Project description:Previously, we have shown that in Entamoeba histolytica, methionine γ-lyase (EhMGL) downregulation results in trifluoromethionine resistance. The transcriptional response, however, of this parasite to the drug is not known. In this study, we used microarray analysis to determine if additional genes are involved. The expression profile of 9,230 genes in wild type and trifluoromethionine resistant strains was compared. Episomal overexpression of EhBspA1 was performed to verify its role in trifluoromethionine resistance. The transcriptomes of trifluoromethionine resistant strain cultured with or without trifluoromethionine, EhMGL-gene silenced strain, metronidazole resistant strain, and wild type strain under cysteine-deprived conditions were compared to determine the specificity of the changes observed in trifluoromethionine resistant strain.

Project description:In vitro studies have described metronidazole (MTZ) resistance and the potential mechanisms involved. Costs to fitness and adaptive responses associated with resistance, however, have not been investigated. In this study we generated an HM-1-derived strain resistant to 12 µM MTZ (MTZR). We examined its phenotypic and transcriptional profile to determine the consequences and mRNA level changes associated with MTZ resistance. The expression profile of 9,230 genes in wild-type and metronidazole-resistant strains was compared. Transcriptome analysis revealed 142 differentially expressed genes in MTZR. In contrast to other MTZ-resistant parasites, MTZR did not down-regulate pyruvate:ferredoxin oxidoreductase, but showed increased expression of genes for a hypothetical protein (HP1) and several iron-sulfur flavoproteins, and the downregulation of genes for leucin-rich proteins. Overexpression of HP1-HA did not confer MTZR level of resistance, but provided a slight advantage in cell survival. Fisher's exact test showed 24 significantly enriched GO terms in MTZR, and a 3-way comparison of modulated genes with MTZR cultured without MTZ and HM-1 cultured with MTZ showed that 88 genes were specific to MTZR.

Project description:I this study we analyzed three lines, two of which were created by UV- directed mutagenesis and showed increased levels of metronidazole tolerance (M1 and M2) and the third being a line that reverted spontanously to sensitive after several passages (M1NR) of M1 without metronidazole in the media. On the physiological side we analyzed the ability of these lines to reists metronidazole exposure and to encyst as well as their respective doublings times. At the same time we conducted a trasncriptomics and proteomics analysis to understand which exact changes lead to M1 and M2 being resistant while M1NR shows wildtype levels of metrondiazole sensitivty. We than compared these datasets to already existing datasets of other metrondiazole resistant lines and managed to identify a few core changes which are shared between all lines. In all lines proteins that are activating the drug are downregulated while proteins that are part of the oxidative stress response are found in higher abundance. On the other side these core changes are accompanied by a line specific set of changes, showing that there is more than one way for Giardia intestinalis to become resistant to metronidazole.

Project description:Instability in the composition of gut bacterial communities, referred as dysbiosis, has been associated with important human intestinal disorders such as CrohnM-bM-^@M-^Ys disease and colorectal cancer. Here, we show that dysbiosis coupled to Nod2 or Rip2 deficiency suffices to cause an increased risk for intestinal inflammation and colitis-associated carcinogenesis in mice. Aggravated epithelial lesions and dysplasia upon chemical-induced injury associated with loss of Nod2 or Rip2 can be prevented by antibiotics or anti-IL6R treatment. Nod2-mediated risk for intestinal inflammation and colitis-associated tumorigenesis is communicable through maternally-transmitted microbiota even to wild-type hosts. Disease progression was identified to drive complex NOD2-dependent changes of the colonic-associated microbiota. Reciprocal microbiota transplantation rescues the vulnerability of Nod2-deficient mice to colonic injury. Altogether, our results unveil an unexpected function for NOD2 in shaping a protective assembly of gut microbial communities, providing a rationale for intentional manipulation of genotype-dependent dysbiosis as a causative therapeutic principle in chronic intestinal inflammation. Analysis used RNA extracted from colonic mucosa of untreated, antibiotics-treated or metronidazole-treated C57Bl/6J and Nod2-deficient mice in CAC model. Direct comparisons were performed as follow: C57Bl/6J untreated mice vs Nod2-deficient untreated mice, C57Bl/6J antibiotics-treated mice vs Nod2-deficient antibiotics-treated mice, C57Bl/6J metronidazole-treated mice vs Nod2-deficient metronidazole-treated mice, C57Bl/6J untreated mice vs C57Bl/6J antibiotics-treated mice, C57Bl/6J untreated mice vs C57Bl/6J metronidazole-treated mice, Nod2-deficient untreated mice vs Nod2-deficient antibiotics-treated mice, Nod2-deficient untreated mice vs Nod2-deficient metronidazole-treated mice. Indirect comparisons with control data were made across multiple arrays with raw data pulled from different channels for data analysis.

Project description:We aimed to delineate mechanisms of T. vaginalis resistance using transcriptome profiling of metronidazole (MTZ)-resistant and sensitive T. vaginalis clinical isolates.

Project description:This study aims to search for the effect of 50uM Metronidazole against Entamoeba histolytica and thereby elucidating their mechanism of action

Project description:This project investigated the phenotypic characteristics of Metronidazole-tolerant Porphyromonas gingivalis persisters, the relevant modulatory effects of hemin and their underlying survival mechanisms. Proteomic analysis was performed to delineate the protein expression profiles of Metronidazole-tolerant P. gingivalis persister fractions and the controls incubated with different levels of hemin supplementation.

