The yeast-phase virulence requirement for α-glucan synthase differs among Histoplasma capsulatum chemotypes

Histoplasma capsulatum strains can be classified into two chemotypes based on cell wall composition. The cell wall of chemotype II yeast contains a layer of α-(1,3)-glucan that masks immunostimulatory β-(1,3)-glucans from detection by the Dectin-1 receptor on host phagocytes. This α-(1,3)-glucan cell wall component is essential for chemotype II Histoplasma virulence. In contrast, chemotype I yeast cells lack α-(1,3)-glucan in vitro, yet they remain fully virulent in vivo. Analysis of the chemotype I α-glucan synthase (AGS1) locus revealed a 2.7-kb insertion in the promoter region that diminishes AGS1 expression. Nonetheless, AGS1 mRNA can be detected during respiratory infection with chemotype I yeast, suggesting that α-(1,3)-glucan could be produced during in vivo growth despite its absence in vitro. To directly test whether AGS1 contributes to chemotype I strain virulence, we prevented AGS1 function by RNA interference and by insertional mutation. Loss of AGS1 function in chemotype I does not impair the cytotoxicity of ags1(-) mutant yeast to cultured macrophages, nor does it affect the intracellular growth of yeast. In a murine model of histoplasmosis, the ags1(-) chemotype I mutant strains show no defect in lung infection or in extrapulmonary dissemination. Together, these studies demonstrate that AGS1 expression is dispensable for chemotype I yeast virulence, in contrast to the case for chemotype II yeast. Despite the absence of cell wall α-(1,3)-glucan, chemotype I yeast can avoid detection by Dectin-1 in a growth stage-dependent manner. This suggests the production of a unique Histoplasma chemotype I factor that, at least partially, circumvents the α-(1,3)-glucan requirement for yeast virulence.     

Variation in Lipid Content of Strains of Histoplasma capsulatum Exhibiting Different Virulence Properties for Mice

Nielsen, H. S., Jr. (Duke University Medical Center, Durham, N.C.). Variation in lipid content of strains of Histoplasma capsulatum exhibiting different virulence properties for mice. J. Bacteriol. 91:273-277. 1966.-Lipid content and virulence were studied in six isolates of Histoplasma capsulatum in an attempt to determine whether or not the two factors could be correlated in this fungus. Virulence was evaluated by injecting dba line 1 male mice intracerebrally with 2.8 x 10(4) infective yeast-phase units and recording organ involvement and spontaneous deaths occurring in a 20-day period. Yeast cells were extracted with mixtures of ethyl alcohol-diethyl ether (3:1, v/v), and the total extractable lipid, as determined by solubility in petroleum ether, was separated into acetone-soluble and phospholipid fractions by acetone precipitation. Neutral lipids were measured directly by weighing, whereas total phospholipids were calculated after the colorimetric determination of phosphorus. The mixed phosphatides of two isolates, differing in virulence, were separated into five fractions by use of a column of silicic acid and Hyflo Super-Cel. In the six isolates studied, neither total extractable lipid, acetone-soluble lipid, nor phospholipid showed a quantitative correlation with virulence. Phosphatidylserine, cephalin, phosphoinositides, and sphingolipids were present in essentially the same amounts in the two strains investigated; however, a lecithin fraction was absent in the less virulent form. These data suggest that the quantity of phosphatidylcholine demonstrated for a given isolate of H. capsulatum may provide some insight as to its virulence, although such a relationship is lacking for total lipid, the acetone-soluble fraction, and the combined phospholipids of yeast-phase growth.     

Mycelial- to yeast-phase transitions of the dimorphic fungi Blastomyces dermatitidis and Paracoccidioides brasiliensis.

The physiological changes that occur during the mycelial- to yeast-phase transitions induced by a temperature shift from 25 to 37 degrees C of cultures of Blastomyces dermatitidis and Paracoccidioides brasiliensis can be divided into three stages. The triggering event is a heat-related insult induced by the temperature shift which results in partial uncoupling of oxidative phosphorylation and declines in cellular ATP levels, respiration rates, and concentrations of electron transport components (stage 1). The cells then enter a stage in which spontaneous respiration ceases (stage 2), and finally, there is a shift into a recovery phase during which transformation to yeast morphology occurs (stage 3). Cysteine is required during stage 2 for the operation of shunt pathways which permit electron transport to bypass blocked portions of the cytochrome system. The mycelial- to yeast-phase transitions of these two fungi are very similar to that of Histoplasma capsulatum. Therefore, these three dimorphic fungal pathogens have evolved parallel mechanisms to adjust to the temperature shifts which induce these mycelial- to yeast-phase transitions.     

