The sensing of environmental conditions such as nutrient availability and the ability to adapt and respond to changing conditions are crucial for the survival of living organisms. Evidence from several organisms have revealed that some metabolic enzymes act as sensors of nutrient status and regulate the expression of sets of genes required for nutrients utilization and condition specific environmental adaptation. Thus metabolic enzymes regulate the signaling pathway by acting as transcriptional regulators and providing required metabolites. The commensal yeast, Candida albicans has recently emerged as a model system for understanding the N-acetylglucosamine (GlcNAc) signaling pathway in eukaryotes. GlcNAc kinase (Hxk1), the first enzyme of the catabolic cascade, has been shown to perform several functions such as regulation of gene expression and regulation of the metabolic status of the cell thereby resulting in a change in cell morphology (yeast-hyphal transition, white-opaque switching), metabolic gene expression, synthesis of metabolic precursors, induction of glycolytic flux rate and biofilm formation. Here, in this review we have discussed various roles of Hxk1that have not been reported in other organisms previously. The enzyme exhibits dynamic changes in subcellular localization consistent with its expanded functions inside the cell. Thus Hxk1 in C. albicans orchestrates several dynamic cellular processes and this signaling system can act as a paradigm to understand the cell fate and metabolic specialization in other eukaryotes too. Still, the molecular cues involved in Hxk1 mediating functions are yet to be unveiled; the relationship between Hxk1 sensing and its signaling effects is also not understood yet.
Keywords: Candida albicans; Gene repression; GlcNAc Kinase; GlcNAc metabolism; Hxk1; Hyperfilamentation; Multifarious roles; White-opaque switch.
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