In vivo iron-sulfur cluster formation

It has been proposed that iron-sulfur [Fe-S] clusters destined for the maturation of [Fe-S] proteins can be preassembled on a molecular scaffold designated IscU. In the present article, it is shown that production of the intact Azotobacter vinelandii [Fe-S] cluster biosynthetic machinery at levels exceeding the amount required for cellular maturation of [Fe-S] proteins results in the accumulation of: (i) apo-IscU, (ii) an oxygen-labile [2Fe-2S] cluster-loaded form of IscU, and (iii) IscU complexed with the S-delivery protein, IscS. It is suggested that these species represent different stages of the [Fe-S] cluster assembly process. Substitution of the IscU Asp(39) residue by Ala results in the in vivo trapping of a stoichiometric, noncovalent, nondissociating IscU-IscS complex that contains an oxygen-resistant [Fe-S] species. In aggregate, these results validate the scaffold hypothesis for [Fe-S] cluster assembly and indicate that in vivo [Fe-S] cluster formation is a dynamic process that involves the reversible interaction of IscU and IscS.     

Evidence for a conserved system for iron metabolism in the mitochondria of Saccharomyces cerevisiae

nifU of nitrogen-fixing bacteria is involved in the synthesis of the Fe-S cluster of nitrogenase. In a synthetic lethal screen with the mitochondrial heat shock protein (HSP)70, SSQ1, we identified a gene of Saccharomyces cerevisiae, NFU1, which encodes a protein with sequence identity to the C-terminal domain of NifU. Two other yeast genes were found to encode proteins related to the N-terminal domain of bacterial NifU. They have been designated ISU1 and ISU2. Isu1, Isu2, and Nfu1 are located in the mitochondrial matrix. ISU genes of yeast carry out an essential function, because a Deltaisu1Deltaisu2 strain is inviable. Growth of Deltanfu1Delta isu1 cells is significantly compromised, allowing assessment of the physiological roles of Nfu and Isu proteins. Mitochondria from Deltanfu1Deltaisu1 cells have decreased activity of several respiratory enzymes that contain Fe-S clusters. As a result, Deltanfu1Deltaisu1 cells grow poorly on carbon sources requiring respiration. Deltanfu1Deltaisu1 cells also accumulate abnormally high levels of iron in their mitochondria, similar to Deltassq1 cells, indicating a role for these proteins in iron metabolism. We suggest that NFU1 and ISU1 gene products play a role in iron homeostasis, perhaps in assembly, insertion, and/or repair of mitochondrial Fe-S clusters. The conservation of these protein domains in many organisms suggests that this role has been conserved throughout evolution.     

Chloroplast iron-sulfur cluster protein maturation requires the essential cysteine desulfurase CpNifS

NifS-like proteins provide the sulfur (S) for the formation of iron-sulfur (Fe-S) clusters, an ancient and essential type of cofactor found in all three domains of life. Plants are known to contain two distinct NifS-like proteins, localized in the mitochondria (MtNifS) and the chloroplast (CpNifS). In the chloroplast, five different Fe-S cluster types are required in various proteins. These plastid Fe-S proteins are involved in a variety of biochemical pathways including photosynthetic electron transport and nitrogen and sulfur assimilation. In vitro, the chloroplastic cysteine desulfurase CpNifS can release elemental sulfur from cysteine for Fe-S cluster biogenesis in ferredoxin. However, because of the lack of a suitable mutant allele, the role of CpNifS has not been studied thus far in planta. To study the role of CpNifS in Fe-S cluster biogenesis in vivo, the gene was silenced by using an inducible RNAi (interference) approach. Plants with reduced CpNifS expression exhibited chlorosis, a disorganized chloroplast structure, and stunted growth and eventually became necrotic and died before seed set. Photosynthetic electron transport and carbon dioxide assimilation were severely impaired in the silenced plant lines. The silencing of CpNifS decreased the abundance of all chloroplastic Fe-S proteins tested, representing all five Fe-S cluster types. Mitochondrial Fe-S proteins and respiration were not affected, suggesting that mitochondrial and chloroplastic Fe-S assembly operate independently. These findings indicate that CpNifS is necessary for the maturation of all plastidic Fe-S proteins and, thus, essential for plant growth.     

