Project description:The antifungal resistance threat posed by Candida auris necessitates bold and innovative therapeutic options. Farnesol, a quorum-sensing molecule with a potential antifungal and/or adjuvant effect; it may be a promising candidate in alternative treatment regimens. To gain further insights into the farnesol-related effect on C. auris, genome-wide gene expression analysis was performed using RNA-Seq. Farnesol exposure resulted in 1,766 differentially expressed genes. Of these, 447 and 304 genes with at least 1.5-fold increase or decrease in expression, respectively, were selected for further investigation. Genes involved in morphogenesis, biofilm events (maturation and dispersion), gluconeogenesis, iron metabolism, and regulation of RNA biosynthesis showed down-regulation, whereas those related to antioxidative defense, transmembrane transport, glyoxylate cycle, fatty acid β-oxidation, and peroxisome processes were up-regulated. In addition, farnesol treatment increased the expression of certain efflux pump genes, including MDR1, CDR1, and CDR2. Growth, measured by change in CFU number, was significantly inhibited within 2 hours of the addition of farnesol (5.8×10^7±1.1×10^7 and 1.1×10^7±0.3×10^7 CFU/ml for untreated control and farnesol-exposed cells, respectively) (p<0.001). In addition, farnesol treatment caused a significant reduction in intracellular iron (152.2±21.1 vs. 116.0±10.0 mg/kg), manganese (67.9±5.1 vs. 18.6±1.8 mg/kg), and zinc (787.8±22.2 vs. 245.8±34.4 mg/kg) (p<0.05–0.001) compared to untreated control cells, whereas the level of cooper was significantly increased (274.6±15.7 vs. 828.8±106.4 mg/kg) (p<0.001). Our data demonstrate that farnesol significantly influences the growth, intracellular metal ion contents, and gene expression related to fatty acid metabolism, which could open new directions in developing alternative therapies against C. auris.

Project description:Tyrosol, a secondary metabolite of Candida species, regulates fungal morphogenesis, and its application may represent a novel innovative therapy against emerging multi-resistant fungal superbug such as Candida auris. In the current study, the effects of tyrosol on growth, redox homeostasis, intracellular microelement contents and activities of virulence-related enzymes released by C. auris were examined. To gain further information about the effect of tyrosol exposure, we revealed gene transcriptional changes using total transcriptome sequencing (RNA-Seq). At a concentration of 15 mM, tyrosol significantly decrease the growth of fungal cells within 2 h of its addition (5.6 × 107±1.2 × 107 and 2.5 × 107±0.6 × 107 colony forming unit/mL for control and tyrosol-treated cells, respectively). Furthermore, it enhanced the release of reactive oxygen species as confirmed by a dichlorofluorescein (DCF) assay (7.3 ± 1.8 [nmol DCF (OD640)−1] versus 16.8 ± 3.9 [nmol DCF (OD640)−1]), which was coincided with elevated superoxide dismutase, catalase and glutathione peroxidase activities. Tyrosol exerted in a 37%, 25%, 34% and 55% decrease in intracellular manganese, iron, zinc and copper contents, respectively, compared to control cells. The tyrosol treatment led to a 142 and 108 differentially transcripted genes with at least a 1.5-fold increase or decrease in transcription, respectively. Genes related to iron and fatty acid metabolism as well as nucleic acid synthesis were down-regulated, whereas those related to the antioxidative defence, adhesion and oxoacid metabolic processes were up-regulated. This study shows that tyrosol significantly influences growth, intracellular physiological processes and gene transcription in C. auris, which could highly support the development of novel treatment approaches against this important pathogen.

