The mitochondrial proteins Atm1p and Nfs1p are essential for biogenesis of cytosolic Fe/S proteins.

Iron-sulfur (Fe/S) cluster-containing proteins catalyse a number of electron transfer and metabolic reactions. Little is known about the biogenesis of Fe/S clusters in the eukaryotic cell. Here, we demonstrate that mitochondria perform an essential role in the synthesis of both intra- and extra-mitochondrial Fe/S proteins. Nfs1p represents the yeast orthologue of the bacterial cysteine desulfurase NifS that initiates biogenesis by producing elemental sulfur. The matrix-localized protein is required for synthesis of both mitochondrial and cytosolic Fe/S proteins. The ATP-binding cassette (ABC) transporter Atm1p of the mitochondrial inner membrane performs an essential function only in the generation of cytosolic Fe/S proteins by mediating export of Fe/S cluster precursors synthesized by Nfs1p and other mitochondrial proteins. Assembly of cellular Fe/S clusters constitutes an indispensable biosynthetic task of mitochondria with potential relevance for an iron-storage disease and the control of cellular iron uptake.     

Disulfide Bond Formation: Sulfhydryl Oxidase ALR Controls Mitochondrial Biogenesis of Human MIA40

The conserved MIA pathway is responsible for the import and oxidative folding of proteins destined for the intermembrane space of mitochondria. In contrast to a wealth of information obtained from studies with yeast, the function of the MIA pathway in higher eukaryotes has remained enigmatic. Here, we took advantage of the molecular understanding of the MIA pathway in yeast and designed a model of the human MIA pathway. The yeast model for MIA consists of two critical components, the disulfide bond carrier Mia40 and sulfhydryl oxidase Erv1/ALR. Human MIA40 and ALR substituted for their yeast counterparts in the essential function for the oxidative biogenesis of mitochondrial intermembrane space proteins. In addition, the sulfhydryl oxidases ALR/Erv1 were found to be involved in the mitochondrial localization of human MIA40. Furthermore, the defective accumulation of human MIA40 in mitochondria underlies a recently identified disease that is caused by amino acid exchange in ALR. Thus, human ALR is an important factor that controls not only the ability of MIA40 to bind and oxidize protein clients but also the localization of human MIA40 in mitochondria.     

Targeting and maturation of Erv1/ALR in the mitochondrial intermembrane space

The interaction of Mia40 with Erv1/ALR is central to the oxidative protein folding in the intermembrane space of mitochondria (IMS) as Erv1/ALR oxidizes reduced Mia40 to restore its functional state. Here we address the role of Mia40 in the import and maturation of Erv1/ALR. The C-terminal FAD-binding domain of Erv1/ALR has an essential role in the import process by creating a transient intermolecular disulfide bond with Mia40. The action of Mia40 is selective for the formation of both intra and intersubunit structural disulfide bonds of Erv1/ALR, but the complete maturation process requires additional binding of FAD. Both of these events must follow a specific sequential order to allow Erv1/ALR to reach the fully functional state, illustrating a new paradigm for protein maturation in the IMS.     

The essential role of mitochondria in the biogenesis of cellular iron-sulfur proteins

Iron-sulfur (Fe/S) proteins play an important role in electron transfer processes and in various enzymatic reactions. In eukaryotic cells, known Fe/S proteins are localised in mitochondria, the cytosol and the nucleus. The biogenesis of these proteins has only recently become the focus of investigations. Mitochondria are the major site of Fe/S cluster biosynthesis in the cell. The organelles contain an Fe/S cluster biosynthesis apparatus that resembles that of prokaryotic cells. This apparatus consists of some ten proteins including a cysteine desulfurase producing elemental sulfur for biogenesis, a ferredoxin involved in reduction, and two chaperones. The mitochondrial Fe/S cluster synthesis apparatus not only assembles mitochondrial Fe/S proteins, but also initiates formation of extra-mitochondrial Fe/S proteins. This involves the export of sulfur and possibly iron from mitochondria to the cytosol, a reaction performed by the ABC transporter Atm1p of the mitochondrial inner membrane. A possible substrate of Atm1p is an Fe/S cluster that may be stabilised for transport. Constituents of the cytosol involved in the incorporation of the Fe/S cluster into apoproteins have not been described yet. Many of the mitochondrial proteins involved in Fe/S cluster formation are essential, illustrating the central importance of Fe/S proteins for life. Defects in Fe/S protein biogenesis are associated with the abnormal accumulation of iron within mitochondria and are the cause of an iron storage disease.     

