The Yeast Scaffold Proteins Isu1p and Isu2p Are Required inside Mitochondria for Maturation of Cytosolic Fe/S Proteins

Iron-sulfur (Fe/S) proteins are located in mitochondria, cytosol,and nucleus. Mitochondrial Fe/S proteins are matured by theiron-sulfur cluster (ISC) assembly machinery. Little is knownabout the formation of Fe/S proteins in the cytosol and nucleus.A function of mitochondria in cytosolic Fe/S protein maturationhas been noted, but small amounts of some ISC components havebeen detected outside mitochondria. Here, we studied the highlyconserved yeast proteins Isu1p and Isu2p, which provide a scaffoldfor Fe/S cluster synthesis. We asked whether the Isu proteinsare needed for biosynthesis of cytosolic Fe/S clusters and inwhich subcellular compartment the Isu proteins are required.The Isu proteins were found to be essential for de novo biosynthesisof both mitochondrial and cytosolic Fe/S proteins. Several linesof evidence indicate that Isu1p and Isu2p have to be locatedinside mitochondria in order to perform their function in cytosolicFe/S protein maturation. We were unable to mislocalize Isu1pto the cytosol due to the presence of multiple, independentmitochondrial targeting signals in this protein. Further, thebacterial homologue IscU and the human Isu proteins (partially)complemented the defects of yeast Isu protein-depleted cellsin growth rate, Fe/S protein biogenesis, and iron homeostasis,yet only after targeting to mitochondria. Together, our datasuggest that the Isu proteins need to be localized in mitochondriato fulfill their functional requirement in Fe/S protein maturationin the cytosol.

INTRODUCTION

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Introduction

Iron-sulfur (Fe/S) proteins perform central functions in catalysis,electron transport, and regulation of biological processes (1,2). They possess an inorganic cofactor that, in its simplestversion, consists of two or four iron and sulfur atoms, theso-called [2Fe-2S] or [4Fe-4S] clusters, respectively (3). Duringthe past few years, complex machineries have been discoveredthat assist in the assembly of the Fe/S clusters and in theirinsertion into apoproteins. The nitrogen fixation (NIF) machineryis dedicated to the assembly of Fe/S clusters in the complexmetalloprotein nitrogenase of nitrogen-fixing bacteria (13,43). The sulfur mobilization (SUF) machinery is present in Bacteria,Archaea, and the apicoplast of parasites and particularly isrequired under oxidative stress and iron-limiting conditions(32, 40, 54). The ISC (iron-sulfur cluster) assembly machineryfound in Bacteria and mitochondria of Eukarya comprises some10 components (8, 14, 16, 31). In many bacteria, the encodinggenes are frequently organized in clusters termed isc operons(67).

Functional studies of Fe/S protein biogenesis in eukaryoteshave been performed with the model organism Saccharomyces cerevisiae,in which Fe/S cluster assembly takes place in mitochondria (see,e.g., references 15, 23, 26, 29, 33, 47, and 53). The presenceof ISC homologues in virtually all eukaryotic species suggeststhat the process is highly conserved in Eukarya. Central playersof the pathway are the cysteine desulfurase Nfs1p, which releasessulfur from cysteine, and the highly homologous proteins Isu1pand Isu2p, which serve as scaffolds for the assembly of theclusters (34). The chemistry of Fe/S cluster formation is stillunder investigation, mainly using ISC components isolated frombacteria (21, 39, 51, 66). One model proposes that ferrous ironassociates with conserved cysteine residues of the Isu (or bacterialIscU) proteins. Complex formation with Nfs1p (or the bacterialhomolog IscS or NifS) (48, 68) leads to the transfer of sulfurfrom a cysteine persulfide moiety on Nfs1p to a cysteine ofIsu/IscU and the subsequent formation of the Fe/S cluster. Furthercomponents required for Fe/S cluster synthesis on the Isu proteinsare an electron transfer chain consisting of the ferredoxinreductase Arh1p and the ferredoxin Yah1p, which likely transferelectrons to sulfur (S⁰) released from cysteine in order toform the sulfide (S^2–) present in the cluster (26, 29).The loading of ferrous iron onto the Isu scaffold proteins isfacilitated by their interaction with frataxin (yeast Yfh1p),a protein depleted in the neurodegenerative disease Friedreich'sataxia (7, 17, 65). Crucial proteins that are required laterin biosynthesis are the heat shock proteins Ssq1p and Jac1p,which interact with Isu1p and Isu2p, and the mitochondrial glutaredoxinGrx5p (12, 22, 33, 44, 59, 60).

Fe/S proteins are found not only in mitochondria but also inthe cytosol and the nucleus (16). Previous studies suggestedthat Fe/S protein maturation in the cytosol requires the functionof mitochondria (see, e.g., references 5, 23, 26, and 29). Forinstance, it was shown that yeast Nfs1p was required insidethe organelles for its functional involvement in cytosolic Fe/Sprotein biogenesis. Other components of the yeast mitochondrialISC assembly machinery were also found to be essential for maturationof Fe/S proteins in the cytosol, such as the electron transferchain Arh1p/Yah1p and Yfh1p. It was proposed that export ofa yet unknown compound from mitochondria to the cytosol is facilitatedby the ABC transporter Atm1p of the inner membrane, therebysupporting cytosolic Fe/S protein maturation (23, 31). Atm1pis needed specifically for cytosolic but not for mitochondrialFe/S protein maturation and may be assisted by the sulfhydryloxidase Erv1p of the intermembrane space and by the tripeptideglutathione (27, 50). Nevertheless, some ISC assembly componentshave been identified not only in mitochondria but also in thecytosol and nucleus (25, 37, 55, 56). Even though the extramitochondrialISC proteins are present at low concentrations, these componentsmay be responsible for Fe/S protein assembly and/or repair outsidemitochondria. However, experimental evidence for the functionalityof the cytosolic ISC components has not been provided yet. Interestingly,a function of extramitochondrial Nfs1p in the synthesis of thionucleotidesof tRNA has been demonstrated recently (38; G. Kispal and U.Mühlenhoff, unpublished data).

