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Project description:This study explored the transcriptional change of Candida glabrata cells due to GCN5 deletion. We also compared the transcriptional responses to fluconazole and micafungin in WT and gcndelta cells relative to respective no drug controls.

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Project description:The goals of this study are to compare C. glabrata transcriptome profiling (RNA-seq) upon exposure to hydrogen peroxide in order to assess the correspondent response. The role of the transcription factor Tog1 is clarified through comparison of the transcrptome profiles of WT and Tog1 mutant cells. mRNA profiles of WT and ∆tog1 were generated by deep sequencing, in duplicate, using Illumina HiSeq. The sequence reads that passed quality filters were analyzed with TopHat followed by HTSeq. RNA-seq data allowed to identify genes whose expression is regulated by the Tog1 transcription factor (147 positively regulated and 112 negatively regulated) with a log2fold change ≥0.5 and p value <0.05. The transcriptomics data was then used to guide further work to detail the function of Tog1.

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Project description: Not available

Project description:Microarray was used to analyze azole resistance of Candida glabrata oropharyngeal isolates from 7 hematopoietic stem cell transplant recipients receiving fluconazole prophylaxis. Transcriptional profiling of the sequential-paired clinical isolates by microarray revealed 19 genes upregulated in the majority of resistant isolates compared to their paired-susceptible isolates. All seven resistant isolates had greater than two fold upregulation of CgPDR1, a master transcriptional regulator of PDR network, and all 7 resistant isolates showed upregulation of known CgPDR1-target genes. The altered transcriptome can be explained in part by the observation that all 7 resistant isolates had acquired a single nonsynonymous mutation in their CgPDR1 ORF. Four mutations occurred in the regulatory domain (L280P, L344S, G348A, S391L) and one in the activation domain (G943S) while two mutations (N764I, R772I) occurred in an undefined region. Association of azole resistance and the CgPDR1 mutations was investigated in the same genetic background by introducing the CgPDR1 sequences from one sensitive and five resistant isolates into a laboratory azole-sensitive strain (cgpdr1) via integrative transformation. The cgpdr1 strain was restored to wild-type fluconazole susceptibility when transformed with CgPDR1 from the susceptible isolate but became resistant when transformed with CgPDR1 from the resistant isolates. However, despite the identical genetic background, upregulation of CgPDR1 and CgPDR1-target genes varied between the 5 transformants, independent of the domain locations in which the mutations occurred. In sum, gain-of-function mutations in CgPDR1 not only contributed to the clinical azole resistance but different mutations had varying degrees of impact on the CgPDR1-target genes.