Project description:The pathogenic yeast species Candida glabrata has an intrinsically high resilience to azoles and a rapid capability of acquiring resistance. Azole-resistant clinical strains derive mostly from them encoding hyperactive mutants of the CgPdr1 regulator, however, strains encoding wild-type CgPdr1 variants were identified suggesting a role for CgPdr1-independent mechanisms in acquisition of resistance in vivo. Seven azole-resistant C. glabrata isolates were found to encode CgPdr1 gain-of-function variants, two, I392M and I803T, being herein described for the first time. OMICS profile of the sole azole-resistant strain encoding a wild-type CgPDR1 allele revealed that these cells over-express several genes described for providing protection against azoles, while down-regulating genes described to increase sensitivity to these drugs. Over-expression of genes required for metabolism and transport of sterols to compensate the azole-induced inhibition of Erg11 and a more active calcineurin pathway are other mechanisms suggested to underlie azole resistance in ISTB218.

Project description:The opportunistic yeast pathogen Candida glabrata is recognized for its ability to acquire resistance during prolonged treatment with azole antifungals. Resistance to azoles is largely mediated by the transcription factor PDR1, resulting in the upregulation of ATP-binding cassette (ABC) transporter proteins and drug efflux. Studies in the related yeast Saccharomyces cerevisiae have shown Pdr1p forms a heterodimer with another transcription factor, Stb5p. In C. glabrata the ORF designated CAGL0I02552g has 38.8% amino acid identity with STB5 (YHR178w), and shares an N-terminal Zn2Cys6 binuclear cluster domain and a fungal specific transcriptional factor domain, prompting us to test for homologous function and a possible role in azole resistance. Complementation of deltayhr178w (stb5) with CAGL0I02552g resolved the increased sensitivity to cold, hydrogen peroxide and caffeine of the mutant, for which reason we designated CAGl0I02552g as CgSTB5. Overexpression of CgSTB5 in C. glabrata repressed azole resistance, whereas deletion of CgSTB5 increased resistance, both by a mechanism independent of CgPDR1. Expression analysis found that CgSTB5 shares many of the same transcriptional targets as CgPDR1 but, unlike the later, is a negative regulator of pleiotropic drug resistance, including the ABC transporter genes CDR1,PDH1, and YOR1.

Project description:The opportunistic yeast pathogen Candida glabrata is recognized for its ability to acquire resistance during prolonged treatment with azole antifungals. Resistance to azoles is largely mediated by the transcription factor PDR1, resulting in the upregulation of ATP-binding cassette (ABC) transporter proteins and drug efflux. Studies in the related yeast Saccharomyces cerevisiae have shown Pdr1p forms a heterodimer with another transcription factor, Stb5p. In C. glabrata the ORF designated CAGL0I02552g has 38.8% amino acid identity with STB5 (YHR178w), and shares an N-terminal Zn2Cys6 binuclear cluster domain and a fungal specific transcriptional factor domain, prompting us to test for homologous function and a possible role in azole resistance. Complementation of deltayhr178w (stb5) with CAGL0I02552g resolved the increased sensitivity to cold, hydrogen peroxide and caffeine of the mutant, for which reason we designated CAGl0I02552g as CgSTB5. Overexpression of CgSTB5 in C. glabrata repressed azole resistance, whereas deletion of CgSTB5 increased resistance, both by a mechanism independent of CgPDR1. Expression analysis found that CgSTB5 shares many of the same transcriptional targets as CgPDR1 but, unlike the later, is a negative regulator of pleiotropic drug resistance, including the ABC transporter genes CDR1,PDH1, and YOR1. The CgPDR1OE (n=5) arrays consisted of five technical repeats with one prepared using reciprocal labeling. The Cgstb5delta (n=4) and CgSTB5OE (n=4) arrays consisted of four technical repeats each with one prepared using reciprocal labeling.

