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Eukaryotic Cell, December 2002, p. 1041-1044, Vol. 1, No. 6
1535-9778/02/$04.00+0     DOI: 10.1128/EC.1.6.1041-1044.2002
Copyright © 2002, American Society for Microbiology. All Rights Reserved.

ROX1 and ERG Regulation in Saccharomyces cerevisiae: Implications for Antifungal Susceptibility

Karl W. Henry,^1, Joseph T. Nickels,² and Thomas D. Edlind^1*

Department of Microbiology and Immunology,¹ Department of Biochemistry, Drexel University College of Medicine, Philadelphia, Pennsylvania 19129²

Received 5 August 2002/ Accepted 19 September 2002

	ABSTRACT

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Yeasts respond to treatment with azoles and other sterol biosynthesis inhibitors by upregulating the expression of the ERG genes responsible for ergosterol production. Previous studies on Saccharomyces cerevisiae implicated the ROX1 repressor in ERG regulation. We report that ROX1 deletion resulted in 2.5- to 16-fold-lower susceptibilities to azoles and terbinafine. In untreated cultures, ERG11 was maximally expressed in mid-log phase and expression decreased in late log phase, while the inverse was observed for ROX1. In azole-treated cultures, ERG11 upregulation was preceded by a decrease in ROX1 RNA. These inverse correlations suggest that transcriptional regulation of ROX1 is an important determinant of ERG expression and hence of azole and terbinafine susceptibilities.

	TEXT

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In fungi, the sterol biosynthesis pathway leads to the formation of ergosterol, with many steps in the pathway being essential (3, 16). Indeed, sterol biosynthesis inhibitors (SBIs) are widely used as antifungal agents in medicine and agriculture. The most important group of SBIs is the azoles, which target the ERG11-encoded enzyme lanosterol 14-demethylase. As clinical use of these agents increased, so did the isolation of azole-resistant mutants, and one of the major resistance mechanisms involves constitutive ERG11 upregulation (18, 20, 24, 29). Furthermore, many strains of Candida albicans and related yeasts display "trailing" growth in azole susceptibility assays (21-23). One potential mechanism for trailing is ERG11 upregulation, and consistent with this idea, it has been shown that exposure of Candida species to SBIs upregulates the expression of ERG11 and other genes in the ergosterol biosynthesis pathway (4, 10). SBI-dependent ERG upregulation has also been demonstrated in the Saccharomyces cerevisiae genetic model (2, 6, 7, 13, 25, 26), and mutations that alter sterol biosynthesis have a similar effect (1, 2, 6, 8, 13, 19, 25, 26).

Previous studies examined regulatory elements within selected ERG promoters (1, 6, 25, 28) and the role of specific transcription factors in ERG expression (13, 28). ERG11 is positively regulated by the heme-activated transcription factor Hap1p and negatively regulated by the oxygen-responsive repressor Rox1p, while ERG9 is similarly regulated by these two factors along with Yap1p and Ino2p-Ino4p. ROX1 is autoregulated and Rox1p has a short half-life (<10 min), which are important characteristics as ROX1 overexpression may be lethal (5, 12, 30). Recently, DNA arrays have identified Rox1p-regulated genes under aerobic and anaerobic conditions (15, 27), confirming that selected ERG genes are regulated by this repressor. We show here that ROX1 is an important determinant of SBI susceptibility and that ROX1 and ERG expression are inversely correlated in response to growth phase and SBI treatment.

Initial studies employed two distinct azoles at concentrations three- to fivefold higher than the drugs' MICs. Log-phase cultures of S. cerevisiae W303-1A (MATaade2-1 can1-100 his3-11,15 leu2-3,112 trp1-1 ura3-1) in YPD medium (1% yeast extract, 2% peptone, 2% dextrose) at 30°C were exposed to fluconazole (20 µg/ml) or miconazole (0.3 µg/ml), and RNA levels were examined by slot blot hybridization as previously described (9). ERG11 expression was upregulated about twofold at 1.5 h and threefold at 3 h by these azoles, while a third drug with a different mechanism of action (the microtubule inhibitor nocodazole) had no effect (Fig. 1). By 5 h the control culture was in late log phase and ERG11 expression had noticeably declined; in contrast, ERG11 expression remained elevated in the presence of miconazole and fluconazole.

