The Sko1 protein represses the yeast-to-hypha transition and regulates the oxidative stress response in Candida albicans.

Cells respond to environmental changes triggering adaptive responses which are, in part, mediated by a transcriptional response. These responses are complex and are dependent on different transcription factors. The present work reports the implication of the Sko1 protein in several processes relevant to the physiology of Candida albicans. First, Sko1 acts as transcriptional repressor of genes involved in pathogenesis and hyphal formation, which results in increased expression of the hyphal related genes ECE1 and HWP1 without significant changes in the virulence using a mouse model of systemic infection. Second Sko1 is involved in the response to oxidative stress and sko1 mutants increase the sensitivity of hog1 to the myelomonocytic cell line HL-60. Genome-wide transcriptional analysis after hydrogen peroxide treatment revealed that sko1 mutants were able to generate an adaptive response similar to wild type strains, although important differences were detected in the magnitude of the transcriptional response. Collectively, these results implicate Sko1 as an important mediator of the oxidative stress response in C. albicans.

Deletion of the SKO1 Gene in a hog1 Mutant Reverts Virulence in Candida albicans.

Candida albicans displays the ability to adapt to a wide variety of environmental conditions, triggering signaling pathways and transcriptional regulation. Sko1 is a transcription factor that was previously involved in early hypoxic response, cell wall remodeling, and stress response. In the present work, the role of sko1 mutant in in vivo and ex vivo studies was explored. The sko1 mutant behaved as its parental wild type strain regarding the ability to colonize murine intestinal tract, ex vivo adhesion to murine gut epithelium, or systemic virulence. These observations suggest that Sko1 is expendable during commensalism or pathogenesis. Nevertheless, the study of the hog1 sko1 double mutant showed unexpected phenotypes. Previous researches reported that the deletion of the HOG1 gene led to avirulent C. albicans mutant cell, which was, therefore, unable to establish as a commensal in a gastrointestinal murine model. Here, we show that the deletion of sko1 in a hog1 background reverted the virulence of the hog1 mutant in a systemic infection model in Galleria mellonella larvae and slightly improved the ability to colonize the murine gut in a commensalism animal model compared to the hog1 mutant. These results indicate that Sko1 acts as a repressor of virulence related genes, concluding that Sko1 plays a relevant role during commensalism and systemic infection.

Arsenic inorganic compounds cause oxidative stress mediated by the transcription factor PHO4 in Candida albicans.

Arsenic is a toxic metalloid widespread in nature. Recently, it has been demonstrated a main role of the transcription factor Pho4 in the acquisition of tolerance to arsenic-derived compounds, arsenite and arsenate in Candida albicans. Here, the effect of these compounds on this pathogenic yeast has been analyzed. In wild type cells, both arsenite and arsenate induced a marked increase in the endogenous production of Reactive Oxygen Species (ROS), together with the accumulation of intracellular trehalose and the activation of catalase, suggesting their role as generators of oxidative stress in this yeast. However, a pho4 null mutant showed a minor increase of intracellular ROS and a different kinetics of catalase activation upon exposure to arsenite and arsenate. Interestingly, the enzymatic activity of glutathione reductase and superoxide dismutase were exclusively triggered by arsenite but not by arsenate. pho4 mutant cells were also found to be sensitive to azide but significantly resistant to arsenate through a process dependent on an active electron transport chain and the alternative oxidase system. Therefore, arsenic-derived compounds induce a strong antioxidant response in C.albicans via different mechanisms.

The Candida albicans Pho4 Transcription Factor Mediates Susceptibility to Stress and Influences Fitness in a Mouse Commensalism Model.

The Pho4 transcription factor is required for growth under low environmental phosphate concentrations in Saccharomyces cerevisiae. A characterization of Candida albicans pho4 mutants revealed that these cells are more susceptible to both osmotic and oxidative stress and that this effect is diminished in the presence of 5% CO2 or anaerobiosis, reflecting the relevance of oxygen metabolism in the Pho4-mediated response. A pho4 mutant was as virulent as wild type strain when assayed in the Galleria mellonella infection model and was even more resistant to murine macrophages in ex vivo killing assays. The lack of Pho4 neither impairs the ability to colonize the murine gut nor alters the localization in the gastrointestinal tract. However, we found that Pho4 influenced the colonization of C. albicans in the mouse gut in competition assays; pho4 mutants were unable to attain high colonization levels when inoculated simultaneously with an isogenic wild type strain. Moreover, pho4 mutants displayed a reduced adherence to the intestinal mucosa in a competitive ex vivo assays with wild type cells. In vitro competitive assays also revealed defects in fitness for this mutant compared to the wild type strain. Thus, Pho4, a transcription factor involved in phosphate metabolism, is required for adaptation to stress and fitness in C. albicans.

The Pho4 transcription factor mediates the response to arsenate and arsenite in Candida albicans.

Arsenate (As (V)) is the dominant form of the toxic metalloid arsenic (As). Microorganisms have consequently developed mechanisms to detoxify and tolerate this kind of compounds. In the present work, we have explored the arsenate sensing and signaling mechanisms in the pathogenic fungus Candida albicans. Although mutants impaired in the Hog1 or Mkc1-mediated pathways did not show significant sensitivity to this compound, both Hog1 and Mkc1 became phosphorylated upon addition of sodium arsenate to growing cells. Hog1 phosphorylation upon arsenate challenge was shown to be Ssk1-dependent. A screening designed for the identification of transcription factors involved in the arsenate response identified Pho4, a transcription factor of the myc-family, as pho4 mutants were susceptible to As (V). The expression of PHO4 was shortly induced in the presence of sodium arsenate in a Hog1-independent manner. Pho4 level affects Hog1 phosphorylation upon As (V) challenge, suggesting an indirect relationship between Pho4 activity and signaling in C. albicans. Pho4 also mediates the response to arsenite as revealed by the fact that pho4 defective mutants are sensitive to arsenite and Pho4 becomes phosphorylated upon sodium arsenite addition. Arsenite also triggers Hog1 phosphorylation by a process that is, in this case, independent of the Ssk1 kinase. These results indicate that the HOG pathway mediates the response to arsenate and arsenite in C. albicans and that the Pho4 transcription factor can differentiate among As (III), As (V) and Pi, triggering presumably specific responses.