The CTA4 transcription factor mediates induction of nitrosative stress response in the fungal pathogen Candida albicans

I have identified regulatory elements in the pathogen Candida albicans that enable response to nitrosative stress. This dimorphic fungus typically resides in the digestive and genitourinary tracts as an innocuous constituent of the normal microflora but can opportunistically cause superficial mucosal infection. In immunocompromised patients, such infections may also progress to potentially lethal systemic disease. One adaptation that facilitates survival of C. albicans against the hostile environment inside the mammalian body is the ability to resist toxic reactive nitrogen species (RNS) generated by macrophages of the host immune system. Recent studies have shown that exposing C. albicans to nitric oxide, one type of RNS, induces upregulation of the flavohemoglobin Yhb1p. This protein confers protection by enzymatically converting nitric oxide to harmless nitrate, but it is unknown how C. albicans is able to detect nitric oxide in its environment and thus initiate this defense only as needed. I therefore analyzed this problem by incrementally mutating the YHB1 regulatory region to identify a nitric oxide-responsive element (NORE) that is required for NO sensitivity. Five transcription factor candidates of the Zn(II)2-Cys6 family were then isolated by using magnetic beads coated with this DNA element in crude whole cell extracts. Of the five, only deletion of the CTA4 gene prevented induction of YHB1 transcription during nitrosative stress and caused growth sensitivity to the nitric oxide donor DPTA NONOate. The virulence of the cta4Delta deletion mutant was also mildly impaired, slightly more so than that of a yhb1Delta deletion mutant. Cta4p is the first protein found to be necessary for nitric oxide response in C. albicans

Inducible Defense Mechanism against Nitric Oxide in Candida albicans

The yeast Candida albicans is an opportunistic pathogen that threatens patients with compromised immune systems. Immune cell defenses against C. albicans are complex but typically involve the production of reactive oxygen species and nitrogen radicals such as nitric oxide (NO) that damage the yeast or inhibit its growth. Whether Candida defends itself against NO and the molecules responsible for this defense have yet to be determined. The defense against NO in various bacteria and the yeast Saccharomyces cerevisiae involves an NO-scavenging flavohemoglobin. The C. albicans genome contains three genes encoding flavohemoglobin-related proteins, CaYHB1, CaYHB4, and CaYHB5. To assess their roles in NO metabolism, we constructed strains lacking each of these genes and demonstrated that just one, CaYHB1, is responsible for NO consumption and detoxification. In C. albicans, NO metabolic activity and CaYHB1 mRNA levels are rapidly induced by NO and NO-generating agents. Loss of CaYHB1 increases the sensitivity of C. albicans to NO-mediated growth inhibition. In mice, infections with Candida strains lacking CaYHB1 still resulted in lethality, but virulence was decreased compared to that in wild-type strains. Thus, C. albicans possesses a rapid, specific, and highly inducible NO defense mechanism involving one of three putative flavohemoglobin genes