Isolation of a New Soluble Antigen from the Yeast Phase of Histoplasma capsulatum

A method is described by which a soluble antigen was prepared from the yeast phase of Histoplasma capsulatum. This soluble preparation had a specificity greater than that of whole-cell yeast-phase antigens. In complement fixation tests with sera from human cases of histoplasmosis, blastomycosis, and coccidioidomycosis, the soluble antigen reacted in 12.1% of 141 tests with heterologous sera, whereas conventional whole-cell yeast antigens reacted in 47.3% of 91 tests with heterologous sera. The reactivities of the two types of antigens with homologous sera were essentially the same.     

VEA1 is required for cleistothecial formation and virulence in Histoplasma capsulatum

Histoplasma capsulatum is a pathogenic fungus dependent on dimorphism for virulence. Among the four described Velvet family genes, two of them, Ryp2 and Ryp3, have been shown to be required for dimorphism. It is known that Velvet A (VeA) is necessary for sexual development and toxin production in Aspergillus nidulans. However, the role of the VeA ortholog in H. capsulatum has not yet been explored. Vea1, H. capsulatum homolog of VeA, was studied to determine its role in cleistothecial formation, dimorphism, and virulence. H. capsulatum Vea1 restores cleistothecial formation and partially restores sterigmatocystin production in an A. nidulans veA deletion strain. Furthermore, silencing VEA1 in an H. capsulatum strain capable of forming cleistothecia abolishes cleistothecial formation. Silenced strains also switch to mycelial phase faster, and show impaired switching to the yeast phase once in mycelial phase. Virulence in mice and macrophages is attenuated in VEA1 silenced strains and silenced strains demonstrate increased sensitivity during growth under acidic conditions. These results indicate that H. capsulatum Vea1 shares a similar role in development as VeA. H. capsulatum is also more susceptible to growth in acidic conditions when VEA1 is silenced, which may contribute to the silenced strains' attenuated virulence in mice and macrophages.     

Monosaccharide and Chitin Content of Cell Walls of Histoplasma capsulatum and Blastomyces dermatitidis

Cell walls of Histoplasma capsulatum and Blastomyces dermatitidis, obtained by mechanical breakage of yeast- and mycelial-phase cultures, were lipid-extracted and then fractionated with ethylenediamine. Unextracted cell walls, lipid-extracted cell walls, and the three fractions resulting from ethylenediamine treatment were examined for monosaccharide and chitin content. The yeast-phase cell walls of five strains of H. capsulatum fell into two categories, designated chemotypes I and II, one of which, chemotype II, was similar to yeast-phase cell walls derived from three strains of B. dermatitidis. H. capsulatum chemotype I cell walls were characterized by lower content of material soluble in ethylenediamine, higher chitin content, and lower monosaccharide content than H. capsulatum chemotype II or B. dermatitidis cell walls. Approximately 80% of the monosaccharides of chemotype I cell walls was combined in forms susceptible to attack by mild acid hydrolysis, compared with about 50% of the monosaccharides of chemotype II and B. dermatitidis. H. capsulatum and B. dermatitidis yeast-phase cell walls could be distinguished, however, by their susceptibility to attack by a crude enzyme system derived from a Streptomyces sp. incubated with chitin as the only carbon source. Both glucose and acetylglucosamine were released from H. capsulatum cell walls, regardless of chemotype, during enzymatic hydrolysis, whereas only acetylglucosamine was released from B. dermatitidis yeast-phase cell walls. Mycelial-phase cell walls of H. capsulatum and B. dermatitidis were characterized by lower content of material soluble in ethylenediamine, higher proportions of mannose, and lower chitin content than their respective yeast phases. Glucose and acetylglucosamine were both released from all mycelial-phase cell walls, whether H. capsulatum or B. dermatitidis, by the crude enzyme system.     

