N-acetylglucosamine (GlcNAc) triggers a rapid, temperature-responsive morphogenetic program in thermally dimorphic fungi

The monosaccharide N-acetylglucosamine (GlcNAc) is a major component of microbial cell walls and is ubiquitous in the environment. GlcNAc stimulates developmental pathways in the fungal pathogen Candida albicans, which is a commensal organism that colonizes the mammalian gut and causes disease in th...

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Bibliographic Details
Published in:PLoS genetics 2013-09, Vol.9 (9), p.e1003799-e1003799
Main Authors: Gilmore, Sarah A, Naseem, Shamoon, Konopka, James B, Sil, Anita
Format: Article
Language:English
Subjects:
Acetylglucosamine - genetics
Acetylglucosamine - metabolism
Blastomyces - genetics
Blastomyces - pathogenicity
Candida albicans - genetics
Candida albicans - pathogenicity
Cell Wall - metabolism
Dimorphism (Biology)
Fungi
Fungi - genetics
Fungi, Pathogenic
Gene expression
Gene Expression Regulation, Fungal
Genetic aspects
Genome, Fungal
Genomes
Glucosamine
Health aspects
Histoplasma - genetics
Histoplasma - pathogenicity
Humans
Mammals
Microbiology
Microscopy
Morphogenesis
Organisms
Pathogenesis
Physiological aspects
Signal Transduction
Soil Microbiology
Studies
Temperature
Yeast
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Summary:The monosaccharide N-acetylglucosamine (GlcNAc) is a major component of microbial cell walls and is ubiquitous in the environment. GlcNAc stimulates developmental pathways in the fungal pathogen Candida albicans, which is a commensal organism that colonizes the mammalian gut and causes disease in the setting of host immunodeficiency. Here we investigate GlcNAc signaling in thermally dimorphic human fungal pathogens, a group of fungi that are highly evolutionarily diverged from C. albicans and cause disease even in healthy individuals. These soil organisms grow as polarized, multicellular hyphal filaments that transition into a unicellular, pathogenic yeast form when inhaled by a human host. Temperature is the primary environmental cue that promotes reversible cellular differentiation into either yeast or filaments; however, a shift to a lower temperature in vitro induces filamentous growth in an inefficient and asynchronous manner. We found GlcNAc to be a potent and specific inducer of the yeast-to-filament transition in two thermally dimorphic fungi, Histoplasma capsulatum and Blastomyces dermatitidis. In addition to increasing the rate of filamentous growth, micromolar concentrations of GlcNAc induced a robust morphological transition of H. capsulatum after temperature shift that was independent of GlcNAc catabolism, indicating that fungal cells sense GlcNAc to promote filamentation. Whole-genome expression profiling to identify candidate genes involved in establishing the filamentous growth program uncovered two genes encoding GlcNAc transporters, NGT1 and NGT2, that were necessary for H. capsulatum cells to robustly filament in response to GlcNAc. Unexpectedly, NGT1 and NGT2 were important for efficient H. capsulatum yeast-to-filament conversion in standard glucose medium, suggesting that Ngt1 and Ngt2 monitor endogenous levels of GlcNAc to control multicellular filamentous growth in response to temperature. Overall, our work indicates that GlcNAc functions as a highly conserved cue of morphogenesis in fungi, which further enhances the significance of this ubiquitous sugar in cellular signaling in eukaryotes.
ISSN:1553-7404
1553-7390
1553-7404
DOI:10.1371/journal.pgen.1003799