Project description:In the pathogenic yeast Candida albicans, the zinc cluster transcription factor Upc2p has been shown to regulate expression of ERG11 and other genes involved in ergosterol biosynthesis upon exposure to azole antifungals. ERG11 encodes lanosterol demethylase, the target enzyme of this antifungal class. Over-expression of UPC2 reduces azole susceptibility, whereas its disruption results in hypersusceptibility to azoles and reduced accumulation of exogenous sterols. Constitutive up-regulation of ERG11 is a major cause of resistance to fluconazole in clinical isolates of C. albicans, yet the mechanism for this has yet to be determined. Using genome-wide gene expression profiling, we found UPC2 and other genes involved in ergosterol biosynthesis to be coordinately up-regulated with ERG11 in a fluconazole resistant clinical isolate as compared with a matched susceptible isolate from the same patient. Sequence analysis of the UPC2 alleles of these isolates revealed that the resistant isolate contained a single nucleotide substitution in one UPC2 allele that resulted in a G648D exchange in the encoded protein. Introduction of the mutated allele into a drug susceptible strain resulted in constitutive up-regulation of ERG11 and increased resistance to fluconazole. By comparing the gene expression profiles of the fluconazole resistant isolate and of strains carrying wild-type and mutated UPC2 alleles, we identified target genes that are controlled by Upc2p. Here we show for the first time that a gain-of-function mutation in UPC2 leads to increased expression of ERG11 and imparts resistance to fluconazole in clinical isolates of C. albicans. Keywords: genome-wide expression profiling

Project description:In the pathogenic yeast Candida albicans, the zinc cluster transcription factor Upc2p has been shown to regulate expression of ERG11 and other genes involved in ergosterol biosynthesis upon exposure to azole antifungals. ERG11 encodes lanosterol demethylase, the target enzyme of this antifungal class. Over-expression of UPC2 reduces azole susceptibility, whereas its disruption results in hypersusceptibility to azoles and reduced accumulation of exogenous sterols. Constitutive up-regulation of ERG11 is a major cause of resistance to fluconazole in clinical isolates of C. albicans, yet the mechanism for this has yet to be determined. Using genome-wide gene expression profiling, we found UPC2 and other genes involved in ergosterol biosynthesis to be coordinately up-regulated with ERG11 in a fluconazole resistant clinical isolate as compared with a matched susceptible isolate from the same patient. Sequence analysis of the UPC2 alleles of these isolates revealed that the resistant isolate contained a single nucleotide substitution in one UPC2 allele that resulted in a G648D exchange in the encoded protein. Introduction of the mutated allele into a drug susceptible strain resulted in constitutive up-regulation of ERG11 and increased resistance to fluconazole. By comparing the gene expression profiles of the fluconazole resistant isolate and of strains carrying wild-type and mutated UPC2 alleles, we identified target genes that are controlled by Upc2p. Here we show for the first time that a gain-of-function mutation in UPC2 leads to increased expression of ERG11 and imparts resistance to fluconazole in clinical isolates of C. albicans. Keywords: genome-wide expression profiling Clinical isolates S1 (susceptible) and S2 (resistant), genome strain SC5314, UPC2 disruption strains (UPC2M4A and UPC2M4B), UPC2 re-integrant strains of non-mutated UPC2 allele (UPC2M2K21A and UPC2M2K21B), and UPC2 re-integrant strains of mutated UPC2 allele (UPC2M2K31A and UPC2M2K31B) were grown for 3 hours until log phase. RNA was extracted for each isolate/strain. Experiments were performed in duplicate.

Project description:In this study we used a transcriptomic approach to study the molecular determinants of the synergy between copper and fluconazole, in Candida glabrata, the second most frequent cause of invasive candidiasis. We demonstrate that copper acts together with fluconazole by downregulating three distinct pathways: azole efflux, ergosterol biosynthesis and zinc homeostasis. Coincidently, all these pathways are important for C. glabrata to cope with fluconazole stress. Therefore, when copper and fluconazole are combined cells fail to detoxify this drug and accumulate toxic methylated intermediates of sterol metabolism. This accumulation, possibly together with copper-induced lipid damages, should affect the activity of plasma membrane transporters, which impedes zinc uptake, leading to zinc depletion

Project description:Fungal infections are an emerging health risk, especially those involving yeast that are resistant to antifungal agents. To understand the range of mechanisms by which yeasts can respond to anti-fungals, we compared gene expression patterns across three evolutionarily distant species - Saccharomyces cerevisiae, Candida glabrata and Kluyveromyces lactis - over time following fluconazole exposure. Conserved and diverged expression patterns were identified using a novel soft clustering algorithm that concurrently clusters data from all species while incorporating sequence orthology. The analysis suggests complementary strategies for coping with ergosterol depletion by azoles - Saccharomyces imports exogenous ergosterol, Candida exports fluconazole, while Kluyveromyces does neither leading to extreme sensitivity. In support of this hypothesis we find that only Saccharomyces becomes more azole resistant in ergosterol-supplemented media; that this depends on sterol importers Aus1 and Pdr11; and that transgenic expression of sterol importers in Kluyveromyces alleviates its drug sensitivity. We have compared the dynamic transcriptional responses of three diverse yeast species to fluconazole treatment using a novel clustering algorithm. This approach revealed significant divergence among regulatory programs associated with fluconazole sensitivity. In future, such approaches might be used to survey a wider range of species, drug concentrations and stimuli to reveal conserved and divergent molecular response pathways.