Biogenesis of cytosolic ribosomes requires the essential iron-sulphur protein Rli1p and mitochondria

Mitochondria perform a central function in the biogenesis of cellular iron-sulphur (Fe/S) proteins. It is unknown to date why this biosynthetic pathway is indispensable for life, the more so as no essential mitochondrial Fe/S proteins are known. Here, we show that the soluble ATP-binding cassette (ABC) protein Rli1p carries N-terminal Fe/S clusters that require the mitochondrial and cytosolic Fe/S protein biogenesis machineries for assembly. Mutations in critical cysteine residues of Rli1p abolish association with Fe/S clusters and lead to loss of cell viability. Hence, the essential character of Fe/S clusters in Rli1p explains the indispensable character of mitochondria in eukaryotes. We further report that Rli1p is associated with ribosomes and with Hcr1p, a protein involved in rRNA processing and translation initiation. Depletion of Rli1p causes a nuclear export defect of the small and large ribosomal subunits and subsequently a translational arrest. Thus, ribosome biogenesis and function are intimately linked to the crucial role of mitochondria in the maturation of the essential Fe/S protein Rli1p.     

The essential mitochondrial protein Erv1 cooperates with Mia40 in biogenesis of intermembrane space proteins

The proteins of the mitochondrial intermembrane space (IMS) are encoded by nuclear genes and synthesized on cytosolic ribosomes. While some IMS proteins are imported by the classical presequence pathway that involves the membrane potential deltapsi across the inner mitochondrial membrane and proteolytic processing to release the mature protein to the IMS, the import of numerous small IMS proteins is independent of a deltapsi and does not include proteolytic processing. The biogenesis of small IMS proteins requires an essential mitochondrial IMS import and assembly protein, termed Mia40. Here, we show that Erv1, a further essential IMS protein that has been reported to function as a sulfhydryl oxidase and participate in biogenesis of Fe/S proteins, is also required for the biogenesis of small IMS proteins. We generated a temperature-sensitive yeast mutant of Erv1 and observed a strong reduction of the levels of small IMS proteins upon shift of the cells to non-permissive temperature. Isolated erv1-2 mitochondria were selectively impaired in import of small IMS proteins while protein import pathways to other mitochondrial subcompartments were not affected. Small IMS precursor proteins remained associated with Mia40 in erv1-2 mitochondria and were not assembled into mature oligomeric complexes. Moreover, Erv1 associated with Mia40 in a reductant-sensitive manner. We conclude that two essential proteins, Mia40 and Erv1, cooperate in the assembly pathway of small proteins of the mitochondrial IMS.     

Mitochondrial Iba57p is required for Fe/S cluster formation on aconitase and activation of radical SAM enzymes

A genome-wide screen for Saccharomyces cerevisiae iron-sulfur (Fe/S) cluster assembly mutants identified the gene IBA57. The encoded protein Iba57p is located in the mitochondrial matrix and is essential for mitochondrial DNA maintenance. The growth phenotypes of an iba57Δ mutant and extensive functional studies in vivo and in vitro indicate a specific role for Iba57p in the maturation of mitochondrial aconitase-type and radical SAM Fe/S proteins (biotin and lipoic acid synthases). Maturation of other Fe/S proteins occurred normally in the absence of Iba57p. These observations identify Iba57p as a novel dedicated maturation factor with specificity for a subset of Fe/S proteins. The Iba57p primary sequence is distinct from any known Fe/S assembly factor but is similar to certain tetrahydrofolate-binding enzymes, adding a surprising new function to this protein family. Iba57p physically interacts with the mitochondrial ISC assembly components Isa1p and Isa2p. Since all three proteins are conserved in eukaryotes and bacteria, the specificity of the Iba57/Isa complex may represent a biosynthetic concept that is universally used in nature. In keeping with this idea, the human IBA57 homolog C1orf69 complements the iba57Δ growth defects, demonstrating its conserved function throughout the eukaryotic kingdom.     

