Histoplasma capsulatum modulates the acidification of phagolysosomes.

The phagolysosome is perhaps the most effective antimicrobial site within macrophages due both to its acidity and to its variety of hydrolytic enzymes. Few species of pathogens survive and multiply in these vesicles. However, one strategy for microbial survival would be to induce a higher pH within these organelles, thus interfering with the activity of many lysosomal enzymes. Altering the intravesicular milieu might also profoundly influence antigen processing, antimicrobial drug delivery, and drug activity. Here we report the first example of an organism proliferating within phagolysosomes that maintain a relatively neutral pH for a sustained period of time. We inoculated P388D1 macrophages with fluorescein isothiocyanate (FITC)-labeled Histoplasma capsulatum or zymosan. Using the ratio of fluorescence excitations at 495 and 450 nm, we determined that vesicles containing either virulent or avirulent FITC-labeled H. capsulatum yeasts had a pH one to two units higher than vesicles containing either zymosan or methanol-killed H. capsulatum. The difference in pH remained stable for at least 5.5 h postinoculation. Longer-term studies using cells preincubated with acridine orange indicated that phagolysosomes containing live Histoplasma continued to maintain a relatively neutral pH for at least 30 h. Many agents raise the pH of multiple vesicles within the same cell. In contrast, H. capsulatum affects only the phagolysosome in which it is located; during coinoculation of cells with unlabeled Histoplasma and labeled zymosan, organelles containing zymosan still acidified normally. Similarly, unlabeled zymosan had no influence on the elevated pH of vesicles housing labeled Histoplasma. Thus, zymosan and Histoplasma were segregated into separate phagolysosomes that responded independently to their phagocytized contents. This localized effect might reflect an intrinsic difference between phagosomes housing the two particle types, active buffering by the microbe, or altered ion transport across the phagolysosomal membrane such that acidification is inhibited.

Intracellular parasitism by Histoplasma capsulatum: fungal virulence and calcium dependence.

Histoplasma capsulatum is an effective intracellular parasite of macrophages and causes the most prevalent fungal respiratory disease in the United States. A "dimorphic" fungus, H. capsulatum exists as a saprophytic mold in soil and converts to the parasitic yeast form after inhalation. Only the yeasts secrete a calcium-binding protein (CBP) and can grow in calcium-limiting conditions. To probe the relation between calcium limitation and intracellular parasitism, we designed a strategy to disrupt CBP1 in H. capsulatum using a telomeric linear plasmid and a two-step genetic selection. The resultingcbp1 yeasts no longer grew when deprived of calcium, and they were also unable to destroy macrophages in vitro or proliferate in a mouse model of pulmonary infection.

Mouse rDNA: sequences and evolutionary analysis of spacer and mature RNA regions.

Two regions of mouse rDNA were sequenced. One contained the last 323 nucleotides of the external transcribed spacer and the first 595 nucleotides of 18S rRNA; the other spanned the entire internal transcribed spacer and included the 3' end of 18S rRNA, 5.8S rRNA, and the 5' end of 28S rRNA. The mature rRNA sequences are very highly conserved from yeast to mouse (unit evolutionary period, the time required for a 1% divergence of sequence, was 30 X 10(6) to 100 X 10(6) years). In 18S rRNA, at least some of the evolutionary expansion and increase in G + C content is due to a progressive accretion of discrete G + C-rich insertions. Spacer sequence comparisons between mouse and rat rRNA reveal much more extensive and frequent insertions and substitutions of G + C-rich segments. As a result, spacers conserve overall G + C richness but not sequence (UEP, 0.3 X 10(6) years) or specific base-paired stems. Although no stems analogous to those bracketing 16S and 23S rRNA in Escherichia coli pre-rRNA are evident, certain features of the spacer regions flanking eucaryotic mature rRNAs are conserved and could be involved in rRNA processing or ribosome formation. These conserved regions include some short homologous sequence patterns and closely spaced direct repeats.

