Janet West Batanghari scite author profile

SummaryA highly adapted parasite of macrophages, the yeast phase of Histoplasma capsulatum, survives and proliferates within phagolysosomes, while the mycelial phase exists only as a saprophyte in the soil. We have shown previously that these two phases of Histoplasma differ in their calcium requirements for growth and in the production of a released calcium-binding protein (CBP). Cloning and sequencing the CBP1 gene revealed two introns, a putative signal peptide and potential calcium-binding sites. We also evaluated CBP1 expression by reverse transcription-polymerase chain reaction (RT-PCR) of yeasts grown in broth culture and within two host cell types, a macrophage-like cell line and respiratory epithelial cells. H. capsulatum yeasts expressed CBP1 in all of these settings. Splenocytes from mice immunized with H. capsulatum yeasts responded to purified CBP in proliferation assays, providing evidence for the production of CBP during the infection of mammalian hosts. In addition, after H. capsulatum yeasts were subjected to a calcium-free shock, exogenously added CBP allowed yeasts to incorporate more calcium than yeasts incubated without added CBP. These results suggest that CBP may function to provide yeasts with calcium when they are in a low-calcium environment, such as the phagolysosomal compartment within macrophages.

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Calcium dependence and binding in cultures of Histoplasma capsulatum

Batanghari

Goldman

1997

Infect Immun

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Histoplasma capsulatum is a pathogenic fungus with two distinct morphologies and lifestyles. The saprophytic form of this organism, a mold, thrives in soil and is especially abundant in the Ohio and Mississippi River valleys. Its parasitic counterpart, a yeast, colonizes phagolysosomes of mammalian macrophages. We have observed a major difference in the calcium requirements of the two forms of Histoplasma, potentially implicating the phagolysosome as a calcium-limiting compartment. Deprivation of calcium by the addition of EGTA to culture media inhibited the growth of mycelial H. capsulatum but had no effect on yeast growth in vitro. In addition, yeasts released a calcium-binding protein (CBP) detectable by a 45 CaCl 2 blotting technique. CBP was a major component of yeast culture supernatant and was also detectable by ruthenium red staining, another assay for calcium-binding activity. Conversely, mycelial H. capsulatum did not produce CBP, a finding that correlates with the dependence of mycelia on calcium for growth. We also describe here the purification of CBP from yeast culture supernatant by reversed-phase high-pressure liquid chromatography.

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Bordetella pertussisInfection of Human Monocytes Inhibits Antigen‐Dependent CD4 T Cell Proliferation

Boschwitz¹,

Batanghari²,

Kedem³

et al. 1997

J INFECT DIS

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Human monocytes and macrophages bind Bordetella pertussis through multiple specific receptor-ligand interactions; however, the effect of these interactions on monocyte and macrophage function is not well understood. In an in vitro system, B. pertussis infection of human monocytes significantly impaired T cell proliferation to exogenous antigen at MOIs as low as 1.0. B. pertussis isogenic mutant strains deficient in filamentous hemagglutinin or adenylate cyclase toxin were incapable of proliferation inhibition, suggesting that these virulence-associated factors are essential for this activity. B. pertussis-induced monocyte death alone did not explain these results, nor did differences in intracellular survival. In addition, B. pertussis infection did not significantly alter monocyte phagocytosis of complement-opsonized latex particles, indicating that B. pertussis infection does not globally impair monocyte functions in this system. These results suggest that B. pertussis may be capable of subverting cellular immune defenses in an infected host.

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Probing the Yeast Phase-Specific Expression of the CBP1 Gene in Histoplasma capsulatum

1998

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Histoplasma capsulatum is a pathogenic fungus that exists in two distinct forms. The saprophytic mycelial phase inhabits moist soil environments; once inhaled, hyphae and conidia convert to a unicellular yeast phase that is capable of parasitizing macrophage phagolysosomes. Yeasts cultures, but not mycelial cultures, release large quantities of a calcium-binding protein (CBP) which may be important in calcium acquisition during intracellular parasitism. In this study, we show that the gene encoding CBP (CBP1) is transcriptionally regulated. To identify promoter sequences that are important for yeast phase-specific activity, we created a series of fusions between successively truncatedCBP1 5′ untranslated regulatory sequences and theEschericha coli lacZ gene. The fusions were constructed on a telomeric shuttle plasmid that can replicate autonomously in the fungus. By assaying for β-galactosidase activity from H. capsulatum transformants, we identified a 102-bp region that mediates promoter activation and yeast phase promoter activity. Base pair substitution analysis suggests that the sequences between 839 and 877 bp upstream of the start codon are the most important for this positive regulation.

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