wall thickness and reduced autolytic activity. Sequencing of rpoB genes of the reverted strains revealed mutations affecting the 512th codon replacing the Proline of Mu3-6RS to Leucine, Serine, or Histidine. This study proposes sVISA as a discrete class of VISA phenotype, which can serve as a temporary shelter for S. aureus to survive relatively high concentrations of vancomycin. The sVISA spontaneously returns to hVISA when the threat of vancomycin passes by. The rpoB(R512P) mutation may be regarded as a ‘regulatory mutation’ switching on and off the reversible sVISA phenotype.

Project description:hVISA clinical strain Mu3 spontaneously generates VISA at an extremely high frequency (1x10-6 or greater) within its cell population. The VISA-converted mutant strains generally grow slower than their parent hVISA strain, but they usually form colonies on vancomycin-containing agar plates after 48 hours of incubation on population analysis. However, we noticed a curious group of VISA mutants whose colony formation is much more delayed and observed as discrete colonies only after 96 hours incubation. They have extremely prolonged lag-phase and doubling-times, but recorded vancomycin MICs of 8 to 24 mg/L when determined after 48 to 96 hours of incubation. We established strain Mu3-6RS having vancomycin MIC of 12 mg/L (at 72h) as a representative of the M-bM-^@M-^Xslow VISAM-bM-^@M-^Y (sVISA) strains. Its cell wall was thickened, and autolytic activity was decreased as compared with those of the parent strain Mu3. Whole genome sequencing of Mu3-6RS revealed only one mutation, which substituted the 512th amino-acid sequence of RNA polymerase M-CM-^_-subunit from Arg of Mu3 to Proline. Its VISA phenotype was unstable, and the strain frequently reverted to hVISA with concomitant loss of small colony morphology, cell-wall thickness and reduced autolytic activity. Sequencing of rpoB genes of the reverted strains revealed mutations affecting the 512th codon replacing the Proline of Mu3-6RS to Leucine, Serine, or Histidine. This study proposes sVISA as a discrete class of VISA phenotype, which can serve as a temporary shelter for S. aureus to survive relatively high concentrations of vancomycin. The sVISA spontaneously returns to hVISA when the threat of vancomycin passes by. The rpoB(R512P) mutation may be regarded as a M-bM-^@M-^Xregulatory mutationM-bM-^@M-^Y switching on and off the reversible sVISA phenotype. 5 sample analysis using 60mer-oligo microarray, 3 rpoB mutant(R512P,R512L,R512S), 2 wild-type strain(Mu3, M-NM-^TIP)

Project description:Vancomycin-intermediate Staphylococcus aureus (VISA) evolve in a strain-specific manner and acquire mutations that lead to alterations in cell wall metabolism that reduce susceptibility to vancomycin. We had earlier isolated several VISA mutant strains of the clinical hVISA strain MM66. This study is aimed at analyzing the metabolome of these mutants in comparison to the parent strain.

Project description:The phenotype “intermediate vancomycin resistance” in Staphylococcus aureus (CLSI: MIC = 4-8 mg/L) has been assigned to changes that lead to alterations in cell wall synthesis and morphology. Most vancomycin intermediately resistant S. aureus (VISA) strains are characterised by an increased cell wall thickness as a consequence of an activated cell wall biosynthesis and decreased autolysis. The purpose of this study was to analyse the genetic basis of the vancomycin resistance mechanism of the clinical VISA isolate SA137/93A and its spontaneous mutant strain SA137/93G. The methicillin-resistant S. aureus (MRSA) SA137/93A was isolated from a tracheal secretion and displays heterogeneous intermediate vancomycin resistance (hVISA strain, MIC: 8 mg/L in BHI). Subculturing in presence of 6 mg/L vancomycin generated a mutant with homogeneous intermediate vancomycin resistance, that showed an MIC value of 16 mg/L in BHI and was designated SA137/93G. PFGE profiles and phage typing of the strains showed that they were members of the Iberian clone (ST247), which was prevalent in Germany in the early nineties under the designation “Northern German epidemic strain”. Both strains possess a thickened cell wall. However, the vancomycin resistance of strain SA137/93A is most probably enhanced by an increased amount of free D-Ala-D-Ala termini in the cell wall, which is due to decreased crosslinking, whereas the mutant strain SA137/93G shows normal crosslinking. Moreover, strain SA137/93A displays an increased expression of the essential two-component system yycFGHI as a consequence of an IS256 insertion in the promoter region, while strain SA137/93G is characterised by an insertion of IS256 into the gene tcaA. Although both insertions were shown to correlate with a decrease in susceptibility to vancomycin, the difference in the vancomycin resistance level of the strain pair could be mainly attributed to the disruption of tcaA in the mutant.This study was conducted to identify resistance mechanisms that both strains might have in common. To this end we compared the transcriptomes of both strains with that of the closely related vancomycin susceptible MRSA/VSSA strain SA1450/94 (MIC: 2 mg/L). We found that the genes of the capsule biosynthesis were the only genes with higher expression in both VISA strains. Keywords: strain comparison

