Isolation, characterization, and regulation of the Candida albicans ERG27 gene encoding the sterol 3-keto reductase.

The Candida albicans ERG27 gene which encodes the 3-keto reductase enzyme required for sterol C-4 demethylation was isolated and found to encode a 349 amino acid protein that is 60% identical at the amino acid level to the Saccharomyces cerevisiae Erg27p. A C. albicans erg27 null was created in a strain containing an integrated ERG27 rescue cassette under the control of the pMAL2 inducible promoter. The C. albicans erg27 strain was able to grow only in the presence of maltose indicating that the ERG27 gene is essential. The C. albicans erg27 null showed complete loss of both 3-keto reductase and oxidosqualene cyclase (Erg7p) activities compromising all sterol synthesis. These results suggest that Erg27p inhibitors might be effective antifungals. To explore ERG27 regulation, an erg11 null strain was generated. C. albicans erg6 and erg24 mutants were also employed along with the inhibitors, itraconazole and zaragozic acid A, to characterize ERG27 expression using Northern analysis. Expression was increased two- to fourfold in erg11, erg6 and erg24 backgrounds. However, itraconazole which targets Erg11p (lanosterol demethylase) increased ERG27 expression 10-fold and zaragozic acid A which targets the Erg9p (squalene synthase) increased ERG27 expression fivefold. The azole and erg11 results support other observations that azoles may affect non-sterol targets.

Disruption of the Candida albicans CYB5 gene results in increased azole sensitivity.

Sterol synthesis in fungi is an aerobic process requiring molecular oxygen and, for several cytochrome-mediated reactions, aerobically synthesized heme. Cytochrome b(5) is required for sterol C5-6 desaturation and the encoding gene, CYB5, is nonessential in Saccharomyces cerevisiae. Cyb5p and Ncp1p (cytochrome P-450 reductase) appear to have overlapping functions in this organism, with disruptions of each alone being viable. The cytochrome P-450 reductase phenotype has also been shown to demonstrate increased sensitivity to azole antifungals. Based on this phenotype, the CYB5 gene in the human pathogen Candida albicans was investigated to determine whether the cyb5 genotype was viable and would also demonstrate azole sensitivity. Sequential disruption of the CYB5 alleles by direct transformation resulted in viability, presumably conferred by the presence of a third copy of the CYB5 gene. Subsequent disruption procedures with a pMAL2-CYB5 rescue cassette and a CYB5-URA3 blaster cassette resulted in viable cyb5 strains with no third copy. The C. albicans CYB5 gene is concluded to be nonessential. Thus, the essentiality of this gene and whether we observed two or three alleles was dependent upon the gene disruption protocol. The C. albicans cyb5 strains produced a sterol profile containing low ergosterol levels and sterol intermediates similar to that reported for the S. cerevisiae cyb5. The C. albicans cyb5 shows increased sensitivity to azoles and terbinafine, an inhibitor of squalene epoxidase, and, unexpectedly, increased resistance to morpholines, which inhibit the ERG2 and ERG24 gene products. These results indicate that an inhibitor of Cyb5p would not be lethal but would make the cell significantly more sensitive to azole treatment.