Project description:Bacteroides fragilis is an anaerobic commensal in the human gut which can act as opportunistic pathogen when leaving its intestinal niche to reach other body sites. Bacteroides infections have a high lethality and must be treated by antimicrobial chemotherapy. Metronidazole is one of the most frequently administered antimicrobials in the treatment of Bacteroides infections and is highly reliable. However, metronidazole resistance does occur, favoring fatal disease outcomes. Most of the resistant isolates harbor a nim gene (12 are currently known, i.e. nimA to nimL), a transferable resistance determinant for metronidazole. Previous research suggested that Nim proteins might affect the cellular physiology by changing the activity of key enzymes like pyruvate:ferredoxin oxidoreductase (PFOR). In this study we wanted to assess the impact of the nimA gene on protein expression in a standard B. fragilis isolate, 638R, and compared overall protein expression in 638R with and without a nim gene and with the nimA gene in a proteomic study. Further, high-level metronidazole resistance was induced in both strains and the protein expression profiles of resulting resistant daughter strains were also compared with their respective parent strains. We found that comparably few proteins displayed altered expression in 638R with the nimA gene, but flavodiiron protein FprA was repeatedly found upregulated. FprA is often found in anaerobes and reduces molecular oxygen to water and/or nitric oxide to nitrous oxide. After induction of metronidazole resistance, a far higher number of proteins were found to be differentially expressed in 638R without nimA than in 638R with nimA. In the former, factors for the import of hemin were strongly downregulated, indicating impaired iron import, whereas in the latter the observed changes were not only less numerous but also less specific. Based on the results of this study we present a novel hypothetic model of metronidazole resistance and Nim function.

Project description:We compared the dynamics and mechanisms of resistance development to ceftazidime, meropenem, ciprofloxacin, and ceftolozane-tazobactam in wild-type (PAO1) and mutator (PAOMS, M-bM-^HM-^FmutS) P. aeruginosa. The strains were incubated for 24 h with 0.5 to 64M-CM-^W MICs of each antibiotic in triplicate experiments. The tubes from the highest antibiotic concentration showing growth were reinoculated in fresh medium containing concentrations up to 64M-CM-^W MIC for 7 consecutive days. The susceptibility profiles and resistance mechanisms were assessed in two isolated colonies from each step, antibiotic, and strain. Ceftolozane-tazobactam-resistant mutants were further characterized by whole-genome analysis through RNA sequencing (RNA-seq). The development of high-level resistance was fastest for ceftazidime, followed by meropenem and ciprofloxacin. None of the mutants selected with these antibiotics showed cross-resistance to ceftolozane-tazobactam. On the other hand, ceftolozane-tazobactam resistance development was much slower, and high-level resistance was observed for the mutator strain only. PAO1 derivatives that were moderately resistant (MICs, 4 to 8 ug/ml) to ceftolozane-tazobactam showed only 2 to 4 mutations, which determined global pleiotropic effects associated with a severe fitness cost. High-level-resistant (MICs, 32 to 128 ug/ml) PAOMS derivatives showed 45 to 53 mutations. Major changes in the global gene expression profiles were detected in all mutants, but only PAOMS mutants showed ampC overexpression, which was caused by dacB or ampR mutations. Moreover, all PAOMS mutants contained 1 to 4 mutations in the conserved residues of AmpC (F147L, Q157R, G183D, E247K, or V356I). Complementation studies revealed that these mutations greatly increased ceftolozane-tazobactam and ceftazidime MICs but reduced those of piperacillin-tazobactam and imipenem, compared to those in wild-type ampC. Therefore, the development of high-level resistance to ceftolozane-tazobactam appears to occur efficiently only in a P. aeruginosa mutator background, in which multiple mutations lead to overexpression and structural modifications of AmpC. Mutants of Pseudomonas aeroginosa PAO1 and PAO1 M-bM-^HM-^FmutS against Ceftolozane-tazobactam were generated and analysed using RNA-Seq

Project description:Three types of phenotypic expression of M-CM-^_-lactam resistance has been reported in MRSA: heterogeneous-, homogeneous-, and Eagle-type resistance. Heterogeneous to homogeneous (hetero-to-homo) conversion of M-CM-^_-lactam resistance is postulated to be caused by a chromosomal mutation (chr*) together with mecA-gene expression. The Eagle-type resistance is a special pattern of chr* expression in the pre-MRSA strain N315 under the strong mecI-gene mediated repression of mecA gene transcription. Here, for the identification of chr*, experiments were conducted using an in-vitro derived homogeneously imipenem-resistant MRSA strain N315M-bM-^HM-^FIPH5 (M-bM-^HM-^FIPH5). The strain was selected with imipenem 8 mg/L from the heterogeneously imipenem-resistant MRSA strain N315M-bM-^HM-^FIP (M-bM-^HM-^FIP). The whole genome sequencing of M-bM-^HM-^FIPH5 revealed the presence of a unique mutation in the rpoB gene, rpoB(N967I), causing the amino-acid (AA) substitution of Asp by Ile at the 967th AA position of the RNA polymerase M-CM-^_ subunit. The effect of the mutation on the phenotypic change was confirmed by constructing and studying the phenotype of the strains H5rpoB(I967N), a M-bM-^HM-^FIPH5-derived strain cured of the rpoB mutation, and N315rpoB(N967I), a N315-derived strain introduced with the mutated rpoB gene. H5rpoB(I967N) regained the hetero-MRSA phenotype, and the mutant strain N315rpoB(N967I) showed an Eagle-type phenotype similar to that of N315h4. Furthermore, subsequent whole genome sequencing revealed that N315h4 also had a missense mutation in the rpoB gene rpoB(R644H). The rpoB mutations caused decreased autolysis, prolonged doubling-time, and tolerance to bactericidal concentrations of methicillin. We concluded that the certain rpoB mutations are chr* responsible for the hetero-to-homo phenotypic conversion of MRSA. We compared the gene expression profiles of the wild-type strain and rpoB mutant (N967I) using a 60mer oligo array.