Project description:The Negative cofactor 2 (NCT) complex is an evolutionally conserved heterodimeric transcription factor. In Aspergillus fumigatus, the NCT complex consists of two subunits NctA and NctB. Through a genome-wide screening of a transcription factor null mutant strains, we found that loss of the NCT complex leads to a multi-drug resistance phenotype including the azoles (itraconazole, voriconazole and posaconazole) as well as the salvage therapeutic amphotericin B, and terbinafine. To obtain further insight into the molecular mechanisms driving the azole-resistance in the NCT complex null mutants, we analyzed genome-wide binding profiles of NctA using chromatin-immunoprecipitation sequencing (ChIP-seq). Our ChIP-seq analysis revealed that NCT complex binds the promoters of several ergosterol biosynthetic genes, their transcriptional regulators, and the azole efflux pump cdr1B. Taken together, these results suggest that the NCT complex plays a role as a master regulator of drug resistance in A. fumigatus.

Project description:Fungal infections are an emerging health risk, especially those involving yeast that are resistant to antifungal agents. To understand the range of mechanisms by which yeasts can respond to anti-fungals, we compared gene expression patterns across three evolutionarily distant species - Saccharomyces cerevisiae, Candida glabrata and Kluyveromyces lactis - over time following fluconazole exposure. Conserved and diverged expression patterns were identified using a novel soft clustering algorithm that concurrently clusters data from all species while incorporating sequence orthology. The analysis suggests complementary strategies for coping with ergosterol depletion by azoles - Saccharomyces imports exogenous ergosterol, Candida exports fluconazole, while Kluyveromyces does neither leading to extreme sensitivity. In support of this hypothesis we find that only Saccharomyces becomes more azole resistant in ergosterol-supplemented media; that this depends on sterol importers Aus1 and Pdr11; and that transgenic expression of sterol importers in Kluyveromyces alleviates its drug sensitivity. We have compared the dynamic transcriptional responses of three diverse yeast species to fluconazole treatment using a novel clustering algorithm. This approach revealed significant divergence among regulatory programs associated with fluconazole sensitivity. In future, such approaches might be used to survey a wider range of species, drug concentrations and stimuli to reveal conserved and divergent molecular response pathways. There are three yeast species being studied. Each species has three biological replicates. Each biological replicate has 6 time points (0,1/3,2/3,1,2,4). These time points are combined in equal proportions to form a species and replicate specific “Reference Pool”. Each time point (except time 0) is compared against the Reference Pool. We also perform dye-swapped technical replicates for each biological replicate.

Project description:Ergosterol, a pivotal constituent of the fungal cell membrane, plays a crucial role in diverse cellular activities. Fungi inherently regulate ergosterol homeostasis, a process traditionally associated with the control of a major transcription factor, like SREBP, activated in response to ergosterol depletion, regardless of which ergosterol biosynthesis step is affected. Contrary to the established paradigm, our investigation demonstrates that the inhibition of ergosterol biosynthesis at specific steps triggers distinct transcriptional responses in erg genes across fungi, including Neurospora crassa, Aspergillus fumigatus, and Fusarium verticillioides. In N. crassa, the targeted responses are orchestrated by several transcription factors that have undergone functional rewiring. Specifically, ERG24 inhibition by amorolfine activates transcription factors SAH-2 and AtrR, resulting in the upregulation of erg24, erg2, erg25 and erg3. Additionally, ERG11 inhibition by azoles activates transcription factor NcSR, leading to the upregulation of erg11 and erg6. Our findings unveil a novel sophisticated regulation model of sterol biosynthesis in fungi which potentially enhances fungal survival in complex environments, thus providing new insights into sterol homeostasis maintenance and a deeper understanding of drug resistance mechanisms in fungi.