In this report, we used yeast as a model system and asked questionsabout whether the scaffold proteins Isu1p and Isu2p participatein cytosolic Fe/S protein maturation and in which subcellularcompartment they perform this possible function. By employinga yeast mutant that allowed the regulated expression of theISU genes, we demonstrate that the Isu proteins support thede novo synthesis of Fe/S proteins not only in mitochondriabut also in the cytosol. For the latter function, mitochondriallocalization of the Isu proteins was essential. The fact thatboth the sulfur donor Nfs1p (23) and the Fe/S cluster assemblyproteins Isu1p and Isu2p (this work) are required inside mitochondriato assist in cytosolic Fe/S protein maturation reinforces theconcept of a primary function of mitochondria in Fe/S proteinmaturation in the entire cell.

MATERIALS AND METHODS

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Materials and Methods

Yeast strains and cell growth. The following strains of S. cerevisiae were used. W303-1A (MATaade2-1 ura3-1 his3-11,15 trp1-1 leu2-3,112 can1-100) servedas the wild type. The ISU1 and ISU2 genes were deleted in wild-typecells by a PCR-based method employing a histidine-selectivemarker (62) (strains ${Delta}$ isu1 and ${Delta}$ isu2). Exchange of the endogenouspromoter of the ISU1 gene for a galactose-inducible promoterin ${Delta}$ isu2 cells (strain Gal-ISU1/ ${Delta}$ isu2) was performed as describedby Lafontaine and Tollervey (http://www.mips.biochem.mpg.de/proj/yeast/info/tools/tollervey/pcr.html).The galactose-inducible promoter (GAL1-10) from plasmid pTL26was cloned into pRS315 as a BamHI/HindIII fragment to yieldplasmid pRS315-GAL1-10. Its LEU2/GAL1-10 cassette was used astarget DNA for ISU1 promoter exchange by PCR using primers matchingnucleotides –477 to –427 and 37 to –15 ofthe ISU1 gene. Growth of yeast cells was as detailed previouslyusing rich (YP) or synthetic complete medium (49) and lactatemedium (10) (with 0.1% glucose) containing the required carbonsources. For experiments involving cell labeling with radioactive⁵⁵Fe, no iron salt was added to the synthetic minimal medium(iron-poor medium).

Plasmids. The different ISU1 constructs were expressed under the controlof the MET25 promoter from a high-copy-number vector (p426Met25;constructed according to reference 36). ISU1 was cloned withoutthe putative mitochondrial targeting sequence (yielding Isu1p ${Delta}$ 30;codons 31 to 165) or fused in frame with the Neurospora crassaF₀-ATPase subunit 9 presequence (pSu9-Isu1p ${Delta}$ 30; pSu9, codons1 to 69; ISU1, codons 31 to 165). To synthesize Isu1p with anegatively charged prepiece (DAE-Isu1p ${Delta}$ 30), the ISU1 gene (codons31 to 165) was amplified by PCR with a 5' primer additionallycoding for the tripeptide DAE.

The human cDNAs encoding cytosolic hIsu1 (IMAGE clone 3617035;RZPD, Berlin, Germany) and mitochondrial hIsu2 (IMAGE clone3900148) were used for complementation experiments. The codingsequences of hIsu1 and of the mature form of hIsu2 (codons 34to 167) were cloned into the yeast vector p424GPD (36) or werefused to the mitochondrial presequence of subunit ßof N. crassa F₁-ATPase (pF₁ß; codons 1 to 40) beforecloning into the same vector. These constructs were used toattach a C-terminal hemagglutinin (HA) epitope tag to the humanIsu proteins. The coding sequences were inserted into vectorp424GPD. The iscU gene from Escherichia coli was amplified byPCR using chromosomal DNA and cloned into the vector p416Met25(36) either without modification or fused in frame to the codingsequence of N. crassa pSu9 presequence (encoding the fusionprotein pSu9-IscU). All constructs were verified by DNA sequencing.

Miscellaneous methods. The following published methods were used: manipulation of DNAand PCR (46), transformation of yeast cells (18), and isolationof yeast mitochondria and postmitochondrial supernatant (11).The mitochondrial iron content was measured with the iron-chelatorbathophenanthroline-disulfonic acid (28). The labeling of yeastcells with radioactive iron (⁵⁵Fe; 2 h for mitochondrial and4 h for cytosolic Fe/S proteins) and the measurement of the⁵⁵Fe incorporation into various Fe/S proteins by immunoprecipitationand liquid scintillation counting were performed as describedearlier (23, 35). Experiments were performed at least threetimes.

RESULTS

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Results

Generation of a mutant strain for regulated expression of ISU1. Yeast mutants were constructed in which either the ISU1 or ISU2genes were deleted ( ${Delta}$ isu1 and ${Delta}$ isu2 strains). In our strain background(W303), these mutants showed wild-type growth and did not displaysignificant defects in mitochondrial and cytosolic Fe/S proteins(not shown). This indicated that Isu1p and Isu2p could replaceeach other and hence perform overlapping functions. To studythe consequences of an Isu protein deficiency, we created ayeast strain that allowed the regulated expression of ISU1 inthe absence of functional Isu2p. The ${Delta}$ isu2 strain was used togenerate the mutant Gal-ISU1/ ${Delta}$ isu2 in which the ISU1 gene isunder the control of the GAL1-10 promoter, and thus Isu1p levelscan be down-regulated by growth of cells in the absence of galactose.Gal-ISU1/ ${Delta}$ isu2 cells grew at wild-type rates in the presenceof galactose yet did not give rise to colonies on glucose-containingagar plates, indicating that depletion of Isu1p in the absenceof Isu2p is lethal (Fig. 1A) (15, 47). When Gal-ISU1/ ${Delta}$ isu2 cellswere grown in liquid medium, they could undergo three to fiveduplications after transfer to medium containing glucose asthe sole carbon source before growth arrest (not shown). Notably,the growth characteristics of Gal-ISU1/ ${Delta}$ isu2 cells were similarto those of Gal-NFS1 cells (Fig. 1A) (23).

