Extracellular ammonia at sites of pulmonary infection with Coccidioides posadasii contributes to severity of the respiratory disease.

Coccidioides is the causative agent of a potentially life-threatening respiratory disease of humans. A feature of this mycosis is that pH measurements of the microenvironment of pulmonary abscesses are consistently alkaline due to ammonia production during the parasitic cycle. We previously showed that enzymatically active urease is partly responsible for elevated concentrations of extracellular ammonia at sites of lung infection and contributes to both localized host tissue damage and exacerbation of the respiratory disease in BALB/c mice. Disruption of the urease gene (URE) of Coccidioides posadasii only partially reduced the amount of ammonia detected during in vitro growth of the parasitic phase, suggesting that other ammonia-producing pathways exist that may also contribute to the virulence of this pathogen. Ureidoglycolate hydrolase (Ugh) expressed by bacteria, fungi and higher plants catalyzes the hydrolysis of ureidoglycolate to yield glyoxylate and the release CO2 and ammonia. This enzymatic pathway is absent in mice and humans. Ureidoglycolate hydrolase gene deletions were conducted in a wild type (WT) isolate of C. posadasii as well as the previously generated Δure knock-out strain. Restorations of UGH in the mutant stains were performed to generate and evaluate the respective revertants. The double mutant revealed a marked decrease in the amount of extracellular ammonia without loss of reproductive competence in vitro compared to both the WT and Δure parental strains. BALB/c mice challenged intranasally with the Δugh/Δure mutant showed 90% survival after 30 days, decreased fungal burden, and well-organized pulmonary granulomas. We conclude that loss of both Ugh and Ure activity significantly reduced the virulence of this fungal pathogen.

Gene disruption in Coccidioides using hygromycin or phleomycin resistance markers.

The following transformation protocol is based on homologous recombination that occurs between a gene disruption or gene replacement construct and a target gene of Coccidioides. The DNA constructs employed contain either the gene that encodes for hygromycin B or phleomycin resistance, which are present in the pAN7.1 or pAN8.1 plasmid vectors, respectively. Hygromycin B or phleomycin are used to select for transformants at concentrations that inhibit growth of the parental strain. Coccidioides protoplasts generated from germinated arthroconidia are used for the transformation experiments. The plasmid DNA constructs are taken up by the protoplasts in the presence of calcium and polyethylene glycol. Twenty to 100 transformants/µg DNA can be obtained in each transformation experiment. Approximately 5-10% of the transformation events are homologous recombinations. Coccidioides cells in all developmental stages, including arthroconidia, are multinucleate. Since all Coccidioides nuclei are haploid, only one run of transformation is sufficient to create a mutant strain. However, the transformed protoplasts develop into heterokaryotic cells that typically contain both the parental and mutated nuclei. To isolate a homokaryotic strain, we perform multiple subcultures of the single colonies which contain heterokaryotic cells on selection plates with hygromycin B or phleomycin to enrich for the mutated nuclei. Homokaryotic mutants can be obtained after three to four subcultures of isolated colonies. In this protocol, we describe the methodology for preparation of Coccidioides protoplasts, transformation and isolation of homokaryotic mutants.