Project description:The mechanisms leading to the vancomycin-intermediate Staphylococcus aureus (VISA) phenotype are incompletely understood. In an effort to identify VISA determinants, clinical hVISA strain MM66 and its 1st-step VISA mutants were compared. S. aureus microarrays, array data analysis protocols (NIAID's Pathogen Functional Genomics Resource Center), as well as comparative genomic sequencing (CGS) were utilized to determine VISA transcriptome alterations and mutations that define the MM66 VISA mechanism. In addition, whole cell autolysis, antimicrobial susceptibility tests, growth in the presence of salt, coagulase and hemolysis assays were performed to confirm VISA transcriptional alterations. Overall, 2 MM66 VISA demonstrated 85 up-regulated and 8 down-regulated genes in common. SAMMD (Staphylococcus aureus Microarray Metadatabase) analysis identified a significant differential gene expression overlap between the global stress response regulator sigB-controlled genes in MM66-3 and MM66-4. CGS analysis on a MM66 VISA revealed two mutations in: a sensory box histidine kinase (yycG) and a putative adenine phosphoribosyltransferase (apt). The yycFG two-component system has been reported to regulate whole cell autolysis and MM66 VISA demonstrated reduced whole cell autolysis. Five ssaA homologues (putative amidases) and a gene that expresses a bifunctional autolysin (atlA) controlled by YycFG were downregulated in MM66 VISA. One MM66 VISA mutant demonstrated drastic downregulation of a gene cluster (betA, gbsA, betB, and cudT) required for the osmoprotective response of S. aureus and MM66 VISA mutants demonstrated reduced growth in high salt media compared to MM66. Virulence genes were also downregulated (coa, hla, hlb, hlgA, hlgB, and hlgC) in 2 MM66 VISA mutants which also demonstrated reduced coagulase and hemolytic activities compared to MM66. pur operon genes were also upregulated in MM66 VISA and it is interesting that we have also found an apt mutation, since Apt activity can be inhibited by high AMP levels and reduces the conversion of AMP into adenine. Conclusion: Mutations in yycG and apt allow hVISA to acquire the VISA phenotype and yycFG is involved with altered autolytic activity in MM66 VISA.

Project description:Treatment of methicillin-resistant Staphylococcus aureus (MRSA) infections is dependant on the efficacy of last-line antibiotics like vancomycin. Vancomycin treatment failure is most commonly linked to the emergence of vancomycin-intermediate resistance in clincal isolates (termed VISA). These isolates have not acquired resistance genes but appear to accumulate a heterogenous collection of single nucleotide polymerisms that collectively alter the physiology of the cell to increase vancomycin tolerance. Cell wall thickening is common among VISA isolates and is thought to decrease vancomycin permeability. Changes in regulatory sRNA expression have been correlated with antibiotic stress responses in VISA isolates however the functions of the vast majority of these RNA regulators is unknown. Here we have used the endoribonuclease RNase III to capture RNA-RNA interactions using an RNA proximity-dependant ligation technique termed CLASH. RNase III-CLASH uncovered hundreds of sRNA-mRNA interactions in vivo allowing functional characterisation of many sRNAs for the first time. Surprisingly, we find that an mRNA encoding an unusually long 3’UTR (here termed vigR) functions as a regulatory ‘hub’ within our RNA-RNA interaction network. We demonstrate vigR promotes expression of the cell wall lytic transglycosylase encoded by isaA through a direct mRNA-mRNA interaction. Further, we find that the vigR mRNA 3’UTR is required for cell wall thickening and that deletion of the vigR 3’UTR re-sensitises VISA to vancomycin. Our results demonstrate the utility of RNase III-CLASH for identifying new regulatory RNA functions and indicate that S. aureus may use mRNA-mRNA interactions to co-ordinate gene expression much more widely than previously appreciated.

Project description:90 S. aureus isolates were analyzed for protein biomarker discovery, including MSSA, vancomycin-susceptible S. aureus (VSSA), hVISA, and VISA strains. Label-free data-independent acquisition proteomics was used to identify protein biomarkers that allow for discrimination among MSSA, hVISA, and VISA strains.

Project description:Staphylococcus aureus is a notorious bacterial pathogen that causes a broad range of human diseases, and isolates that are resistant to several antibiotic classes including last resort antibiotics like vancomycin and daptomycin complicate the situation. We characterized S. aureus VC40, a strain that shows full resistance to vancomycin (MIC of 64 M-BM-5g/ml) and daptomycin (MIC of 4 M-BM-5g/ml) as well as a decreased susceptibility to further cell wall active agents. Genome sequencing revealed mutations in genes encoding the histidine kinases WalK and VraS that control cell envelope related processes and gene expression profiling indicated the induction of the respective regulons in strain VC40. Reconstitution of the mutations in walK or vraS into the susceptible S. aureus NCTC 8325 background resulted in a considerably increased resistance to vancomycin and daptomycin with MICs surpassing the clinical breakpoints for these antibiotics, thereby generating vancomycin-intermediate S. aureus (VISA) strains. As observed for S. aureus VC40, the walKwalk and vraS mutations also led to an increased expression of the respective regulons in the NCTC 8325 background. Phenotypic studies showed that S. aureus VC40 as well as the walKwalk and vraS mutants of strain NCTC 8325 were characterized by a significantly thickened cell wall, a decreased growth rate, a reduced autolytic activity and an increased resistance to lysostaphin-induced lysis. These results demonstrate that the WalK and VraS histidine kinases act as major switches which allow S. aureus to rapidly develop vancomycin resistance up to the VISA level via mutation of one single gene locus and concomitantly contribute to cross-resistance to other antibiotics including the last resort antibiotic daptomycin. Microarray was used to evaluate alteration in the transcriptome of mutS mutant and compared to the parental strain VC40