On the novel H2-activating iron-sulfur center of the "Fe-only" hydrogenases

The two hydrogenases (I and II) of the anaerobic N2-fixing bacterium Clostridium pasteurianum (Cp) and the hydrogenases of the anaerobes Megasphaera elsdenii (Me) and Desulfovibrio vulgaris (strain Hildenborough, Dv), contain iron-sulfur clusters but not nickel. They are the most active hydrogenases known. All four enzymes in their reduced states give rise to EPR signals typical of [4Fe-4S]1+ clusters but exhibit novel EPR signals in their oxidized states. For example, Cp hydrogenase I exhibits a sharp rhombic EPR signal when oxidized under mild conditions but the enzyme is inactivated by over-oxidation and then exhibits an axial EPR signal. A similar axial signal is observed from mildly oxidized hydrogenase I after treatment with CO. EPR, M?ssbauer and ENDOR spectroscopy indicate that the EPR signals from the oxidized enzyme and its CO derivative arise from a novel spin-coupled Fe center. Low temperature magnetic circular dichroism (MCD) studies reveal that an EPR-silent Fe-S cluster with S greater than 1/2 is also present in oxidized hydrogenase I. From a study of all spectroscopic properties of Cp, Dv, and Me hydrogenases, it is concluded that the H2-activating site of all four is a novel Fe-S cluster with S greater than 0 and integer, which in the oxidized state is exchange-coupled to a S = 1/2 species. The data are most consistent with the S = 1/2 species being a low spin Fe(III) center. The H2-activating site is susceptible to oxidative rearrangements to yield both active and inactive states of the enzyme. We discuss the possible implications of these finding to methods of enzyme oxidation and purification procedures currently used for hydrogenases.     

EPR and electron nuclear double resonance investigation of oxidized hydrogenase II (uptake) from Clostridium pasteurianum W5. Effects of carbon monoxide binding

Two different hydrogenases have been isolated from Clostridium pasteurianum W5. Hydrogenase II (uptake) is active in H2 oxidation while hydrogenase I (bidirectional) is active both in H2 oxidation and evolution. Previous EPR and electron nuclear double resonance (ENDOR) studies of oxidized hydrogenase I have now been complemented by analogous studies on oxidized 57Fe-enriched hydrogenase II and its CO derivative (using 12CO and 13CO). Binding of CO greatly changes the EPR spectrum of oxidized hydrogenase II, and use of 13CO leads to resolved hyperfine splitting from interaction with a single 13CO molecule (AC approximately 34 MHz). This coupling is over 50% larger than that seen for hydrogenase I. 57Fe ENDOR disclosed two types of iron site in both oxidized hydrogenase II and its CO derivative. Combination of EPR, ENDOR, and M?ssbauer results shows that site 1 has AFe1 = 18 MHz shifting to approximately 30 MHz upon CO binding and consisting of two Fe atoms and site 2 has A2 approximately 7 MHz shifting to approximately 10 MHz and containing a single Fe. These results are very similar to those seen for hydrogenase I, which indicates that a structurally similar 3Fe cluster, believed to be the catalytically active site, is present in both. Proton ENDOR shows a solvent exchangeable resonance only in the CO derivative of hydrogenase II. This indicates a structural difference between hydrogenases I and II that is brought out by CO binding. No evidence of 14N coordination to the cluster is seen for either enzyme.     

