Crystal structure of the 2[4Fe-4S] ferredoxin from Chromatium vinosum: evolutionary and mechanistic inferences for [3/4Fe-4S] ferredoxins.

The crystal structure of the 2[4Fe-4S] ferredoxin from Chromatium vinosum has been solved by molecular replacement using data recorded with synchrotron radiation. The crystals were hexagonal prisms that showed a strong tendency to develop into long tubes. The hexagonal prisms diffracted to 2.1 A resolution at best, and a structural model for C. vinosum ferredoxin has been built with a final R of 19.2%. The N-terminal domain coordinates the two [4Fe-4S] clusters in a fold that is almost identical to that of other known ferredoxins. However, the structure has two unique features. One is a six-residue insertion between two ligands of one cluster forming a two-turn external loop; this short loop changes the conformation of the Cys 40 ligand compared to other ferredoxins and hampers the building of one NH...S H-bond to one of the inorganic sulfurs. The other remarkable structural element is a 3.5-turn alpha-helix at the C-terminus that covers one side of the same cluster and is linked to the cluster-binding domain by a six-residue external chain segment. The charge distribution is highly asymmetric over the molecule. The structure of C. vinosum ferredoxin strongly suggests divergent evolution for bacterial [3/4Fe-4S] ferredoxins from a common ancestral cluster-binding core. The unexpected slow intramolecular electron transfer rate between the clusters in C. vinosum ferredoxin, compared to other similar proteins, may be attributed to the unusual electronic properties of one of the clusters arising from localized changes in its vicinity rather than to a global structural rearrangement.     

Protein control of iron-sulfur cluster redox potentials.

The relationship between the three-dimensional structures of iron-sulfur proteins and the redox potentials of their iron-sulfur clusters is of fundamental importance. We report calculations of the redox potentials of the [Fe4S4(S-cys)4]-2/-3 couple in four crystallographically characterized proteins: Azotobacter vinelandii ferredoxin I, Peptococcus aerogenes ferredoxin, Bacillus thermoproteolyticus ferredoxin, and Chromatium vinosum high potential iron protein (HiPIP). Our calculations use the "protein dipoles Langevin dipoles" microscopic electrostatic model, which includes both protein and solvent water. The variations in calculated redox potentials are in excellent agreement with experimental data. In particular, our results confirm the important role of amide groups close to the cluster in separating the potential of C. vinosum HiPIP from those of the other three proteins. However, the potentials of these latter exhibit a substantial range despite extremely similar amide group environments of their clusters. Our results show that the potentials in these proteins are tuned in part by varying the access of solvent water to the neighborhood of the cluster. Our calculations provide the first successful quantitative modeling of the protein control of iron-sulfur cluster redox potentials.     

Unusual spectroscopic and electrochemical properties of the 2[4Fe-4S] ferredoxin of Thauera aromatica

A reduced ferredoxin serves as the natural electron donor for key enzymes of the anaerobic aromatic metabolism in the denitrifying bacterium Thauera aromatica. It contains two [4Fe-4S] clusters and belongs to the Chromatium vinosum type of ferredoxins (CvFd) which differ from the "clostridial" type by a six-amino acid insertion between two successive cysteines and a C-terminal alpha-helical amino acid extension. The electrochemical and electron paramagnetic resonance (EPR) spectroscopic properties of both [4Fe-4S] clusters from T. aromatica ferredoxin have been investigated using cyclic voltammetry and multifrequency EPR. Results obtained from cyclic voltammetry revealed the presence of two redox transitions at -431 and -587 mV versus SHE. X-band EPR spectra recorded at potentials where only one cluster was reduced (greater than -500 mV) indicated the presence of a spin mixture of S = (3)/(2) and (5)/(2) spin states of one reduced [4Fe-4S] cluster. No typical S = (1)/(2) EPR signals were observed. At lower potentials (less than -500 mV), the more negative [4Fe-4S] cluster displayed Q-, X-, and S-band EPR spectra at 20 K which were typical of a single S = (1)/(2) low-spin [4Fe-4S] cluster with a g(av) of 1.94. However, when the temperature was decreased stepwise to 4 K, a magnetic interaction between the two clusters gradually became observable as a temperature-dependent splitting of both the S = (1)/(2) and S = (5)/(2) EPR signals. At potentials where both clusters were reduced, additional low-field EPR signals were observed which can only be assigned to spin states with spins of >(5)/(2). The results that were obtained establish that the common typical amino acid sequence features of CvFd-type ferredoxins determine the unusual electrochemical properties of the [4Fe-4S] clusters. The observation of different spin states in T. aromatica ferredoxin is novel among CvFd-type ferredoxins.     