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FIG. 1. Deficiency of the Isu proteins impairs growth and results in mitochondrial iron accumulation in Gal-ISU1/ ${Delta}$ isu2 cells. (A) Wild-type, Gal-NFS1 (23), and Gal-ISU1/ ${Delta}$ isu2 cells were grown on agar plates with rich medium containing galactose (YPGal) or glucose (YPD) for 3 days at 30°C. (B) Mitochondria were isolated from wild-type and Gal-ISU1/ ${Delta}$ isu2 cells grown in YPGal or lactate medium containing 0.1% glucose (Lac) (11). Equal amounts of protein (50 µg) were analyzed by immunostaining with antisera raised against Isu1p and the indicated mitochondrial proteins. (C) The non-heme, non-Fe/S iron content of isolated mitochondria was measured by the bathophenanthroline method. Standard deviations were derived from three independent experiments.

Mitochondria were isolated from Gal-ISU1/ ${Delta}$ isu2 cells grown for16 h in glucose-containing medium and analyzed by immunostaining.Almost quantitative depletion of Isu1p was seen relative towild-type mitochondria or mitochondria isolated from Gal-ISU1/ ${Delta}$ isu2cells that were grown in the presence of galactose (Fig. 1B).The amounts of other mitochondrial proteins needed for preproteinor metabolite transport were not altered upon depletion of Isu1p.Proteins of the ISC assembly machinery were either slightlyincreased, such as Nfs1p or Ssq1p, or somewhat decreased, suchas Yfh1p (yeast frataxin). We noted, however, that in the absenceof Isu1p and Isu2p, the amounts and activities of several mitochondrialFe/S proteins were decreased (not shown). This is consistentwith earlier findings that showed a crucial role of the Isuproteins in mitochondrial Fe/S protein biogenesis (15, 34, 47).Further, Isu protein-depleted mitochondria accumulated 20-fold-largeramounts of iron than wild-type organelles (Fig. 1C). This phenotypeis characteristic for yeast cells exhibiting defects in theassembly of cellular Fe/S proteins. Thus, the strain Gal-ISU1/ ${Delta}$ isu2is suitable for functional studies of the Isu proteins in Fe/Sprotein maturation.

The Isu proteins are required for de novo biogenesis of mitochondrial and cytosolic Fe/S proteins. We first tested whether the Isu proteins are required for thede novo formation of mitochondrial Fe/S proteins and chose biotinsynthase (Bio2p) as a model Fe/S protein (41). Wild-type andGal-ISU1/ ${Delta}$ isu2 cells were grown overnight in iron-poor minimalmedium containing either galactose or glucose. The incorporationof ⁵⁵Fe into overproduced Bio2p was analyzed by radiolabelingcells for 2 h with ⁵⁵Fe in the presence of ascorbate, preparationof a cell extract, and immunoprecipitation of the Fe/S proteinby using specific anti-Bio2p antibodies. The radioactivity associatedwith the immunobeads reflects the de novo assembly of an Fe/Scluster with the respective apoprotein and can be estimatedby scintillation counting (23). Comparable amounts of radioactivitywere associated with Bio2p in wild-type cells and in Gal-ISU1/ ${Delta}$ isu2cells grown in the presence of galactose (Fig. 2A). Only a smallamount of radioactivity was coimmunoprecipitated with preimmuneserum. Upon depletion of Isu1p by growth in glucose-containingmedium, hardly any radioactivity was associated with Bio2p despiteunchanged levels of the Bio2p polypeptide chain (inset). Thesedata indicate that the role of the Isu proteins in maintainingthe activity of mitochondrial Fe/S proteins (15, 47; not shown)is explained by their necessity for de novo Fe/S cluster synthesis.⁵⁵Fe uptake into Isu1p-depleted cells was increased about threefold(Fig. 2B), a finding compatible with the iron accumulation inmitochondria (see above).

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FIG. 2. Depletion of Isu1p in Gal-ISU1/ ${Delta}$ isu2 cells causes defects in the de novo biogenesis of mitochondrial Fe/S proteins and increases cellular iron uptake. Wild-type and Gal-ISU1/ ${Delta}$ isu2 cells were transformed with the plasmid p426GPD carrying the BIO2 gene coding for mitochondrial biotin synthase Bio2p. Cells were grown in iron-poor minimal medium containing galactose (Gal) or glucose (Glu). They were radiolabeled with [⁵⁵Fe]iron chloride in the presence of 1 mM ascorbate, and a cell extract was prepared. The amount of Fe/S cluster incorporation into Bio2p was estimated by immunoprecipitation with Bio2p-specific antibodies ( ${alpha}$ -Bio2p) and quantitation of coimmunoprecipitated ⁵⁵Fe by liquid scintillation counting. A control immunoprecipitation was performed with preimmune serum (PIS) to detect the background levels of ⁵⁵Fe precipitation. The inset shows the amounts of Bio2p and Isu1p in Gal-ISU1/ ${Delta}$ isu2 cells detected by immunostaining of cell extracts (50 µg). (B) The amounts of ⁵⁵Fe uptake by the cells were quantified by liquid scintillation counting. Standard deviations were calculated from three independent experiments.

