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J. Biol. Chem., Vol. 279, Issue 28, 29513-29518, July 9, 2004

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Transcription of the Yeast Iron Regulon Does Not Respond Directly to Iron but Rather to Iron-Sulfur Cluster Biosynthesis^*

Opal S. Chen, Robert J. Crisp¶, Martin Valachovic||, Martin Bard||, Dennis R. Winge**, and Jerry Kaplan

From the Department of Pathology, School of Medicine, University of Utah, Salt Lake City, Utah 84132, ^||Department of Biology, Indiana University-Purdue University Indianapolis, Indianapolis, Indiana 46202-5132, and ^**Departments of Medicine and Biochemistry, University of Utah, Salt Lake City, Utah 84132

Received for publication, March 23, 2004 , and in revised form, April 28, 2004.

	ABSTRACT

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Saccharomyces cerevisiae responds to iron deprivation by increased transcription of the iron regulon, including the high affinity cell-surface transport system encoded by FET3 and FTR1. Here we demonstrate that transcription of these genes does not respond directly to cytosolic iron but rather to the mitochondrial utilization of iron for the synthesis of iron-sulfur (Fe-S) clusters. We took advantage of a mutant form of an iron-dependent enzyme in the sterol pathway (Erg25-2p) to assess cytosolic iron levels. We showed that disruption of mitochondrial Fe-S biosynthesis, which results in excessive mitochondrial iron accumulation, leads to transcription of the iron transport system independent of the cytosolic iron level. There is an inverse correlation between the activity of the mitochondrial Fe-S-containing enzyme aconitase and the induction of FET3. Regulation of transcription by Fe-S biosynthesis represents a mechanism by which cellular iron acquisition is integrated with mitochondrial iron metabolism.

	INTRODUCTION

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High affinity iron uptake in Saccharomyces cerevisiae is mediated by a transport system comprising the multicopper oxidase Fet3p and the transmembrane permease Ftr1p (1). Genes that encode these proteins are part of an iron regulon in which transcription is activated by Aft1p. Aft1p is cytosolic when iron is replete and translocates to the nucleus when iron is limited (2). It has been speculated that Aft1p responds to cytosolic levels of elemental iron, as conditions that lower cytosolic iron result in increased transcription of the iron regulon. Binding of iron to Aft1p, however, has not been demonstrated.

Mutations that affect mitochondrial Fe-S biosynthesis or export result in increased cellular and mitochondrial iron as a result of decreased mitochondrial iron efflux (3). It has been thought that the increase in mitochondrial iron occurs at the expense of cytosolic iron, and the decrease in cytosolic iron is responsible for the increase in Aft1p-mediated transcription of the iron regulon (3, 4). Herein, we demonstrate that activation of Aft1p does not directly respond to cytosolic iron. Using a novel measure of cytosolic iron, we showed that activation of the iron regulon can occur when cytosolic iron levels are high. We further demonstrated that activation of the iron regulon is controlled by the synthesis of Fe-S clusters, which in yeast is localized within mitochondria. Our studies revealed that cellular iron acquisition is coordinated with the mitochondrial use of iron.

	MATERIALS AND METHODS

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Yeast Strains—All yeast strains used in this study were derived from a W303 background strain. The following yeast strains have been described previously: DY150 (Mata ade2-1 his3-11 leu2-3,112 trp1-1 ura3-52 can1-100(oc)), METYFH1 (Mat ade2-1 his3-11 yfh1::HIS3 leu2-3,112 trp1-1 ura3-52 can1-100(oc), pMET3YFH1 [URA3]) (5), METNFS1 (Mat ade2-1 his3-11 nfs1::HIS3 leu2-3,112 trp1-1 ura3-52 can1-100(oc), pMET3NFS1 [URA3]) (3), and erg25-2 (Mat erg25-2 ade2-1 his3-11 leu2-3,112 trp1-1 ura3-52 can1-100(oc)) (6). DNA transformations of Escherichia coli and S. cerevisiae were performed by standard procedures (7). An erg25-2 METCCC1 strain was generated by transforming pMET3CCC1 (5) into the erg25-2 strain. An erg25-2 METYFH1 strain was generated by crossing the METYFH1 strain with an erg25-2 strain. The erg25-2 METNSF1 strain was generated by crossing the METNSF1 strain with an erg25-2 strain. Sporulation and dissection of diploids generated the haploid strains erg25-2 METYFH1 and erg25-2 METNFS1. To generate methionine-regulated genes, the promoter region of MET3 was fused in-frame to the indicated open reading frame (3). Gene expression was achieved by incubating the strain that contained the construct in methionine-free medium. To turn the methionine-regulated gene off, 10-fold normal medium methionine was supplemented to the medium (final concentration 0.56 mg/ml). To generate strains carrying a FET3-LacZ reporter construct, a plasmid containing the FET3-LacZ reporter was integrated at the HO locus (8). Strains carrying a PGK1-regulated FET3/FTR1 were generated by integrating a plasmid (pFET3/FTR1) at the ade2-1 locus (9).