High and low reduction potential 4Fe-4S clusters in Azotobacter vinelandii (4Fe-4S) 2ferredoxin I. Influence of the polypeptide on the reduction potentials.

Azotobacter vinelandii (4Fe-4S)2 ferredoxin I (Fd I) is an electron transfer protein with Mr equals 14,500 and Eo equals -420 mv. It exhibits and EPR signal of g equals 2.01 in its isolated form. This resonance is almost identical with the signal that originates from a "super-oxidized" state of the 4Fe-4S cluster of potassium ferricyanide-treated Clostridium ferredoxin. A cluster that exhibits this EPR signal at g equals 2.01 is in the same formal oxidation state as the cluster in oxidized Chromatium High-Potential-Iron-Protein (HiPIP). On photoreduction of Fd I with spinach chloroplast fragments, the resonance at g equals 2.01 vanishes and no EPR signal is observed. This EPR behavior is analogous to that of reduced HiPIP, which also fails to exhibit an EPR spectrum. These characteristics suggest that a cluster in A. vinelandii Fd I functions between the same pair of states on reduction as does the cluster in HiPIP, but with a midpoint reduction potential of -420 mv in contrast to the value of +350 mv characteristic of HiPIP. Quantitative EPR and stoichoimetry studies showed that only one 4Fe-4S cluster in this (4Fe-4S)2 ferredoxin is reduced. Oxidation of Fd I with potassium ferricyanide results in the uptake of 1 electron/mol as determined by quantitative EPR spectroscopy. This indicates that a cluster in Fd I shows no electron paramagnetic resonance in the isolated form of the protein accepts an electron on oxidation, as indicated by the EPR spectrum, and becomes paramagnetic. The EPR behavior of this oxidizable cluster indicates that it also functions between the same pair of oxidation states as does the Fe-S cluster in HiPIP. The midpoint reduction potential of this cluster is approximately +340 mv. A. vinelandii Fd I is the first example of an iron-sulfur protein which contains both a high potential cluster (approximately +340 mv) and a low potential cluster (-420 mv). Both Fe-S clusters appear to function between the same pair of oxidation states as the single Fe-S cluster in Chromatium HiPIP, although the midpoint reduction potentials of the two clusters are approximately 760 mv different.     

Characterization of the selenium-substituted 2 [4Fe-4Se] ferredoxin from Clostridium pasteurianum

The sulfur atoms of the two [4Fe-4S] clusters present in the ferredoxin from Clostridium pasteurianum have been replaced by selenium. The substitution is readily carried out by incubating the apoferredoxin with excess amounts of Fe3+, selenite, and dithiothreitol under anaerobic conditions. The UV-visible absorption spectrum of the Se-substituted ferredoxin, the core extrusion of its active sites, and analyses of its iron and selenium contents show that it contains two [4Fe-4Se] clusters. The Se-substituted ferredoxin is considerably less resistant to oxygen or to acidic and alkaline pH than the native ferredoxin: the half-lives of the former are 20-500 times shorter than those of the latter. The native ferredoxin and the Se-substituted ferredoxin display similar kinetic properties when used as electron donors to the hydrogenase from C. pasteurianum. It is of note, however, that the Km and Vmax values are lower for the 2[4Fe-4Se] ferredoxin than for the 2[4Fe-4S] ferredoxin. Reductive and oxidative titrations with dithionite and with thionine, respectively, show that both ferredoxins are two-electron carriers. The redox potentials of the ferredoxins have been measured by equilibrating them with the H2/H+ couple via hydrogenase: values of -423 and -417 mV have been found for the 2[4Fe-4S] ferredoxin and 2[4Fe-4Se] ferredoxin, respectively. Ferredoxins containing both chalcogenides in their [4Fe-4X] (X = S, Se) clusters have been prepared by reconstitution reactions involving mixtures of sulfide and selenide: the latter experiments show that sulfide and selenide are equally reactive in the incorporation of [4Fe-4X] (X = S, Se) sites into ferredoxin. The present report, together with former studies, establishes the general feasibility of the Se/S substitution in [2Fe-2S] and in [4Fe-4S] clusters of proteins and of synthetic analogues.     