Next, de novo formation of cytosolic Fe/S proteins was studiedby using isopropylmalate isomerase Leu1p and the essential Rli1pas model Fe/S proteins. The latter protein was overproducedas a hemagglutinin-tagged version (termed Rli1p-HA) (27). Upondepletion of Isu1p in Gal-ISU1/ ${Delta}$ isu2 cells, a strong decreaseof ⁵⁵Fe/S cluster assembly on both Leu1p and Rli1p-HA was observedcompared with that in wild-type cells or Gal-ISU1/ ${Delta}$ isu2 cellscontaining Isu1p (Fig. 3). The levels of both proteins werenot significantly altered upon depletion of Isu1p, as shownby immunostaining (insets in Fig. 3). These results demonstratethat the Isu proteins are also required for the biosynthesisof Fe/S proteins in the cytosol.

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FIG. 3. The Isu proteins are required for the maturation of cytosolic Fe/S proteins. Wild-type and Gal-ISU1/ ${Delta}$ isu2 cells were transformed with the plasmid p426GPD carrying the gene encoding Rli1p-HA. Cell growth, radiolabeling with ⁵⁵Fe, and immunoprecipitation using antibodies against Leu1p ( ${alpha}$ -Leu1p) or the HA tag ( ${alpha}$ -Rli1p-HA) were performed as described in the legend to Fig. 2A. Control immunoprecipitations were performed with preimmune serum (PIS). The insets show the amounts of Leu1p, Rli1p-HA, and Isu1p in Gal-ISU1/ ${Delta}$ isu2 cells detected by immunostaining. Standard deviations were estimated from five independent experiments.

Failure to mislocalize Isu1p to the yeast cytosol. Both Isu1p and Isu2p were found to be located exclusively inthe mitochondrial matrix in yeast (15, 47). Nevertheless, basedon findings with yeast Nfs1p (37), it cannot be excluded fromsuch cell fractionation data that minimal amounts of the Isuproteins may be located in other subcellular compartments. Thisfraction may be responsible for maturation of extramitochondrialFe/S proteins. To study the potential activity of Isu1p outsidemitochondria, we attempted to mislocalize the protein by removingits N-terminal mitochondrial targeting sequence. Upon synthesisof the truncated protein termed Isu1p ${Delta}$ 30 (Fig. 4A) in Isu1p-depletedGal-ISU1/ ${Delta}$ isu2 cells, Isu1p ${Delta}$ 30 was detectable only in mitochondria(Fig. 4B). As expected from this result, Isu1p ${Delta}$ 30 fully complementedthe growth defect of Gal-ISU1/ ${Delta}$ isu2 cells after depletion ofendogenous Isu1p in glucose-containing medium (Fig. 4C). Apparently,Isu1p contains targeting information in parts other than theN terminus of its precursor form.

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FIG. 4. Isu1p lacking its N-terminal presequence is targeted efficiently to mitochondria. (A) Schematic description of various yeast Isu1p mutant proteins either carrying another N-terminal mitochondrial targeting sequence from the F₀-ATPase subunit 9 of N. crassa (pSu9-Isu1p ${Delta}$ 30), lacking its N-terminal presequence (Isu1p ${Delta}$ 30), or containing a short negatively charged tripeptide (DAE-Isu1p ${Delta}$ 30) instead of the presequence. Numbers indicate the amino acid positions in the proteins. The white boxes represent wild-type mature Isu1p, and the light gray boxes represent the various N-terminal extensions. (B) Plasmids (p426Met25) carrying the indicated ISU1 mutants (described for panel A) were transformed into Gal-ISU1/ ${Delta}$ isu2 cells, and cells were grown in glucose-containing minimal medium to deplete endogenous Isu1p. Mitochondria (M) and postmitochondrial supernatants (PMS) were isolated from wild-type cells and from Gal-ISU1/ ${Delta}$ isu2 cells expressing the different ISU1 mutants (11). Equal amounts of protein (50 µg) were analyzed by immunostaining with specific antisera against Isu1p, the mitochondrial marker Aco1p, and the cytosolic marker Bmh1p. (C) Wild-type cells and Gal-ISU1/ ${Delta}$ isu2 (Gal-ISU) cells transformed with plasmids encoding various Isu1p mutant proteins (indicated in parentheses and described for panel A) were incubated on synthetic complete minimal medium with either galactose (SGal) or glucose (SD) for 3 days at 30°C.

Inspection of the N terminus of mature Isu1p (predicted cleavagesite after residue 27) by several mitochondrial presequenceprediction programs (Mitoprot, TargetP, and Predotar) revealeda high (41 to 99%) probability of mitochondrial targeting ofmature Isu1p. Thus, targeting information present in the N terminusof mature Isu1p may readily explain the efficient localizationof this protein to mitochondria. Since the N terminus of matureIsu1p is highly conserved, it was not possible to introducemutations into this region, since they might interfere withboth targeting to mitochondria and the function of Isu1p. Wetherefore decided to add a short negatively charged N-terminalextension (DAE) to Isu1p ${Delta}$ 30. Negatively charged amino acids areincompatible with mitochondrial targeting (61), and consequentlythe mutant protein termed DAE-Isu1p ${Delta}$ 30 (Fig. 4A) was predictedto be targeted to mitochondria with rather low efficiency (3to 15%) by presequence prediction programs. Surprisingly, expressionof the gene encoding DAE-Isu1p ${Delta}$ 30 in Gal-ISU1/ ${Delta}$ isu2 cells yieldedmitochondrial localization of the protein and did not lead toany detectable amounts of DAE-Isu1p ${Delta}$ 30 in the cytosol (Fig. 4B).Synthesis of DAE-Isu1p ${Delta}$ 30 fully complemented the growth defectof Isu1p-depleted Gal-ISU1/ ${Delta}$ isu2 cells (Fig. 4C). We did notfurther analyze the reason why Isu1p still was targeted exclusivelyto mitochondria, but apparently there exists targeting informationin parts other than the N terminus of this protein.