The hydrogenase-like Nar1p is essential for maturation of cytosolic and nuclear iron-sulphur proteins

The genome of the yeast Saccharomyces cerevisiae encodes the essential protein Nar1p that is conserved in virtually all eukaryotes and exhibits striking sequence similarity to bacterial iron-only hydrogenases. A human homologue of Nar1p was shown previously to bind prenylated prelamin A in the nucleus. However, yeast neither exhibits hydrogenase activity nor contains nuclear lamins. Here, we demonstrate that Nar1p is predominantly located in the cytosol and contains two adjacent iron-sulphur (Fe/S) clusters. Assembly of its Fe/S clusters crucially depends on components of the mitochondrial Fe/S cluster biosynthesis apparatus such as the cysteine desulphurase Nfs1p, the ferredoxin Yah1p and the ABC transporter Atm1p. Using functional studies in vivo, we show that Nar1p is required for maturation of cytosolic and nuclear, but not of mitochondrial, Fe/S proteins. Nar1p-depleted cells do not accumulate iron in mitochondria, distinguishing these cells from mutants in components of the mitochondrial Fe/S cluster biosynthesis apparatus. In conclusion, Nar1p represents a crucial, novel component of the emerging cytosolic Fe/S protein assembly machinery that catalyses an essential and ancient process in eukaryotes.     

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 the iron-sulfur cluster (ISC) assembly machinery. Little is known about the formation of Fe/S proteins in the cytosol and nucleus. A function of mitochondria in cytosolic Fe/S protein maturation has been noted, but small amounts of some ISC components have been detected outside mitochondria. Here, we studied the highly conserved yeast proteins Isu1p and Isu2p, which provide a scaffold for Fe/S cluster synthesis. We asked whether the Isu proteins are needed for biosynthesis of cytosolic Fe/S clusters and in which subcellular compartment the Isu proteins are required. The Isu proteins were found to be essential for de novo biosynthesis of both mitochondrial and cytosolic Fe/S proteins. Several lines of evidence indicate that Isu1p and Isu2p have to be located inside mitochondria in order to perform their function in cytosolic Fe/S protein maturation. We were unable to mislocalize Isu1p to the cytosol due to the presence of multiple, independent mitochondrial targeting signals in this protein. Further, the bacterial homologue IscU and the human Isu proteins (partially) complemented the defects of yeast Isu protein-depleted cells in growth rate, Fe/S protein biogenesis, and iron homeostasis, yet only after targeting to mitochondria. Together, our data suggest that the Isu proteins need to be localized in mitochondria to fulfill their functional requirement in Fe/S protein maturation in the cytosol.     

Yeast ERV2p is the first microsomal FAD-linked sulfhydryl oxidase of the Erv1p/Alrp protein family

Saccharomyces cerevisiae Erv2p was identified previously as a distant homologue of Erv1p, an essential mitochondrial protein exhibiting sulfhydryl oxidase activity. Expression of the ERV2 (essential for respiration and vegetative growth 2) gene from a high-copy plasmid cannot substitute for the lack of ERV1, suggesting that the two proteins perform nonredundant functions. Here, we show that the deletion of the ERV2 gene or the depletion of Erv2p by regulated gene expression is not associated with any detectable growth defects. Erv2p is located in the microsomal fraction, distinguishing it from the mitochondrial Erv1p. Despite their distinct subcellular localization, the two proteins exhibit functional similarities. Both form dimers in vivo and in vitro, contain a conserved YPCXXC motif in their carboxyl-terminal part, bind flavin adenine dinucleotide (FAD) as a cofactor, and catalyze the formation of disulfide bonds in protein substrates. The catalytic activity, the ability to form dimers, and the binding of FAD are associated with the carboxyl-terminal domain of the protein. Our findings identify Erv2p as the first microsomal member of the Erv1p/Alrp protein family of FAD-linked sulfhydryl oxidases. We propose that Erv2p functions in the generation of microsomal disulfide bonds acting in parallel with Ero1p, the essential, FAD-dependent oxidase of protein disulfide isomerase.     