Characterization of the iron-sulfur clusters in ferredoxin from acetate-grown Methanosarcina thermophila.

Ferredoxin from Methanosarcina thermophila is an electron acceptor for the CO dehydrogenase complex which decarbonylates acetyl-coenzyme A and oxidizes the carbonyl group to carbon dioxide in the pathway for conversion of the methyl group of acetate to methane (K. C. Terlesky and J. G. Ferry, J. Biol. Chem. 263:4080-4082, 1988). Resonance Raman spectroscopy and electron paramagnetic resonance spectroelectrochemistry indicated that the ferredoxin contained two [4Fe-4S] clusters per monomer of 6,790 Da, each with a midpoint potential of -407 mV. A [3Fe-4S] species, with a midpoint potential of +103 mV, was also detected in the protein at high redox potentials. Quantitation of the [3Fe-4S] and [4Fe-4S] centers revealed 0.4 and 2.1 spins per monomer, respectively. The iron-sulfur clusters were unstable in the presence of air, and the rate of cluster loss increased with increasing temperature. A ferredoxin preparation, with a low spin quantitation of [4Fe-4S] centers, was treated with Fe2+ and S2-, which resulted in an increase in [4Fe-4S] and a decrease in [3Fe-4S] clusters. The results of these studies suggest the [3Fe-4S] species may be an artifact formed from degradation of [4Fe-4S] clusters.     

Electron transfer properties of iron-sulfur proteins

The details of most electron transfer reactions involving iron-sulfur proteins have remained undisclosed because of the lack of experimental methods suitable to measure precisely the relevant rates. Nuclear magnetic resonance (NMR) provides a powerful means to overcome these problems, at least with selected proteins. A combination of NMR studies and site-directed mutagenesis experiments has been instrumental in defining both the site of interaction and the main trends of the intracomplex electron transfer in the case of rubredoxin electron self-exchange. Analysis of the NMR data obtained for mixtures of different redox levels of several 2[4Fe-4S] ferredoxins provided both first-order, for intramolecular, and second-order, for intermolecular, rate constants. Their dependence as a function of structural changes gave insight into the mechanism of electron transfer in this type of protein. Contrary to some expectations, the high-spin [4Fe-4Se]+ clusters assembled in isopotential ferredoxins do not change the intramolecular electron transfer rate as compared to low-spin [4Fe-4S]+ homologs. In combination with activity measurements, the kinetic data have been used to model the electron transfer competent complexes between Clostridium pasteurianum ferredoxin and the main enzymes acting as redox partners in vivo.     

Redox properties of several bacterial ferredoxins using square wave voltammetry

The equilibrium reduction potential of the 2[4Fe-4S] ferredoxin (Fd) isolated from four different bacterial strains was determined at a methyl viologen-modified gold electrode using square wave voltammetry. The observed reduction potential at pH 8 for Clostridium thermoaceticum Fd was -385 mV; Clostridium pasteurianum, -393 mV; Clostridium thermosaccharolyticum, -408 mV; and Chromatium vinosum, -460 mV versus normal hydrogen electrode at 25 degrees C. The reduction potential of the C. pasteurianum Fd was found to be pH independent from pH 6.4 to 8.7, indicating that the electron transfer mechanism does not involve proton exchange. In contrast, the reduction potential of the C. thermosaccharolyticum Fd was found to be pH dependent from pH 6.4 to 8.7, with pKox approximately 7 and pKred approximately 7.5. The +30 mV change in reduction potential from pH 8.7 to 6.4 was attributed to an electrostatic interaction between the iron-sulfur cluster II and the protonated histidine 2 residue located about 6 A away. The Ch. vinosum Fd interacted reversibly at the methyl viologen-modified gold electrode, and its reduction potential was verified using visible spectroelectrochemistry. The reduction potential of Ch. vinosum Fd was found to be 30 mV more positive than previously reported. The similarities of the bacterial Fd reduction potentials are discussed in terms of the homology of their primary structure as reflected by the similarities in the visible and circular dichroic spectra.     