The inability to mislocalize Isu1p to the cytosol precludedthe detection of the functional location of Isu1p in cytosolicFe/S protein maturation. Nevertheless, the data show that theprotein contains multiple pieces of targeting information, includingthe N-terminal presequence, the N terminus of the mature part,and additional, internal information. It seems highly likelythat the combination of these multiple targeting sequences ensuresoverwhelming localization of Isu1p to the mitochondrial matrix.

Bacterial IscU supports cellular Fe/S protein biogenesis after targeting to mitochondria. To circumvent the inability to mislocate yeast Isu1p to thecytosol, we asked whether bacterial IscU proteins can replacethe function of the yeast Isu protein homologues and allow localizationof IscU to either mitochondria or the cytosol for use in functionalstudies. The E. coli gene iscU was cloned into a yeast expressionvector with or without the coding sequence for the strong mitochondrialpresequence of N. crassa F₀-ATPase subunit 9 (pSu9). Productionof mitochondrion-targeted pSu9-IscU in yeast resulted in partialcomplementation of the growth defect of Isu1p-depleted Gal-ISU1/ ${Delta}$ isu2cells (Fig. 5A). In contrast, no colony formation was foundfor IscU synthesized without a mitochondrial presequence, despitethe fact that the IscU protein was detectable in the postmitochondrialsupernatant, as analyzed by immunostaining (Fig. 5B). This findingprovided further support for the essential function of the Isu/IscUproteins inside mitochondria.

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FIG. 5. Targeting of E. coli IscU to mitochondria partially restores the defects of Isu protein deficiency in Gal-ISU1/ ${Delta}$ isu2 cells. (A) The gene encoding IscU from E. coli was inserted into the yeast vector p416Met25 either without (IscU) or with an N-terminal mitochondrial targeting sequence of N. crassa F₀-ATPase subunit 9 (pSu9-IscU). Plasmids were transformed into Gal-ISU1/ ${Delta}$ isu2 (Gal-ISU) cells, and cell growth was compared to that of wild-type cells or Gal-ISU1/ ${Delta}$ isu2 cells with a plasmid lacking an insert (none) by incubation on agar plates containing synthetic complete medium with either galactose (SGal) or glucose (SD) for 3 days at 30°C. (B) Mitochondria (M) and postmitochondrial supernatants (PMS) were isolated from Gal-ISU1/ ${Delta}$ isu2 cells described for panel A after growth in minimal medium containing galactose (Gal) or glucose (Glu). Subcellular localization of IscU was analyzed by immunostaining (50 µg of protein per lane) with antisera raised against yeast Isu1p, which exhibits cross-reactivity against E. coli IscU. The mitochondrial proteins Por2p and Yfh1p and cytosolic Bmh1p served as controls. (C) The cells described for panel A were transformed with the plasmid p424GPD carrying the BIO2 or the HA-tagged RLI1 genes. Cells were examined for de novo Fe/S protein maturation as described for Fig. 2A. The levels of Rli1p-HA and Bio2p were visualized by immunostaining (insets). (D) The cellular ⁵⁵Fe uptake of the various cell types was quantified by liquid scintillation counting. Standard deviations were calculated from five independent experiments.

The function of bacterial IscU in the two cellular locationswas examined by measuring the ⁵⁵Fe incorporation into mitochondrialBio2p and cytosolic Rli1p-HA as model Fe/S proteins with Isu1p-depletedGal-ISU1/ ${Delta}$ isu2 cells. Only mitochondrion-targeted but not cytosolicIscU supported Fe/S cluster association with both Bio2p andRli1p (Fig. 5C). The efficiency of Fe/S protein formation bymitochondrial IscU was rather low but two- to fourfold higherthan the levels of Fe/S cluster formation in Isu1p-depletedGal-ISU1/ ${Delta}$ isu2 cells. Further, the higher iron uptake observedin Isu1p-depleted Gal-ISU1/ ${Delta}$ isu2 cells was almost fully reversedby mitochondrial IscU (Fig. 5D). Despite the incomplete functionalreplacement of the yeast Isu proteins by bacterial IscU, theseproteins can be regarded as functional orthologues. Clearly,IscU requires mitochondrial localization for participation inboth mitochondrial and cytosolic Fe/S protein biogenesis. Thesedata provide evidence for the notion that the mitochondrialmatrix is the functional location of the Isu proteins for maturationof Fe/S proteins, including those located in the cytosol.

Targeting of human Isu proteins to mitochondria restores the defects of Isu protein-depleted yeast cells. Since the complementation of the Isu protein deficiency by bacterialIscU was only partial, we asked whether a eukaryotic Isu proteinwould complement these defects more efficiently. We took advantageof the two human Isu protein homologues to study their functionalityin Gal-ISU1/ ${Delta}$ isu2 cells and to further explore the functionalsite of Isu proteins in eukaryotes. In humans, two cDNAs havebeen discovered that are transcribed from a single ISU gene(56). The predominant form (ca. 90 DNA sequence database entries)encodes a mitochondrial version of Isu protein (termed hIsu2).A minor form (seven expressed sequence tag [EST] entries; allderived from tumor cell lines) lacks the mitochondrial presequencedue to a splice variation and gives rise to small amounts ofan Isu protein isoform in the cytosol (termed hIsu1) (56). Wefirst tested the functional complementation of Isu1p-depletedGal-ISU1/ ${Delta}$ isu2 cells by mitochondrion-targeted human Isu proteins.To achieve efficient targeting of the human proteins to yeastmitochondria, the endogenous N-terminal mitochondrial presequenceof hIsu2 was replaced by the strong pF₁ß presequence(to yield pF₁ß-hIsu2 ${Delta}$ 33 [Fig. 6A]), and hIsu1 was synthesizedwith an N-terminal pF₁ß presequence (pF₁ß-hIsu1).Synthesis of both proteins in Gal-ISU1/ ${Delta}$ isu2 cells complementedthe deficiency in the endogenous Isu proteins in a differentmanner. Almost-wild-type growth was observed for pF₁ß-hIsu2 ${Delta}$ 33,whereas hardly any growth was seen for mitochondrion-localizedpF₁ß-hIsu1 (Fig. 6B). A likely reason for the lowactivity of hIsu1 in mitochondria may be the lack of a conservedtyrosine residue at its N terminus. This residue is found invirtually all eukaryotic Isu and prokaryotic IscU protein familymembers, yet is lacking in cytosolic hIsu1 as a result of differentialsplicing of its mRNA.