Protein Profiling of the Dimorphic Pathogenic Fungus, Sporothrix schenckii

Sporotrichosis is a common cutaneous mycosis caused by the dimorphic fungus Sporothrix schenckii, which exhibits a temperature-dependent dimorphic switch. At 25°C, it grows in a mycelial phase, while at 37°C, it forms unicellular yeast cells. The formation of yeast cells was thought to be a requisite for the pathogenicity of S. schenckii. To identify fragments that might be related to morphogenesis, whole-cell proteins from the mold and early yeast stages of S. schenckii were analyzed using 2DE. Among thousands of protein molecules displayed, more than 300 showed a differential expression between the two phases. In particular, 24 yeast-specific proteins were identified using MALDI-TOF/MS. One of the most interesting proteins was a hybrid histidine kinase, DRK1, a global regulator of dimorphism and virulence in Blastomyces dermatitidis and Histoplasma capsulatum that was abundant in the yeast phase. Our study introduced a new approach to study dimorphism in S. schenckii, and the data may help us better understand the molecular mechanisms of phase transition.     

Soluble Antigens for Immunofluorescence Detection of Histoplasma capsulatum Antibodies

Soluble antigens from Histoplasma capsulatum in the mycelial and yeast phase were purified by gel filtration, fixed onto paper discs, and employed in an indirect immunofluorescence procedure to detect antibody in sera from individuals infected with H. capsulatum. The elution patterns of crude histoplasmin passed through Sephadex G-200 revealed two minor peaks of protein showing immunofluorescence, complement fixing, and precipitating-antigen activity. A large peak containing the pigment and other low molecular weight materials showed no serological activity. A polysaccharide antigen obtained from fragmented, deproteinized yeast-phase cells was reactive in the fluorescent-antibody test but showed no antigen activity in complement fixation or precipitin tests. Although certain sera from culturally proven cases of blastomycosis, coccidioidomycosis, and cryptococcosis reacted with the purified Histoplasma antigens, preliminary evaluation indicated that the immunofluorescence technique may be of value as a screening procedure for the serodiagnosis of histoplasmosis.     

RNA interference in Histoplasma capsulatum demonstrates a role for alpha-(1,3)-glucan in virulence

Histoplasma capsulatum is a fungal pathogen that causes respiratory and systemic disease by proliferating within macrophages. While much is known about histoplasmosis, only a single virulence factor has been defined, in part because of the inefficiency of Histoplasma reverse genetics. As an alternative to allelic replacement, we have developed a telomeric plasmid-based system for silencing gene expression in Histoplasma by RNA interference (RNAi). Episomal expression of long RNAs that form stem-loop structures triggered gene silencing. To test the effectiveness of RNAi in Histoplasma, we depleted expression of a gfp transgene as well as two endogenous genes, ADE2 and URA5, and showed significant reductions in corresponding gene function. Silencing was target gene specific, stable during macrophage infection and reversible. We used RNAi targeting AGS1 (encoding alpha-(1,3)-glucan synthase) to deplete levels of alpha-(1,3)-glucan, a cell wall polysaccharide. Loss of alpha-(1,3)-glucan by RNAi yielded phenotypes indistinguishable from an AGS1 deletion: attenuation of the ability to kill macrophages and colonize murine lungs. This demonstrates for the first time that alpha-(1,3)-glucan is an important contributor to Histoplasma virulence.     

Virulence of Candida albicans mutants toward larval Galleria mellonella (Insecta, Lepidoptera, Galleridae)

Culture medium affected the virulence of a strain of Candida albicans toward Galleria mellonella larvae, but the yeast growth rates in yeast extract - peptone - dextrose broth and synthetic Galleria serum were not correlated with yeast virulence. Virulent C. albicans grew rapidly in larval serum, whereas, it limited nodulation and continued development in vivo, producing toxins that damaged the hemocytes and fat body. Nonpathogenic yeast-phase cells grew slowly in larval serum but induced extensively melanized nodules in vivo and developed no further. There was no discernible relationship in 14 exo-enzymes between the virulent and avirulent yeast strains and virulence. The avirulent myosin-I-defective yeast cells were rapidly removed from the hemolymph in vivo because of lysozyme-mediated yeast agglutination and the possible binding of the yeast cells by lysozyme and apolipophorin-III. Both lysozyme and apolipophorin-III are proteins that bind beta-1,3-glucan. Finally, insects with nonpathogenic C. albicans exhibited induced immunity and were more resistant to candidiasis from the wild-type yeast cells than were noninduced insects.     