Design and functional expression in Escherichia coli of a synthetic gene encoding Clostridium pasteurianum 2[4Fe-4S] ferredoxin.

A gene encoding the exact sequence of Clostridium pasteurianum 2[4Fe-4S] ferredoxin and containing 11 unique restriction endonuclease cleavage sites has been synthesized and cloned in Escherichia coli. The synthetic gene is efficiently expressed in E. coli and its product has been purified and characterized. The N-terminal sequence is identical to that of the protein isolated from C. pasteurianum and the recombinant ferredoxin contains the exact amount of [4Fe-4S] clusters (2 per monomer) expected for homogeneous holoferredoxin. It displays reduction potential and kinetic parameters as electron donor to C. pasteurianum hydrogenase I identical to those determined for the native ferredoxin. All of these properties demonstrate that the 2[4Fe-4S] ferredoxin expressed in E. coli is identical to the parent clostridial protein.     

Purification and characterization of a ferredoxin from Rhizobium japonicum bacteroids

An eight-iron, eight-sulfur ferredoxin from Rhizobium japonicum bacteroids of soybean root nodules has been purified to apparent homogeneity as judged by disc gel electrophoresis. The purification procedure included chromatography on DEAE-cellulose, Bio-Gel P-60, and hydroxylapatite. Specific activities of several purified preparations of bacteroid ferredoxin ranged from 1700 to 1900 nmol of C2H4 produced . min-1 . mg-1 in the reaction mediating electron transfer between illuminated chloroplasts and bacteroid nitrogenase. A molecular weight of 6740 for the protein was determined by low speed sedimentation equilibrium and a molecular weight of 6500 was estimated from the mobility of bacteroid ferredoxin relative to the mobility of standard proteins during sodium dodecyl sulfate disc gel electrophoresis. All of the common amino acids were present except arginine, methionine, and tryptophan. The absorbance spectrum of the oxidized protein exhibited maxima at 285 nm and 380 nm with a shoulder near 305 nm. The A380/A285 ratio was 0.76 and the extinction coefficient at 380 nm for the oxidized protein was found to be 30,800 M-1. Equilibration of bacteroid ferredoxin with methyl viologen at various potentials revealed a midpoint oxidation-reduction potential of -484 mV. Spectrophotometric examination of iron-sulfur clusters extruded from bacteroid ferredoxin with benzenethiol and the transfer of its iron-sulfur clusters to other ferredoxins established the presence of two [4Fe-4S] clusters in a molecule of bacteroid ferredoxin. The EPR spectrum of oxidized ferredoxin consisted of a small signal at g = 2.02 integrating to 0.19 spin/molecule. The EPR spectrum of ferredoxin reduced with 5-deazaflavin exhibited a signal with features at g values of 1.88, 1.94, 2.01, and 2.07, and integrated to 1.7 spins/molecule. The EPR properties of bacteroid ferredoxin are characteristic of a ferredoxin operating between the 1+ and 2+ oxidation levels. Bacteroid ferredoxin mediated electron transfer to clostridial hydrogenase, but was not reduced by the clostridial phosphoroclastic system in the presence of pyruvate. Bacteroid ferredoxin reduced by illuminated 5-deazariboflavin also supported a high rate of C2H2 reduction by bacteroid nitrogenase which was free of Na2S2O4. It was concluded, on this basis, that bacteroid ferredoxin has the capability of functioning as the electron donor for nitrogenase in R. japonicum.     