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FIG. 6. Upon targeting to mitochondria, human Isu proteins restore the defects of Isu protein-depleted Gal-ISU1/ ${Delta}$ isu2 cells. (A) Schematic description of human cytosolic hIsu1 and mitochondrial hIsu2 with and without mitochondrial targeting sequences. hIsu1 was used in native form or with the N-terminal mitochondrial targeting sequence of F₁ß-ATPase (pF₁ß-hIsu1). The presequence of hIsu2 was either deleted (hIsu2 ${Delta}$ 33) or replaced with the presequence of F₁ß-ATPase (pF₁ß-hIsu2 ${Delta}$ 33). (B) Gal-ISU1/ ${Delta}$ isu2 (Gal-ISU) cells weretransformed with plasmids carrying either no gene or the genes for human hIsu1 and hIsu2 proteins indicated in panel A. These cells and wild-type cells were grown on agar plates containing synthetic complete medium with either galactose (SGal) or glucose (SD) for 3 days at 30°C. (C) Cells from panel B were transformed with the plasmid p426GPD carrying the BIO2 gene. After growth in the presence of galactose (Gal) or glucose (Glu), cell extracts were examined for de novo ⁵⁵Fe/S cluster incorporation into mitochondrial Bio2p and cytosolic Leu1p as described for Fig. 2A. (D) The cellular ⁵⁵Fe uptake of the various cell types was quantified by liquid scintillation counting. Data were normalized to the amounts of iron uptake into Isu1p-containing Gal-ISU1/ ${Delta}$ isu2 cells (grown with galactose). Standard deviations were calculated from four independent experiments. (E) Plasmid p424GPD carrying the genes for HA-tagged versions of pF₁ß-hIsu2 ${Delta}$ 33, hIsu2 ${Delta}$ 33, or hIsu1 was transformed into Gal-ISU1/ ${Delta}$ isu2 cells. After growth in minimal medium containing glucose, mitochondria (M) and postmitochondrial supernatants (PMS) were prepared. Equal amounts of protein (50 µg) were analyzed by immunostaining for the HA-tagged human Isu proteins and Bmh1p.

To analyze the function of the mitochondrion-targeted humanIsu proteins in mitochondrial and cytosolic Fe/S protein biogenesis,we used the ⁵⁵Fe incorporation into Bio2p and Leu1p, respectively,in Isu1p-depleted Gal-ISU1/ ${Delta}$ isu2 cells. Mitochondrial pF₁ß-hIsu2 ${Delta}$ 33supported Fe/S cluster formation in both Fe/S apoproteins atalmost wild-type efficiencies (75% of Isu1p-containing Gal-ISU1/ ${Delta}$ isu2cells [Fig. 6C]). Thus, yeast Isu proteins and human mitochondrialhIsu2 can be regarded as functional orthologues. Only a slightimprovement of Fe/S cluster insertion into Bio2p and virtuallyno effect on Leu1p were observed for mitochondrion-targetedpF₁ß-hIsu1. Apparently, hIsu1 exhibits only a weakactivity in Fe/S cluster biogenesis, despite its almost identicalamino acid sequence compared to hIsu2 ${Delta}$ 33. This finding is consistentwith the slow growth of the corresponding cells (Fig. 6B). Wealso analyzed the cellular iron uptake, which is characteristicallyhigher in Isu protein-depleted cells (Fig. 2B). Iron uptakewas fully reversed to levels observed for Isu1p-containing Gal-ISU1/ ${Delta}$ isu2cells by synthesis of pF₁ß-hIsu2 ${Delta}$ 33, but no significanteffect was seen by pF₁ß-hIsu1, corroborating the resultspresented above (Fig. 6D).

We further tested whether the human Isu proteins might be functionalin cytosolic Fe/S protein assembly, when localized to the yeastcytosol. To this end, cytosolic human hIsu1 was synthesizedwithout modification in Gal-ISU1/ ${Delta}$ isu2 cells, and the truncatedversion of hIsu2 lacking its N-terminal presequence (hIsu2 ${Delta}$ 33)was used (Fig. 6A). No colony formation was observed when thesetwo isoforms were produced without a mitochondrial presequence(Fig. 6B). These data show that mitochondrial localization wasessential for functional replacement of the yeast Isu proteinsby the human homologues. No positive influence of both cytosol-localizedhuman Isu proteins was detectable for Fe/S cluster assemblyon cytosolic Leu1p in Isu1p-deficient Gal-ISU1/ ${Delta}$ isu2 cells, demonstratingthat also for functional participation in cytosolic Fe/S proteinbiogenesis, the Isu proteins need to be localized in mitochondria(Fig. 6C). Moreover, the increased cellular ⁵⁵Fe uptake wasnot altered upon synthesis of cytosol-targeted human Isu proteins(Fig. 6D).