Project description:Candida auris is an enigmatic fungal pathogen, recently elevated to the Critical Priority group of fungal pathogens by the World Health Organisation. Of key concern is its ability to cause outbreaks within intensive and chronic care units, which is facilitated through biofilm formation. We investigated the susceptibility of phenotypically-diverse C. auris isolates to sodium hypochlorite (NaOCl) disinfection, and the subsequent role of biofilms in surviving disinfection using a dry-surface biofilm (DSB) model and transcriptomic profiling. Planktonic cells were tested for susceptibility to NaOCl using minimum inhibitory concentration and disinfection protocols. Biofilm formation using the DSB model consisted of consecutive 48 hr cycles with/without media across a 12-day period, assessed using viable counts, biomass assays, and microscopy. Disinfection efficacy was assessed using clinically relevant protocols of 500-1000 ppm for 1-5 min. RNA-sequencing was performed on untreated DSBs in comparison to planktonic cells. Isolates were found to be sensitive to NaOCl planktonically at concentrations ≤62.5 ppm, and grew robust biofilms using the DSB protocol. Biofilms developed tolerance to all NaOCl treatment parameters, with 2-4 log10-reductions in viable cells observed at highest concentrations. Transcriptomics identified ABC transporters and iron acquisition pathways as strongly upregulated in DSBs relative to planktonic cells. We have optimised a DSB protocol in which C. auris biofilms can mediate tolerance to adverse conditions such as NaOCl disinfection, suggesting a lifestyle through which this problematic yeast can environmentally persist and transmit. Mechanistically, the upregulation of small-molecule and iron transport pathways have been identified as potential facilitators of survival.

Project description:Biofilms with immobilized cells in industrial fermentation are beneficial. Encased in extracellular polymeric substance, cells forming biofilms are regulated by various factors. Nitric oxide (NO), as a signaling molecule, recognized as quorum sensing molecule regulating microbe biofilm formation. Regulation mechanisms of NO on bacteria biofilm have been studied extensively and deeply, while on fungus are rarely studied. In this study, we observed that low concentration of NO enhanced S. cerevisiae biofilm formation. Transcriptional and proteomic analysis revealed that transcription factor MAC1 was activated in biofilm cells under NO treatment. Overexpressed MAC1 increased yeast biofilm formation bypassing regulating the expression level of FLO11. Increased copper and iron contents in NO treated and MAC1 overexpressed cells were not responsible for increased biofilm formation. Among six downstream genes of MAC1, overexpressed CTR1 contributed yeast biofilm formation. Moreover, MAC1 and CTR1 contributed to biofilm cells ethanol resistance resulting from enhanced biofilm. The role of CTR1 protein in yeast biofilm formation may result from its hydrophobic residues in N-terminal extracellular domain. These findings suggested a NO-mediated biofilm formation mechanism that NO regulated expression levels of CTR1 through activating its transcription factor MAC1, leading enhanced biofilm formation.

Project description:Farnesol is a quorum-sensing sesquiterpene alcohol that, via regulation of specific signalling and transcription components, inhibits filamentous growth in Candida. We have found that farnesol also inhibits translation at the initiation step. In contrast to fusel alcohols, that target the eukaryotic initiation factor 2B (eIF2B), farnesol affects the interaction of the mRNA with the small ribosomal subunit leading to reduced levels of the 48S pre-ribosomal complex. To establish the impact of farnesol and how effects on transcription and translation might be co-ordinated, we identified farnesol-dependent changes at both the transcript level and at the level of polysome association using next generation sequencing approaches.

Project description:Transcriptomic, metabolomic, physiological, and computational modeling approaches were integrated to gain insight into the mechanisms of antibiotic tolerance in an in vitro biofilm system. Pseudomonas aeruginosa biofilms were grown in drip-flow reactors on a medium composed to mimic the exudate from a chronic wound (CWE). After 72 hours, the biofilms were treated with CWE (control biofilms) or CWE containing ciprofloxacin (treated biofilms) for an additional 24 hours. Planktonic samples were cultivated to early logarithmic phase in CWE. The biofilm specific growth rate was estimated via elemental balances to be approximately 0.37 h-1, or one-third of the planktonic maximum specific growth rate. Global analysis of gene expression indicated decreased anabolic activity in biofilms compared to planktonic cells. A focused transcriptomic analysis revealed the induction of multiple stress responses in biofilm cells, including those associated with growth arrest, zinc limitation, hypoxia, and acyl-homoserine lactone quorum sensing.