Media—Yeast strains were grown in rich medium (YPD; 1% yeast extract, 2% peptone, 2% dextrose) or in synthetic complete medium (CM; 0.7% yeast nitrogen base without amino acids, 2% dextrose, and 0.12% amino acid drop-out mix). The media were made iron-limited by the addition of 80 µM bathophenanthroline disulfonate (BPS)¹ to YPD and 40 µM BPS to the CM. To vary the concentration of media iron, FeSO₄ (50 mM stock in 0.1 M HCl) was added back to the media at the indicated concentrations.

Experimental Protocols—Cells were iron-loaded by the addition of 50 µM FeSO₄ in the presence of 1 mM ascorbate for 30 min. Ascorbate-reduced iron is the substrate for Fet3p/Ftr1p and bypasses the rate-limiting cell-surface reductases. -Galactosidase was assayed as described by Li et al. (10), sterols were extracted and analyzed by gas chromatography as described by Kennedy and Bard (11), and aconitase was assayed as described by Chen et al. (3).

	RESULTS

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Decreased Cytosolic Iron Levels Induce the Iron Regulon—We developed a system in which we could determine the effect of cytosolic iron on induction of the iron transport system. To increase cellular iron, we utilized an integrating plasmid that contains FET3/FTR1 under the control of a constitutive iron-independent promoter (PGK1) (9). For these and other experiments, ascorbate-reduced iron was employed to bypass the need for a ferrireductase to provide reduced iron, which is the substrate for the Fet3p/Ftr1p transport system. Increased expression of FET3/FTR1 led to a >3-fold increase in cellular iron uptake above that seen in cells where the endogenous FET3/FTR1 is maximally induced (8). To determine whether the increase in iron due to the integrated FET3/FTR1 plasmid was detrimental to cell survival (i.e. increased oxidative damage), we examined cell growth in response to iron loading. Cells containing the integrated FET3/FTR1 plasmid that had been incubated with iron grew as well as cells without the plasmid or cells with the plasmid not exposed to iron (data not shown). To determine the effect of iron loading on induction of the iron regulon, cells (containing a FET3-LacZ reporter construct) both with and without the integrated FET3/FTR1 plasmid were exposed to ascorbate-reduced iron for 10 min and then incubated in media without bioavailable iron. As might be expected from the increased cytosolic iron, the cells that were exposed to iron and expressing higher levels of FET3/FTR1 showed a lag in the induction of the FET3-LacZ reporter construct (Fig. 1A).

View larger version (19K): [in this window] [in a new window]   FIG. 1. Increased cellular iron delays expression of iron uptake genes. A, wild-type and FET3/FTR1 cells with the FET3-LacZ reporter construct were iron-loaded, washed, and grown in iron-limited media for the indicated times. The cells were harvested, and -galactosidase was assayed. B, the indicated strains were incubated with iron before the induction of CCC1 by incubation in methionine-free media. The cells were incubated in iron-replete media through the time course of the experiment. At the specified times, the cells were harvested, and -galactosidase activity was determined.

Expression of the iron transport system has often been used as a measure of cytosolic iron. We developed an alternative method of measuring cytosolic iron. To examine the relationship between iron and the expression of iron transport genes, we utilized strains that contained a mutant allele of ERG25, erg25-2, which is responsive to cytosolic iron (6). ERG25 encodes C-4 methyl sterol oxidase, an enzyme essential for ergosterol biosynthesis. Erg25p has been shown to localize to the endoplasmic reticulum and contains histidine motifs thought to coordinate oxo-diiron as a catalytic group (6). ERG25-2 has a point mutation that appears to result in an enzyme with a lower affinity for iron. When cytosolic iron levels are low, iron is released from the mutant enzyme abolishing its catalytic activity. Thus, enzyme activity is a reflection of cytosolic iron concentration. Under low iron conditions, the erg25-2 strain does not synthesize ergosterol and accumulates the ergosterol intermediate 4,4-dimethylzymosterol (4,4-DMZ). Initially, we constructed a standard curve where we assayed both FET3-LacZ induction and the sterol profile in erg25-2 cells with respect to varying concentrations of media iron. Decreased media iron resulted in an induction in -galactosidase activity, a decrease in ergosterol biosynthesis, and an increase in 4,4-DMZ (Fig. 2). This result confirms previous work (6) showing that ergosterol synthesis in cells with the erg25-2 allele responds to cytosolic iron. Consequently, the levels of the sterol intermediate 4,4-DMZ can be used as a measure of cytosolic iron, as the concentration of 4,4-DMZ varies inversely with cytosolic iron.

