Invasive fungal infections are a leading cause of human mortality. Effective treatment is hindered by the rapid emergence of resistance to the limited number of antifungal drugs, demanding new strategies to treat life-threatening fungal infections. Here, we explore a powerful strategy to enhance antifungal efficacy against leading human fungal pathogens by using the natural product beauvericin. We found that beauvericin potentiates the activity of azole antifungals against azole-resistant Candida isolates via inhibition of multidrug efflux and that beauvericin itself is effluxed via Yor1. As observed in Saccharomyces cerevisiae, we determined that beauvericin inhibits TOR signaling in Candida albicans. To further characterize beauvericin activity in C. albicans, we leveraged genome sequencing of beauvericin-resistant mutants. Resistance was conferred by mutations in transcription factor genes TAC1, a key regulator of multidrug efflux, and ZCF29, which was uncharacterized. Transcriptional profiling and chromatin immunoprecipitation coupled to microarray analyses revealed that Zcf29 binds to and regulates the expression of multidrug transporter genes. Beyond drug resistance, we also discovered that beauvericin blocks the C. albicans morphogenetic transition from yeast to filamentous growth in response to diverse cues. We found that beauvericin represses the expression of many filament-specific genes, including the transcription factor BRG1. Thus, we illuminate novel circuitry regulating multidrug efflux and establish that simultaneously targeting drug resistance and morphogenesis provides a promising strategy to combat life-threatening fungal infections.
Invasive fungal infections caused by the pathogen Candida albicans have transitioned from a rare curiosity to a major cause of human mortality. This is in part due to the emergence of resistance to the limited number of antifungals available to treat fungal infections. Azoles function by targeting the biosynthesis of ergosterol, a key component of the fungal cell membrane. Loss-of-function mutations in the ergosterol biosynthetic gene ERG3 mitigate azole toxicity and enable resistance that depends upon fungal stress responses. Here, we performed a genome-wide synthetic genetic array screen in Saccharomyces cerevisiae to map ERG3 genetic interactors and uncover novel circuitry important for azole resistance. We identified nine genes that enabled erg3-mediated azole resistance in the model yeast and found that only two of these genes had a conserved impact on resistance in C. albicans. Further, we screened a C. albicans homozygous deletion mutant library and identified 13 genes for which deletion enhances azole susceptibility. Two of the genes, RGD1 and PEP8, were also important for azole resistance acquired by diverse mechanisms. We discovered that loss of function of retrograde transport protein Pep8 overwhelms the functional capacity of the stress response regulator calcineurin, thereby abrogating azole resistance. To identify the mechanism through which the GTPase activator protein Rgd1 enables azole resistance, we selected for mutations that restore resistance in strains lacking Rgd1. Whole genome sequencing uncovered parallel adaptive mechanisms involving amplification of both chromosome 7 and a large segment of chromosome 3. Overexpression of a transporter gene on the right portion of chromosome 3, NPR2, was sufficient to enable azole resistance in the absence of Rgd1. Thus, we establish a novel mechanism of adaptation to drug-induced stress, define genetic circuitry underpinning azole resistance, and illustrate divergence in resistance circuitry over evolutionary time.
Legionellosis was diagnosed in an immunocompromised 3-year-old girl in Canada. We traced the source of the bacterium through co-culture with an ameba collected from a hot tub in her home. We identified Legionella pneumophila serogroup 6, sequence type 185, and used whole-genome sequencing to confirm the environmental and clinical isolates were of common origin.
The eukaryotic CCR4-NOT deadenylase complex is a highly conserved regulator of mRNA metabolism that influences the expression of the complete transcriptome, representing a prime target for a generalist bacterial pathogen. We show that a translocated bacterial effector protein, PieF (Lpg1972) of L. pneumophila Str. Philadelphia-1, interacts specifically with the CNOT7/8 nuclease module of CCR4-NOT, with a dissociation constant in the low nanomolar range. PieF inhibits the catalytic deadenylase subunit CNOT7 of the CCR4-NOT complex in a stoichiometric, dose-dependent manner in vitro. In transfected cells, PieF can silence reporter gene expression and reduce mRNA steady-state levels when artificially tethered. PieF demonstrates molecular similarities to another family of CNOT7-associated factors but demonstrates divergence concerning the interaction interface with CNOT7. In addition, we show that PieF overexpression changes the subcellular localization of CNOT7 and displaces the CNOT6/6L nucleases from CCR4-NOT. Finally, PieF expression phenocopies knockout of the CNOT7 ortholog in S. cerevisiae, resulting in 6-azauracil sensitivity. Collectively, this work suggests that L. pneumophila targets host mRNA stability and expression through a highly conserved host pathway not previously associated with Legionella pathogenesis.
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