Iron-sulfur cluster assembly: characterization of IscA and evidence for a specific and functional complex with ferredoxin

The synthesis of iron-sulfur clusters in Escherichia coli is believed to require a complex protein machinery encoded by the isc (iron-sulfur cluster) operon. The product of one member of this operon, IscA, has been overexpressed, purified, and characterized. It can assemble an air-sensitive [2Fe-2S] cluster as shown by UV-visible and resonance Raman spectroscopy. The metal form but not the apoform of IscA binds ferredoxin, another member of the isc operon, selectively, allowing transfer of iron and sulfide from IscA to ferredoxin and formation of the [2Fe-2S] holoferredoxin. These results thus suggest that IscA is involved in ferredoxin cluster assembly and activation. This is an important function because a functional ferredoxin is required for maturation of other cellular Fe-S proteins.     

Formation of a linear [3Fe-4S] cluster in a seven-iron ferredoxin triggered by polypeptide unfolding

Cubic iron-sulfur ([Fe-S]) clusters are common inorganic cofactors in proteins. The presence of a linear [3Fe-4S] cluster in a protein was first observed in beef-heart aconitase at high pH, where the protein structure was perturbed. Not long ago, the same linear cluster was discovered upon unfolding of a thermophilic di-cluster seven-iron ferredoxin, suggesting a more general relevance for this type of linear clusters in Nature. Since structure-induced cluster rearrangements may be important regulatory, on-going processes in living systems, we decided to further characterize the formation of the linear iron-sulfur cluster observed upon ferredoxin unfolding. Here we present a kinetic investigation of parameters that affect the linear-cluster formation and disassembly in the Sulfolobus acidocaldarius seven-iron ferredoxin. We find the linear cluster to be an intermediate on the protein-mediated cluster-degradation pathway under a wide range of pH and denaturant conditions. The linear species forms in parallel with secondary-structure disappearance. In contrast, the disassembly rate constant for the linear cluster is independent of denaturant concentration but depends strongly on solution pH. At high pH, the disassembly rate is slower and the linear iron-sulfur species has a longer lifetime, than at low pH.     

Enzymic synthesis of the 4Fe-4S clusters of Clostridium pasteurianum ferredoxin

Ex novo enzymic synthesis of the two 4Fe-4S clusters of Clostridium pasteurianum ferredoxin has been achieved by incubation of the apoprotein with catalytic amounts of the sulfurtransferase rhodanese in the presence of thiosulfate, DL-dihydrolipoate and ferric ammonium citrate. This enzymic reconstitution procedure was compared to a chemical one, in which the enzyme was replaced by sodium sulfide. A further comparison was made with the results previously obtained in the enzymic synthesis of the 2Fe-2S cluster of spinach ferredoxin, allowing the following conclusions to be drawn. The nature of the cluster to be inserted into the reconstituted iron-sulfur protein is determined by the apoprotein itself. The refolding of the structure of the iron-sulfur proteins around the newly inserted cluster is the rate-limiting step in both chemical and enzymic reconstitution. Rhodanese appears to play a role in the recovery of the native architecture of the reconstituted iron-sulfur protein(s). The extension to the 4Fe-4S centers of the rhodanese-based biosynthetic system allows this enzymic route to be proposed as a general way to the in vivo synthesis of iron-sulfur structures.     

The iron-sulfur clusters in Escherichia coli succinate dehydrogenase direct electron flow

Succinate dehydrogenase is an indispensable enzyme involved in the Krebs cycle as well as energy coupling in the mitochondria and certain prokaryotes. During catalysis, succinate oxidation is coupled to ubiquinone reduction by an electron transfer relay comprising a flavin adenine dinucleotide cofactor, three iron-sulfur clusters, and possibly a heme b556. At the heart of the electron transport chain is a [4Fe-4S] cluster with a low midpoint potential that acts as an energy barrier against electron transfer. Hydrophobic residues around the [4Fe-4S] cluster were mutated to determine their effects on the midpoint potential of the cluster as well as electron transfer rates. SdhB-I150E and SdhB-I150H mutants lowered the midpoint potential of this cluster; surprisingly, the His variant had a lower midpoint potential than the Glu mutant. Mutation of SdhB-Leu-220 to Ser did not alter the redox behavior of the cluster but instead lowered the midpoint potential of the [3Fe-4S] cluster. To correlate the midpoint potential changes in these mutants to enzyme function, we monitored aerobic growth in succinate minimal medium, anaerobic growth in glycerol-fumarate minimal medium, non-physiological and physiological enzyme activities, and heme reduction. It was discovered that a decrease in midpoint potential of either the [4Fe-4S] cluster or the [3Fe-4S] cluster is accompanied by a decrease in the rate of enzyme turnover. We hypothesize that this occurs because the midpoint potentials of the [Fe-S] clusters in the native enzyme are poised such that direction of electron transfer from succinate to ubiquinone is favored.     

