Project description:Candida auris has been globally recognized as a multidrug-resistant human fungal pathogen that contributes for the worldwide occurrence of nosocomial outbreaks. It has been reported that C. auris was able to avoid neutrophil attack, suggestive of an impaired innate immune response. Whether C. auris evades the innate immune recognition of BMDM (bone marrow derived macrophage) remains poorly understood, and as for well-known Candida species -C. albicans, it can trigger immune response. To determine whether occurs difference between immune response stimulated by C. auris or C. albicans, we performed mRNA-seq of BMDM stimulated by C. auris or C. albicans.
Project description:Candida auris clinical isolate FY279 was exposed to tebuconazole (32μg/ml). Randomly14 adaptors were chosen. 10 adaptors obtained resistance to tebuconazole. These resistant adaptors were sequenced.
Project description:Approximately 1 million cells of Candida auris isolate FY279 were spread on YPD plate supplemented with 8ug/ml tunicamycin. Randomly 21 adaptors were chosen. These adaptors were sequenced.
Project description:Candida auris reference strain B11221 was spread on YPD plate supplemented with 8 μg/ml tunicamycin. Randomly 25 adaptors (T2080-T2104) were chosen. These adaptors and the parent were sequenced.
Project description:The limited number of antifungals and the emergence of multidrug-resistant Candida auris pose a significant challenge to human medicine. Here, we utilized combinatorial drug therapy as an approach to augment the activity of current azole antifungals against C. auris. We evaluated the fluconazole chemosensitization activity of 1547 FDA-approved drugs and clinical molecules against an azole-resistant strain of C. auris. This led to the discovery that lopinavir, an antiviral drug, is a potent agent capable of sensitizing C. auris to the effect of azole antifungals. At a therapeutically achievable concentration (4-8 µg/ml), lopinavir exhibited potent synergistic interactions with azole drugs, particularly with itraconazole, against C. auris (ΣFICI ranged from 0.05-0.50). The lopinavir/itraconazole combination enhanced the survival rate of C. auris-infected Caenorhabditis elegans by 90% and reduced the fungal burden in infected nematodes by 88.5% (p < 0.05). Moreover, lopinavir enhanced the antifungal activity of itraconazole against other medically important Candida species including C. albicans, C. tropicalis, C. glabrata, C. tropicalis, and C. parapsilosis. Comparative transcriptomic profiling revealed that lopinavir interferes with glucose permeation and ATP synthesis. This compromises the function of the efflux pumps presents in C. auris enhancing sensitivity to azole antifungals, as demonstrated by Nile red efflux assays. This study presents lopinavir as a novel, potent and broad-spectrum azole chemosensitizing agent that warrants further investigation against recalcitrant Candida infections.
