Adhesion and the ability to form filaments are thought to contribute to the pathogenicity of Candida albicans, the leading cause of fungal disease in immunocompromised patients. Int1p is a C. albicans surface protein with limited similarity to vertebrate integrins. INT1 expression in Saccharomyces cerevisiae was sufficient to direct the adhesion of this normally nonadherent yeast to human epithelial cells. Furthermore, disruption of INT1 in C. albicans suppressed hyphal growth, adhesion to epithelial cells, and virulence in mice. Thus, INT1 links adhesion, filamentous growth, and pathogenicity in C. albicans and Int1p may be an attractive target for the development of antifungal therapies.
One potentially rich source of possible targets for antifungal therapy are those Candida albicans genes deemed essential for growth under the standard culture (i.e., in vitro) conditions; however, these genes are largely unexplored as drug targets because essential genes are not experimentally amenable to conventional gene deletion and virulence studies. Using tetracycline-regulatable promoter-based conditional mutants, we investigated a murine model of candidiasis in which repressing essential genes in the host was achieved. By adding doxycycline to the drinking water starting 3 days prior to (dox − 3D) or 2 days post (dox þ 2D) infection, the phenotypic consequences of temporal gene inactivation were assessed by monitoring animal survival and fungal burden in prophylaxis and acute infection settings. Of 177 selected conditional shutoff strains tested, the virulence of 102 was blocked under both repressing conditions, suggesting that the corresponding genes are essential for growth and survival in a murine host across early and established infection periods. Among these genes were those previously identified as antifungal drug targets (i.e., FKS1, ERG1, and ERG11), verifying that this methodology can be used to validate potential new targets. We also identify genes either conditionally essential or dispensable for in vitro growth but required for survival and virulence, including those in late stage ergosterol synthesis, or early steps in fatty acid or riboflavin biosynthesis. This study evaluates the role of essential genes with respect to pathogen virulence in a large-scale, systems biology context, and provides a general method for gene target validation and for uncovering unexpected antimicrobial targets.animal model | antifungal target | conditional expression | systemic candidiasis | virulence factor
1,8-Dihydroxynaphthalene (1,8-DHN) is a fungal polyketide that contributes to virulence when polymerized to 1,8-DHN melanin in the cell walls of Wangiella dermatitidis, an agent of phaeohyphomycosis in humans.To begin a genetic analysis of the initial synthetic steps leading to 1,8-DHN melanin biosynthesis, a 772-bp PCR product was amplified from genomic DNA using primers based on conserved regions of fungal polyketide synthases (Pks) known to produce the first cyclized 1,8-DHN-melanin pathway intermediate, 1,3,6,8-tetrahydroxynaphthalene. The cloned PCR product was then used as a targeting sequence to disrupt the putative polyketide synthase gene, WdPKS1, in W. dermatitidis. The resulting wdpks1⌬ disruptants showed no morphological defects other than an albino phenotype and grew at the same rate as their black wild-type parent. Using a marker rescue approach, the intact WdPKS1 gene was then successfully recovered from two plasmids. The WdPKS1 gene was also isolated independently by complementation of the mel3 mutation in an albino mutant of W. dermatitidis using a cosmid library. Sequence analysis substantiated that WdPKS1 encoded a putative polyketide synthase (WdPks1p) in a single open reading frame consisting of three exons separated by two short introns. This conclusion was supported by the identification of highly conserved Pks domains for a -ketoacyl synthase, an acetyl-malonyl transferase, two acyl carrier proteins, and a thioesterase in the deduced amino acid sequence. Studies using a neutrophil killing assay and a mouse acute-infection model confirmed that all wdpks1⌬ strains were less resistant to killing and less virulent, respectively, than their wild-type parent. Reconstitution of 1,8-DHN melanin biosynthesis in a wdpks1⌬ strain reestablished its resistance to killing by neutrophils and its ability to cause fatal mouse infections.The zoopathogenic fungus Wangiella (Exophiala) dermatitidis is one of many form species of the Fungi Imperfecti, which are darkly pigmented (dematiaceous) owing to the deposition of 1,8-dihydroxynaphthalene (1,8-DHN) melanin in their cell walls (22,45). This fungus has recently become better known as a paradigm for the causative agents of phaeohyphomycosis and other emerging dermatomycoses of humans, because of its increasing detection as a systemic pathogen in both immunocompetent and immunocompromised patients (34, 35). Moreover, because W. dermatitidis has a well-defined polymorphic nature and a well-characterized cell wall chemistry, it serves as an excellent model for the more than 100 other dematiaceous fungal pathogens of humans (14,37,42).Although dark pigments of fungi are often called melanin without regard to mode of enzymatic synthesis or chemical composition, most syntheses of melanin are attributed to either a phenoloxidase, e.g., laccases and tyrosinases, or a polyketide synthase (Pks) of a pentaketide biosynthetic pathway (52). The phenoloxidases have been found mostly among basidiomycete fungi and are usually composed of soluble enzymes with broad substra...
In this study of the Saccharomyces cerevisiae G protein-coupled receptor Ste2p, we present data indicating that the first extracellular loop (EL1) of the ␣-factor receptor has tertiary structure that limits solvent accessibility and that its conformation changes in a ligand-dependent manner. The substituted cysteine accessibility method was used to probe the solvent exposure of single cysteine residues engineered to replace residues Tyr 101 through Gln 135 of EL1 in the presence and absence of the tridecapeptide ␣-factor and a receptor antagonist. Surprisingly, many residues, especially those at the N-terminal region, were not solvent-accessible, including residues of the binding-competent yet signal transduction-deficient mutants L102C, N105C, S108C, Y111C, and T114C. In striking contrast, two N-terminal residues, Y101C and Y106C, were readily solvent-accessible, but upon incubation with ␣-factor labeling was reduced, suggesting a pheromone-dependent conformational change limiting solvent accessibility had occurred. Labeling in the presence of the antagonist, which binds Ste2p but does not initiate signal transduction, did not significantly alter reactivity with the Y101C and Y106C receptors, suggesting that the ␣-factor-dependent decrease in solvent accessibility was not because of steric hindrance that prevented the labeling reagent access to these residues. Based on these and previous observations, we propose a model in which the N terminus of EL1 is structured such that parts of the loop are buried in a solventinaccessible environment interacting with the extracellular part of the transmembrane domain bundle. This study highlights the essential role of an extracellular loop in activation of a G protein-coupled receptor upon ligand binding. G protein-coupled receptors (GPCRs)3 are ubiquitous in eukaryotes and have been found in a diversity of organisms ranging from yeast to humans. In most eukaryotes, GPCRs comprise 1-2% of the total genes in the genome (1) and participate in virtually all aspects of cellular physiology, including hormonal responses, neuronal transmission, and mediation of taste, smell, and vision (2). Modulation of GPCR function is a major pharmaceutical target, currently accounting for Ͼ30% of all drugs prescribed (3-5). Thus a thorough understanding of the nature of the receptor-ligand interaction and subsequent signal transduction is essential for the development of more effective and safer therapeutic agents.The structural hallmarks of this diverse collection of receptors are seven membrane-spanning domains linked by extracellular and intracellular loops, oriented such that the N terminus is external to the cell and the C terminus is internal. Although the structure-function relationships in the membrane-spanning domains and the intracellular loop regions have been well examined in many GPCRs (6 -11), few studies have focused on the importance of the extracellular loop structures and their role in receptor activation. In those studies where the extracellular domains were studied in deta...
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