Definition of the extracellular proteome of pathogenic-phase Histoplasma capsulatum

The dimorphic fungal pathogen Histoplasma capsulatum causes respiratory and systemic disease. Within the mammalian host, pathogenic Histoplasma yeast infect, replicate within, and ultimately kill host phagocytes. Surprisingly, few factors have been identified that contribute to Histoplasma virulence. To address this deficiency, we have defined the constituents of the extracellular proteome using LC-MS/MS analysis of the proteins in pathogenic-phase culture filtrates of Histoplasma. In addition to secreted Cbp1, the extracellular proteome of pathogenic Histoplasma yeast consists of 33 deduced proteins. The proteins include glycanases, extracellular enzymes related to oxidative stress defense, dehydrogenase enzymes, chaperone-like factors, and five novel culture filtrate proteins (Cfp's). For independent verification of proteomics-derived identities, we employed RNA interference (RNAi)-based depletion of candidate factors and showed loss of specific proteins from the cell-free culture filtrate. Quantitative RT-PCR revealed the expression of 10 of the extracellular factors was particularly enriched in pathogenic yeast cells as compared to nonpathogenic Histoplasma mycelia, suggesting that these proteins are linked to Histoplasma pathogenesis. In addition, Histoplasma yeast express these factors within macrophages and during infection of murine lungs. As extracellular proteins are positioned at the interface between host and pathogen, the definition of the pathogenic-phase extracellular proteome provides a foundation for the molecular dissection of how Histoplasma alters the host-pathogen interaction to its advantage.     

Preparation and study of an exoantigen of Histoplasma capsulatum for serological reactions.

The aim of this study was to determine the usefulness of a yeast-phase exo-antigen of Histoplasma capsulatum in standard serologic reactions. Three native strains of H.capsulatum which belong to Mycology Center collection were employed. They were maintained in their yeast-phase by weekly subcultures in 2% dextrose broth agar at 37 degrees C. After one week incubation yeast cells were suspended in distilled water containing thimerosal and phenylmethyl sulfonyl fluoride at a concentration of 1:5000. This suspension was left at room temperature for 72 h, then the supernatant was separated by centrifugation and it was lyophilized. Proteins and polysaccharides concentrations were determined. Immunodiffusion (ID) tests were carried out with an antigenic dilution containing 1.4 mg/ml of proteins. This exo-antigen was submitted to SDS-PAGE. Seven protein fractions were detected but only two of them showed antigenic activity against a pool of positive human sera; the molecular weights of these two proteins were 97 kDa and 66 kDa respectively. A metabolic antigen from the mycelial phase of H. capsulatum was used as control. A rabbit gammaglobulin anti-H. capsulatum was prepared and employed as positive control in serologic reactions. The antigenic capacity of ten batches of this exo-antigen was studied by ID and counterimmunoelectrophoresis (CIE) tests using serum samples of 20 hamsters experimentally infected by intracardiac inoculation of the yeast-phase of H. capsulatum. All tests presented positive results after three weeks of the infection. Fifty sera from patients suffering progressive histopasmosis were analyzed: ID, CIE and complement fixation (CF) tests were performed in all cases. HIV negative patients presented 7/7 (100%) positive reactions with the yeast-phase exoantigen and 5/7 (71.4%) with histoplasmin. In HIV positive patients CIE and CF were the most sensitive serologic tests, they gave positive results in 15/43 cases (34.8%) with the yeast-phase exo-antigen and in 7/43 cases (13.9%) with histoplasmin. Sera from 10 patients with paracoccidioidomycosis, aspergillosis and candidiasis respectively were studied by ID with the aim of detecting serologic cross reactions. No cross reaction was detected in these serum samples. This yeast-phase exo-antigen of H. capsulatum is more sensitive than and equally as specific as control histoplasmin.     

Surface localization of the Yps3p protein of Histoplasma capsulatum

The YPS3 gene of Histoplasma capsulatum encodes a protein that is both resident in the cell wall and also released into the culture medium. This protein is produced only during the pathogenic yeast phase of infection and is also expressed differently in H. capsulatum strains that differ in virulence. We investigated the cellular localization of Yps3p. We demonstrated that the cell wall fraction of Yps3p was surface localized in restriction fragment length polymorphism class 2 strains. We also established that Yps3p released into the G217B culture supernatant binds to the surface of strains that do not naturally express the protein. This binding was saturable and occurred within 5 min of exposure and occurred similarly with live and heat-killed H. capsulatum. Flow cytometric analysis of H. capsulatum after enzymatic treatments was consistent with Yps3p binding to chitin, a carbohydrate polymer that is a component of fungal cell walls. Polysaccharide binding assays demonstrated that chitin but not cellulose binds to and extracts Yps3p from culture supernatants.     