Disordered form of the scaffold protein IscU is the substrate for iron-sulfur cluster assembly on cysteine desulfurase

The scaffold protein for iron-sulfur cluster assembly, apo-IscU, populates two interconverting conformational states, one disordered (D) and one structured (S) as revealed by extensive NMR assignments. At pH 8 and 25 °C, approximately 70% of the protein is S, and the lifetimes of the states are 1.3 s (S) and 0.50 s (D). Zn(II) and Fe(II) each bind and stabilize structured (S-like) states. Single amino acid substitutions at conserved residues were found that shift the equilibrium toward either the S or the D state. Cluster assembly takes place in the complex between IscU and the cysteine desulfurase, IscS, and our NMR studies demonstrate that IscS binds preferentially the D form of apo-IscU. The addition of 10% IscS to IscU was found to greatly increase H/D exchange at protected amides of IscU, to increase the rate of the S → D reaction, and to decrease the rate of the D → S reaction. In the saturated IscU:IscS complex, IscU is largely disordered. In vitro cluster assembly reactions provided evidence for the functional importance of the S⇆D equilibrium. IscU variants that favor the S state were found to undergo a lag phase, not observed with the wild type, that delayed cluster assembly; variants that favor the D state were found to assemble less stable clusters at an intermediate rate without the lag. It appears that IscU has evolved to exist in a disordered conformational state that is the initial substrate for the desulfurase and to convert to a structured state that stabilizes the cluster once it is assembled.     

NifS-directed assembly of a transient [2Fe-2S] cluster within the NifU protein

The NifS and NifU proteins from Azotobacter vinelandii are required for the full activation of nitrogenase. NifS is a homodimeric cysteine desulfurase that supplies the inorganic sulfide necessary for formation of the Fe-S clusters contained within the nitrogenase component proteins. NifU has been suggested to complement NifS either by mobilizing the Fe necessary for nitrogenase Fe-S cluster formation or by providing an intermediate Fe-S cluster assembly site. As isolated, the homodimeric NifU protein contains one [2Fe-2S](2+, +) cluster per subunit, which is referred to as the permanent cluster. In this report, we show that NifU is able to interact with NifS and that a second, transient [2Fe-2S] cluster can be assembled within NifU in vitro when incubated in the presence of ferric ion, L-cysteine, and catalytic amounts of NifS. Approximately one transient [2Fe-2S] cluster is assembled per homodimer. The transient [2Fe-2S] cluster species is labile and rapidly released on reduction. We propose that transient [2Fe-2S] cluster units are formed on NifU and then released to supply the inorganic iron and sulfur necessary for maturation of the nitrogenase component proteins. The role of the permanent [2Fe-2S] clusters contained within NifU is not yet known, but they could have a redox function involving either the formation or release of transient [2Fe-2S] cluster units assembled on NifU. Because homologs to both NifU and NifS, respectively designated IscU and IscS, are found in non-nitrogen fixing organisms, it is possible that the function of NifU proposed here could represent a general mechanism for the maturation of Fe-S cluster-containing proteins.     

Cysteine desulfurase Nfs1 and Pim1 protease control levels of Isu, the Fe-S cluster biogenesis scaffold

Fe-S clusters are critical prosthetic groups for proteins involved in various critical biological processes. Before being transferred to recipient apo-proteins, Fe-S clusters are assembled on the highly conserved scaffold protein Isu, the abundance of which is regulated posttranslationally on disruption of the cluster biogenesis system. Here we report that Isu is degraded by the Lon-type AAA+ ATPase protease of the mitochondrial matrix, Pim1. Nfs1, the cysteine desulfurase responsible for providing sulfur for cluster formation, is required for the increased Isu stability occurring after disruption of cluster formation on or transfer from Isu. Physical interaction between the Isu and Nfs1 proteins, not the enzymatic activity of Nfs1, is the important factor in increased stability. Analysis of several conditions revealed that high Isu levels can be advantageous or disadvantageous, depending on the physiological condition. During the stationary phase, elevated Isu levels were advantageous, resulting in prolonged chronological lifespan. On the other hand, under iron-limiting conditions, high Isu levels were deleterious. Compared with cells expressing normal levels of Isu, such cells grew poorly and exhibited reduced activity of the heme-containing enzyme ferric reductase. Our results suggest that modulation of the degradation of Isu by the Pim1 protease is a regulatory mechanism serving to rapidly help balance the cell's need for critical iron-requiring processes under changing environmental conditions.     