Finally, the localization of the human Isu proteins in yeastwas analyzed by transforming cells with plasmids carrying genesencoding HA-tagged human Isu proteins. Mitochondria and postmitochondrialsupernatants were prepared and analyzed by immunostaining. Thepresequence-containing pF₁ß-hIsu2 ${Delta}$ 33-HA was localizedin mitochondria, whereas both hIsu2 ${Delta}$ 33-HA and hIsu1-HA were foundin the postmitochondrial supernatant fraction (Fig. 6E). Thesefindings support the conclusion that only mitochondrion-targetedbut not cytosol-localized human Isu proteins were functionalin replacing the yeast Isu proteins. In summary, our data demonstratethat the Isu proteins perform their function in Fe/S proteinbiogenesis in mitochondria, for both mitochondrial and cytosolicFe/S target proteins.

DISCUSSION

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Discussion

In vivo and in vitro evidence suggests that the members of theIsu/IscU protein family provide a scaffold for the de novo synthesisof an Fe/S cluster in mitochondria and bacteria (34, 39, 66).The central importance of these proteins becomes most evidentfrom their functional interaction with several other proteinsof the ISC assembly machinery that are needed either for Fe/Scluster synthesis (Nfs1p and frataxin) (17) or for later stepsof Fe/S protein biosynthesis (Ssq1q and Jac1p) (12). Our presentstudy adds another feature that establishes an important functionof the Isu proteins for the entire cell. We demonstrate thatthe Isu proteins not only play a central role in mitochondrialFe/S cluster metabolism but also are involved in the biosynthesisof the cytosolic Fe/S proteins Leu1p and Rli1p. Most probably,the Isu proteins participate in the biosynthesis of all (orat least most) cellular Fe/S proteins. Similar findings havebeen made for other members of the ISC assembly machinery, includingNfs1p, Yah1p, Arh1p, and frataxin (23, 26, 29, 35), underscoringthe central task of mitochondria in the generation of cellularFe/S proteins.

Several lines of evidence indicate that location of the Isuproteins inside the mitochondrial matrix is crucial for theirfunction in maturation of both mitochondrial and cytosolic Fe/Sproteins. First, Isu1p could not be mistargeted to the cytosol,a property that likely is due to the presence of multiple targetingsequences in this protein. As a consequence, Isu1p appears tobe located only inside mitochondria. The same may be true forIsu2p, since the functions of both Isu proteins are fully overlapping,and no significant phenotypes of the single-gene-deletion strains ${Delta}$ isu1 and ${Delta}$ isu2 were evident in our strain background. Second,both bacterial and human Isu homologues can (at least partially)replace the yeast Isu proteins, yet only after targeting tomitochondria. Synthesis of both human and bacterial Isu proteinsin the yeast cytosol did not support growth of yeast cells andmost strikingly had no detectable influence on the biosynthesisof cytosolic Fe/S proteins. Thus, mitochondrial location ofthe Isu proteins is necessary for the maturation of cytosolicFe/S proteins in yeast cells. Whether a cytosolic version ofthe Isu proteins may be required in addition to mitochondrion-locatedcopies cannot be excluded with certainty, but it seems ratherunlikely from the virtually quantitative location of the Isuproteins within yeast mitochondria.

The participation of the yeast Isu proteins and the sulfur donorNfs1p in cellular Fe/S protein biogenesis is strikingly similar(23). Like the Isu proteins, the cysteine desulfurase performsits function in both mitochondrial and cytosolic Fe/S proteinmaturation inside mitochondria. Cytosolic location of Nfs1pdoes not give rise to Fe/S protein formation in the yeast cytosol.In addition to the essential mitochondrial function of Nfs1p,genetic studies have identified an indispensable task in thenucleus (37). Recent biochemical studies indicate that the nuclearform of Nfs1p is involved in thiouridine modification of tRNAand not in Fe/S metabolism (38; G. Kispal and U. Mühlenhoff,unpublished observation). Notably, IscS, the bacterial homologueof Nfs1p, provides sulfur for Fe/S clusters, tRNA, and thiamine,thus impressively illustrating the functional similarity ofthe eukaryotic and prokaryotic enzymes (19).

Mitochondrial function of the Isu proteins (this work) and Nfs1p(23) in cytosolic Fe/S protein maturation implies that mitochondriaexport a component required for Fe/S protein maturation in thecytosol. Presently, little is known about this putative exportprocess and the chemical nature of the transported moiety. Potentialexported components include an Fe/S cluster synthesized by themitochondrial ISC machinery or a product of a mitochondrialFe/S protein (31). Central players of the export pathway arethe ABC transporter Atm1p of the mitochondrial inner membrane,the sulfhydryl oxidase Erv1p of the intermembrane space, andthe tripeptide glutathione (23, 27, 50). Depletion of thesecomponents results in defects of cytosolic but not mitochondrialFe/S proteins. This specific phenotype is distinct from theconsequences of functional inactivation of components of theISC assembly machinery (such as the Isu proteins or Nfs1p),resulting in defects in both mitochondrial and extramitochondrialFe/S proteins (15, 23, 28, 47, 53; this study). Recently, yetanother factor needed for cytosolic Fe/S protein maturationwas identified (45). The cytosolic P-type ATPase Cfd1p was foundto be involved in cytosolic but not mitochondrial Fe/S proteinbiosynthesis: i.e., inactivation of Cfd1p elicits a phenotypecomparable to the defects in components of the mitochondrialISC export machinery. It is tempting to speculate that Cfd1pcooperates with the mitochondrial ISC export machinery in maturationof cytosolic Fe/S proteins.