Reactivity of nitric oxide with the [4Fe-4S] cluster of dihydroxyacid dehydratase from Escherichia coli

Although the NO (nitric oxide)-mediated modification of iron-sulfur proteins has been well-documented in bacteria and mammalian cells, specific reactivity of NO with iron-sulfur proteins still remains elusive. In the present study, we report the first kinetic characterization of the reaction between NO and iron-sulfur clusters in protein using the Escherichia coli IlvD (dihydroxyacid dehydratase) [4Fe-4S] cluster as an example. Combining a sensitive NO electrode with EPR (electron paramagnetic resonance) spectroscopy and an enzyme activity assay, we demonstrate that NO is rapidly consumed by the IlvD [4Fe-4S] cluster with the concomitant formation of the IlvD-bound DNIC (dinitrosyl-iron complex) and inactivation of the enzyme activity under anaerobic conditions. The rate constant for the initial reaction between NO and the IlvD [4Fe-4S] cluster is estimated to be (7.0+/-2.0)x10(6) M(-2) x s(-1) at 25 degrees C, which is approx. 2-3 times faster than that of the NO autoxidation by O2 in aqueous solution. Addition of GSH failed to prevent the NO-mediated modification of the IlvD [4Fe-4S] cluster regardless of the presence of O2 in the medium, further suggesting that NO is more reactive with the IlvD [4Fe-4S] cluster than with GSH or O2. Purified aconitase B [4Fe-4S] cluster from E. coli has an almost identical NO reactivity as the IlvD [4Fe-4S] cluster. However, the reaction between NO and the endonuclease III [4Fe-4S] cluster is relatively slow, apparently because the [4Fe-4S] cluster in endonuclease III is less accessible to solvent than those in IlvD and aconitase B. When E. coli cells containing recombinant IlvD, aconitase B or endonuclease III are exposed to NO using the Silastic tubing NO delivery system under aerobic and anaerobic conditions, the [4Fe-4S] clusters in IlvD and aconitase B, but not in endonuclease III, are efficiently modified forming the protein-bound DNICs, confirming that NO has a higher reactivity with the [4Fe-4S] clusters in IlvD and aconitase B than with O2 or GSH. The results suggest that the iron-sulfur clusters in proteins such as IlvD and aconitase B may constitute the primary targets of the NO cytotoxicity under both aerobic and anaerobic conditions.     

Characteristic features of the heterologous functional synthesis in Escherichia coli of a 2[4Fe-4S] ferredoxin

Different strategies have been used to express synthetic genes all encoding Clostridium pasteurianum 2[4Fe-4S] ferredoxin (Fd) in Escherichia coli. The polypeptide can be produced as the C-terminal addition to a hybrid Cro::Protein A fusion protein lacking the metallic centers. The incorporation of the [4Fe-4S] clusters into the cleaved apoFd cannot be carried out in the same conditions as those affording holoFd from purified C. pasteurianum apoFd. In contrast, fully functional Fds can be produced from non-fused synthetic genes under the dependence of strong promoters. The yields of recombinant Fd, although sufficient to purify significant quantities of protein, are limited by the very short half-life of the 2[4Fe-4S] Fd in E. coli, irrespective of the expression system used. These features are characteristic of 2[4Fe-4S] Fds when compared with the far more stable recombinant rubredoxin, and probably other small iron-sulfur proteins which have already been produced in high yields. The reasons for the high turnover of 2[4Fe-4S] Fds are discussed.     