The cysteine desulfurase, IscS, has a major role in in vivo Fe-S cluster formation in Escherichia coli

The cysteine desulfurase, IscS, provides sulfur for Fe-S cluster synthesis in vitro, but a role for IscS in in vivo Fe-S cluster formation has yet to be established. To study the in vivo function of IscS in Escherichia coli, a strain lacking IscS was constructed and characterized. Using this iscS deletion strain, we have observed decreased specific activities for proteins containing [4Fe-4S] clusters from soluble (aconitase B, 6-phosphogluconate dehydratase, glutamate synthase, fumarase A, and FNR) and membrane-bound proteins (NADH dehydrogenase I and succinate dehydrogenase). A specific role for IscS in in vivo Fe-S cluster assembly was demonstrated by showing that an Fe-S cluster independent mutant of FNR is unaffected by the lack of IscS. These data support the conclusion that, via its cysteine desulfurase activity, IscS provides the sulfur that subsequently becomes incorporated during in vivo Fe-S cluster synthesis. We also have characterized a growth phenotype associated with the loss of IscS. Under aerobic conditions the deletion of IscS caused an auxotrophy for thiamine and nicotinic acid, whereas under anaerobic conditions, only nicotinic acid was required. The lack of IscS also had a general effect on the growth of E. coli because the iscS deletion strain grew at half the rate of wild type in many types of media even when the auxotrophies were satisfied.     

Evolution of Fe/S cluster biogenesis in the anaerobic parasite Blastocystis

Iron/sulfur cluster (ISC)-containing proteins are essential components of cells. In most eukaryotes, Fe/S clusters are synthesized by the mitochondrial ISC machinery, the cytosolic iron/sulfur assembly system, and, in photosynthetic species, a plastid sulfur-mobilization (SUF) system. Here we show that the anaerobic human protozoan parasite Blastocystis, in addition to possessing ISC and iron/sulfur assembly systems, expresses a fused version of the SufC and SufB proteins of prokaryotes that it has acquired by lateral transfer from an archaeon related to the Methanomicrobiales, an important lineage represented in the human gastrointestinal tract microbiome. Although components of the Blastocystis ISC system function within its anaerobic mitochondrion-related organelles and can functionally replace homologues in Trypanosoma brucei, its SufCB protein has similar biochemical properties to its prokaryotic homologues, functions within the parasite's cytosol, and is up-regulated under oxygen stress. Blastocystis is unique among eukaryotic pathogens in having adapted to its parasitic lifestyle by acquiring a SUF system from nonpathogenic Archaea to synthesize Fe/S clusters under oxygen stress.     

Cys-328 of IscS and Cys-63 of IscU are the sites of disulfide bridge formation in a covalently bound IscS/IscU complex: implications for the mechanism of iron-sulfur cluster assembly

IscS and IscU from Escherichia coli cooperate with each other in the biosynthesis of iron-sulfur clusters. IscS catalyzes the desulfurization of L-cysteine to produce L-alanine and sulfur. Cys-328 of IscS attacks the sulfur atom of L-cysteine, and the sulfane sulfur derived from L-cysteine binds to the Sgamma atom of Cys-328. In the course of the cluster assembly, IscS and IscU form a covalent complex, and a sulfur atom derived from L-cysteine is transferred from IscS to IscU. The covalent complex is thought to be essential for the cluster biogenesis, but neither the nature of the bond connecting IscS and IscU nor the residues involved in the complex formation have been determined, which have thus far precluded the mechanistic analyses of the cluster assembly. We here report that a covalent bond is formed between Cys-328 of IscS and Cys-63 of IscU. The bond is a disulfide bond, not a polysulfide bond containing sulfane sulfur between the two cysteine residues. We also found that Cys-63 of IscU is essential for the IscU-mediated activation of IscS: IscU induced a six-fold increase in the cysteine desulfurase activity of IscS, whereas the IscU mutant with a serine substitution for Cys-63 had no effect on the activity. Based on these findings, we propose a mechanism for an early stage of iron-sulfur cluster assembly: the sulfur transfer from IscS to IscU is initiated by the attack of Cys-63 of IscU on the Sgamma atom of Cys-328 of IscS that is bound to sulfane sulfur derived from L-cysteine.     