Several components of the yeast mitochondrial ISC assembly andexport machineries including the two Isu proteins are encodedby essential genes (30). In fact, Fe/S protein biogenesis isthe only known biochemical process (apart from biogenesis ofthe organelle by preprotein import, processing and folding)that renders mitochondria essential. Surprisingly, with theexception of Yah1p (26) no essential mitochondrial Fe/S proteinis known to date that could explain this property. However,the yeast cytosol contains several essential Fe/S proteins,including Rli1p. The fact that mitochondrial location of theIsu proteins, Nfs1p, and other essential ISC proteins is requiredfor Rli1p maturation provides a logical reason why these organellesmay be indispensable for the eukaryotic cell. This requirementreadily explains the essential character of the Isu proteins,of other central members of the mitochondrial ISC machineries,and of cytosolic Cfd1p, which also is encoded by an essentialgene (31, 45). This view is further supported by recent datashowing that even in organisms such as Giardia lamblia lackingclassical mitochondria, Fe/S protein biogenesis appears to becompartmentalized (57). Giardia was shown to contain so-calledmitosomes, double-membrane-bounded organelles derived from mitochondriaby reductive evolution. Mitosomes lack classical functions ofmitochondria (20, 63), but maintained the ISC assembly machineryas their prominent function, underlining the importance of mitochondria/mitosomesfor Fe/S cluster biogenesis in the entire cell.

Fe/S protein biogenesis appears to be conserved in eukaryotes.Mammalian genomes contain homologues of virtually all componentsof the yeast ISC assembly and export machineries, and theseproteins share extensive sequence similarity. Some of thesecomponents have been demonstrated to functionally replace eachother, such as human and yeast Isu proteins (this study), humanfrataxin and Yfh1p (64), human ALR and Erv1p (27), or humanABC7 and its functional orthologue, Atm1p (9). Moreover, thelargely increased mitochondrial iron uptake in mammalian cellsharboring defective frataxin or ABC7 suggests close functionalsimilarities between the yeast and mammalian systems (4, 24,42). However, only a few functional studies on the biosynthesisof Fe/S proteins in higher eukaryotes have been reported sofar. For instance, maturation of the cytosolic aconitase IRP1depends on the function of energized mitochondria (i.e., organellesexhibiting a membrane potential [5]). This finding is strikinglysimilar to our observations made for yeast cells described above(23). Despite these conspicuous similarities, Fe/S protein biogenesisin human cells may be more complex than it is in yeast. Somecomponents of the human ISC assembly machinery have been detectedin the cytosol and the nucleus, even though at rather low concentrations(25, 55, 56). This raises several intriguing questions, includingwhat contribution the human cytosolic ISC components might providefor cytosolic Fe/S protein maturation and what role human mitochondriamight play in this process. We show here that mitochondrialhIsu2 can replace the endogenous yeast proteins after targetingto mitochondria, whereas the cytosolic human hIsu1 is hardlyfunctional in yeast mitochondria, despite its sequence identitywith mitochondrial hIsu2 (56). The reason for this strikingfunctional difference is the lack of a conserved tyrosine atthe N terminus of cytosolic hIsu1. Notably, hIsu1 is the onlymember of the large Isu/IscU protein family lacking this residue.The inherent functional defect combined with the low cytosolicconcentration of hIsu1 questions the functionality of hIsu1in cytosolic Fe/S cluster synthesis.

Counterparts of the splice variants of human Isu mRNA have notbeen identified in other higher eukaryotes so far. A recentsystematic study has shown that splice variations are remarkablyconserved in higher eukaryotes (6). On the basis of this study,it is expected that the same Isu splice variants exist in otherorganisms. Indeed, the general split gene structure of the Isuprotein is conserved in, e.g., mice and rats, but we did notfind any ESTs matching the N-terminal region of hIsu1. Instead,we identified a single mouse EST that deviates from the normalmitochondrial forms of murine Isu protein (represented by 30ESTs encoded by two almost identical genes on chromosomes 5and 19). However, the open reading frame lacks a start methionineat its N terminus, and hence, its mRNA may not give rise toa functional protein. Thus, at present, it is unclear whethermouse and other organisms contain a cytosolic form of the Isuproteins. If Fe/S cluster synthesis in human cells should usethe ISC machinery in the cytosol, human cytosolic Isu1 and Nfs1may likely need the support of other crucial ISC components.For instance, mammalian adrenodoxin and adrenodoxin reductase,homologues of yeast Yah1p and Arh1p, may be needed for biogenesis.However, these two proteins do not appear to be functional outsidemitochondria, as they participate in partial reactions of steroidhormone biosynthesis only after steroid precursor import intomitochondria from the smooth endoplasmic reticulum (52).

Clearly, all this information is indirect and speculative andtherefore does not clarify the interesting problem of mitochondrialversus cytosolic Fe/S cluster assembly in mammalian cells. Thestudies with yeast, including those presented here, stronglyindicate that there is no duplication of the mitochondrial ISCassembly machinery in the cytosol. However, with respect tothe apparent fundamental differences in the mechanisms of ironsensing, uptake, and storage in fungi and humans (58), it isnot excluded that cytosolic Fe/S assembly may take a differentpath in mammalian systems. Solution of this problem will haveto come from in vivo investigations of Fe/S cluster assemblyin higher eukaryotes.

ACKNOWLEDGMENTS

Our work was supported by grants from the Deutsche Forschungsgemeinschaft(Gottfried-Wilhelm Leibniz program), Sonderforschungsbereich593, the European Commission (QLG1-CT-2001-00966), the DeutscheHumangenomprojekt, and Fonds der Chemischen Industrie.

FOOTNOTES

* Corresponding author. Mailing address: Institut für Zytobiologie und Zytopathologie, Philipps-Universität Marburg, Robert-Koch Strasse 6, D-35033 Marburg, Germany. Phone: 49-6421-286 6449. Fax: 49-6421-286 6414. E-mail: Lill{at}mailer.uni-marburg.de.

REFERENCES

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