View larger version (15K): [in this window] [in a new window]   FIG. 2. Standard curve for FET3 induction and sterol profile of erg25-2 strain grown in varying iron media. erg25-2 METYFH1 cells were grown in media permitting the expression of YFH1. The media were made iron-limited by the addition of 40 µM BPS, and specified amounts of FeSO4 were supplemented back to the media. The cells were grown for 12 h, harvested, and then assayed for -galactosidase activity and sterols.

View larger version (13K): [in this window] [in a new window]   FIG. 3. Constitutive expression of FET3/FTR1 in the erg25-2 strain delays changes in sterol profile when CCC1 is overexpressed. An erg25-2 pMETCCC1 strain with and without FET3/FTR1 was grown overnight in 10-fold excess methionine (see "Materials and Methods"). The cultures were harvested, washed, and re-inoculated in 50 µM FeSO4, 1 mM ascorbate, methionine-free medium to induce overexpression of CCC1. At the indicated times, the cells were harvested and assayed for sterols. Standard deviation from two independent experiments are shown.

View larger version (19K): [in this window] [in a new window]   FIG. 4. Changes in cytosolic iron do not affect the induction of the iron regulon when Fe-S biosynthesis is repressed. The indicated cell strains were loaded with iron (50 µM FeSO4, 1 mM ascorbate) before repressing YFH1 expression by the addition of methionine. At the specified times, the cells were harvested, and -galactosidase activity was determined.

View larger version (23K): [in this window] [in a new window]   FIG. 5. Repression of Fe-S biosynthesis induces the iron regulon but does not change the sterol profile of erg25-2 cells. erg25-2 cells were grown under iron-replete conditions by the addition of 50 µM FeSO4 and under iron-limited conditions by the addition of 40 µM BPS. erg25-2 METYFH1 and erg25-2 METNFS1 cells were grown in iron-replete media under conditions that repress gene expression. The cells were grown for 12 h, harvested, and then assayed for -galactosidase activity and sterols.

Growth of erg25-2 cells can also be used to monitor cytosolic iron levels in cells depleted of Yfh1p. In the absence of Yfh1p, if iron accumulates in mitochondria at the expense of cytosolic iron, then depletion of cytosolic iron should exacerbate the low iron growth defect of the erg25-2 allele. In iron-replete media, erg25-2 METYFH1 grew as well as wild-type or erg25-2 cells independent of YFH1 expression (Fig. 6). On iron-limited plates, erg25-2 cells showed the expected growth defect as did erg25-2 METYFH1 cells that expressed YFH1. In the absence of YFH1 expression, erg25-2 METYFH1 cells grew better than erg25-2, suggesting that cytosolic iron was sufficient to iron-load Erg25-2p and maintain ergosterol biosynthesis. Although overexpression of CCC1 also leads to induction of FET3, the erg25-2 METCCC1 strain failed to grow on iron-limited media. These results indicate that although deletion of YFH1 increases mitochondrial iron, it does not deplete the pool of cytosolic iron.

View larger version (80K): [in this window] [in a new window]   FIG. 6. Growth of erg25-2 cells on iron-limited media is rescued by repression of YFH1 expression. Cells were grown in methionine-free media to induce expression of MET3 promoter-regulated genes. The cells were washed, and 104 cells were spotted on plates with (+) and without (-) methionine (met) to regulate the expression of YFH1 or CCC1. The plates were made iron-limited by the addition of 40 µM BPS and 2 µM FeSO4. The plates were incubated for 3 days before imaging. WT, wild-type.

