Deletion of the Candida albicans PIR32 Results in Increased Virulence, Stress Response, and Upregulation of Cell Wall Chitin Deposition

Candida albicans is a common opportunistic pathogen that causes a wide variety of diseases in a human immunocompromised host leading to death. In a pathogen, cell wall proteins are important for stability as well as for acting as antigenic determinants and virulence factors. Pir32 is a cell wall protein and member of the Pir protein family previously shown to be upregulated in response to macrophage contact and whose other member, Pir1, was found to be necessary for cell wall rigidity. The purpose of this study is to characterize Pir32 by generating a homozygous null strain and comparing the phenotype of the null with that of the wild-type parental strain as far as filamentation, virulence in a mouse model of disseminated candidiasis, resistance to oxidative stress and cell wall disrupting agents, in addition to adhesion, biofilm capacities, and cell wall chitin content. Our mutant was shown to be hyperfilamentous, resistant to sodium dodecyl sulfate, hydrogen peroxide, sodium chloride, and more virulent in a mouse model when compared to the wild type. These results were unexpected, considering that most cell wall mutations weaken the wall and render it more susceptible to external stress factors and suggests the possibility of a cell surface compensatory mechanism. As such, we measured cell wall chitin deposition and found a twofold increase in the mutant, possibly explaining the above-observed phenotypes.     

Melanin Externalization in Candida albicans Depends on Cell Wall Chitin Structures