Project description:Tyrosol plays a key role in fungal morphogenesis and biofilm development. Also, it has a remarkable antifungal effect at supraphysiological concentrations. However, the background of the antifungal effect remains unknown, especially in the case of non-albicans Candida species such as Candida parapsilosis We examined the effect of tyrosol on the growth, adhesion, redox homeostasis, virulence, as well as on fluconazole susceptibility. To gain further insights into the physiological consequences of tyrosol treatment we also determined the caused genome-wide gene expression changes using RNA-Seq. Fifteen mM tyrosol caused significant growth inhibition within two hours of the addition of tyrosol, while the adhesion of yeast cells was not affected. Tyrosol increased the production of reactive oxygen species remarkably as revealed by the dichlorofluorescein-test, and it was associated with elevated superoxide dismutase, glutathione peroxidase, and catalase activities. The interaction between fluconazole and tyrosol was antagonistic. Tyrosol exposure resulted in 261 and 181 differentially expressed genes with at least a 1.5-fold increase or decrease in expression, respectively, were selected for further study. Genes involved in ribosome biogenesis showed down-regulation, while genes related to oxidative stress response, and ethanol fermentation were up-regulated. In addition, tyrosol treatment up-regulated the expression of efflux pump genes including MDR1 and CDR1 and down-regulated the FAD2 and FAD3 virulence genes involved in desaturated fatty acid formation. Our data demonstrate that exogenous tyrosol significantly affects the physiology and gene expression of C. parapsilosis, which could contribute to the development of treatments targeting quorum-sensing in the future.

Project description:HNOX infleunces biofilm, central Metabolism, and quorum Sensing in Paracoccus denitrifican

Project description:Bacteria in biofilms have higher antibiotic tolerance than their planktonic counterparts. A major outstanding question is the degree to which the biofilm-specific cellular state and its constituent genetic determinants contribute to this hyper-tolerant phenotype. Here, using genome-wide functional profiling of a complex, heterogeneous mutant population of Pseudomonas aeruginosa MPAO1, we identified large sets of mutations that contribute to antibiotic tolerance predominantly in the biofilm or planktonic setting only. Our mixed population-based experimental design recapitulated the complexity of natural biofilms and, unlike previous studies, revealed clinically observed behaviors including the emergence of quorum sensing-deficient mutants. Our study revealed a substantial contribution of the cellular state to the antibiotic tolerance of biofilms, providing a rational foundation for the development of novel therapeutics against P. aeruginosa biofilm-associated infections. This dataset compares the expression of SAH108, a strain with enhanced antibiotic tolerance in the biofilm state, to expression in wild-type strains. We compared the expression of two biological replicates from strain SAH108 to samples from three wild-type, reference strains. All samples were collected from exponentially-growing planktonic cultures.

Project description:Bacteria in biofilms have higher antibiotic tolerance than their planktonic counterparts. A major outstanding question is the degree to which the biofilm-specific cellular state and its constituent genetic determinants contribute to this hyper-tolerant phenotype. Here, using genome-wide functional profiling of a complex, heterogeneous mutant population of Pseudomonas aeruginosa MPAO1, we identified large sets of mutations that contribute to antibiotic tolerance predominantly in the biofilm or planktonic setting only. Our mixed population-based experimental design recapitulated the complexity of natural biofilms and, unlike previous studies, revealed clinically observed behaviors including the emergence of quorum sensing-deficient mutants. Our study revealed a substantial contribution of the cellular state to the antibiotic tolerance of biofilms, providing a rational foundation for the development of novel therapeutics against P. aeruginosa biofilm-associated infections. This dataset compares the expression of SAH108, a strain with enhanced antibiotic tolerance in the biofilm state, to expression in wild-type strains.