Project description:Cryptococcus neoformans is a human fungal pathogen responsible for fatal infections, especially in patients with a depressed immune system. Overexposure to antifungal drugs due to prolonged treatment regimens and structure-similar applications in agriculture have weakened the efficacy of current antifungals in the clinic. The rapid evolution of antifungal resistance urges the discovery of new compounds that inhibit fungal virulence factors, rather than directly killing the pathogen as alternative strategies to overcome disease and reduce selective pressure towards resistance. Recent studies, including our own, have highlighted the antimicrobial properties of natural sources, such as invertebrates, against human fungal pathogens, including C. neoformans, through virulence factor impairment. Here, we evaluated the efficacy of freshwater mussel extracts (crude and clarified) against virulence factor production (i.e., thermotolerance, melanin, capsule, and biofilm) in C. neoformans. Similarly, we demonstrated the critical potential of these extracts to increase the susceptibility of the pathogen to fluconazole across resistant strains, overcoming a globally devastating problem. Additionally, we measured the inhibitory activity of the extracts against peptidases related to fungal virulence and drug resistance. Furthermore, we integrated these phenotypic findings with quantitative proteomics profiling to define distinct signatures of each treatment and validated a new mechanism of anti-virulence action for a selected extract. By understanding the mechanisms driving the antifungal activity of mussels, we may develop innovative treatments for fungal infections lacking susceptibility to conventional drugs.

Project description:The opportunistic fungal pathogen Cryptococcus neoformans faces a wide range of environmental pH within the host, and adaptation to different pH conditions plays a critical role in their survival and pathogenesis. In the current study, how environmental pH influences antifungal susceptibility and iron uptake in C. neoformans was investigated. We found that acidic pH conditions significantly reduced antifungal susceptibility of C. neoformans to fluconazole. Moreover, our study revealed that iron acquisition in C. neoformans at acidic pH is independent of the high-affinity iron uptake system, and leads to increase of intracellular iron accumulation, increased ergosterol and heme levels, which may contribute to reduced fluconazole susceptibility of the fungus. Transcriptome analysis further elucidated the molecular mechanisms underlying the pH-dependent shift of iron uptake and antifungal susceptibility of C. neoformans. Our findings highlight the importance of environmental pH in physiology and pathogenesis of C. neoformans and provide insights into developing novel treatment for cryptococcosis.

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.

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.

Project description:Cryptococcosis is an opportunistic fungal infection affecting individuals with compromised immunity, particularly those with HIV. The limited accessibility to effective treatments, emerging resistance to current antifungals, and treatment-related toxicities underline the pressing need for more effective therapeutic options. In this study, we conducted a whole-cell screening of ~ 3,700 FDA-approved drugs and clinical molecules against the Cryptococcus neoformans H99 strain to identify potential antifungal candidates. The anti-mycobacterial agent SQ109 was identified as one of the most potent hits, with broad antifungal activity. SQ109 exhibited potent activity against Cryptococcus spp., with an MIC90 of 4 μg/mL. In the time-kill assay, SQ109 demonstrated fungicidal activity against proliferating cryptococcal cells in a concentration-dependent manner. Unlike fluconazole (FLC) and flucytosine (5-FC), C. neoformans showed minimal tendency to develop resistance to SQ109 during frequent passaging. Furthermore, SQ109 exhibited a potent efficiency in the murine model of cryptococcal infection, resulting in a 50% survival rate among the group treated with 25 mg/kg for 10 consecutive days. The transcriptomic analysis revealed that SQ109 disrupts ergosterol biosynthesis, affecting membrane integrity and oxidative stress homeostasis, which aligns with its interaction with other ergosterol pathway inhibitors, including FLC. Additionally, molecular docking and structural analysis indicated that squalene synthase protein ERG9 is the most likely target of SQ109 within the ergosterol biosynthesis machinery of cryptococcal cells. These findings highlight the therapeutic potential of SQ109 in combating cryptococcal infections, both as a standalone therapy and as an adjuvant to FLC monotherapy.