Mycobacterium tuberculosis WhiB3 responds to O2 and nitric oxide via its [4Fe-4S] cluster and is essential for nutrient starvation survival

A fundamental challenge in the redox biology of Mycobacterium tuberculosis (Mtb) is to understand the mechanisms involved in sensing redox signals such as oxygen (O2), nitric oxide (NO), and nutrient depletion, which are thought to play a crucial role in persistence. Here we show that Mtb WhiB3 responds to the dormancy signals NO and O2 through its iron-sulfur (Fe-S) cluster. To functionally assemble the WhiB3 Fe-S cluster, we identified and characterized the Mtb cysteine desulfurase (IscS; Rv3025c) and developed a native enzymatic reconstitution system for assembling Fe-S clusters in Mtb. EPR and UV-visible spectroscopy analysis of reduced WhiB3 is consistent with a one-electron reduction of EPR silent [4Fe-4S]2+ to EPR visible [4Fe-4S]+. Atmospheric O2 gradually degrades the WhiB3 [4Fe-4S]2+ cluster to generate a [3Fe-4S]+ intermediate. Furthermore, EPR analysis demonstrates that NO forms a protein-bound dinitrosyl-iron-dithiol complex with the Fe-S cluster, indicating that NO specifically targets the WhiB3 Fe-S cluster. Our data suggest that the mechanism of WhiB3 4Fe-4S cluster degradation is similar to that of fumarate nitrate regulator. Importantly, Mtb DeltawhiB3 shows enhanced growth on acetate medium, but a growth defect on media containing glucose, pyruvate, succinate, or fumarate as the sole carbon source. Our results implicate WhiB3 in metabolic switching and in sensing the physiologically relevant host signaling molecules NO and O2 through its [4Fe-4S] cluster. Taken together, our results suggest that WhiB3 is an intracellular redox sensor that integrates environmental redox signals with core intermediary metabolism.     

Interaction of the iron-sulfur cluster assembly protein IscU with the Hsc66/Hsc20 molecular chaperone system of Escherichia coli

The iscU gene in bacteria is located in a gene cluster encoding proteins implicated in iron-sulfur cluster assembly and an hsc70-type (heat shock cognate) molecular chaperone system, iscSUA-hscBA. To investigate possible interactions between these systems, we have overproduced and purified the IscU protein from Escherichia coli and have studied its interactions with the hscA and hscB gene products Hsc66 and Hsc20. IscU and its iron-sulfur complex (IscU-Fe/S) stimulated the basal steady-state ATPase activity of Hsc66 weakly in the absence of Hsc20 but, in the presence of Hsc20, increased the ATPase activity up to 480-fold. Hsc20 also decreased the apparent K(m) for IscU stimulation of Hsc66 ATPase activity, and surface plasmon resonance studies revealed that Hsc20 enhances binding of IscU to Hsc66. Surface plasmon resonance and isothermal titration calorimetry further showed that IscU and Hsc20 form a complex, and Hsc20 may thereby aid in the targeting of IscU to Hsc66. These results establish a direct and specific role for the Hsc66/Hsc20 chaperone system in functioning with isc gene components for the assembly of iron-sulfur cluster proteins.     

AtNAP7 is a plastidic SufC-like ATP-binding cassette/ATPase essential for Arabidopsis embryogenesis

In bacteria, yeast, and mammals, iron-sulfur (Fe-S) cluster-containing proteins are involved in numerous processes including electron transfer, metabolic reactions, sensing, signaling, and regulation of gene expression. In humans, iron-storage diseases such as X-linked sideroblastic anemia and ataxia are caused by defects in Fe-S cluster availability. The biogenesis of Fe-S clusters involves several pathways, and in bacteria, the SufABCDSE operon has been shown to play a vital role in Fe-S biogenesis and repair during oxidative stress. Although Fe-S proteins play vital roles in plants, Fe-S cluster biogenesis and maintenance and physiological consequences of dysfunctional Fe-S cluster assembly remains obscure. Here we report that Arabidopsis plants deficient for the SufC homolog AtNAP7 show lethality at the globular stage of embryogenesis. AtNAP7 is expressed in developing embryos and in apical, root, and floral meristems and encodes an ATP-binding cassette/ATPase that can partially rescue growth defects in an Escherichia coli SufC mutant during oxidative stress. AtNAP7 is plastid-localized, and mutant embryos contain abnormal developing plastids with disorganized thylakoid structures. We found that AtNAP7 can interact with AtNAP6, a plastidic Arabidopsis SufD homolog, and because Arabidopsis plastids also harbor SufA, SufB, SufS, and SufE homologs, plastids probably contain a complete SUF system. Our results imply that AtNAP7 represents a conserved SufC protein involved in the biogenesis and/or repair of oxidatively damaged Fe-S clusters and suggest an important role for plastidic Fe-S cluster maintenance and repair during Arabidopsis embryogenesis.     