Location of the initial cleavage sites in mouse pre-rRNA.

The locations of three cleavages that can occur in mouse 45S pre-rRNA were determined by Northern blot hybridization and S1 nuclease mapping techniques. These experiments indicate that an initial cleavage of 45S pre-rRNA can directly generate the mature 5' terminus of 18S rRNA. Initial cleavage of 45S pre-rRNA can also generate the mature 5' terminus of 5.8S rRNA, but in this case cleavage can occur at two different locations, one at the known 5' terminus of 5.8S rRNA and another 6 or 7 nucleotides upstream. This pattern of cleavage results in the formation of cytoplasmic 5.8S rRNA with heterogeneous 5' termini. Further, our results indicate that one pathway for the formation of the mature 5' terminus of 28S rRNA involves initial cleavages within spacer sequences followed by cleavages which generate the mature 5' terminus of 28S rRNA. Comparison of these different patterns of cleavage for mouse pre-rRNA with that for Escherichia coli pre-rRNA implies that there are fundamental differences in the two processing mechanisms. Further, several possible cleavage signals have been identified by comparing the cleavage sites with the primary and secondary structure of mouse rRNA (see W. E. Goldman, G. Goldberg, L. H. Bowman, D. Steinmetz, and D. Schlessinger, Mol. Cell. Biol. 3:1488-1500, 1983).

Molecular mycology: a genetic toolbox for Histoplasma capsulatum.

Research in medical mycology has traditionally been a mix of exciting biology and frustrating genetics, although the excitement has been steadily increasing as genetic obstacles have been successfully overcome. Now, a variety of fungal pathogens can be studied using molecular techniques derived from classical bacterial and yeast genetics, but with selective and strategic adaptations. Histoplasma capsulatum is the best-studied of the primary pathogens known as 'dimorphic' fungi, and tailored molecular genetic strategies are beginning to reveal a repertoire of genes and gene products intimately associated with pathogenesis.

Phagosome-lysosome fusion in P388D1 macrophages infected with Histoplasma capsulatum.

The issue of whether or not phagocytized Histoplasma capsulatum yeasts evade phagosome-lysosome fusion (P-LF) has been debated by several investigators. To resolve this problem, yet avoid drawbacks associated with the conventional assays of P-LF (electron microscopy and the acridine orange assay), we used fluorescein isothiocyanate-labeled dextran (FITC-dextran) to monitor P-LF in the macrophage-like cell line P388D1.D2. Controls indicated that FITC-dextran could be used to distinguish between evasion of P-LF by Toxoplasma gondii and phagolysosome formation following ingestion of Saccharomyces cerevisiae. Phagosomes containing H. capsulatum clearly fused with FITC-dextran-labeled lysosomes at a rate comparable to that observed for S. cerevisiae. This was true for several strains of H. capsulatum including two avirulent strains derived in this laboratory. Varying the dose of H. capsulatum did not alter the percentage of phagolysosomes formed. Our results indicate that H. capsulatum is one of a small number of organisms which is able to survive in phagolysosomes.

Mucus and surfactant synthesis and secretion by cultured hamster respiratory cells.

Procedures for the selective isolation and cultivation in monolayer of respiratory cells have been developed. This technique requires repeated protease treatment and gradient centrifugation of hamster tracheal or lung tissues and permits the establishment of proliferating cultures of epithelial cells with biologic specialization. Mucus synthesis was monitored in cultured tracheal cells by incorporation of 3H-labeled N-acetyl-D-galactosamine and 14C-serine into glycoprotein as determined by trichloroacetic acid precipitation of growth medium followed by acrylamide gel electrophoresis. For comparative purposes tracheal explants and several established cell lines were also examined. Synthesis and secretion of the glycoprotein macromolecule by tracheal cell monolayers appeared to be regulated by vitamin A since its addition to the culture medium significantly increased both the number of cell-associated granules and glycoprotein secretion. Lung-originated cell cultures were grown to confluence and radio-labeled with 3H-choline in serum-free medium for 24 hr to examine surfactant synthesis. Cell monolayers and growth medium were then extracted by the Folch method, and total radioactive phosphatidylcholine as well as disaturated phosphatidylcholine were determined by thin-layer chromatography and alumina gel fractionation of osmium tetroxide-reactive phospholipid, respectively. Data indicate that these cultures have a marked ability to synthesize and secrete surfactant when compared to other established cell lines. In addition, naturally transformed cells that arose during passage and senescence of the primary cultures were analyzed for their biosynthetic capabilities.