Divergent Molecular Evolution of the Mitochondrial Sulfhydryl:Cytochrome c Oxidoreductase Erv in Opisthokonts and Parasitic Protists

Mia40 and the sulfhydryl:cytochrome c oxidoreductase Erv1/ALR are essential for oxidative protein import into the mitochondrial intermembrane space in yeast and mammals. Although mitochondrial protein import is functionally conserved in the course of evolution, many organisms seem to lack Mia40. Moreover, except for in organello import studies and in silico analyses, nothing is known about the function and properties of protist Erv homologues. Here we compared Erv homologues from yeast, the kinetoplastid parasite Leishmania tarentolae, and the non-related malaria parasite Plasmodium falciparum. Both parasite proteins have altered cysteine motifs, formed intermolecular disulfide bonds in vitro and in vivo, and could not replace Erv1 from yeast despite successful mitochondrial protein import in vivo. To analyze its enzymatic activity, we established the expression and purification of recombinant full-length L. tarentolae Erv and compared the mechanism with related and non-related flavoproteins. Enzyme assays indeed confirmed an electron transferase activity with equine and yeast cytochrome c, suggesting a conservation of the enzymatic activity in different eukaryotic lineages. However, although Erv and non-related flavoproteins are intriguing examples of convergent molecular evolution resulting in similar enzyme properties, the mechanisms of Erv homologues from parasitic protists and opisthokonts differ significantly. In summary, the Erv-mediated reduction of cytochrome c might be highly conserved throughout evolution despite the apparent absence of Mia40 in many eukaryotes. Nevertheless, the knowledge on mitochondrial protein import in yeast and mammals cannot be generally transferred to all other eukaryotes, and the corresponding pathways, components, and mechanisms remain to be analyzed.     

Role of tryptophan residues of Erv1: Trp95 and Trp183 are important for its folding and oxidase function

Erv1 is an FAD-dependent thiol oxidase of the ERV (essential for respiration and viability)/ALR (augmenter of liver regeneration) sub-family and an essential component of the mitochondrial import and assembly pathway. Erv1 contains six tryptophan residues, which are all located in the highly conserved C-terminal FAD-binding domain. Though important structural roles were predicted for the invariable Trp⁹⁵, no experimental study has been reported. In the present study, we investigated the structural and functional roles of individual tryptophan residues of Erv1. Six single tryptophan-to-phenylalanine yeast mutant strains were generated and their effects on cell viability were tested at various temperatures. Then, the mutants were purified from Escherichia coli. Their effects on folding, FAD-binding and Erv1 activity were characterized. Our results showed that Erv1^W95F has the strongest effect on the stability and function of Erv1 and followed by Erv1^W183F. Erv1^W95F results in a decrease in the T_m of Erv1 by 23°C, a significant loss of the oxidase activity and thus causing cell growth defects at both 30°C and 37°C. Erv1^W183F induces changes in the oligomerization state of Erv1, along with a pronounced effect on the stability of Erv1 and its function at 37°C, whereas the other mutants had no clear effect on the function of Erv1 including the highly conserved Trp¹⁵⁷ mutant. Finally, computational analysis indicates that Trp⁹⁵ plays a key role in stabilizing the isoalloxazine ring to interact with Cys¹³³. Taken together, the present study provided important insights into the molecular mechanism of how thiol oxidases use FAD in catalysing disulfide bond formation.     

Functional characterization of the eukaryotic cysteine desulfurase Nfs1p from Saccharomyces cerevisiae

Previous studies have indicated that the essential protein Nfs1 performs a crucial role in cellular iron-sulfur (Fe/S) protein maturation. The protein is located predominantly in mitochondria, yet low amounts are present in cytosol and nucleus. Here we examined several aspects concerning the molecular function of yeast Nfs1p as a model protein. First, we demonstrated that purified Nfs1p facilitates the in vitro assembly of Fe/S proteins by using cysteine as its specific substrate. Thus, eukaryotic Nfs1 is a functional orthologue of the bacterial cysteine desulfurase IscS. Second, we showed that only the mitochondrial version but not the extramitochondrial version of Nfs1p is functional in generating cytosolic and nuclear Fe/S proteins. Mutation of the nuclear targeting signal of Nfs1p did not affect the maturation of cytosolic and nuclear Fe/S proteins, despite a severe growth defect under this condition. Nfs1p could not assemble an Fe/S cluster on the Isu scaffold proteins when they were located in the yeast cytosol. The lack of function of these central Fe/S cluster assembly components suggests that the maturation of extramitochondrial Fe/S protein does not involve functional copies of the mitochondrial Fe/S cluster assembly machinery in the yeast cytosol. Third, the extramitochondrial version of Nfs1p was shown to play a direct role in the thiomodification of tRNAs. Finally, we identified a highly conserved N-terminal beta-sheet of Nfs1p as a functionally essential part of the protein. The implication of these findings for the structural stability of Nfs1p and for its targeting mechanism to mitochondria and cytosol/nucleus will be discussed.     