A mitochondrial ferredoxin is essential for biogenesis of cellular iron-sulfur proteins

Iron-sulfur (Fe/S) cluster-containing proteins catalyze a number of electron transfer and metabolic reactions. The components and molecular mechanisms involved in the assembly of the Fe/S clusters have been identified only partially. In eukaryotes, mitochondria have been proposed to execute a crucial task in the generation of intramitochondrial and extramitochondrial Fe/S proteins. Herein, we identify the essential ferredoxin Yah1p of Saccharomyces cerevisiae mitochondria as a central component of the Fe/S protein biosynthesis machinery. Depletion of Yah1p by regulated gene expression resulted in a 30-fold accumulation of iron within mitochondria, similar to what has been reported for other components involved in Fe/S protein biogenesis. Yah1p was shown to be required for the assembly of Fe/S proteins both inside mitochondria and in the cytosol. Apparently, at least one of the steps of Fe/S cluster biogenesis within mitochondria requires reduction by ferredoxin. Our findings lend support to the idea of a primary function of mitochondria in the biosynthesis of Fe/S proteins outside the organelle. To our knowledge, Yah1p is the first member of the ferredoxin family for which a function in Fe/S cluster formation has been established. A similar role may be predicted for the bacterial homologs that are encoded within iron-sulfur cluster assembly (isc) operons of prokaryotes.     

Inhibition of Fe-S cluster biosynthesis decreases mitochondrial iron export: evidence that Yfh1p affects Fe-S cluster synthesis

Decreased expression of Yfh1p in the budding yeast, Saccharomyces cerevisiae, and the orthologous human gene frataxin results in respiratory deficiency and mitochondrial iron accumulation. The absence of Yfh1p decreases mitochondrial iron export. We demonstrate that decreased expression of Nfs1p, the yeast cysteine desulfurase that plays a central role in Fe-S cluster synthesis, also results in mitochondrial iron accumulation due to decreased export of mitochondrial iron. In the absence of Yfh1p, activity of Fe-S-containing enzymes (aconitase, succinate dehydrogenase) is decreased, whereas the activity of a non-Fe-S-containing enzyme (malate dehydrogenase) is unaffected. Aconitase protein was abundant even though the activity of aconitase was decreased in both aerobic and anaerobic conditions. These results demonstrate a direct role of Yfh1p in the formation of Fe-S clusters and indicate that mitochondrial iron export requires Fe-S cluster biosynthesis.     

ErpA, an iron sulfur (Fe S) protein of the A-type essential for respiratory metabolism in Escherichia coli

Understanding the biogenesis of iron-sulfur (Fe-S) proteins is relevant to many fields, including bioenergetics, gene regulation, and cancer research. Several multiprotein complexes assisting Fe-S assembly have been identified in both prokaryotes and eukaryotes. Here, we identify in Escherichia coli an A-type Fe-S protein that we named ErpA. Remarkably, erpA was found essential for growth of E. coli in the presence of oxygen or alternative electron acceptors. It was concluded that isoprenoid biosynthesis was impaired by the erpA mutation. First, the eukaryotic mevalonate-dependent pathway for biosynthesis of isopentenyl diphosphate restored the respiratory defects of an erpA mutant. Second, the erpA mutant contained a greatly reduced amount of ubiquinone and menaquinone. Third, ErpA bound Fe-S clusters and transferred them to apo-IspG, a protein catalyzing isopentenyl diphosphate biosynthesis in E. coli. Surprisingly, the erpA gene maps at a distance from any other Fe-S biogenesis-related gene. ErpA is an A-type Fe-S protein that is characterized by an essential role in cellular metabolism.     

