Daniel Kornitzer scite author profile

SummaryThe ability to acquire iron from host tissues is a major virulence factor of pathogenic microorganisms. Candida albicans is an important fungal pathogen, responsible for an increasing proportion of systemic infections. C. albicans , like many pathogenic bacteria, is able to utilize haemin and haemoglobin as iron sources. However, the molecular basis of this pathway in pathogenic fungi is unknown. Here, we identify a conserved family of plasma membrane-anchored proteins as haem-binding proteins that are involved in haem-iron utilization. We isolated RBT51 as a gene that is sufficient by itself to confer to S. cerevisiae the ability to utilize haemoglobin iron. RBT51 is highly homologous to RBT5 , which was previously identified as a gene negatively regulated by the transcriptional suppressor CaTup1. Rbt5 and Rbt51 are mannosylated proteins that carry the conserved CFEM domain. We find that RBT5 is strongly induced by starvation for iron, and that deletion of RBT5 is by itself sufficient to significantly reduce the ability of C. albicans to utilize haemin and haemoglobin as iron sources. Iron starvation-inducible, antigenically cross-reacting haem-binding proteins are also present in other Candida species that are able to utilize haem-iron, underscoring the conservation of this iron acquisition pathway among pathogenic fungi.

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Regulated degradation of the transcription factor Gcn4.

Kornitzer

et al. 1994

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We report that Gcn4, a yeast transcriptional activator of the bZIP family involved in the regulation of the biosynthesis of amino acids and purines, is rapidly turned over. This degradation is inhibited under conditions of starvation for amino acids. Degradation is also inhibited by single amino acid alterations in a region adjacent to the Gcn4 activation domain. Furthermore, we show that degradation of Gcn4 proceeds through the ubiquitin pathway, a major proteolytic system for cytoplasmic proteins, and is dependent on two specific ubiquitin conjugating enzymes, Cdc34 (Ubc3) and Rad6 (Ubc2). As a first step towards reconstituting the Gcn4 degradation pathway in vitro, we show that purified Cdc34 and Rad6 proteins are able to direct the specific ubiquitination of Gcn4.

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Degradation of the Transcription Factor Gcn4 Requires the Kinase Pho85 and the SCF^CDC4Ubiquitin–Ligase Complex

Meimoun

Holtzman

Weissman

et al. 2000

MBoC

130

192

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Gcn4, a yeast transcriptional activator that promotes the expression of amino acid and purine biosynthesis genes, is rapidly degraded in rich medium. Here we report that SCFCDC4, a recently characterized protein complex that acts in conjunction with the ubiquitin-conjugating enzyme Cdc34 to degrade cell cycle regulators, is also necessary for the degradation of the transcription factor Gcn4. Degradation of Gcn4 occurs throughout the cell cycle, whereas degradation of the known cell cycle substrates of Cdc34/SCFCDC4 is cell cycle regulated. Gcn4 ubiquitination and degradation are regulated by starvation for amino acids, whereas the degradation of the cell cycle substrates of Cdc34/SCFCDC4 is unaffected by starvation. We further show that unlike the cell cycle substrates of Cdc34/SCFCDC4, which require phosphorylation by the kinase Cdc28, Gcn4 degradation requires the kinase Pho85. We identify the critical target site of Pho85 on Gcn4; a mutation of this site stabilizes the protein. A specific Pho85-Pcl complex that is able to phosphorylate Gcn4 on that site is inactive under conditions under which Gcn4 is stable. Thus, Cdc34/SCFCDC4 activity is constitutive, and regulation of the stability of its various substrates occurs at the level of their phosphorylation.

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The high copper tolerance of Candida albicans is mediated by a P-type ATPase

Weissman

Berdicevsky

Cavari

et al. 2000

Proc. Natl. Acad. Sci. U.S.A.

136

167

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The pathogenic yeast Candida albicans has higher resistance than the baker's yeast Saccharomyces cerevisiae to elevated concentrations of copper. To understand the basis of this differential resistance, we performed a functional screen for C. albicans genes involved in copper detoxification. Here, we report the isolation of two such genes: a metallothionein, CaCUP1, and a copper-transporting P-type ATPase, CaCRP1. Both genes are induced by extracellular copper. Gene disruptions indicated that the copper extrusion pump is responsible for the unusual resistance of C. albicans to copper, whereas the metallothionein is responsible for the residual copper resistance of the Cacrp1⌬ mutant. We show further that under acidic and anaerobic conditions, such as prevail in the natural niche of C. albicans, the digestive tract of animals, CaCRP1 function becomes essential for survival in the presence of even very low copper concentrations. These observations suggest that copper in the gastrointestinal tract may present a toxic challenge to which enteric organisms had to adapt.copper toxicity ͉ metallothionein

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An endocytic mechanism for haemoglobin‐iron acquisition in Candida albicans

Weissman

Shemer

Conibear

et al. 2008

Molecular Microbiology

128

165

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SummaryThe fungal pathogen Candida albicans is able to utilize haemin and haemoglobin as iron sources. Haem-iron utilization is facilitated by Rbt5, an extracellular, glycosylphophatidylinositol (GPI)-anchored, haemin-and haemoglobin-binding protein. Here, we show that Rbt5 and its close homologue Rbt51 are short-lived plasma membrane proteins, degradation of which depends on vacuolar activity. Rbt5 facilitates the rapid endocytosis of haemoglobin into the C. albicans vacuole. We relied on recapitulation of the Rbt51-dependent haem-iron utilization in Saccharomyces cerevisiae to identify mutants defective in haemoglobin utilization. Homologues of representative mutants in S. cerevisiae were deleted in C. albicans and tested for haemoglobin-iron utilization and haemoglobin uptake. These mutants define a novel endocytosis-mediated haemoglobin utilization mechanism that depends on acidification of the lumen of the late secretory pathway, on a type I myosin and on the activity of the ESCRT pathway.

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