RESUMEN
Mucor circinelloides is an etiologic agent of mucormycosis, a fungal infection produced by Mucorales often associated with mortality due to unavailability of antifungal drugs. Arl proteins belong to the Arf family and are involved in vesicle trafficking and tubulin assembly. This study identified two Arl (Arf-like)-encoding genes, arl1 and arl2, in M. circinelloides and explored their function in morphogenesis, virulence, and antifungal susceptibility. Although Arl1 and Arl2 proteins shared 55% amino acid sequence identity, arl1 and arl2 genes showed distinct transcriptional expression patterns. arl1 was expressed at higher levels than arl2 and induced in mycelia, suggesting a role in morphological transitions. Disruption of the arl1 and arl2 genes led to heterokaryon (Δarl1(+)(-)) and homokaryon (Δarl2) genotypes, respectively. The incapacity to generate homokaryon mutants for arl1 suggested that it is essential for growth of M. circinelloides. Deletion of each gene reduced the expression of the other, suggesting the existence of a positive cross-regulation between them. Thus, deletion of arl2 resulted in a ~60% reduction of arl1 expression, whereas the Δarl1(+)(-) showed â¼90% reduction of arl1 expression. Mutation of arl2 showed no phenotype or a mild phenotype between Δarl1(+)(-) and wild-type (WT), suggesting that all observed phenotypes in both mutant strains corresponded to arl1 low expression. The Δarl1(+)(-) produced a small amount of spores that showed increased sensitivity to dodecyl-sulfate and azoles, suggesting a defect in the cell wall that was further supported by decrease in saccharide content. These defects in the cell wall were possibly originated by abnormal vesicle trafficking since FM4-64 staining of both mutants Δarl1(+)(-) and Δarl2 revealed less well-localized endosomes compared to the WT. Moreover, aberrant vesicle trafficking may be responsible for the secretion of specific virulence-related proteins since cell-free medium from Δarl1(+)(-) were found to increase killing of Caenorhabditis elegans compared to WT.
Asunto(s)
Antifúngicos/farmacología , Proteínas Fúngicas/genética , Mucor/efectos de los fármacos , Mucor/genética , Genotipo , Mucor/patogenicidad , Mutación , Filogenia , Transporte de Proteínas , Esporas Fúngicas/patogenicidad , Proteínas de Transporte Vesicular/genética , VirulenciaRESUMEN
Mucor circinelloides is a dimorphic fungus used to study cell differentiation that has emerged as a model to characterize mucormycosis. In this work, we identified four ADP-ribosylation factor (Arf)-encoding genes (arf1-arf4) and study their role in the morphogenesis and virulence. Arfs are key regulators of the vesicular trafficking process and are associated with both growth and virulence in fungi. Arf1 and Arf2 share 96% identity and Arf3 and Arf4 share 89% identity, which suggests that the genes arose through gene-duplication events in M. circinelloides. Transcription analysis revealed that certain arf genes are affected by dimorphism of M. circinelloides, such as the arf2 transcript, which was accumulated during yeast development. Therefore, we created knockout mutants of four arf genes to evaluate their function in dimorphism and virulence. We found that both arf1 and arf2 are required for sporulation, but these genes also perform distinct functions; arf2 participates in yeast development, whereas arf1 is involved in aerobic growth. Conversely, arf3 and arf4 play only minor roles during aerobic growth. Moreover, we observed that all single arf-mutant strains are more virulent than the wild-type strain in mouse and nematode models, with the arf3 mutant being most virulent. Lastly, arf1/arf2 and arf3/arf4 double mutations produced heterokaryon strains that did not reach the homokaryotic state, indicating that these genes participate in essential and redundant functions. Overall, this work reveals that Arfs proteins regulate important cellular processes in M. circinelloides such as morphogenesis and virulence, laying the foundation to characterize the molecular networks underlying this regulation.