Molecular genetic technology transfer to pathogenic fungi.

Histoplasma capsulatum, the best fungal model for studying intracellular parasitism, is now becoming a model system for evaluating the molecular basis of virulence. This brief review summarizes the available tools and emerging techniques for molecular genetic studies of H. capsulatum and related fungal pathogens.

Structure and functions of the Bordetella tracheal cytotoxin.

Of the various toxins and virulence-related factors produced by Bordetella pertussis, only one has been demonstrated to reproduce the specific respiratory epithelial cytopathology characteristic of the pertussis syndrome. That molecule is tracheal cytotoxin (TCT), which is released by B. pertussis during log phase growth. An HPLC-based method has allowed us to purify TCT from culture supernatants, resulting in a preparation with undetectable levels of endotoxin and which is homogeneous by all analytical criteria, including fast atom bombardment-mass spectrometry (FAB-MS). Exposure to purified TCT specifically damages ciliated epithelial cells, causing ciliostasis and extrusion of these cells. Other species of Bordetella, which generate remarkably similar respiratory tract infections and ciliated cell-specific pathology, produce a chemically identical TCT. Compositional analysis and FAB-MS have unambiguously defined the structure of TCT as N-acetylglucosaminyl-1, 6-anhydro-N-acetylmuramylalanyl-gamma-glutamyl-diaminopimelylalanine+ ++. This particular disaccharide-tetrapeptide composition and arrangement reveals that TCT is apparently formed by cleavage of peptidoglycan. Unlike other gram-negative bacteria, however, B. pertussis seems to be very selective in its release of cell wall fragments: greater than 95% of soluble peptidoglycan in culture supernatants is TCT. The structure of TCT places it in the "muramyl peptide" family, a group of structurally related molecules that are responsible for a diverse array of biological activities. Neisseria gonorrhoeae also releases muramyl peptides (one of which is identical to TCT) that can cause ciliated cell-specific damage like that seen during gonococcal infection of fallopian tube mucosa. In addition, TCT is absolutely identical in structure to FSu, a potent sleep-promoting factor isolated from humans.(ABSTRACT TRUNCATED AT 250 WORDS)

Towards a molecular genetic system for the pathogenic fungus Paracoccidioides brasiliensis.

We herein report the development of a molecular toolbox for the dimorphic fungus Paracoccidioides brasiliensis, specifically a more efficient transformation and a gene expression system. We evaluated several parameters that influence Agrobacterium tumefaciens-mediated transformation (ATMT), such as co-cultivation conditions and host cell susceptibility. Our results show that cellular recovery and air drying of A. tumefaciens:P. brasiliensis mixtures are essential for ATMT. Overall, our data indicate a transformation efficiency of 78+/-9 transformants/co-cultivation (5+/-1 transformants/10(6) target cells). P. brasiliensis GFP-expressing isolates were also constructed by insertion of the GFP gene under the control of several fungal promoters. RT-PCR, epifluorescence microscopy and flow cytometry analysis revealed Gfp visualization for all studied promoters but without significant differences in fluorescence and gene expression levels. Moreover, we present evidence for the occurrence of random single gene copy integration per haploid nuclei and the generation of homokaryon progeny, relevant for the future use in targeted mutagenesis and linking mutations to phenotypes.