Repair of nitric oxide-modified ferredoxin [2Fe-2S] cluster by cysteine desulfurase (IscS)

Iron-sulfur proteins are among the sensitive targets of the nitric oxide cytotoxicity. When Escherichia coli cells are exposed to nitric oxide, iron-sulfur clusters are modified forming protein-bound dinitrosyl iron complexes. Such modified protein dinitrosyl iron complexes are stable in vitro but are efficiently repaired in aerobically growing E. coli cells even without any new protein synthesis. Here we show that cysteine desulfurase encoded by the gene iscS of E. coli can directly convert the ferredoxin dinitrosyl iron complex to the ferredoxin [2Fe-2S] cluster in the presence of L-cysteine in vitro. A reassembly of the [2Fe-2S] cluster in the ferredoxin dinitrosyl iron complex does not require any addition of iron or other protein components. Furthermore, a complete removal of the dinitrosyl iron complex from ferredoxin prevents reassembly of the [2Fe-2S] cluster in the protein. The results suggest that cysteine desulfurase (IscS) together with L-cysteine can efficiently repair the nitric oxide-modified ferredoxin [2Fe-2S] cluster and that the iron center in the dinitrosyl iron complex may be recycled for the reassembly of iron-sulfur clusters in proteins.     

EPR and Mössbauer studies of benzoyl-CoA reductase

Benzoyl-CoA reductase catalyzes the two-electron transfer from a reduced ferredoxin to the aromatic ring of benzoyl-CoA; this reaction is coupled to stoichiometrical ATP hydrolysis. A very low reduction potential (less than -1 V) is required for the first electron transfer to the aromatic ring. In this work the nature of the redox centers of purified benzoyl-CoA reductase from Thauera aromatica was studied by EPR and M?ssbauer spectroscopy. The results obtained indicated the presence of three [4Fe-4S] clusters. Redox titration studies revealed that the reduction potentials of all three clusters were below -500 mV. The previously reported S = 7/2 state of the enzyme during benzoyl-CoA-independent ATPase activity (Boll, M., Albracht, S. J. P., and Fuchs, G. (1997) Eur. J. Biochem. 244, 840-851) was confirmed by M?ssbauer spectroscopy. Inactivation by oxygen was associated with the irreversible conversion of part of the [4Fe-4S] clusters to [3Fe-4S] clusters. Acetylene stimulated the benzoyl-CoA-independent ATPase activity and induced novel EPR signals with g(av) >2. The presence of simple cubane clusters in benzoyl-CoA reductase as the sole redox-active metal centers demonstrates novel aspects of [4Fe-4S] clusters since they adopt the role of elemental sodium or lithium which are used as electron donors in the analogous chemical Birch reduction of aromatic rings.     

Modulating the midpoint potential of the [4Fe-4S] cluster of the nitrogenase Fe protein

Protein-bound [FeS] clusters function widely in biological electron-transfer reactions, where their midpoint potentials control both the kinetics and thermodynamics of these reactions. The polarity of the protein environment around [FeS] clusters appears to contribute largely to modulating their midpoint potentials, with local protein dipoles and water dipoles largely defining the polarity. The function of the [4Fe-4S] cluster containing Fe protein in nitrogenase catalysis is, at least in part, to serve as the nucleotide-dependent electron donor to the MoFe protein which contains the sites for substrate binding and reduction. The ability of the Fe protein to function in this manner is dependent on its ability to adopt the appropriate conformation for productive interaction with the MoFe protein and on its ability to change redox potentials to provide the driving force required for electron transfer. Phenylalanine at position 135 is located near the [4Fe-4S] cluster of nitrogenase Fe protein and has been suggested by amino acid substitution studies to participate in defining both the midpoint potential and the nucleotide-induced changes in the [4Fe-4S] cluster. In the present study, the crystal structure of the Azotobacter vinelandii nitrogenase Fe protein variant having phenylalanine at position 135 substituted by tryptophan has been determined by X-ray diffraction methods and refined to 2.4 A resolution. A comparison of available Fe protein structures not only provides a structural basis for the more positive midpoint potential observed in the tryptophan substituted variant but also suggests a possible general mechanism by which the midpoint potential could be controlled by nucleotide interactions and nitrogenase complex formation.