eWe determined the changes in transcriptional profiles that occur in the first hour following the transfer of Candida albicans to hypoxic growth conditions. The impressive speed of this response is not compatible with current models of fungal adaptation to hypoxia that depend on the depletion of sterol and heme. Functional analysis using Gene Set Enrichment Analysis (GSEA) identified the Sit4 phosphatase, Ccr4 mRNA deacetylase, and Sko1 transcription factor (TF) as potential regulators of the early hypoxic response. Cells mutated in these and other regulators exhibit a delay in their transcriptional responses to hypoxia. Promoter occupancy data for 29 TFs were combined with the transcriptional profiles of 3,111 in vivo target genes in a Network Component Analysis (NCA) to produce a model of the dynamic and highly interconnected TF network that controls this process. With data from the TF network obtained from a variety of sources, we generated an edge and node model that was capable of separating many of the hypoxia-upregulated and -downregulated genes. Upregulated genes are centered on Tye7, Upc2, and Mrr1, which are associated with many of the gene promoters that exhibit the strongest activations. The connectivity of the model illustrates the high redundancy of this response system and the challenges that lie in determining the individual contributions of specific TFs. Finally, treating cells with an inhibitor of the oxidative phosphorylation chain mimics most of the early hypoxic profile, which suggests that this response may be initiated by a drop in ATP production.
Candida albicans is an opportunistic pathogen responsible for various non-life-threatening infections and is a major cause of morbidity and mortality, particularly in immunosuppressed patients. Its ability to invade multiple body sites and organs requires adaptation to changes in oxygen and carbon dioxide concentrations, temperature, pH, osmolarity, and nutrient availability. Colonization of aerobic body sites, including the skin and mucosal surfaces, as well as of oxygen-poor locations such as internal organs and the gastrointestinal tract, demonstrates that C. albicans is adept at acclimating to both normoxia and hypoxia. Under hypoxic conditions, the ability of C. albicans to form hyphae, the growth mode dedicated to host invasion and colonization, is enhanced, suggesting a close relationship between the hypoxic response and pathogenesis (1). Furthermore, hypoxia positively affects different biological processes such as chlamydospore formation and the stability of mating-competent opaque cells (1-3). In an earlier study, we demonstrated that C. albicans cells growing as biofilms in a flow model present a transcriptional signature similar to that of planktonic cells growing under hypoxic conditions (4). This suggests that the biofilm cells, or at least a subpopulation of the biofilm, are confronting hypoxic conditions.The majority of studies on sensing, signaling, and transcriptional regulatory mechanisms of hypoxia adaptation in fungi have bee...