An alpha-(1,4)-amylase is essential for alpha-(1,3)-glucan production and virulence in Histoplasma capsulatum

Histoplasma capsulatum is a dimorphic fungus that causes respiratory and systemic disease and is capable of surviving and replicating within macrophages. The virulence of Histoplasma has been linked to cell wall alpha-(1,3)-glucan; however, the role of this polysaccharide during infection, its organization within the cell wall, and its synthesis and regulation remain poorly understood. To identify genes involved in the biosynthesis of alpha-(1,3)-glucan, we employed a forward genetics strategy to isolate physically marked mutants with reduced alpha-(1,3)-glucan. Insertional mutants were generated in a virulent strain of H. capsulatum by optimization of Agrobacterium tumefaciens-mediated transformation. Approximately 90% of these mutants possessed single insertions with no chromosomal rearrangements or deletions in the host genome. To confirm the role and specificity of identified candidate genes, we phenocopied the disrupted locus by either RNA interference or targeted gene deletion. Our findings indicate alpha-(1,3)-glucan production requires the function of the AMY1 gene product, a novel protein with homology to the alpha-amylase family of glycosyl hydrolases, and UGP1, a UTP-glucose-1-phosphate uridylyltransferase which synthesizes UDP-glucose monomers. Loss of AMY1 function attenuated the ability of Histoplasma to kill macrophages and to colonize murine lungs.     

Growth of dimorphic human pathogenicfungi on media containing cycloheximide and chloramphenicol

Summary Studies of 24 strains ofBlastomyces dermatitidis confirmed previously published results that the yeast-phase of this fungus is more sensitive than the mycelial-phase to cycloheximide and chloramphenicol.Studies of 5 strains each ofHistoplasma capsulatum, Paracoccidioides brasiliensis andSporotrichum schenckii show that that these species also have a similar yeast-phase mycelial -phase sensitivity differential in regard to these antibiotics.A cycloheximide resistant strain ofB. dermatitidis was developed from a sensitive strain.The experimental results support the general practice of using 0.5 mg/ml cycloheximide and 0.05 mg/ml chloramphenicol in media for the isolation of the four fungi at 25° C. The results indicate, however, that some strains would not be recovered at 37° C with similar concentrations of these antibiotics.It is recommended that a concentration of not more than 0.2 mg/ml chloramphenicol should be used to preserve sputum which is subsequently to be cultured forB. dermatitidis, Histoplasma capsulatum, Paracoccidioides brasiliensis orS. schenckii.     

Dimorphism in Histoplasma capsulatum: a model for the study of cell differentiation in pathogenic fungi.

Several fungi can assume either a filamentous or a unicellular morphology in response to changes in environmental conditions. This process, known as dimorphism, is a characteristic of several pathogenic fungi, e.g., Histoplasma capsulatum, Blastomyces dermatitidis, and Paracoccidioides brasiliensis, and appears to be directly related to adaptation from a saprobic to a parasitic existence. H. capsulatum is the most extensively studied of the dimorphic fungi, with a parasitic phase consisting of yeast cells and a saprobic mycelial phase. In culture, the transition of H. capsulatum from one phase to the other can be triggered reversibly by shifting the temperature of incubation between 25 degrees C (mycelia) and 37 degrees C (yeast phase). Mycelia are found in soil and never in infected tissue, in contrast to the yeast phase, which is the only form present in patients. The temperature-induced phase transition and the events in establishment of the disease state are very likely to be intimately related. Furthermore, the temperature-induced phase transition implies that each growth phase is an adaptation to two critically different environments. A fundamental question concerning dimorphism is the nature of the signal(s) that responds to temperature shifts. So far, both the responding cell component(s) and the mechanism(s) remain unclear. This review describes the work done in the last several years at the biochemical and molecular levels on the mechanisms involved in the mycelium to yeast phase transition and speculates on possible models of regulation of morphogenesis in dimorphic pathogenic fungi.