View larger version (59K): [in this window] [in a new window]   FIG. 1. Azole-dependent upregulation of ERG11. RNA slot blot hybridization was used to examine ERG11 expression in strain W303-1A following treatment with nocodazole (3 µg/ml), fluconazole (20 µg/ml), miconazole (0.3 µg/ml), or dimethyl sulfide (DMSO; drug vehicle) for the times indicated in the figure. ACT1 expression was employed as a loading control. Cells were cultured in YPD medium. Probes were prepared from PCR products generated with the primers indicated in Table 1.

rox1

View larger version (29K): [in this window] [in a new window]   FIG. 2. ROX1 deletion results in increased expression of multiple ERG genes. RNA slot blot hybridization was used to measure the expression of the indicated ERG genes in strains YJN433 (solid bars) and YJN433 rox1 (stippled bars). RNA was extracted from mid-log-phase cultures (2 x 107 cells/ml) (unshaded bars) or late-log-phase cultures (1 x 108 cells/ml) (shaded bars). Autoradiographs were densitometrically scanned; values shown represent the fold change in RNA relative to the levels in mid-log YJN433 cultures, with normalization to ACT1 RNA levels.

rox1

View this table: [in this window] [in a new window]   TABLE 2. SBI susceptibilities of S. cerevisiae strains and rox1 derivativesa

View larger version (23K): [in this window] [in a new window]   FIG. 3. ERG11 expression is inversely correlated with ROX1 expression. RT-PCR (odd-numbered lanes) was used to examine ROX1, ERG11, and ACT1 expression in untreated (lanes 3 to 11) or fluconazole-treated (9 µg/ml) (lanes 13 to 21) cultures of strain W303-1A. Log-phase cultures (3 x 107 cells per ml) were sampled after incubation for 0 h (lane 1), 0.25 h (lanes 3 and 13), 0.5 h (lanes 5 and 15), 1 h (lanes 7 and 17), 2 h (lanes 9 and 19), or 5 h (lanes 11 and 21). Control reactions which lacked RT (even-numbered lanes) confirmed that the observed bands were not due to genomic DNA contamination. Lane G is a positive control from a reaction mixture containing genomic DNA. Amplification was for 23 (ROX1 and ERG11) or 25 (ACT1) cycles, which was within the logarithmic range. Primers are indicated in Table 1.

The SBI-dependent ERG upregulation demonstrated here and previously is predicted to reduce SBI susceptibility, just as constitutive ERG upregulation (due to currently uncharacterized mutations) contributes to SBI resistance in many clinical isolates. Understanding the mechanism behind this SBI response could lead to much needed improvements in antifungal therapy and a greater understanding of resistance mechanisms. Since disruption of ergosterol biosynthesis by SBI treatment or genetic lesion at any of several different steps in the pathway results in the upregulation of multiple ERG genes, there is likely to be a common mechanism for their transcriptional control. The data presented here, combined with those from previous studies, indicate that the repressor Rox1p is a promising candidate. Potential Rox1p binding sites (31) can be identified upstream of most ERG promoters; specifically, 17 of 22 ERG promoters but only 5 of 22 randomly selected non-ERG promoters include at least one copy (allowing for two mismatches) of the YYYATTGTTCTC consensus binding site (unpublished data).

A C. albicans gene, RFG1, with limited homology to ROX1 was recently reported; however, its deletion did not alter the expression of oxygen-regulated genes but rather blocked hypha-to-yeast morphogenesis (11, 14). C. albicans may therefore regulate its ERG genes by mechanisms that are at least partially distinct from those employed by S. cerevisiae. Other clinically important species, such as Candida glabrata, are more closely related to S. cerevisiae and even more problematic in terms of azole resistance. Examining the role of ROX1 homologs in these species would therefore be of interest.

	ACKNOWLEDGMENTS

 
This study was funded by National Institutes of Health grants AI46768 and AI47718 to T.D.E. and HL67401 to J.T.N.

We thank R. Zitomer for providing strains.

	FOOTNOTES

 
* Corresponding author. Mailing address: Department of Microbiology and Immunology, Drexel University College of Medicine, 2900 Queen Ln., Philadelphia, PA 19129. Phone: (215) 991-8377. Fax: (215) 848-2271. E-mail: edlind{at}drexel.edu.

Present address: The Wistar Institute, Philadelphia, PA 19104.

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