Structural origins of redox potentials in Fe-S proteins: electrostatic potentials of crystal structures.

Redox potentials often differ dramatically for homologous proteins that have identical redox centers. For two types of iron-sulfur proteins, the rubredoxins and the high-potential iron-sulfur proteins (HiPIPs), no structural explanations for these differences have been found. We calculated the classical electrostatic potential at the redox site using static crystal structures of four rubredoxins and four HiPIPs to identify important structural determinants of their redox potentials. The contributions from just the backbone and polar side chains are shown to explain major features of the experimental redox potentials. For instance, in the rubredoxins, the presence of Val 44 versus Ala 44 causes a backbone shift that explains a approximately 50 mV lower redox potential in one of the four rubredoxins. This result is consistent with experimental redox potentials of five additional rubredoxins with known sequence. Also, we attribute the unusually lower redox potentials of two of the HiPIPs studied to a less positive electrostatic environment around their redox sites. Finally, molecular dynamics simulations of solvent around static rubredoxin crystal structures indicate that water alone is a major factor in dampening the contribution of charged side chains, in accord with experiments showing that mutations of surface charges produce relatively little effect on redox potentials.     

Multiple Rieske proteins in prokaryotes: Where and why?

Many microbial genomes have been sequenced in the recent years. Multiple genes encoding Rieske iron-sulfur proteins, which are subunits of cytochrome bc-type complexes or oxygenases, have been detected in many pro- and eukaryotic genomes. The diversity of substrates, co-substrates and reactions offers obvious explanations for the diversity of the low potential Rieske proteins associated with oxygenases, but the physiological significance of the multiple genes encoding high potential Rieske proteins associated with the cytochrome bc-type complexes remains elusive. For some organisms, investigations into the function of the later group of genes have been initiated. Here, we summarize recent finding on the characteristics and physiological functions of multiple high potential Rieske proteins in prokaryotes. We suggest that the existence of multiple high potential Rieske proteins in prokaryotes could be one way of allowing an organism to adapt their electron transfer chains to changing environmental conditions.     

The coordination sphere of iron-sulfur clusters: lessons from site-directed mutagenesis experiments

 Cysteine is the ubiquitous ligand of iron-sulfur clusters in proteins, although chemical models have indicated that functional groups other than thiolates can coordinate iron in iron-sulfur compounds. Only a small number of naturally occurring examples of hydroxyl, histidinyl or carboxyl coordination have been clearly established but many others are suspected. Quite a few site-directed mutagenesis experiments have been aimed at replacing the cysteine ligands of iron-sulfur centers by other amino acids in various systems. The available data set shows that substituting one ligand, even by another functional residue, is very often destabilizing enough to impair cluster assembly; in some cases, the apoprotein cannot even be detected. One for one replacements have been demonstrated, but they have been so far almost exclusively confined to clusters with no more than one or two iron atoms. In contrast, changes of the cluster nuclearity or recruitment of free cysteine residues seem preferred ways for proteins containing larger clusters to cope with removal of a ligand, rather than using coordinating amino acids bearing different chemical functions. Furthermore, the possibility of replacing cysteines by other residues as ligands in iron-sulfur proteins does not uniquely depend on the ability of the cluster to accept other kinds of coordination than cysteinate; other factors such as the local flexibility of the polypeptide chain, the accessibility of the solvent and the electronic distribution on the active centers may also play a prominent role.     

A modified ferrozine method for the measurement of enzyme-bound iron

A general procedure for the determination of the iron content of enzymes by digestion with methanesulfonic acid to release protein-bound iron has been developed. This procedure replaces the tedious and potentially hazardous method of wet ashing with concentrated nitric-sulfuric-perchloric acids. The method has been used to determine the stoichiometry of iron for nanomole quantities of heme-iron proteins, iron-sulfur proteins, complex iron-sulfur proteins, as well as in phenylalanine hydroxylase, an enzyme with iron in an undetermined coordination.     

