Project description:Increasing antifungal drug resistance is a major concern associated with human fungal infections. Genetic mutation and epimutation mechanisms are clearly linked to resistance in some fungi, but few studies have investigated RNA modifications (the epitranscriptome) as a mediator of resistance. Here, deletion of the Aspergillus fumigatus tRNA-modifying isopentenyl transferase ortholog, Mod5, led to altered growth and stress response, but also unexpected resistance against the antifungal drug 5-fluorocytosine (5-FC). Simultaneous profiling of the transcriptome and proteome of 5-FC-stressed wild-type and ∆mod5 strains revealed a similar general adaptation to stress; however, the knockout displayed elevated expression of cross-pathway control (CPC) genes. Quantification of CPC transcription factor cpcA and client gene argB showed premature CPC activation in ∆mod5, which was further increased upon treatment with 5-FC. By associating codon usage patterns with proteomics abundances, we observed the number of tRNATyrGΨA-decoded codons to negatively correlate with protein abundance in the knockout, indicative of modification-tuneable transcripts. Subsequent overexpression of tRNATyrGΨA in the ∆mod5 strain rescued select phenotypes but, surprisingly, failed to reverse 5-FC resistance. Investigation of the purported tRNA gene-mediated silencing function of Mod5 uncovered a negative correlation between tRNA proximity and gene induction under normal growth, suggesting that tRNA gene-mediated silencing is active in A. fumigatus. In conclusion, 5-FC resistance in the absence of the bifunctional Mod5 protein likely originates from multifaceted transcriptional and translational changes that skew the fungus towards starvation responses over optimal growth, potentially offering a mechanism reliant on RNA modification and tRNA gene-mediated silencing capable of facilitating transient antifungal resistance.

Project description:Increasing antifungal drug resistance is a major concern associated with human fungal pathogens like Aspergillus fumigatus. Genetic mutation and epimutation mechanisms clearly drive resistance, yet the epitranscriptome remains relatively untested. Here, deletion of the A. fumigatus tRNA-modifying isopentenyl transferase ortholog, Mod5, led to altered stress response and unexpected resistance against the antifungal drug 5-fluorocytosine (5-FC). After confirming the canonical isopentenylation activity of Mod5 by LC-MS/MS and Nano-tRNAseq, we performed simultaneous profiling of transcriptomes and proteomes to reveal a comparable overall response to 5-FC stress; however, a premature activation of cross-pathway control (CPC) genes in the knockout was further increased after antifungal treatment. We identified several orthologues of the A. nidulans Major Facilitator Superfamily (MFS) transporter nmeA as specific CPC-client genes in A. fumigatus. Overexpression of Mod5-target tRNATyrGΨA in the ∆mod5 strain rescued select phenotypes but failed to reverse 5-FC resistance, whereas deletion of nmeA largely, but incompletely, reverted the resistance phenotype, implying additional relevant exporters. In conclusion, 5-FC resistance in the absence of Mod5 and i6A likely originates from multifaceted transcriptional and translational changes that skew the fungus towards premature CPC-dependent activation of antifungal toxic-intermediate exporter nmeA, offering a potential mechanism reliant on RNA modification to facilitate transient antifungal resistance.

Project description:tRNA hypomodification facilitates 5-fluorocytosine resistance via cross-pathway control system activation in Aspergillus fumigatus.

Project description:Genome sequence data results are reported from experimental and bioinfomatic work using the technique 'Bulk Segregant Analysis' to determine the genetic basis of observed resistance to the azole antifungal compound itraconazole in the opportunistic fungal pathogen Aspergillus fumigatus.

Project description:The effect of cell free supernatant from the antifungal strain Lactobacillus plantarum 16 on the growth of Aspergillus fumigatus Af293 was assessed. Transcriptome analysis of the genome was performed after ten minutes exposure to antifungal supernatant in order to determine the molecular targets involved in inhibtion.

Project description:The identification of novel transcription factors associated to antifungal response may allow the discovery of fungal specific targets for new therapeutic strategies. A collection of 241 C. albicans transcriptional regulators mutants was screened for altered susceptibility to fluconazole, caspofungin, amphotericin B, and 5-fluorocytosine. Thirteen of these mutants not yet identified in their role in antifungal response were further investigated, and the function of one of them, mutant for orf19.6102 (RCA1) was characterized by transcriptome analysis. Strand specific RNA sequencing and phenotypic tests assigned Rca1 as the regulator of hyphal formation through the cAMP/PKA signaling pathway and the transcription factor Efg1, but also probably through its interaction with a transcriptional repressor, most likely Tup1. The mechanisms responsible for the high level of resistance to caspofungin and fluconazole observed resulting from Rca1 deletion were investigated. From our observations, we propose that caspofungin resistance was the consequence of the deregulation of cell wall gene expression, and that fluconazole resistance was linked to the modulation of the cAMP/PKA signaling pathway activity. In conclusion, our large-scale screening of a C. albicans transcription factor mutants collection allowed the identification of new effectors of the response to antifungals. The functional characterization of Rca1 assigned this TF and its downstream targets as promising candidates for the development of new therapeutic strategies, as Rca1 influences host sensing, hyphal development, and antifungal response. Total RNAs from RCA1 mutant and revertant isolates were extracted in duplicate from exponential growth-phase cultures in YEPD media. Differential expression was resolved by strand specific RNA sequencing.

