Project description:Candida auris (Candidozyma auris) is a yeast pathogen that poses a public health threat because of its ability to develop antifungal resistance. Notably, most C. auris isolates are resistant to fluconazole. The efflux pump Cdr1 is a key contributor of azole resistance in C. auris. In C. albicans, Cdr1 is regulated by the transcription factor Tac1, which has two orthologs in C. auris (Tac1a and Tac1b). While the role of Tac1b has been described, little is known about Tac1a. In this study, we characterized the respective roles of Tac1a and Tac1b in azole resistance. To investigate their transcriptional regulation and binding targets, we performed RNA sequencing and ChEC-seq (Chromatin endogenous cleavage sequencing) for both transcription factors. RNA sequencing was carried out by comparing hyperactivated mutants (TAC1a-HA or TAC1b-HA) with the wild-type strain IV.1. ChEC-seq was performed in strains carrying endogenous C-terminal MNase fusions (TAC1a-MNase and TAC1b-MNase) and in a control strain expressing ectopically MNase (Free MNase). Both Tac1a and Tac1b mediate azole resistance in C. auris via regulation of Cdr1, with overlapping downstream targets and evidence of autoregulation.

Project description:Comparative analysis of genome wide binding profile of Ncb2 in azole sensitive (AS, Gu4) and azole resistant (AR, Gu5) clinical isolates of Candida albicans. The goal was to study the role of Ncb2 in acquisition of drug resistance by comparing the binding profiles of Ncb2 in both the isolates.

Project description:In Candida albicans, the transcription factor Upc2 is central to the regulation of ergosterol biosynthesis. UPC2-activating mutations contribute to azole resistance, whereas disruption increases azole susceptibility. In the present study, we investigated the relationship of UPC2 to fluconazole susceptibility, particularly in azole-resistant strains. In addition to the reduced fluconazole MIC previously observed with UPC2 disruption, we observed a lower minimum fungicidal concentration (MFC) for a upc2Δ/Δ mutant than for its azole-susceptible parent, SC5314. Moreover, the upc2Δ/Δ mutant was unable to grow on a solid medium containing 10 µg/ml fluconazole and exhibited increased susceptibility and a clear zone of inhibition by Etest. Time-kill analysis showed higher fungistatic activity against the upc2Δ/Δ mutant than against SC5314. UPC2 disruption in strains carrying specific resistance mutations also resulted in reduced MICs and MFCs. UPC2 disruption in a highly azole resistant clinical isolate containing multiple resistance mechanisms likewise resulted in a reduced MIC and MFC. This mutant was unable to grow on a solid medium containing 10 µg/ml fluconazole and exhibited increased susceptibility and a clear zone of inhibition by Etest. Time-kill analysis showed increased fungistatic activity against the upc2Δ/Δ mutant in the resistant background. Microarray analysis showed attenuated induction by fluconazole of genes involved in sterol biosynthesis, iron transport, or iron homeostasis in the absence of UPC2. Taken together, these data demonstrate that the UPC2 transcriptional network is universally essential for azole resistance in C. albicans and represents an attractive target for enhancing azole antifungal activity.

Project description:From C. albicans reference strain SC5314, CDR1, CDR2, MDR1, CMP1, CNB1, CRZ1 were deleted. The deletion strains were spread on YPD plates supplemented with tebuconazole. Randomly 4 adaptors derived from each deletion strain were sequenced.

Project description:It has previously been shown that Isw2 represses cryptic antisense transcripts from the 3’-end of three genes. However, whether Isw2 generally functions to repress cryptic RNA transcription is currently unknown. We thus sought to determine the loci at which Isw2 is required to repress cryptic non-coding RNA (ncRNA) expression and to map their transcription start sites relative to nucleosome positions on a global scale.

Project description:we performed mitochondrial proteomic analysis on multiple Candida species (C. albicans, C. glabrata, C. krusei and Candida auris) and analyzed the differentially expressed mitochondrial proteins (DEMPs) between azole-sensitive and azole-resistant Candida species.