Isa1p is a component of the mitochondrial machinery for maturation of cellular iron-sulfur proteins and requires conserved cysteine residues for function

In eukaryotes, mitochondria execute a central task in the assembly of cellular iron-sulfur (Fe/S) proteins. The organelles synthesize their own set of Fe/S proteins, and they initiate the generation of extramitochondrial Fe/S proteins. In the present study, we identify the mitochondrial matrix protein Isa1p of Saccharomyces cerevisiae as a new member of the Fe/S cluster biosynthesis machinery. Isa1p belongs to a family of homologous proteins present in prokaryotes and eukaryotes. Deletion of the ISA1 gene results in the loss of mitochondrial DNA precluding the use of the Deltaisa1 strain for functional analysis. Cells in which Isa1p was depleted by regulated gene expression maintained the mitochondrial DNA, yet the cells displayed retarded growth on nonfermentable carbon sources. This finding indicates the importance of Isa1p for mitochondrial function. Deficiency of Isa1p caused a defect in mitochondrial Fe/S protein assembly. Moreover, Isa1p was required for maturation of cytosolic Fe/S proteins. Two cysteine residues in a conserved sequence motif characterizing the Isa1p protein family were found to be essential for Isa1p function in the biogenesis of both intra- and extramitochondrial Fe/S proteins. Our findings suggest a function for Isa1p in the binding of iron or an intermediate of Fe/S cluster assembly.     

Deciphering Structural and Functional Roles of Individual Disulfide Bonds of the Mitochondrial Sulfhydryl Oxidase Erv1p