Autonomous replication of foreign DNA in Histoplasma capsulatum: role of native telomeric sequences.

Genetic transformation of the dimorphic pathogenic fungus Histoplasma capsulatum can result in chromosomal integration of the transforming DNA or the generation of multicopy linear plasmids carrying the transforming DNA. We showed previously that Escherichia coli plasmids do not replicate autonomously in H. capsulatum without significant modifications, one of which is the in vivo addition of Histoplasma telomeres at the termini of linear DNA. To address the requirements for autonomous replication in H. capsulatum, we constructed a circular E. coli plasmid containing adjacent inverted stretches of Histoplasma telomeric repeats separated by a unique restriction site. The linearized plasmid bearing telomeric termini was maintained in H. capsulatum without modification other than the addition of more telomeric sequence. We recovered the original plasmid in E. coli after removal of the telomeric termini by using engineered restriction sites. Thus, no special Histoplasma modification or sequence other than the telomeres was needed for autonomous replication in H. capsulatum. Additionally, this plasmid provides a shuttle vector that replicates autonomously in E. coli (as a circular plasmid) and in H. capsulatum (as a linear plasmid).

Signalling and cellular specificity of airway nitric oxide production in pertussis.

Bordetella pertussis, the aetiological agent of whooping cough (pertussis), causes selective destruction of ciliated cells of the human airway mucosa. In a hamster tracheal organ culture model, B. pertussis causes identical cytopathology as does tracheal cytotoxin (TCT), a glycopeptide released by the bacterium. The damage caused by B. pertussis or TCT has been shown to be mediated via nitric oxide (NO*). Using immunofluorescence detection of the cytokine-inducible NO synthase (iNOS; NOS type II), we determined that B. pertussis induced epithelial NO* production exclusively within non-ciliated cells. This epithelial iNOS activation could be reproduced by the combination of TCT and endotoxin. However, neither TCT alone nor endotoxin alone was capable of inducing epithelial iNOS. This result mirrors the synergistic activity of TCT and endotoxin exhibited in monolayer cultures of tracheal epithelial cells. Therefore, TCT and endotoxin are both important virulence factors of B. pertussis, combining synergistically to cause the specific epithelial pathology of pertussis.

Selective isolation and culture of a proliferating epithelial cell population from the hamster trachea.

A reliable cell isolation technique was developed to allow the cultivation of cells from the hamster respiratory tract. Repeated thermolysin treatments and gradient centrifugation yielded a cellculture completely free from contamination by fibroblasts. Viable cells could be isolated from as little tissue as a single hamster trachea, but in vitro proliferation occurred only if the hamster was less than 4 months of age. The cultured cells could be repeatedly passaged and subcultured for weeks by employing normal tissue culture techniques. Morphologically, the monolayers appeared to be a homogeneous population of epithelial cells, and successful cloning of freshly isolated single cells resulted in apparently identical cultures. The epiethelial origin of these cells was also suggested by continued growth in minimum essential medium with D-valine substituted for L-valine. The relative ease with which this cell type can be isolated, cultured, and manipulated in vitro should encourage its application as a model of the respiratory epithelium.

Muramyl peptide probes derived from tracheal cytotoxin of Bordetella pertussis.

A novel semisynthetic scheme was developed to couple amine-reactive labeling reagents to the muramyl peptide tracheal cytotoxin (TCT) without affecting a critical amine group. Tracheal cytotoxin, N-acetylglucosaminyl-1, 6-anhydro-N-acetylmuramyl-Ala-gamma-Glu-A2pmAla (A2pm, diaminopimelic acid), is released by Bordetella pertussis, the etiologic agent of whooping cough. This glycopeptide reproduces the specific ciliated cell damage observed in the respiratory tract during B. pertussis infection. To examine binding of TCT to target respiratory cells, we have produced labeled TCT analogs. Structure-function studies have shown that the primary amine of the A2pm side chain is essential for TCT toxicity in respiratory tissue. The methodology described here allows coupling of amine-reactive reagents to TCT without affecting this essential amine. The terminal N-acetylglucosamine ring is opened by oxidation with periodic acid, a dihydrazide linker is coupled to the oxidized ring, and pH control is used to selectively derivatize the free hydrazide with an N-hydroxysuccinimide ester, while the A2pm side-chain amine remains free. Using this method, we have coupled the Bolton-Hunter reagent to TCT, producing a biologically active 125I-labeled TCT analog.

