O-Mannosylation of Proteins Enables Histoplasma Yeast Survival at Mammalian Body Temperatures.

The ability to grow at mammalian body temperatures is critical for pathogen infection of humans. For the thermally dimorphic fungal pathogen Histoplasma capsulatum, elevated temperature is required for differentiation of mycelia or conidia into yeast cells, a step critical for invasion and replication within phagocytic immune cells. Posttranslational glycosylation of extracellular proteins characterizes factors produced by the pathogenic yeast cells but not those of avirulent mycelia, correlating glycosylation with infection. Histoplasma yeast cells lacking the Pmt1 and Pmt2 protein mannosyltransferases, which catalyze O-linked mannosylation of proteins, are severely attenuated during infection of mammalian hosts. Cells lacking Pmt2 have altered surface characteristics that increase recognition of yeast cells by the macrophage mannose receptor and reduce recognition by the ß-glucan receptor Dectin-1. Despite these changes, yeast cells lacking these factors still associate with and survive within phagocytes. Depletion of macrophages or neutrophils in vivo does not recover the virulence of the mutant yeast cells. We show that yeast cells lacking Pmt functions are more sensitive to thermal stress in vitro and consequently are unable to productively infect mice, even in the absence of fever. Treatment of mice with cyclophosphamide reduces the normal core body temperature of mice, and this decrease is sufficient to restore the infectivity of O-mannosylation-deficient yeast cells. These findings demonstrate that O-mannosylation of proteins increases the thermotolerance of Histoplasma yeast cells, which facilitates infection of mammalian hosts.IMPORTANCE For dimorphic fungal pathogens, mammalian body temperature can have contrasting roles. Mammalian body temperature induces differentiation of the fungal pathogen Histoplasma capsulatum into a pathogenic state characterized by infection of host phagocytes. On the other hand, elevated temperatures represent a significant barrier to infection by many microbes. By functionally characterizing cells lacking O-linked mannosylation enzymes, we show that protein mannosylation confers thermotolerance on H. capsulatum, enabling infection of mammalian hosts.

Selective photoinactivation of Histoplasma capsulatum by water-soluble derivatives chalcones.

Histoplasmosis is a respiratory and systemic disease caused by the dimorphic fungus Histoplasma capsulatum. The clinical features may vary from asymptomatic infections to disseminated severe form depending of patient immunity. The treatment of histoplasmosis can be performed with itraconazole, fluconazole, and in the disseminated forms is used amphotericin B. However, the critical side effects of amphotericin B, the cases of itraconazole therapy failure and the appearance of fluconozole-resistant strains makes necessary the search of new strategies to treat this disease. Antimicrobial photodynamic therapy (aPDT) seems to be a potential candidate once have been show efficacy to inhibit others dimorphic fungi. Although the photosensitizer (PS) chalcone aggregates in biological medium, it has antifungal activity and show a high quantum yield of ROS formation. So, the aim of this study was to obtain the experimental parameters to achieve an acceptable selective chalcone water-soluble derivatives photoinactivation of H. capsulatum comparing with fibroblastic and keratinocytes cells which are the constituents of some potential host tissues. Yeast and cells were incubated with the same chalchones concentrations and short incubation time followed by irradiation with equal dose of light. The best conditions to kill H. capsulatum selectively were very low photosensitizers concentration (1.95µgmL-1) incubated by 15min and irradiated with LED 450nm with 24Jcm-2. Key words: chalcone, Histoplasma capsulatum, aPDT, selectivity.

Dual localization of Mdj1 in pathogenic fungi varies with growth temperature.

Paracoccidioides brasiliensis and P. lutzii are temperature-dependent dimorphic fungi that cause paracoccidioidomycosis (PCM). Previously, we characterized the PbMDJ1 gene. This gene encodes P. brasiliensis chaperone Mdj1, which in yeast is a mitochondrial member of the J-domain family, whose main function is to regulate cognate Hsp70 activities. We produced rabbit polyclonal antibody antirecombinant PbMdj1 (rPbMdj1), which labeled the protein not only in mitochondria but also at the cell wall of P. brasiliensis yeasts of isolate Pb18. Here we used anti-rPbMdj1 in confocal microscopy to localize Mdj1 in Pb18 and other fungal isolates grown at different temperatures. Dual intracellular and cell surface pattern were initially seen in yeast-phase P. brasiliensis Pb3, Pb18 (control), P. lutzii Pb01, and Histoplasma capsulatum. Pb18 and Aspergillus fumigatus hyphae as well as Pb3 pseudo hyphae formed at 36°C were labeled predominantly along the cell surface. Preferential surface localization was observed by 72 h of yeast-mycelium thermotransition. It was interesting to observe that anti-rPbMdj1 concentrated at the surface tip and branching points of A. fumigatus hyphae grown at 36°C, suggesting a role in growth, whereas at 23°C, anti-rPbMdj1 was distributed along the hyphal surface. In Pb3, Pb18, and Pb01 mitochondrial extracts, the antibodies revealed a specific 55-kDa band, which corresponds to the processed Mdj1 size. The presence of Mdj1 on the fungal cell wall suggests that this protein could also play a role in the interaction with the host.