Project description:In Candida albicans, the transcription factor Upc2 is central to the regulation of ergosterol biosynthesis. UPC2-activating mutations contribute to azole resistance, whereas disruption increases azole susceptibility. In the present study, we investigated the relationship of UPC2 to fluconazole susceptibility, particularly in azole-resistant strains. In addition to the reduced fluconazole MIC previously observed with UPC2 disruption, we observed a lower minimum fungicidal concentration (MFC) for a upc2M-NM-^T/M-NM-^T mutant than for its azole-susceptible parent, SC5314. Moreover, the upc2M-NM-^T/M-NM-^T mutant was unable to grow on a solid medium containing 10 M-BM-5g/ml fluconazole and exhibited increased susceptibility and a clear zone of inhibition by Etest. Time-kill analysis showed higher fungistatic activity against the upc2M-NM-^T/M-NM-^T mutant than against SC5314. UPC2 disruption in strains carrying specific resistance mutations also resulted in reduced MICs and MFCs. UPC2 disruption in a highly azole resistant clinical isolate containing multiple resistance mechanisms likewise resulted in a reduced MIC and MFC. This mutant was unable to grow on a solid medium containing 10 M-BM-5g/ml fluconazole and exhibited increased susceptibility and a clear zone of inhibition by Etest. Time-kill analysis showed increased fungistatic activity against the upc2M-NM-^T/M-NM-^T mutant in the resistant background. Microarray analysis showed attenuated induction by fluconazole of genes involved in sterol biosynthesis, iron transport, or iron homeostasis in the absence of UPC2. Taken together, these data demonstrate that the UPC2 transcriptional network is universally essential for azole resistance in C. albicans and represents an attractive target for enhancing azole antifungal activity. We examined the genome-wide gene expression profiles of the wild-type parent strain SC5314 and its upc2M-NM-^T/M-NM-^T derivative in response to fluconazole in order to identify genes whose expression in response to fluconazole is influenced by Upc2.

Project description:Histone octamers are thought to be a rigid part of nucleosomes that shape chromatin and block cellular machinery from accessing DNA. ATP-dependent chromatin remodelers like ISW2 mobilize nucleosomes to provide DNA access. We find evidence for histone octamer distortion preceding DNA being moved into nucleosomes and processive movement of the ATPase motor of ISW2 on nucleosomal DNA. DNA entering nucleosome is uncoupled from the ATPase activity of ISW2 and alterations of the histone octamer structure mediated by ISW2 by deletion of the SANT domain from the C-terminus of the Isw2 catalytic subunit. We also find that restricting histone movement by chemical crosslinking traps remodeling intermediates resembling those seen by loss of the SANT domain, further supporting the importance of changes in histone octamer structure early in ISW2 remodeling. Transient octamer distortions are stabilized by H3-H4 tetramer disulfide crosslinking, thereby linking intrinsic histone octamer flexibility to chromatin remodeling.

Project description:Exposure of the budding Saccharomyces cerevisiae to an alkaline environment produces a robust transcriptional response involving hundreds of genes. Part of this response is triggered by an almost immediate burst of calcium that activates the Ser/Thr protein phosphatase calcineurin. Activated calcineurin dephosphorylates the transcription factor Crz1, which moves to the nucleus and binds to calcineurin/Crz1 responsive gene promoters. In this work we present a genome-wide study of the binding of Crz1 to gene promoters in response to high pH stress. Environmental alkalinization promoted a time-dependent recruitment of Crz1 to 152 intergenic regions, the vast majority between 1 to 5 min upon stress onset. Positional evaluation of the genomic coordinates combined with existing transcriptional studies allowed identifying 139 genes likely responsive to Crz1 regulation. Gene Ontology analysis confirmed the relevant impact of calcineurin/Crz1 on a set of genes involved in glucose utilization, and uncovered novel targets, such as genes responsible for trehalose metabolism. We also identified over a dozen of genes encoding transcription factors that are likely under the control of Crz1, suggesting a possible mechanism for amplification of the signal at the transcription level. Further analysis of the binding sites allowed refining the consensus sequence for Crz1 binding to gene promoters and the effect of chromatin accessibility in the timing of Crz1 recruitment to promoters. The present work defines at the genomic-wide level the kinetics of binding of Crz1 to gene promoters in response to alkaline stress, confirms diverse previously known Crz1 targets and identifies many putative novel ones. Because the relevance of calcineurin/Crz1 in signaling diverse stress conditions, our data will contribute to understand the transcriptional response in other circumstances that also involves calcium signaling, such as exposition to sexual pheromones or saline stress.

Project description:We report the expression levels of transcripts for two alleles of 6,211 genes in log-phase growing cells of the wild type SN148 and the crz1/crz1 with or without 0.2M CaCl2 treatment.We find that as compared to the wild type cells without 0.2M CaCl2 treatment, there are 828 genes upregulated in the wild type cells with 0.2M CaCl2 treatment.