MitoNEET is a uniquely folded 2Fe 2S outer mitochondrial membrane protein stabilized by pioglitazone

Iron-sulfur (Fe-S) proteins are key players in vital processes involving energy homeostasis and metabolism from the simplest to most complex organisms. We report a 1.5 A x-ray crystal structure of the first identified outer mitochondrial membrane Fe-S protein, mitoNEET. Two protomers intertwine to form a unique dimeric structure that constitutes a new fold to not only the approximately 650 reported Fe-S protein structures but also to all known proteins. We name this motif the NEET fold. The protomers form a two-domain structure: a beta-cap domain and a cluster-binding domain that coordinates two acid-labile 2Fe-2S clusters. Binding of pioglitazone, an insulin-sensitizing thiazolidinedione used in the treatment of type 2 diabetes, stabilizes the protein against 2Fe-2S cluster release. The biophysical properties of mitoNEET suggest that it may participate in a redox-sensitive signaling and/or in Fe-S cluster transfer.     

The mitochondrial monothiol glutaredoxin S15 is essential for iron-sulfur protein maturation in Arabidopsis thaliana

The iron-sulfur cluster (ISC) is an ancient and essential cofactor of many proteins involved in electron transfer and metabolic reactions. In Arabidopsis, three pathways exist for the maturation of iron-sulfur proteins in the cytosol, plastids, and mitochondria. We functionally characterized the role of mitochondrial glutaredoxin S15 (GRXS15) in biogenesis of ISC containing aconitase through a combination of genetic, physiological, and biochemical approaches. Two Arabidopsis T-DNA insertion mutants were identified as null mutants with early embryonic lethal phenotypes that could be rescued by GRXS15. Furthermore, we showed that recombinant GRXS15 is able to coordinate and transfer an ISC and that this coordination depends on reduced glutathione (GSH). We found the Arabidopsis GRXS15 able to complement growth defects based on disturbed ISC protein assembly of a yeast Δgrx5 mutant. Modeling of GRXS15 onto the crystal structures of related nonplant proteins highlighted amino acid residues that after mutation diminished GSH and subsequently ISC coordination, as well as the ability to rescue the yeast mutant. When used for plant complementation, one of these mutant variants, GRXS15_K83/A, led to severe developmental delay and a pronounced decrease in aconitase activity by approximately 65%. These results indicate that mitochondrial GRXS15 is an essential protein in Arabidopsis, required for full activity of iron-sulfur proteins.Iron-sulfur cluster (ISC) containing proteins conduct essential metabolic processes in all organisms. In plants, autonomous pathways for ISC assembly are present in plastids and mitochondria, whereas ISC biosynthesis and incorporation in cytosolic and nuclear proteins relies on export of bound sulfide from mitochondria (1). Because ISCs are sensitive to superoxide and its reaction products formed by aerobic metabolism, increasing oxidation of the atmosphere led to evolution of sophisticated machineries mediating and controlling the assembly and the transfer of ISCs to acceptor proteins (2). The entire machinery consisting of more than 14 proteins in plastids and 19 proteins in mitochondria includes proteins providing sulfur and iron atoms, scaffold proteins for cluster assembly and transfer proteins that insert ISCs into recipient apoproteins (3). The fundamental role of ISC assembly for building the machineries that are at the center of maintaining life is emphasized by the fact that mutants affecting genes of the ISC assembly pathways are frequently embryo-lethal (3). Among the proteins considered as transfer proteins are representatives of the type II subset of glutaredoxins (GRX), which are characterized by their CGFS monothiol active site motif and their ability to bind glutathione-bridged ISCs (4).Although evidence exists for the function of GRXs in the assembly of Fe-S proteins in yeast cells and vertebrates (5, 6), their significance in planta is still unclear. Null mutants for plastidic monothiol GRXS14 and GRXS16 are viable, which may be explained by partially overlapping activities (3). Nevertheless, the ability of both proteins to complement the yeast Δgrx5 mutant that lacks the mitochondrial monothiol Grx5p strongly hints to involvement in maturation of Fe-S proteins (7). Similarly, it has been shown that the cytosolic and nuclear GRXS17, both from poplar and Arabidopsis, can also complement the Δgrx5 mutant (7, 8). However, Arabidopsis grxs17 null mutants had only a minor decrease in cytosolic Fe-S enzyme activities, whereas a severe developmental phenotype is visible under elevated temperature and extended daylight. These data indicate that GRXS17 is likely not required for de novo ISC assembly in the cytosol, although it could play a role in cluster repair. Rather, it may be that GRXS17 functions as an oxidoreductase, regulating the function of its partners as BolA2, NF-YC11, or other unidentified targets (8, 9).However, the involvement of GRXS15 in the maturation of Fe-S proteins in mitochondria remains elusive in plants because, among poplar monothiol GRXs, it is the only isoform failing to rescue most phenotypes of the yeast Δgrx5 mutant (7). Furthermore, the subcellular localization of GRXS15 is ambiguous. Independent targeting experiments have reported GFP-tagged poplar GRXS15 in mitochondria (7) and Arabidopsis GRXS15 in the plastid stroma (10) or dual-targeted plastidic mitochondrial in bifunctional fluorescence complementation (BiFC) experiments with BolA4 (9). In proteome studies, GRXS15 has been repeatedly found in the mitochondria of Arabidopsis (11) and potato (12), but also in the chloroplast proteome of maize (13). The only phenotype of grxs15-null mutants described thus far is sensitivity toward H₂O₂, which led to the suggestion that GRXS15 may be involved in the maintenance of growth and development under oxidative stress conditions (10).Here, we provide evidence that GRXS15 is an essential component of the mitochondrial ISC machinery that for a long time has been controversial because of the lack of suitable mutants and the failure to complement yeast cells lacking the orthologous gene. The results from in vitro ISC reconstitution and transfer assays and complementation of null mutants in yeast and Arabidopsis with mutated variants of GRXS15 demonstrate that GRXS15 coordinates an ISC and is likely essential for the delivery of ISC to apoproteins in mitochondria, serving in particular for the maturation of ISC into aconitase.     