Susceptibility of the human pathogenic fungi Cryptococcus neoformans and Histoplasma capsulatum to gamma-radiation versus radioimmunotherapy with alpha- and beta-emitting radioisotopes.

UNLABELLED: Fungal diseases are difficult to treat in immunosuppressed patients and, consequently, new approaches to therapy are urgently needed. One novel strategy is to use radioimmunotherapy (RIT) with fungal-binding monoclonal antibodies (mAbs) labeled with radionuclides. However, many fungi manifest extreme resistance to gamma-radiation, such that the doses of several thousand gray are required for 90% cell killing, whereas for mammalian cells the lethal dose is only a few gray. We compared the susceptibility of human pathogenic fungi Cryptococcus neoformans (CN) and Histoplasma capsulatum (HC) to external gamma-radiation and to the organism-specific mAbs 18B7 and 9C7, respectively, conjugated to (213)Bi and (188)Re radionuclides. METHODS: CN and HC cells were irradiated with up to 8,000 Gy ((137)Cs source, 30 Gy/min). RIT of CN with (213)Bi- and (188)Re-labeled specific mAb and of HC with (188)Re-labeled specific mAb used 0-1.2 MBq per 10(5) microbial cells. After irradiation or RIT, the cells were plated for colony-forming units (CFUs). Cellular dosimetry calculations were performed, and the pathway of cell death after irradiation was evaluated by flow cytometry. RESULTS: Both CN and HC proved to be extremely resistant to gamma-radiation such that significant killing was observed only for doses of >4,000 Gy. In contrast, these cells were much more susceptible to killing by radiation delivered with a specific mAb, such that a 2-logarithm reduction in colony numbers was achieved by incubating them with (213)Bi- and (188)Re-labeled mAb 18B7 or with (188)Re-9C7 mAb. Dosimetry calculations showed that RIT was approximately 1,000-fold more efficient in killing CN and approximately 100-fold more efficient in killing HC than gamma-radiation. Both gamma-radiation and RIT caused cell death via an apoptotic-like pathway with a higher percentage of apoptosis observed in RIT-treated cells. CONCLUSION: Conjugating a radioactive isotope to a fungal-specific antibody converted an immunoglobulin with no antifungal activity into a microbicidal molecule. RIT of fungal cells using specific antibodies labeled with alpha- and beta-emitting radioisotopes was significantly more efficient in killing CN and HC than gamma-radiation when based on the mean absorbed dose to the cell. These results strongly support the concept of using RIT as an antimicrobial modality.

Selection and characterization of ura5 mutants of Histoplasma capsulatum.

The combined use of non-aggregating Histoplasma capsulatum strains and a defined medium which allows quantitative plating of the yeast phase has allowed us to select 5-fluoroorotic acid (5-FOA)-resistant mutants of this dimorphic fungus. Approximately two-thirds of the 5-FOA-resistant strains were auxotrophic for uracil; all were deficient in orotidine-5'-monophosphate pyrophosphorylase (OMPpase) activity. One class of OMPpase mutant (alpha), which retained a low level of OMPpase activity, was auxotrophic in the yeast phase (37 degrees C) but grew slowly in the mycelial phase (25 degrees C) without exogenous uracil. This phenotype was not due to a temperature-sensitive OMPpase activity. Both wild-type and alpha mutants had a higher OMPpase activity in the mycelial phase than the yeast phase; this increased activity may be sufficient to allow mycelial growth of alpha mutants.

Determination of viability of Histoplasma capsulatum yeast cells grown in vitro: comparison between dye and colony count methods.

The viability of Histoplasma capsulatum yeast cells grown under different conditions was determined by dye tests with Eosin-Y and Janus Green B and by colony counts of cells plated on brain-heart infusion agar supplemented with histoplasma growth factor and bovine serum albumin (BHI-SAG). The test samples included cells grown on brain-heart infusion agar at 37 degrees C for 2-7 days, cells grown in glucose-cysteine broth medium for 1-31 days, and cells grown on brain-heart infusion agar for 3 days at 37 degrees C and then irradiated by ultraviolet light. The colony count indicated that the viability of the yeast cells grown on brain-heart infusion agar for 2 or 3 days varied between 68 and 100% depending on the isolates. The viability, however, dropped from 16 to 29% by day 7. The results of dye tests showed 78 to 99% dye-negative cells among the 2- and 3-day-old cultures while the number of dye-negative cells dropped to 32-36% on day 7. The colony count with the cells grown in the broth culture showed 100% viability until day 7 and dropped significantly by day 9. The results of dye tests showed no correlation with the colony count findings. The survival curve of ultraviolet-irradiated cells determined by colony count showed that irradiation at 180 erg mm-2 killed more than 50% of cells; fewer than 10% of cells survived 360 erg mm-2. The results of the dye test showed no difference between the irradiated and control populations.(ABSTRACT TRUNCATED AT 250 WORDS)