Interplay of IscA and IscU in biogenesis of iron-sulfur clusters

Increasing evidence suggests that sulfur in ubiquitous iron-sulfur clusters is derived from L-cysteine via cysteine desulfurases. In Escherichia coli, the major cysteine desulfurase activity for biogenesis of iron-sulfur clusters has been attributed to IscS. The gene that encodes IscS is a member of an operon iscSUA, which also encodes two highly conserved proteins: IscU and IscA. Previous studies suggested that both IscU and IscA may act as the iron-sulfur cluster assembly scaffold proteins. However, recent evidence indicated that IscA is an iron-binding protein that can provide iron for the iron-sulfur cluster assembly in IscU (Ding, H., Harrison, K., and Lu, J. (2005) J. Biol. Chem. 280, 30432-30437). To further elucidate the function of IscA in biogenesis of iron-sulfur clusters, we evaluate the iron-sulfur cluster binding activity of IscA and IscU under physiologically relevant conditions. When equal amounts of IscA and IscU are incubated with an equivalent amount of ferrous iron in the presence of IscS, L-cysteine and dithiothreitol, iron-sulfur clusters are assembled in IscU, but not in IscA, suggesting that IscU is a preferred iron-sulfur cluster assembly scaffold protein. In contrast, when equal amounts of IscA and IscU are incubated with an equivalent amount of ferrous iron in the presence of IscS and dithiothreitol but without L-cysteine, nearly all iron is bound to IscA. The iron binding in IscA appears to prevent the formation of the biologically inaccessible ferric hydroxide under aerobic conditions. Subsequent addition of L-cysteine efficiently mobilizes the iron center in IscA and transfers the iron for the iron-sulfur cluster assembly in IscU. The results suggest an intriguing interplay between IscA and IscU in which IscA acts as an iron chaperon that recruits "free" iron and delivers the iron for biogenesis of iron-sulfur clusters in IscU under aerobic conditions.     

Linear three-iron centres are unlikely cluster degradation intermediates during unfolding of iron-sulfur proteins

Recent studies on the chemical alkaline degradation of ferredoxins have contributed to the hypothesis that linear three-iron centres are commonly observed as degradation intermediates of iron-sulfur clusters. In this work we assess the validity of this hypothesis. We studied different proteins containing iron-sulfur clusters, iron-sulfur centres and di-iron centres with respect to their chemical degradation kinetics at high pH, in the presence and absence of exogenous sulfide, to investigate the possible formation of linear three-iron centres during protein unfolding. Our spectroscopic and kinetic data show that in these different proteins visible absorption bands at 530 and 620 nm are formed that are identical to those suggested to arise from linear three-iron centres. Iron release and protein unfolding kinetics show that these bands result from the formation of iron sulfides at pH 10, produced by the degradation of the iron centres, and not from rearrangements leading to linear three-iron centres. Thus, at this point any relevant functional role of linear three-iron centres as cluster degradation intermediates in iron-sulfur proteins remains elusive.     

Iron-sulfur proteins are the major source of protein-bound dinitrosyl iron complexes formed in Escherichia coli cells under nitric oxide stress

Protein-bound dinitrosyl iron complexes (DNICs) have been observed in prokaryotic and eukaryotic cells under nitric oxide (NO) stress. The identity of proteins that bind DNICs, however, still remains elusive. Here we demonstrate that iron-sulfur proteins are the major source of protein-bound DNICs formed in Escherichia coli cells under NO stress. Expression of recombinant iron-sulfur proteins, but not proteins without iron-sulfur clusters, almost doubles the amount of protein-bound DNICs formed in E. coli cells after NO exposure. Purification of recombinant proteins from the NO-exposed E. coli cells further confirms that iron-sulfur proteins, but not proteins without iron-sulfur clusters, are modified, forming protein-bound DNICs. Deletion of the iron-sulfur cluster assembly proteins IscA and SufA to block the [4Fe-4S] cluster biogenesis in E. coli cells largely eliminates the NO-mediated formation of protein-bound DNICs, suggesting that iron-sulfur clusters are mainly responsible for the NO-mediated formation of protein-bound DNICs in cells. Furthermore, depletion of the "chelatable iron pool" in wild-type E. coli cells effectively removes iron-sulfur clusters from proteins and concomitantly diminishes the NO-mediated formation of protein-bound DNICs, indicating that iron-sulfur clusters in proteins constitute at least part of the chelatable iron pool in cells.     

Iron-sulfur cluster proteins: electron transfer and beyond

Iron-sulfur clusters-containing proteins participate in many cellular processes, including crucial biological events like DNA synthesis and processing of dioxygen. In most iron-sulfur proteins, the clusters function as electron-transfer groups in mediating one-electron redox processes and as such they are integral components of respiratory and photosynthetic electron transfer chains and numerous redox enzymes involved in carbon, oxygen, hydrogen, sulfur and nitrogen metabolism. Recently, novel regulatory and enzymatic functions of these proteins have emerged. Iron-sulfur cluster proteins participate in the control of gene expression, oxygen/nitrogen sensing, control of labile iron pool and DNA damage recognition and repair. Their role in cellular response to oxidative stress and as a source of free iron ions is also discussed.     