Erv1p is a FAD-dependent sulfhydryl oxidase of the mitochondrial intermembrane space. It contains three conserved disulfide bonds arranged in two CXXC motifs and one CX₁₆C motif. Experimental evidence for the specific roles of the individual disulfide bonds is lacking. In this study, structural and functional roles of the disulfides were dissected systematically using a wide range of biochemical and biophysical methods. Three double cysteine mutants with each pair of cysteines mutated to serines were generated. All of the mutants were purified with the normal FAD binding properties as the wild type Erv1p, showing that none of the three disulfides are essential for FAD binding. Thermal denaturation and trypsin digestion studies showed that the CX₁₆C disulfide plays an important role in stabilizing the folding of Erv1p. To understand the functional role of each disulfide, small molecules and the physiological substrate protein Mia40 were used as electron donors in oxygen consumption assays. We show that both CXXC disulfides are required for Erv1 oxidase activity. The active site disulfide is well protected thus requires the shuttle disulfide for its function. Although both mutants of the CXXC motifs were individually inactive, Erv1p activity was partially recovered by mixing these two mutants together, and the recovery was rapid. Thus, we provided the first experimental evidence of electron transfer between the shuttle and active site disulfides of Erv1p, and we propose that both intersubunit and intermolecular electron transfer can occur.Disulfide bonds play very important roles in the structure and function of many proteins by stabilizing protein folding and/or acting as thiol/disulfide redox switches. The process of disulfide formation is catalyzed by dedicated enzymes in vivo (1–4). Erv1p is a FAD-dependent sulfhydryl oxidase located in the Saccharomyces cerevisiae mitochondrial intermembrane space (4–6). It is an essential component of the redox regulated Mia40/Erv1 import and assembly pathway used by many of the cysteine-containing intermembrane space proteins, such as members of the “small Tim” and Cox17 families (7–10). Upon import of a Cys-reduced substrate, Mia40 interacts with the substrate via intermolecular disulfide bond and shuttles a disulfide to its substrate. Although oxidized Mia40 promotes disulfide bond formation in the substrates, Erv1p functions in catalyzing reoxidation of the reduced Mia40 and/or release of the substrate (11–13).The common features for the FAD-dependent sulfhydryl oxidases are that the enzymes can catalyze the electron transfer from substrate molecules (e.g. protein thiols) through the noncovalent bound FAD cofactor to molecular oxygen or oxidized cytochrome c (14). The sulfhydryl oxidases can be divided into three groups: Ero1 enzymes, multidomain quiesin sulfhydryl oxidases, and single domain Erv (essential for respiration and vegetative growth)/ALR proteins. The yeast Ero1p and the mammalian homologues (Ero1α and Ero1β) are large flavoenzymes present in the ER with at least five disulfide bonds, but only two of the disulfide bonds are conserved. The conserved cysteines are essential for the catalytic activity of Ero1p forming the active site CXXC and shuttle disulfide CX₄C, respectively (15, 16). Furthermore, nonconserved disulfide bonds have been shown recently to be important in regulating the activity of both yeast and mammalian Ero1 (17–19). The second group of oxidases, the multidomain quiesin sulfhydryl oxidases, have important functions in higher eukaryotes (14, 20). Quiesin sulfhydryl oxidases consist of an Erv/ALR module fused to one or more thioredoxin-like domains with two conserved CXXC motifs in the Erv/ALR module. Quiesin sulfhydryl oxidase enzymes are found in many subcellular and extracellular locations, but not in mitochondria. Instead, single domain Erv/ARL enzymes of the third group are found in the 7mitochondria of many eukaryotic cells (21). Erv1p belongs to this single domain Erv/ARL family, which includes the human mitochondrial ARL, plant AtErv1, and yeast Erv2p of the ER lumen.The Erv/ARL enzymes are characterized by a highly conserved central catalytic core of ∼100 amino acids, which includes an active site CXXC motif (Cys¹³⁰–Cys¹³³ for Erv1p), CX₁₆C disulfide bond (Cys¹⁵⁹–Cys¹⁷⁶ for Erv1p), and residues involved in FAD binding (Fig. 1A). Based on the partial crystal structure data of Erv2p (22) and AtErv1 (23), the catalytic core of Erv proteins contains a four-helix bundle forming the noncovalent FAD-binding site with the active site CXXC in close proximity to the isoalloxazine ring of FAD. In addition, the long range CX₁₆C disulfide bond of the Erv proteins brings the short fifth helix to the four-helix bundle in proximity to the adenine ring of FAD (Fig. 1A). Thus, the CX₁₆C disulfide bond is proposed to play a structural role in stabilizing the FAD binding and/or protein folding, but direct experimental evidence to verify the roles is lacking. Apart from the catalytic core, the other parts of the proteins seem flexible and unfolded. Importantly, all members of the Erv/ALR family have at least an additional disulfide bond located in the nonconserved N- or C-terminal region to the catalytic core (Fig. 1B), which is hypothesized as a shuttle disulfide based on the partial crystal structure of Erv2 (22). The hypothesized shuttle disulfide of Erv2p CXC and AtErv1 CX₄C are located in the C terminus, but Erv1p (Cys³⁰–Cys³³) and ALR have a CXXC shuttle disulfide located N-terminal to the catalytic core. Furthermore, structural and chemical data have suggested that Erv/ARL enzymes form homodimer or oligomers in the presence or absence of intermolecular disulfide bonds (5, 23, 24).Open in a separate windowFIGURE 1.Structure and conserved Cys motifs of Erv/ALR enzymes. A, modeled structures of the conserved central catalytic core domain of Erv1p dimer based on the crystal structure data of AtErv1 (Protein Data Bank accession number 2HJ3, residues 73–173, the helix 1 starts with residue 75). The helices of the four-helix bundle and the short fifth helix are labeled from 1 to 5. The two disulfides are shown as yellow spheres, and the cofactor FAD is in red. The Cys¹³⁰–Cys¹³³ is the redox active disulfide located closely to the isoalloxazine ring of FAD. The N and C termini were labeled as N and C, respectively. The structure was generated using Pymol program. B, schematic of the primary structure of yeast, plant, and human sulfhydryl oxidase with the conserved Cys motifs. The conserved central catalytic core regions are shown as black bars, and the nonconserved regions are in gray.Yeast mitochondrial Erv1p contains a total of six Cys residues forming three pairs of disulfide bonds (residues 30–33, 130–133, and 159–176) as described above. Previous studies with single Cys mutants showed that although all three disulfide bonds are essential for Erv1p function in vivo, only Cys¹³⁰–Cys¹³³ disulfide is required for the oxidase activity of Erv1p in vitro (24). The conclusion that only Cys¹³⁰–Cys¹³³ disulfide is required for Erv1p oxidase activity in vitro was based on a study using the artificial substrate DTT² as the electron donor. Abnormal color changes were observed for some of the single Cys mutants of Erv1p in the previous study that were probably caused by protein misfolding or formation of non-native disulfides because of the presence of a redox active but unpaired Cys. It is clear that Cys¹³⁰–Cys¹³³ is the active site disulfide; however, experimental evidence for the role of Cys³⁰–Cys³³ disulfide is lacking, and the specific role played by the unique CX₁₆C motif of Erv proteins is unknown.In this study, we dissected the structural and functional roles of all three individual disulfides of Erv1p systematically. To avoid misfolding via unpaired Cys, three double Cys mutants of Erv1p were generated with each of the disulfides mutated to serines. All three mutants were successfully purified with the normal FAD binding properties of the wild type (WT) Erv1p. Various biophysical and biochemical methods were used to study the folding and oxidase activity of the WT and Erv1p mutants. Both artificial and the natural substrate (Mia40) of Erv1p were used as electron donors to understand the functional mechanism of Erv1p. Our results show that both the first (Cys³⁰–Cys³³) and second (Cys¹³⁰–Cys¹³³) disulfides are essential for Erv1 oxidase activity in vitro. Although none of the three disulfides are essential for FAD binding, the third disulfide (Cys¹⁵⁹–Cys¹⁷⁶) plays an important role in stabilizing the folding of Erv1p. More importantly, this study provided direct experimental evidence to show that Cys³⁰–Cys³³ functionally acts as a shuttle disulfide passing electrons to the active site Cys¹³⁰–Cys¹³³ disulfide. Moreover, the electron transfer seems to occur through both intersubunit and intermolecular interactions.     