Project description:More than 10 million people suffer from lung diseases caused by the pathogenic fungus Aspergillus fumigatus. The azole class of antifungals represent first line therapeutics for most of these infections however resistance is rising. Identification of novel antifungal targets that, when inhibited, synergise with the azoles will aid the development of agents that can improve therapeutic outcomes and supress the emergence of resistance. As part of the A. fumigatus genome-wide knockout program (COFUN), we have completed the generation of a library that consists of 120 genetically barcoded null mutants in genes that encode the protein kinase cohort of A. fumigatus. We have employed a competitive fitness profiling approach (Bar-Seq), to identify targets which when deleted result in hypersensitivity to the azoles and fitness defects in a murine host. The most promising candidate from our screen is a previously uncharacterised DYRK kinase orthologous to Yak1 of Candida albicans, a TOR signalling pathway kinase involved in modulation of stress responsive transcriptional regulators. Here we show that the orthologue YakA has been repurposed in A. fumigatus to regulate blocking of the septal pore upon exposure to stress via phosphorylation of the Woronin body tethering protein Lah. Loss of YakA function reduces the ability of A. fumigatus to penetrate solid media and impacts growth in murine lung tissue. We also show that 1-ethoxycarbonyl-beta-carboline (1-ECBC), a compound previously shown to inhibit Yak1 in C. albicans prevents stress mediated septal spore blocking and synergises with the azoles to inhibit A. fumigatus growth.

Project description:Two mutant strains of Aspergillus fumigatus derived from strain A1160, HapB and 29.9, display resistance to the antifungal drug itraconazole. To understand what underlying transcriptional processes contribute to this resistance, A1160, HapB and 29.9 were cultured either in the presence or absence of itraconazole. RNA-sequencing was used to compare transcription profiles of each mutant strain with or without the drug, to A1160 with or without drug.

Project description:The most common cause of cryptococcal meningitis is Cryptococcus neoformans. The addition of 5-fluorocytosine to the treatment of patient with this potentially fatal infection significantly improves disease outcome. However, developing resistance to this drug is a serious problem in patient management. In this study, we investigated the molecular mechanisms causing 5-FC resistance in three clinical isolates of C. neoformans using genomic and proteomic approaches. Our findings show that genetic alterations in genes involved in the pyrimidine salvage pathway caused 5-FC resistance in these isolates. Specifically, one isolate had a missense mutation (E64G) in the uracil phosphoribosyl transferase gene (FUR1), another isolate had a large deletion spanning the cytosine deaminase gene (FCY1), and the third isolate had a point mutation in the same gene leading to a truncated protein at amino acid 164 (STOPW164*). Proteomic data confirmed that the genetic changes led to the absence or decreased the amount of the enzymes in the 5-FC resistant isolates. Transformation experiments confirmed that the genetic changes ultimately affected 5-FC susceptibility, providing further evidence of the effect of the genetic changes on 5-FC susceptibility.

Project description:Cryptococcus neoformans poses a great threat to human communities, given that it quickly becomes resistant to available antifungal drugs. Herein, a conserved chromatin remodeler, Isw1, is shown to function as a master transcriptional modulator of genes responsible for multidrug resistance. It reciprocally controls drug resistance, and cells with disrupted ISW1 demonstrate profound resistance to fluconazole, ketoconazole, 5-fluorocytosine and 5-fluorouracil. Mass spectrometry reveals that Isw1 is both acetylated and ubiquitinated. These two protein posttranslational modifications confer an interplay regulation mechanism that controls Isw1 protein degradation via a ubiquitin-mediated proteasome and, consequently, C. neoformans resistance to drugs. Functional mutagenesis analysis of acetylation and ubiquitination sites reveals that the acetylation status of the lysine 97 residue on Isw1 coordinates its ubiquitination processes at lysines 113 and 441 by modulating the protein interactions between Isw1 and Cdc4, an E3 ligase. Clinical C. neoformans isolates overexpressing the undegradable ISW1 mutant demonstrate impaired drug-resistant phenotypes. Collectively, our studies reveal a sophisticated acetylation-Isw1-ubiquintation regulation axis that controls multidrug resistance in fungal pathogens.