铁硫簇的生物合成

铁硫簇在细胞的生物学过程中起着重要的作用,可参与电子传递、代谢控制和基因调节等过程。研究显示铁硫簇具有多样性,它的合成依赖于ISC和SUF系统,固氮酶中还需要NIF系统的参与。ISC系统由iscSUA-hscBA-fdx基因串编码,合成的是一类“管家”蛋白,适于在正常条件下表达。SUF系统由基因串sufABCDSE编码,常在恶劣环境如氧化应激和铁饥饿条件下表达。NIF系统由nifSU基因编码,适于固氮酶(厌氧条件下起作用)铁硫簇的合成。     

Kinetics of Electron Transfer within Cytochrome bc 1 and Between Cytochrome bc 1 and Cytochrome c

In this minireview an overview is presented of the kinetics of electron transfer within the cytochrome bc (1) complex, as well as from cytochrome bc (1) to cytochrome c. The cytochrome bc (1) complex (ubiquinone:cytochrome c oxidoreductase) is an integral membrane protein found in the mitochondrial respiratory chain as well as the electron transfer chains of many respiratory and photosynthetic bacteria. Experiments on both mitochondrial and bacterial cyatochrome bc (1) have provided detailed kinetic information supporting a Q-cycle mechanism for electron transfer within the complex. On the basis of X-ray crystallographic studies of cytochrome bc (1), it has been proposed that the Rieske iron-sulfur protein undergoes large conformational changes as it transports electrons from ubiquinol to cytochrome c (1). A new method was developed to study electron transfer within cytochrome bc (1) using a binuclear ruthenium complex to rapidly photooxidize cytochrome c (1). The rate constant for electron transfer from the iron-sulfur center to cytochrome c (1) was found to be 80,000 s(-1), and is controlled by the dynamics of conformational changes in the iron-sulfur protein. Moreover, a linkage between the conformation of the ubiquinol binding site and the conformational dynamics of the iron-sulfur protein has been discovered which could play a role in the bifurcated oxidation of ubiquinol. A ruthenium photoexcitation method has also been developed to measure electron transfer from cytochrome c (1) to cytochrome c. The kinetics of electron transfer are interpreted in light of a new X-ray crystal structure for the complex between cytochrome bc (1) and cytochrome c.     

Observations concerning the quinol oxidation site of the cytochrome bc1 complex

A direct hydrogen bond between ubiquinone/quinol bound at the QO site and a cluster-ligand histidine of the iron-sulfur protein (ISP) is described as a major determining factor explaining much experimental data on position of the ISP ectodomain, electron paramagnetic resonance (EPR) lineshape and midpoint potential of the iron-sulfur cluster, and the mechanism of the bifurcated electron transfer from ubiquinol to the high and low potential chains of the bc1 complex.     

Iron-sulfur proteins of the green photosynthetic bacterium Chlorobium.

The iron-sulfur proteins of the green photosynthetic bacterium Chlorobium have been characterized by oxidation-reduction potentiometry in conjunction with low-temperature electron paramagnetic resonance spectroscopy. Chlorobium ferredoxin was the only iron-sulfur protein detected in the soluble fraction; no high-potential iron-sulfur protein was observed. In addition, high-potential iron-sulfur protein was not detected in the chromatophores. Four chromatophore-bound iron-sulfur proteins were detected. One is the "Rieske" type iron-sulfur protein with a g-value of 1.90 in the reduced state; the protein has a midpoint potential of + 160 mV (pH 7.0), and this potential is pH dependent. Three g=1.94 chromatophore-bound iron-sulfur proteins were observed, with midpoint potentials of -25, -175, and about -550 mV. A possible role for the latter iron-sulfur protein in the primary photochemical reaction in Chlorobium is considered.     

The high potential iron-sulfur cluster of aconitase is a binuclear iron-sulfur cluster.