Erv2p: characterization of the redox behavior of a yeast sulfhydryl oxidase

The FAD prosthetic group of the ERV/ALR family of sulfhydryl oxidases is housed at the mouth of a 4-helix bundle and communicates with a pair of juxtaposed cysteine residues that form the proximal redox active disulfide. Most of these enzymes have one or more additional distal disulfide redox centers that facilitate the transfer of reducing equivalents from the dithiol substrates of these oxidases to the isoalloxazine ring where the reaction with molecular oxygen occurs. The present study examines yeast Erv2p and compares the redox behavior of this ER luminal protein with the augmenter of liver regeneration, a sulfhydryl oxidase of the mitochondrial intermembrane space, and a larger protein containing the ERV/ALR domain, quiescin-sulfhydryl oxidase (QSOX). Dithionite and photochemical reductions of Erv2p show full reduction of the flavin cofactor after the addition of 4 electrons with a midpoint potential of -200 mV at pH 7.5. A charge-transfer complex between a proximal thiolate and the oxidized flavin is not observed in Erv2p consistent with a distribution of reducing equivalents over the flavin and distal disulfide redox centers. Upon coordination with Zn2+, full reduction of Erv2p requires 6 electrons. Zn2+ also strongly inhibits Erv2p when assayed using tris(2-carboxyethyl)phosphine (TCEP) as the reducing substrate of the oxidase. In contrast to QSOX, Erv2p shows a comparatively low turnover with a range of small thiol substrates, with reduced Escherichia coli thioredoxin and with unfolded proteins. Rapid reaction studies confirm that reduction of the flavin center of Erv2p is rate-limiting during turnover with molecular oxygen. This comparison of the redox properties between members of the ERV/ALR family of sulfhydryl oxidases provides insights into their likely roles in oxidative protein folding.     