The fungal pathogen Candida albicans produces dark-pigmented melanin after 3 to 4 days of incubation in medium containing l-3,4-dihydroxyphenylalanine (l-DOPA) as a substrate. Expression profiling of C. albicans revealed very few genes significantly up- or downregulated by growth in l-DOPA. We were unable to determine a possible role for melanin in the virulence of C. albicans. However, we showed that melanin was externalized from the fungal cells in the form of electron-dense melanosomes that were free or often loosely bound to the cell wall exterior. Melanin production was boosted by the addition of N-acetylglucosamine to the medium, indicating a possible association between melanin production and chitin synthesis. Melanin externalization was blocked in a mutant specifically disrupted in the chitin synthase-encoding gene CHS2. Melanosomes remained within the outermost cell wall layers in chs3Δ and chs2Δ chs3Δ mutants but were fully externalized in chs8Δ and chs2Δ chs8Δ mutants. All the CHS mutants synthesized dark pigment at equivalent rates from mixed membrane fractions in vitro, suggesting it was the form of chitin structure produced by the enzymes, not the enzymes themselves, that was involved in the melanin externalization process. Mutants with single and double disruptions of the chitinase genes CHT2 and CHT3 and the chitin pathway regulator ECM33 also showed impaired melanin externalization. We hypothesize that the chitin product of Chs3 forms a scaffold essential for normal externalization of melanosomes, while the Chs8 chitin product, probably produced in cell walls in greater quantity in the absence of CHS2, impedes externalization.Candida albicans is a major opportunistic fungal human pathogen that causes a wide variety of infections (9, 68). In healthy individuals C. albicans resides as a commensal within the oral cavity and gastrointestinal and urogenital tracts. However, in immunocompromised hosts, C. albicans causes infections ranging in severity from mucocutaneous infections to life-threatening disseminated diseases (9, 68). Research into the pathogenicity of C. albicans has revealed a complex mix of putative virulence factors (7, 60), perhaps reflecting the fine balance this species strikes between commensal colonization and opportunistic invasion of the human host.Melanins are biological pigments, typically dark brown or black, formed by the oxidative polymerization of phenolic compounds. They are negatively charged hydrophobic molecules with high molecular weights and are insoluble in both aqueous and organic solvents. Their insolubility makes melanins difficult to study, and no definitive structure has yet been found for them; they probably represent an amorphous mixture of polymers (35). There are various types of melanin in nature, including eumelanin and phaeomelanin (76). Two principal types of melanin are found in the fungal kingdom. The majority are 1.8-dihydroxynapthalene (DNH) melanins synthesized from acetyl-coenzyme A (CoA) via the polyketide pathway (5). DNH melanins have been found in a wide range of opportunistic fungal pathogens of humans, including dark (dematiaceous) molds, such as Cladosporium, Fonsecaea, Phialophora, and Wangiella species, and as conidial pigments in Aspergillus fumigatus and Aspergillus niger (41, 80, 87, 88). However, several other fungal pathogens, including Blastomyces dermatitidis, Coccidioides posadasii, Cryptococcus neoformans, Histoplasma capsulatum, Paracoccidioides brasiliensis, and Sporothrix schenckii, produce eumelanin (3,4-dihydroxyphenylalanine [DOPA]-melanin) through the activity of a polyphenol oxidase (laccase) and require an exogenous o-diphenolic or p-diphenolic substrate, such as l-DOPA (16, 30, 63,–65, 67, 79).The production of melanin in humans and other mammals is a function of specialized cells called melanocytes. Particles of melanin polymers, sometimes, including more than one melanin type, are built up within membrane-bound organelles called melanosomes (76), and these are actively transported along microtubules to the tips of dendritic outgrowths of melanocytes, from where they are transferred to neighboring cells (32, 81). The mechanism of intercellular transfer of melanosomes has not yet been established, but the export process probably involves the fusion of cell and vesicular membranes rather than secretion of naked melanin (82). In pathogenic fungi, melanins are often reported to be associated with or “in” the cell wall (35, 36, 50, 72, 79). However, there is variation between species: the melanin may be located external to the wall, e.g., in P. brasiliensis (79); within the wall itself (reviewed in reference 42); or as a layer internal to the wall and external to the cell membrane, e.g., in C. neoformans (22, 45, 85). However, mutants of C. neoformans bearing disruptions of three CDA genes involved in the biosynthesis of cell wall chitosan, or of CHS3, encoding a chitin synthase, or of CSR2, which probably regulates Chs3, all released melanin into the culture supernatant, suggesting a role for chitin or chitosan in retaining the pigment polymer in its normal intracellular location (3, 4). However, vesicles externalized from C. neoformans cells also show laccase activity (21), so the effect of chitin may be on vesicle externalization rather than on melanin itself. Internal structures compatible with mammalian melanosomes have been observed in Cladosporium carrionii (73) and in Fonsecaea pedrosoi (2, 26). Remarkably, F. pedrosoi also secretes melanin and locates the polymer within the cell wall (1, 2, 25, 27, 74).Melanization has been found to play an important role in the virulence of several human fungal pathogens, such as C. neoformans, A. fumigatus, P. brasiliensis, S. schenckii, H. capsulatum, B. dermatitidis, and C. posadasii (among recent reviews are references 29, 42, 62, 74, and 79). From these and earlier reviews of the extensive literature, melanin has been postulated to be involved in a range of virulence-associated properties, including interactions with host cells; protection against oxidative stresses, UV light, and hydrolytic enzymes; resistance to antifungal agents; iron-binding activities; and even the harnessing of ionizing radiation in contaminated soils (15). The most extensively studied fungal pathogen for the role of melanization is C. neoformans, which possesses two genes, LAC1 and LAC2, encoding melanin-synthesizing laccases (52, 69, 90). It has been known since early studies with naturally occurring albino variants of C. neoformans (39) that melanin-deficient strains are attenuated in mouse models of cryptococcosis. Deletion of both the LAC1 and LAC2 genes reduced survival of C. neoformans in macrophages (52), and a study based on otherwise isogenic LAC1⁺ and LAC1⁻ strains confirmed the importance of LAC1 in experimental virulence (66). Other genes in the regulatory pathway for LAC1 are similarly known to be essential to virulence (12, 84).C. albicans has been shown to produce melanin with DOPA as a substrate for production of the polymer (53). The cells could be treated with hot acids to produce typical melanin “ghosts,” and antibodies specific for melanin reacted with the fungal cells by immunohistochemistry with tissues from experimentally infected mice, demonstrating that C. albicans produces melanin in vivo (53). However, no candidate genes encoding laccases have yet been identified in the C. albicans genome (http://www.candidagenome.org/). In this study, we investigated the production of melanin by C. albicans and showed that its normal externalization from wild-type cells, including formation of melanosomes, can be altered to an intracellular and intrawall location by mutation of genes involved in chitin synthesis. C. albicans has four genes encoding chitin synthase enzymes. CHS1 is an essential gene under normal conditions (59), and its product is the main enzyme involved in septum formation (83). Chs3 forms the bulk of the chitin in the cell wall and the chitinous ring at sites of bud emergence (8, 51, 57), while Chs2 contributes to differential chitin levels found between yeast and hyphal forms of the fungus, and Chs8 influences the architecture of chitin microfibrils (43, 51, 55, 57, 58). We found that melanin externalization was unaffected in a chs8Δ mutant but was reduced or abrogated in chs2Δ and chs3Δ mutants. Expression profiles of melanin-producing cells grown in the presence of l-DOPA did not identify any potential laccase-synthesizing genes.     

The Calcium Channel Blocker Verapamil Inhibits Oxidative Stress Response in Candida albicans

Candida albicans is a common opportunistic fungal pathogen, causing both superficial candidiasis and life-threatening systemic infections in immune-compromised individuals. Calcium signaling is responsible for this pathogen in responding to several stresses, such as antifungal drugs, alkaline pH and membrane-perturbing agents. Our recent study revealed that it is also involved in oxidative stress response. In this study, we investigated the effect of verapamil, an L-type voltage-gated calcium channel blocker, on oxidative stress response in this fungus. The addition of verapamil resulted in increased sensitivity to the oxidative agent H₂O₂, which is associated with a decrease of calcium fluctuation under the stress. Moreover, this agent caused enhanced oxidative stress, with increased levels of ROS and enhanced dysfunction of the mitochondria under the oxidative stress. Further investigations in SOD activity, GSH contents and expression of oxidative stress response-related genes indicated that the effect of verapamil is related to the repression of oxidative stress response. Our findings demonstrated that verapamil has an inhibitory effect on oxidative stress response, confirming the relationship between calcium signaling and oxidative stress in C. albicans. Therefore, calcium channels may be potential targets for therapy to enhance the efficacy of oxidative stress against C. albicans-related infections.     