View larger version (14K): [in this window] [in a new window]   FIG. 7. Induction of FET3 expression is correlated with decreasing aconitase activity. A, wild-type cells containing a FET3-lacZ reporter construct were grown in media with different amounts of bioavailable iron. The media were made iron-limited by adding 40 µM BPS with different concentrations of FeSO4 supplemented to the media. The cells were harvested after 12 h of growth, and aconitase and -galactosidase activities were measured. B, the data from A were plotted as the relationship between aconitase and -galactosidase activities (closed circles). The following strain cells were grown in the presence or absence of methionine for 12 h: METYFH1 (open squares; A, YFH1 on; B, YFH1 off), METNFS1 (open squares; C, NFS1 on; D, NFS1 off), and METCCC1 (wild-type cells with high copy plasmid of CCC1 under the MET3 promoter) (open squares; E, CCC1 off; F, CCC1 on). Each data point (aconitase activity versus -galactosidase activity) was then plotted (open squares).

	DISCUSSION

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Although cytosolic iron is the substrate for mitochondrial Fe-S biosynthesis, conditions that lead to cytosolic iron deprivation (e.g. reduced media iron level, defective iron transport, or increased vacuolar iron storage) result in decreased Fe-S biosynthesis and increased expression of the iron regulon (3). Activation of the iron regulon by impaired mitochondrial Fe-S biosynthesis can explain the apparent conundrum in which loss of Fe-S leads to mitochondrial iron accumulation but only when the cytosolic iron level is high (12, 20). Conditions that result in cytosolic iron starvation will prevent mitochondrial iron accumulation in strains defective in Fe-S biosynthesis. Our results suggest that in the absence of Fe-S biosynthesis, the cytosolic iron level is high, thus permitting mitochondrial iron accumulation.

The prediction from our data is that Aft1p, or a protein that associates with Aft1p, may be an Fe-S-containing protein and that the status of the Fe-S may regulate transcription of genes required for iron acquisition. Aft1p contains a CXC motif that could potentially participate in binding Fe-S. Further, mutation in one of the cysteines (C293F), which might prevent Aft1p from binding an Fe-S, results in a constitutively active allele (21). Expression of Aft1p in bacteria under conditions in which the Fe-S cluster operon was overexpressed did not provide evidence that Aft1p contains Fe-S clusters.² It is worth noting that although Aft1p transitions between cytosol and the nucleus, the metal-sensing transcription factors for the copper regulon (Mac1p) and zinc regulon (Zap1p) are always nuclear (1). We speculate that the difference in the localization of metal-sensing transcription factors is because of the binding of elemental metals by Mac1p and Zap1p in contrast to Aft1p, which senses a mitochondrial product rather than elemental iron. A precedent for Fe-S regulation of gene expression is demonstrated by mammalian IRP1, in which the status of an Fe-S cluster regulates the turnover and expression of mRNA involved in iron transport and storage (22). In bacteria, the Fe-S state of FNR and IscR regulates the transcription of genes required for anaerobiosis and the Isc operon, respectively (23, 24). It may well be that Aft1p binds to other proteins that contain Fe-S clusters or that Aft1p senses the product of an Fe-S cluster-containing protein.

Cells respond to defective Fe-S cluster synthesis by increasing the amount of iron in the mitochondria and in the cell. By increasing iron in the mitochondria, the concentration of one of the essential substrates for Fe-S cluster synthesis is also increased. Recently, we demonstrated that transcription of the cell-surface iron transport system requires heme (8). In the absence of heme, transcription is inhibited even though Aft1p occupies the promoters of genes such as FET3. This observation suggests that transactivation of Aft1p is regulated by other gene products. In yeast, however, heme synthesis is dispensable, as yeast can live anaerobically without heme. Fe-S cluster synthesis, however, is essential. Coupling transcription of the iron transport system to the presence of heme or the synthesis of Fe-S clusters provides mechanisms for integrating mitochondrial iron usage with cellular iron acquisition.

	FOOTNOTES

 
^* This work was supported by National Institutes of Health Grants DK52380 (to J. K.), CA 61286 (to D. R. W.), and GM62104 (to M. B.). Support for use of the Core facilities was provided through Grant NCI-CCSG P30CA 42014 from the NCI, National Institutes of Health. The costs of publication of this article were defrayed in part by the payment of page charges. This article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

These authors contributed equally to this work.

^¶ Supported by National Institutes of Health Training Grant T32 DK07115-29.

To whom correspondence should be addressed: Dept. of Pathology, School of Medicine, 50 North 1900 East, University of Utah, Salt Lake City, UT 84132-2501. Tel.: 801-581-7427; Fax: 801-581-4517; E-mail: jerry.kaplan{at}path.utah.edu.

¹ The abbreviations used are: BPS, bathophenanthroline disulfonate; 4,4-DMZ, 4,4-dimethylzymosterol.

² D. R. Winge, unpublished data.

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TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

 

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