Crystal structure of the cystine C-S lyase from Synechocystis: stabilization of cysteine persulfide for FeS cluster biosynthesis

FeS clusters are versatile cofactors of a variety of proteins, but the mechanisms of their biosynthesis are still unknown. The cystine C-S lyase from Synechocystis has been identified as a participant in ferredoxin FeS cluster formation. Herein, we report on the crystal structure of the lyase and of a complex with the reaction products of cystine cleavage at 1.8- and 1.55-A resolution, respectively. The sulfur-containing product was unequivocally identified as cysteine persulfide. The reactive persulfide group is fixed by a hydrogen bond to His-114 in the center of a hydrophobic pocket and is thereby shielded from the solvent. Binding and stabilization of the cysteine persulfide represent an alternative to the generation of a protein-bound persulfide by NifS-like proteins and point to the general importance of persulfidic compounds for FeS cluster assembly.     

Extrapineal melatonin: analysis of its subcellular distribution and daily fluctuations

Abstract: We studied the subcellular levels of melatonin in cerebral cortex and liver of rats under several conditions. The results show that melatonin levels in the cell membrane, cytosol, nucleus, and mitochondrion vary over a 24‐hr cycle, although these variations do not exhibit circadian rhythms. The cell membrane has the highest concentration of melatonin followed by mitochondria, nucleus, and cytosol. Pinealectomy significantly increased the content of melatonin in all subcellular compartments, whereas luzindole treatment had little effect on melatonin levels. Administration of 10 mg/kg bw melatonin to sham‐pinealectomized, pinealectomized, or continuous light‐exposed rats increased the content of melatonin in all subcellular compartments. Melatonin in doses ranging from 40 to 200 mg/kg bw increased in a dose‐dependent manner the accumulation of melatonin on cell membrane and cytosol, although the accumulations were 10 times greater in the former than in the latter. Melatonin levels in the nucleus and mitochondria reached saturation with a dose of 40 mg/kg bw; higher doses of injected melatonin did not further cause additional accumulation of melatonin in these organelles. The results suggest some control of extrapineal accumulation or extrapineal production of melatonin and support the existence of regulatory mechanisms in cellular organelles, which prevent the intracellular equilibration of the indolamine. Seemingly, different concentrations of melatonin can be maintained in different subcellular compartments. The data also seem to support a requirement of high doses of melatonin to obtain therapeutic effects. Together, these results add information that assists in explaining the physiology and pharmacology of melatonin.