Identification of Histoplasma capsulatum Transcripts Induced in Response to Reactive Nitrogen Species

M. Paige Nittler, Davina Hocking-Murray, Catherine K. Foo, and Anita Sil

Department of Microbiology and Immunology, University of California-San Francisco, San Francisco, CA 94143-0414

Monitoring Editor: Mark Solomon

The pathogenic fungus Histoplasmacapsulatum escapes innate immune defenses and colonizes hostmacrophages during infection. After the onset of adaptive immunity,the production of the antimicrobial effector nitric oxide (^•NO)restricts H. capsulatum replication. However, H. capsulatumcan establish persistent infections, indicating that it survivesin the host despite exposure to reactive nitrogen species (RNS).To understand how H. capsulatum responds to RNS, we determinedthe transcriptional profile of H. capsulatum to ^•NO-generatingcompounds using a shotgun genomic microarray. We identified695 microarray clones that were induced $≥$ 4-fold upon nitrosativestress. Because our microarray clones were generated from randomfragments of genomic DNA, they did not necessarily correspondto H. capsulatum ORFs. To identify induced genes, we used high-densityoligonucleotide tiling arrays to determine the genomic boundariesand coding strand of 153 RNS-induced transcripts. Homologuesof these genes in other organisms are involved in iron acquisition,energy production, stress response, protein folding/degradation,DNA repair, and ^•NO detoxification. Ectopic expressionof one of these genes, a P450 nitric oxide reductase homolog,was sufficient to increase resistance of H. capsulatum to RNSin culture. We propose that H. capsulatum uses the pathwaysidentified here to cope with RNS-induced damage during pathogenesis.

Address correspondence to: Anita Sil (sil{at}cgl.ucsf.edu)

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