Calcium dependence and binding in cultures of Histoplasma capsulatum.

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 45CaCl2 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.

Development of a genetic transformation system for Histoplasma capsulatum: complementation of uracil auxotrophy.

We have developed a simple and efficient transformation system for the dimorphic fungus Histoplasma capsulatum. Mutants of H. capsulatum defective in orotidine-5'-monophosphate pyrophosphorylase were transformed to prototrophy by the cloned URA5 gene of the filamentous fungus Podospora anserina. Abortive and mitotically stable transformants were obtained. The stable transformants had integrated copies of the plasmid, some in tandem head-to-tail orientation. Free plasmid identical to the transforming plasmid was present in some of the transformants. We obtained a transformation efficiency of up to 30 transformants/micrograms DNA for plasmid pPAura5-1 (9.2 kb). pPW2001, a smaller plasmid (4.7 kb) derived from pPAura5-1, transformed H. capsulatum more efficiently (up to 155 transformants/micrograms DNA).

Histoplasma variation and adaptive strategies for parasitism: new perspectives on histoplasmosis.

This review summarizes the biology of Histoplasma capsulatum in relation to a wide variety of corresponding pathologies in histoplasmosis. Features of these disease syndromes can be explained in part by natural variations within the fungal population and adaptations made by individual organisms to specific environments. H. capsulatum grows as mycelia and conidia in the soil; once inhaled, the organism undergoes a dramatic morphological and physiological conversion to a yeast form. The yeasts proliferate within the phagolysosomes of macrophages, using a variety of specific strategies for intracellular survival. Even avirulent strains or variants are able to avoid being killed by macrophages and instead establish inapparent or persistent infections. The ingested avirulent organisms assume enlarged shapes similar in appearance to those seen in histological sections of tissues from patients with histoplasmosis. Respiratory tract epithelial cells also appear to play a role in persistence: within them yeasts undergo phenotypic switching akin to the phase variation observed in other pathogens. This particular change involves the loss or modification of cell wall alpha-(1,3)-glucan, which is also correlated with the spontaneous appearance of avirulent variants. The repertoire of adaptive responses and natural variations within this species probably evolved from the need to adjust to a wide range of dynamic environments. In combination with the immune status of the host, these characteristics of H. capsulatum appear to influence the epidemiology, extent, and persistence of histoplasmosis.

Autotoxicity of nitric oxide in airway disease.

Though nitric oxide (NO) plays a role in many normal pulmonary functions and is involved in inflammatory and immune responses, it also has cytopathologic potential if not tightly controlled. In Bordetella pertussis infection, NO mediates the respiratory epithelial pathology that is a hallmark of the pertussis syndrome. Tracheal cytotoxin (TCT) released by B. pertussis triggers the production of an inducible NO synthase (iNOS) within tracheal epithelial cells, which produce the NO ultimately responsible for their destruction. The induction of iNOS is most likely due to the cytokine interleukin-1, which is generated intracellularly in response to TCT; this cytokine, like TCT, can reproduce the pathology caused by B. pertussis infection. Similar epithelial destruction is observed in asthma, but the precise mechanism of damage remains incompletely defined. It is possible that NO induced by proinflammatory cytokines in the asthmatic respiratory epithelium plays a central role in the observed epithelial damage in asthma as it does in pertussis.