Metabolic and Phenotypic Changes Induced during N-Acetylglucosamine Signalling in the Fungal Pathogen Candida albicans.

The human commensal yeast Candida albicans is pathogenic and results in a variety of mucosal and deep tissue problems when the host is immunocompromised. Candida exhibits enormous metabolic flexibility and dynamic morphogenetic transition to survive under host niche environmental conditions and to cause virulence. The amino sugar N-acetylglucosamine (GlcNAc) available at the host infection sites, apart from acting as an extremely good carbon and nitrogen source, also induces cellular signalling in this pathogen. In C. albicans, GlcNAc performs multifaceted roles, including GlcNAc scavenging, GlcNAc import and metabolism, morphogenetic transition (yeast-hyphae and white-opaque switch), GlcNAc-induced cell death (GICD), and virulence. Understanding the molecular mechanism(s) involved in GlcNAc-induced cellular processes has become the main focus of many studies. In the current study, we focused on GlcNAc-induced metabolic changes associated with phenotypic changes. Here, we employed gas chromatography-mass spectrometry (GC-MS), which is a high-throughput and sensitive technology, to unveil global metabolomic changes that occur in GlcNAc vs. glucose grown conditions in Candida cells. The morphogenetic transition associated with metabolic changes was analysed by high-resolution field emission scanning electron microscopy (FE-SEM). Metabolite analysis revealed the upregulation of metabolites involved in the glyoxylate pathway, oxidative metabolism, and fatty acid catabolism to probably augment the synthesis of GlcNAc-induced hypha-specific materials. Furthermore, GlcNAc-grown cells showed slightly more sensitivity to amphotericin B treatment. These results all together provide new insights into the development of antifungal therapeutics for the control of candidiasis in humans.

N-acetylglucosamine kinase, Hxk1 is a multifaceted metabolic enzyme in model pathogenic yeast Candida albicans.

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.

Srg1, a putative protein phosphatase from the HAD-family, is involved in stress adaptation in Candida albicans.

BACKGROUND: The cell stress response plays an important role in the survival of organisms. Studies have revealed that the pathogenic yeast Candida albicans that constantly encounters various environmental insults inside the host has emerged as an ideal system to understand the molecular mechanism (s) of stress response. In this study, we characterize a stress-inducible gene SRG1 which is a Halo Acid Dehalogenase (HAD) family member from C. albicans. METHODS: We used confocal microscopy, site-directed mutagenesis, gene deletion techniques, and tandem-affinity purification and co-immunoprecipitation studies to functionally characterize SRG1. RESULTS: The sub-cellular localization of Srg1 is predominantly cytoplasmic and includes punctate mitochondrial staining in the presence of salt. Protein purification studies coupled with LC-MS analysis showed that Srg1 is a phosphoprotein. The Srg1 mutant carrying S47A and S49A mutations failed to migrate to mitochondria in the presence of salt but retained its phosphatase activity. Srg1 migrates to the nucleus in ∆hog1 mutant cells indicating an unorthodox role for HAD family proteins in stress-mediated transcriptional response. Srg1 also interacts with Erg13, a component involved in the mitochondrial membrane lipid biosynthesis pathway. CONCLUSIONS: A multistep relay mechanism that includes a positive modulation by the MAP kinase Hog1 and a negative modulation by the global repressor Tup1 controls SRG1 expression. GENERAL SIGNIFICANCE: Taken together, our work contributes towards gaining a functional insight into a class of phosphatases that probably have evolved with novel specificities in the pathogenic yeast C. albicans to counteract stressful conditions.

Env7p Associates with the Golgin Protein Imh1 at the trans-Golgi Network in Candida albicans.