It has been reported (Ruzicka, F.J., and Beinert, H. (1978) J. Biol. Chem. 253, 2514-2517) that aconitase in the oxidized state, as isolated, shows an electron paramagnetic resonance signal centered at g = 2.01, typical of high potential iron-sulfur proteins. Since the magnetic state corresponding to this signal has thus far only been found in tetranuclear iron-sulfur clusters in model compounds and proteins, it could be expected that aconitase also contains a [4Fe-4S] cluster. We show here that core extrusion, in the presence of hexamethylphosphoramide and o-xylyl-alpha,alpha'-dithiol and subsequent ligand exchange with p-trifluoromethylbenzenethiol yield absorption spectra typical of binuclear iron-sulfur clusters. According to the absorbance measured, the concentration of the extruded [2Fe-2S] cluster quantitatively accounts for the iron-sulfur content of the preparations examined. Preliminary studies of the 19F nuclear magnetic resonance spectrum obtained on extrusion with p-trifluoromethylbenzenethiol confirm the presence of a binuclear cluster in aconitase.     

Characterization of the recombinant Rieske [2Fe–2S] proteins HcaC and YeaW from E. coli

Three genes within the genome of E. coli K12 are predicted to encode proteins containing the typical Rieske iron-sulfur cluster-binding motifs. Two of these, hcaC and yeaW, were overexpressed in E. coli BL21 and Tuner (DE3) pLacI. The recombinant proteins were purified and analyzed by UV/Vis- and EPR-spectroscopy. HcaC and YeaW display the typical redox-dependent UV/Vis-spectra of iron-sulfur proteins. The EPR spectrum of reduced HcaC shows characteristic g-values of a Rieske cluster whereas the g-values for YeaW are close to the upper limit for this type of iron-sulfur cluster. Both iron-sulfur clusters could be reduced by dithionite, but not by ascorbate, confirming their classification as low-potential Rieske proteins as derived from the amino acid sequences. A phylogenetic analysis of the two proteins reveals that HcaC clearly segregates with the Rieske ferredoxins of class IIB oxygenases whereas the classification of YeaW remains doubtful.     

Circular dichroism and redox properties of high redox potential ferredoxins

The circular dichroism (CD) spectra of 13 examples of high-potential iron-sulfur proteins (HiPIPs), a class of [4Fe-4S] ferredoxins, have been determined. In contrast to the proposal of Carter [Carter, C. W., Jr. (1977) J. Biol. Chem. 252, 7802-7811], no strict correlation between visible CD features and utilization of the [4Fe-4S]2+/[4Fe-4S]3+ oxidation levels was found. Although most HiPIPs have these features, the model requires their presence in all species. There is also no simple relationship between CD spectral features and the presence of conserved tyrosine-19. In addition, no apparent correlation between CD properties and oxidation-reduction potential could be detected. However, amino acid side chains in close contact to the iron-sulfur cluster appear to be important in modulating spectral and oxidation-reduction properties. In particular, the negative shoulder at 290 nm and negative maximum at 230 nm correlate with the presence of Trp-80 (Chromatium vinosum numbering). Two HiPIPs that do not have Trp at this position have positive bands at 290 and 230 nm. These bands in the Ectothiorhodospira halophila HiPIPs are apparently associated with Trp-49, which is located on the opposite side of the effective mirror plane of the cluster from Trp-80. The effect of pH on circular dichroism and redox potential in Thiocapsa roseopersicina HiPIP, which has a histidine at position 49, is consistent with the interaction of the side chain with the cluster. Despite specific differences in their CD spectra, the various HiPIPs studied show general similarity consistent with structural homology within this class of iron-sulfur proteins.     

Intermediate length Rieske iron-sulfur protein is present and functionally active in the cytochrome bc1 complex of Saccharomyces cerevisiae

To investigate the relationship between post-translational processing of the Rieske iron-sulfur protein of Saccharomyces cerevisiae and its assembly into the mitochondrial cytochrome bc1 complex we used iron-sulfur proteins in which the presequences had been changed by site-directed mutagenesis of the cloned iron-sulfur protein gene, so that the recognition sites for the matrix processing peptidase or the mitochondrial intermediate peptidase (MIP) had been destroyed. When yeast strain JPJ1, in which the gene for the iron-sulfur protein is deleted, was transformed with these constructs on a single copy expression vector, mitochondrial membranes and bc1 complexes isolated from these strains accumulated intermediate length iron-sulfur proteins in vivo. The cytochrome bc1 complex activities of these membranes and bc1 complexes indicate that intermediate iron-sulfur protein (i-ISP) has full activity when compared with that of mature sized iron-sulfur protein (m-ISP). Therefore the iron-sulfur cluster must have been inserted before processing of i-ISP to m-ISP by MIP. When iron-sulfur protein is imported into mitochondria in vitro, i-ISP interacts with components of the bc1 complex before it is processed to m-ISP. These results establish that the iron-sulfur cluster is inserted into the apoprotein before MIP cleaves off the second part of the presequence and that this second processing step takes place after i-ISP has been assembled into the bc1 complex.     