Project description:A family of APSES transcription factor is known to be fungal-specific transcriptional regulators and play important roles in governing growth, differentiation, and virulence of diverse fungal pathogens. Yet none of APSES-like transcription factors have been identified and investigated in a basidiomycetous fungal pathogen, Cryptococcus neoformans. In the present study we discovered an APSES-like transcription factor, mbs1 (Mbp1/Swi4-like APSES protein 1), as one of novel flucytosine-responsive genes (total 194 genes) identified through comparative transcriptome analysis of C. neoformans hybrid sensor kinase mutants, tco1 and tco2 mutants, which displayed differential flucytosine-susceptibility. Supporting the microarray data, Northern blot and quantitative RT-PCR analysis confirmed that expression of mbs1 is rapidly induced in response to flucytosine in the wild-type strain, but not in the tco1 and tco2 mutants. Furthermore, C. neoformans with deletion of the mbs1 gene exhibited increased susceptibility to flucytosine. Intriguingly, mbs1 plays pleiotropic roles in diverse cellular process of C. neoformans. mbs1 positively regulates ergosterol biosynthesis and thereby its inhibition confers increased susceptibility and resistance to amphotericin B and azole drugs, respectively. mbs1 is also involved in DNA damage repair counteracting genotoxic stresses. During sexual differentiation mbs1 represses pheromone production, but promotes cell-cell fusion. Furthermore mbs1 is required for production of antioxidant melanin pigment and full virulence of C. neoformans. Finally we also performed DNA microarrray analysis to identify mbs1-regulated genes in C. neoformans. A majority of them were found to be involved in cell cycle regulation and DNA repair. Therefore, this study provides a novel antifungal therapeutic method for treatment of cryptococcosis. total RNAs are extracted 2 strains from H99 (H99 Wild type strain (Cryptococcus neoformans var. grubii serotype A), mbs1Δ), We use the mixed all of total RNAs from this experiment as a control RNA. We use Cy5 as Sample dye and Cy3 as a control dye.

Project description:Cryptococcus neoformans (Cn) is an opportunistic fungal microorganism that causes life-threatening meningoencephalitis. During the infection, the microbial population is heterogeneously composed of cells with varying generational ages, with older cells accumulating during chronic infections. This is attributed to their enhanced resistance to phagocytic killing and tolerance of antifungals like fluconazole (FLC). Using RNA-seq, we investigated how transcriptomic changes in different aspects of metabolism contribute to age-associated FLC tolerance in Cn.

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:A family of APSES transcription factor is known to be fungal-specific transcriptional regulators and play important roles in governing growth, differentiation, and virulence of diverse fungal pathogens. Yet none of APSES-like transcription factors have been identified and investigated in a basidiomycetous fungal pathogen, Cryptococcus neoformans. In the present study we discovered an APSES-like transcription factor, Msa1 (Mbp1/Swi4-like APSES protein 1), as one of novel flucytosine-responsive genes (total 194 genes) identified through comparative transcriptome analysis of C. neoformans hybrid sensor kinase mutants, tco1 and tco2 mutants, which displayed differential flucytosine-susceptibility. Supporting the microarray data, Northern blot and quantitative RT-PCR analysis confirmed that expression of MSA1 is rapidly induced in response to flucytosine in the wild-type strain, but not in the tco1 and tco2 mutants. Furthermore, C. neoformans with deletion of the MSA1 gene exhibited increased susceptibility to flucytosine. Intriguingly, Msa1 plays pleiotropic roles in diverse cellular process of C. neoformans. Msa1 positively regulates ergosterol biosynthesis and thereby its inhibition confers increased susceptibility and resistance to amphotericin B and azole drugs, respectively. Msa1 is also involved in DNA damage repair counteracting genotoxic stresses. During sexual differentiation Msa1 represses pheromone production, but promotes cell-cell fusion. Furthermore Msa1 is required for production of antioxidant melanin pigment and full virulence of C. neoformans. Finally we also performed DNA microarrray analysis to identify Msa1-regulated genes in C. neoformans. A majority of them were found to be involved in cell cycle regulation and DNA repair. Therefore, this study provides a novel antifungal therapeutic method for treatment of cryptococcosis. There are more than 95% of genome homology between JEC21 and H99. Therefore 24 slides of JEC21 (cryptococcus neoformans var. neoformans serotype D) 70-mer oligo are used in this analysis, 3 biological replicate experiments are performed, total RNAs are extracted under 2 conditions (with or without treatment of Flucytosine) with 4 strains from H99 (H99 Wild type strain (Cryptococcus neoformans var. grubii serotype A), tco1Δ , tco2Δ , skn7Δ), We use the mixed all of total RNAs from this experiment as a control RNA. We use Cy5 as Sample dye and Cy3 as a control dye.

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.