The White Cell Response to Pheromone Is a General Characteristic of Candida albicans Strains

For Candida albicans, evidence has suggested that the mating pheromones activate not only the mating response in mating-competent opaque cells but also a unique response in mating-incompetent white cells that includes increased cohesion and adhesion, enhanced biofilm formation, and expression of select mating-related and white cell-specific genes. On the basis of a recent microarray analysis comparing changes in the global expression patterns of white cells in two strains in response to α-pheromone, however, skepticism concerning the validity and generality of the white cell response has been voiced. Here, we present evidence that the response occurs in all tested media (Lee's, RPMI, SpiderM, yeast extract-peptone-dextrose, and a synthetic medium) and in all of the 27 tested strains, including a/a and α/α strains, derivatives of the common laboratory strain SC5314, and representatives from all of the five major clades. The white cell response to pheromone is therefore a general characteristic of MTL-homozygous strains of C. albicans.     

Mutants in the Candida glabrata Glycerol Channels Are Sensitized to Cell Wall Stress

Many fungal species use glycerol as a compatible solute with which to maintain osmotic homeostasis in response to changes in external osmolarity. In Saccharomyces cerevisiae, intracellular glycerol concentrations are regulated largely by the high osmolarity glycerol (HOG) response pathway, both through induction of glycerol biosynthesis and control of its flux through the plasma membrane Fps1 glycerol channel. The channel activity of Fps1 is also controlled by a pair of positive regulators, Rgc1 and Rgc2. In this study, we demonstrate that Candida glabrata, a fungal pathogen that possesses two Fps1 orthologs and two Rgc1/-2 orthologs, accumulates glycerol in response to hyperosmotic stress. We present an initial characterization of mutants with deletions in the C. glabrata FPS1 (CAGL0C03267 [www.candidagenome.org]) and FPS2 (CAGL0E03894) genes and find that a double mutant accumulates glycerol, experiences constitutive cell wall stress, and is hypersensitive to treatment by caspofungin, an antifungal agent that targets the cell wall. This mutant is cleared more efficiently in mouse infections than is wild-type C. glabrata by caspofungin treatment. Finally, we demonstrate that one of the C. glabrata RGC orthologs complements an S. cerevisiae rgc1 rgc2 null mutant, supporting the conclusion that this regulatory assembly is conserved between these species.     

The Electrostatic Nature of the Cell Surface of Candida albicans: A Role in Adhesion

Jones, L., and O'Shea, P. 1994. The electrostatic nature of the cell surface of Candida albicans: A role in adhesion. Experimental Mycology 18, 111-120. The yeast form of Candida albicans is subjected to particle electrophoresis in a variety of media, in order to determine whether the cell surface of the fungus conforms to a simple electrostatic system. It is found that C. albicans behaves essentially as a simple charged colloidal system. Similar measurements were performed with various glass surfaces in order to identify whether electrostatic interactions have any bearing on fungal adhesion. It was found that under all the circumstances studied, the fungi and glass were electronegative; the degree of adhesion was found to be affected by the magnitude of the coulombic repulsion. Significant adhesion still occurred, however, even when the coulombic repulsion was a maximum; this was taken to indicate that the fungal surface possesses other nonelectrostatic forces which are attractive. Both the electrostatic repulsive and the nonelectrostatic (presumably nonpolar) forces are considered to play a role in the adhesion of fungi to each other, to artificial surfaces such as glass, and presumably to other surfaces which occur in living systems.     

Gut Bacteria Shape Intestinal Microhabitats Occupied by the Fungus Candida albicans

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Transverse Septum Formation in Budding Cells of the Yeastlike Fungus Candida albicans

Septum formation is initiated in Candida albicans by an electron transparent primary septum, which is then thickened on both sides to form secondary septa. Primary and secondary septa are incorporated into the bud scar, and secondary septum material only is incorporated into the birth scar.     

Transcriptional Analysis of the Candida albicans Cell Cycle

We have examined the periodic expression of genes through the cell cycle in cultures of the human pathogenic fungus Candida albicans synchronized by mating pheromone treatment. Close to 500 genes show increased expression during the G1, S, G2, or M transitions of the C. albicans cell cycle. Comparisons of these C. albicans periodic genes with those already found in the budding and fission yeasts and in human cells reveal that of 2200 groups of homologous genes, close to 600 show periodicity in at least one organism, but only 11 are periodic in all four species. Overall, the C. albicans regulatory circuit most closely resembles that of Saccharomyces cerevisiae but contains a simplified structure. Although the majority of the C. albicans periodically regulated genes have homologues in the budding yeast, 20% (100 genes), most of which peak during the G1/S or M/G1 transitions, are unique to the pathogenic yeast.