Mouse knock-out of IOP1 protein reveals its essential role in mammalian cytosolic iron-sulfur protein biogenesis

Iron-sulfur proteins play an essential role in a variety of biologic processes and exist in multiple cellular compartments. The biogenesis of these proteins has been the subject of extensive investigation, and particular focus has been placed on the pathways that assemble iron-sulfur clusters in the different cellular compartments. Iron-only hydrogenase-like protein 1 (IOP1; also known as nuclear prelamin A recognition factor like protein, or NARFL) is a human protein that is homologous to Nar1, a protein in Saccharomyces cerevisiae that, in turn, is an essential component of the cytosolic iron-sulfur protein assembly pathway in yeast. Previous siRNA-induced knockdown studies using mammalian cells point to a similar role for IOP1 in mammals. In the present studies, we pursued this further by knocking out Iop1 in Mus musculus. We find that Iop1 knock-out results in embryonic lethality before embryonic day 10.5. Acute, inducible global knock-out of Iop1 in adult mice results in lethality and significantly diminished activity of cytosolic aconitase, an iron-sulfur protein, in liver extracts. Inducible knock-out of Iop1 in mouse embryonic fibroblasts results in diminished activity of cytosolic but not mitochondrial aconitase and loss of cell viability. Therefore, just as with knock-out of Nar1 in yeast, we find that knock-out of Iop1/Narfl in mice results in lethality and defective cytosolic iron-sulfur cluster assembly. The findings demonstrate an essential role for IOP1 in this pathway.     

Mitochondrial NADH:ubiquinone reductase: complementary DNA sequence of the import precursor of the bovine 75-kDa subunit

The 75-kDa subunit of complex I (NADH:ubiquinone oxidoreductase) from bovine heart mitochondria is its largest subunit and is a component of the iron-sulfur (IP) fragment of the enzyme. It is encoded in nuclear DNA and is imported into the organelle. Protein sequences have been determined at the N-terminus of the intact protein and on fragments generated by partial cleavage with cyanogen bromide and with Staphylococcus aureus protease V8. Parts of these data have been used to design two mixtures of oligonucleotides 17 bases long, containing 192 and 256 different sequences, which have been synthesized and used as hybridization probes for identification of cognate cDNA clones. Two different but overlapping clones have been isolated, and the sequences of the cloned DNAs have been determined. Together they code for a precursor of the 75-kDa subunit of complex I. The mature protein is 704 amino acids in length, has a calculated molecular mass of 75,961 daltons, and contains no segments of sequence that could be folded into hydrophobic alpha-helixes of sufficient length to span the inner membrane of the mitochondrion. Its precursor has an N-terminal extension of 23 amino acids to specify its import into the mitochondrion from the cytoplasm. Seventeen cysteine residues are dispersed throughout the 75-kDa subunit; some of them are close to each other in the sequence in three separate groups and, by analogy with other iron-sulfur proteins, could be involved in iron-sulfur clusters.(ABSTRACT TRUNCATED AT 250 WORDS)     

Iron-sulfur proteins of the green photosynthetic bacterium Chlorobium

The iron-sulfur proteins of the green photosynthetic bacterium Chlorobium have been characterized by oxidation-reduction potentiometry in conjunction with low-temperature electron paramagnetic resonance spectroscopy. Chlorobium ferredoxin was the only iron-sulfur protein detected in the soluble fraction; no high-potential iron-sulfur protein was observed. In addition, high-potential iron-sulfur protein was not detected in the chromatophores. Four chromatophore-bound iron-sulfur proteins were detected. One is the “Rieske” type iron-sulfur protein with a g-value of 1.90 in the reduced state; the protein has a midpoint potential of +160 mV (pH 7.0), and this potential is pH dependent. Three g = 1.94 chromatophore-bound iron-sulfur proteins were observed, with midpoint potentials of ?25, ?175, and about ?550 mV. A possible role for the latter iron-sulfur protein in the primary photochemical reaction in Chlorobium is considered.