Vesicular dynamics is one of the very important aspects of cellular physiology, an imbalance of which leads to the disorders or diseases in higher eukaryotes. We report the functional characterization of a palmitoylated protein kinase from Candida albicans whose homologue in Saccharomyces cerevisiae has been reported to be involved in negative regulation of membrane fusion and was named Env7. However, the downstream target of this protein remains to be identified. Env7 in C. albicans (CaEnv7) could be isolated from the membrane fraction and localized to vesicular structures associated with the Golgi apparatus. Our work reports Env7 in C. albicans as a new player involved in maintaining the functional dynamics at the trans-Golgi network (TGN) by interacting with two other TGN-resident proteins, namely, Imh1p and Arl1p. Direct interaction could be detected between Env7p and the golgin protein Imh1p. Env7 is itself phosphorylated (Env7p) and phosphorylates Imh1 in vivo. An interaction between Env7 and Imh1 is required for the targeted localization of Imh1. CaEnv7 has a putative palmitoylation site toward both N and C termini. An N-terminal palmitoylation-defective strain retains its ability to phosphorylate Imh1 in vitro. An ENV7 homozygous mutant showed compromised filamentation in solid media and attenuated virulence, whereas an overexpressed strain affected cell wall integrity. Thus, Env7 plays a subtle but important role at the level of multitier regulation that exists at the TGN. IMPORTANCE A multitier regulation exists at the trans-Golgi network in all higher organisms. We report a palmitoylated protein kinase, Env7, that functions at the TGN interface by interacting with two more TGN-resident proteins, namely, Imh1 and Arl1. Palmitoylation seems to be important for the specific localization. This study focuses on the involvement of a ubiquitous protein kinase, whose substrates had not yet been reported from any organism, as an upstream signaling component that modulates the activity of the Imh1-Arl1 complex crucial for maintaining membrane asymmetry. Virulence is significantly diminished in an Env7 mutant. The functioning of this protein in C. albicans seems to be quite different from its nearest homologue in S. cerervisiae, which reflects the evolutionary divergence between these two organisms.

N-acetylglucosamine kinase, HXK1 contributes to white-opaque morphological transition in Candida albicans.

Morphological transition (yeast-hyphal and white-opaque) is an important biological process in the life cycle of pathogenic yeast, Candida albicans and is a major determinant of virulence. Earlier reports show that the amino sugar, N-acetylglucosamine (GlcNAc) induces white to opaque switching in this pathogen. We report here a new contributor to this switching phenomenon, namely N-acetylglucosamine kinase or HXK1, the first enzyme of the GlcNAc catabolic cascade. Microarray profile analysis of wild type vs. hxk1 mutant cells grown under switching inducing condition showed upregulation of opaque specific and cell wall specific genes along genes involved in the oxidative metabolism. Further, our qRT-PCR and immunoblot analysis revealed that the expression levels of Wor1, a master regulator of the white-opaque switching phenomenon remained unaltered during this HXK1 mediated transition. Thus the derepression of opaque specific gene expression observed in hxk1 mutant could be uncoupled to the expression of WOR1. Moreover, this regulation via HXK1 is independent of Ras1, a major regulator of morphogenetic transition and probably independent of MTL locus too. These results extend our understanding of multifarious roles of metabolic enzymes like Hxk1 and suggest an adaptive mechanism during host-pathogen interactions.

N-acetylglucosamine kinase, HXK1 is involved in morphogenetic transition and metabolic gene expression in Candida albicans.

Candida albicans, a common fungal pathogen which diverged from the baker's yeast Saccharomyces cerevisiae has the unique ability to utilise N-acetylglucosamine, an amino sugar and exhibits phenotypic differences. It has acquired intricate regulatory mechanisms at different levels in accordance with its life style. N-acetylglucosamine kinase, a component of the N-acetylglucosamine catabolic cascade is an understudied gene since Saccharomyces cerevisiae lacks it. We report HXK1 to act as both positive and negative regulator of transcription of genes involved in maintaining cellular homeostasis. It is involved in repression of hyphal specific genes in addition to metabolic genes. Its regulation of filamentation and GlcNAc metabolism is independent of the known classical regulators like EFG1, CPH1, RAS1, TPK2 or TUP1. Moreover, Hxk1-GFP is localised to cytoplasm, nucleus and mitochondria in a condition specific manner. By employing two-step affinity purification, we report the interaction of HXK1 with SIR2 under filamentation inducing conditions. Our work highlights a novel regulatory mechanism involved in filamentation repression and attempts to decipher the GlcNAc catabolic regulatory cascade in eukaryotes.