Precursor oxidation by Mia40 and Erv1 promotes vectorial transport of proteins into the mitochondrial intermembrane space

The mitochondrial intermembrane space contains chaperone complexes that guide hydrophobic precursor proteins through this aqueous compartment. The chaperones consist of hetero-oligomeric complexes of small Tim proteins with conserved cysteine residues. The precursors of small Tim proteins are synthesized in the cytosol. Import of the precursors requires the essential intermembrane space proteins Mia40 and Erv1 that were proposed to form a relay for disulfide formation in the precursor proteins. However, experimental evidence for a role of Mia40 and Erv1 in the oxidation of intermembrane space precursors has been lacking. We have established a system to directly monitor the oxidation of precursors during import into mitochondria and dissected distinct steps of the import process. Reduced precursors bind to Mia40 during translocation into mitochondria. Both Mia40 and Erv1 are required for formation of oxidized monomers of the precursors that subsequently assemble into oligomeric complexes. Whereas the reduced precursors can diffuse back into the cytosol, the oxidized precursors are retained in the intermembrane space. Thus, oxidation driven by Mia40 and Erv1 determines vectorial transport of the precursors into the mitochondrial intermembrane space.     

Dre2, a conserved eukaryotic Fe/S cluster protein, functions in cytosolic Fe/S protein biogenesis

In a forward genetic screen for interaction with mitochondrial iron carrier proteins in Saccharomyces cerevisiae, a hypomorphic mutation of the essential DRE2 gene was found to confer lethality when combined with Δmrs3 and Δmrs4. The dre2 mutant or Dre2-depleted cells were deficient in cytosolic Fe/S cluster protein activities while maintaining mitochondrial Fe/S clusters. The Dre2 amino acid sequence was evolutionarily conserved, and cysteine motifs (CX₂CXC and twin CX₂C) in human and yeast proteins were perfectly aligned. The human Dre2 homolog (implicated in blocking apoptosis and called CIAPIN1 or anamorsin) was able to complement the nonviability of a Δdre2 deletion strain. The Dre2 protein with triple hemagglutinin tag was located in the cytoplasm and in the mitochondrial intermembrane space. Yeast Dre2 overexpressed and purified from bacteria was brown and exhibited signature absorption and electron paramagnetic resonance spectra, indicating the presence of both [2Fe-2S] and [4Fe-4S] clusters. Thus, Dre2 is an essential conserved Fe/S cluster protein implicated in extramitochondrial Fe/S cluster assembly, similar to other components of the so-called CIA (cytoplasmic Fe/S cluster assembly) pathway although partially localized to the mitochondrial intermembrane space.     

Structure of Yeast Sulfhydryl Oxidase Erv1 Reveals Electron Transfer of the Disulfide Relay System in the Mitochondrial Intermembrane Space

The disulfide relay system in the mitochondrial intermembrane space drives the import of proteins with twin CX₉C or twin CX₃C motifs by an oxidative folding mechanism. This process requires disulfide bond transfer from oxidized Mia40 to a substrate protein. Reduced Mia40 is reoxidized/regenerated by the FAD-linked sulfhydryl oxidase Erv1 (EC 1.8.3.2). Full-length Erv1 consists of a flexible N-terminal shuttle domain (NTD) and a conserved C-terminal core domain (CTD). Here, we present crystal structures at 2.0 Å resolution of the CTD and at 3.0 Å resolution of a C30S/C133S double mutant of full-length Erv1 (Erv1FL). Similar to previous homologous structures, the CTD exists as a homodimer, with each subunit consisting of a conserved four-helix bundle that accommodates the isoalloxazine ring of FAD and an additional single-turn helix. The structure of Erv1FL enabled us to identify, for the first time, the three-dimensional structure of the Erv1NTD, which is an amphipathic helix flanked by two flexible loops. This structure also represents an intermediate state of electron transfer from the NTD to the CTD of another subunit. Comparative structural analysis revealed that the four-helix bundle of the CTD forms a wide platform for the electron donor NTD. Moreover, computational simulation combined with multiple-sequence alignment suggested that the amphipathic helix close to the shuttle redox enter is critical for the recognition of Mia40, the upstream electron donor. These findings provide structural insights into electron transfer from Mia40 via the shuttle domain of one subunit of Erv1 to the CTD of another Erv1 subunit.