Magnetic circular dichroism and electron paramagnetic resonance studies of hydrogenases I and II from Clostridium pasteurianum

The two iron-only hydrogenases (I and II) from Clostridium pasteurianum have been investigated by variable temperature magnetic circular dichroism (MCD) and electron paramagnetic resonance (EPR) spectroscopies. Samples were studied both reduced with dithionite under an atmosphere of H2 and after oxidation with thionine. The results are consistent with four and two [4Fe-4S]1+,2+ (F)-clusters in hydrogenases I and II, respectively. All four F-clusters are reduced and paramagnetic in reduced hydrogenase I, with up to one exhibiting an S = 3/2 ground state and the remainder having conventional S = 1/2 ground states. Both F-clusters have S = 1/2 ground states in reduced hydrogenase II; however, one appears to be only partially reduced under the conditions used for reduction. MCD studies of the oxidized enzymes show no temperature-dependent features in the visible region which can be attributed to the EPR-active S = 1/2 hydrogen-activating cluster, suggesting predominantly oxygen and nitrogen coordination for the iron atoms of this center. However, temperature-dependent MCD transitions arising from a hitherto undetected S greater than 1/2 Fe-S clusters are apparent in both oxidized hydrogenases. Detailed EPR studies of oxidized hydrogenase I revealed resonances from an S = 3/2 species, however, spin quantitation reveals this to be a trace component that is unlikely to be responsible for the observed low temperature MCD spectrum. The nature and origin of these S greater than 1/2 Fe-S clusters are discussed in light of the available spectroscopic data for these and other iron-only hydrogenases.     

The mechanisms of H2 activation and CO binding by hydrogenase I and hydrogenase II of Clostridium pasteurianum

Hydrogenase I (bidirectional) and hydrogenase II (uptake) of Clostridium pasteurianum have been investigated by electron paramagnetic resonance (EPR) spectroscopy, in the presence and absence of the inhibitor, CO. These hydrogenases contain both a novel type of iron-sulfur cluster (H), which is the proposed site of H2 catalysis, and ferredoxin-type [4Fe-4S] clusters (F). The results show that the H clusters of these two hydrogenases have very different properties. The H cluster of oxidized hydrogenase II (Hox-II) exhibits three distinct EPR signals, two of which are pH-dependent. Hox-II binds CO reversibly to give a single, pH-independent species with a novel, rhombic EPR spectrum. The H cluster of reduced hydrogenase II (Hred-II) does not react with CO. In contrast, the EPR spectrum of Hox-I appears homogeneous and independent of pH. Hox-I has a much lower affinity for CO than Hox-II, and binds CO irreversibly to give an axial EPR signal. Hred-I also binds CO irreversibly. The EPR spectra of Fred-I and Fred-II show little or no change after CO treatment. Prior exposure to CO does not affect the catalytic activity of the reduced or oxidized hydrogenases when assayed in the absence of CO, but both enzymes are irreversibly inactivated if CO is present during catalysis. Mechanisms for H2 activation by hydrogenase I and hydrogenase II are proposed from the determined midpoint potentials (Em, pH 8.0) of H-I and H-II (Em approximately -400 mV, -CO; approximately -360 mV, +CO), F-I (Em = -420 mV, +/- CO), and F-II (Em = -180 mV, +/- CO). These allow one to rationalize the different modes of CO binding to the two hydrogenases and suggest why hydrogenase II preferentially catalyzes H2 oxidation. The results are discussed in light of recent spectroscopic data on the structures of the two H clusters.     

Spectroscopic studies of nickel-deficient carbon monoxide dehydrogenase from Rhodospirillum rubrum: nature of the iron-sulfur clusters

Carbon monoxide dehydrogenase (CODH) from Rhodospirillum rubrum utilizes three types of Fe-S clusters to catalyze the reversible oxidation of CO to CO(2): a novel [Ni4Fe5S] active site (C cluster) and two distinct [4Fe4S] electron-transfer sites (B and D clusters). While recent X-ray data show the geometric arrangement of the five metal centers at the C cluster, electronic structures of the various [Ni4Fe5S] oxidation states remain ambiguous. These studies report magnetic circular dichroism (MCD), variable temperature, variable field MCD (VTVH MCD), and resonance Raman (rR) spectroscopic properties of the Fe-S clusters contained in Ni-deficient CODH. Essentially homogeneous sample preparations aided in the resolution of the reduced [4Fe4S](1+) (S = (1)/(2)) B cluster and the reduced Ni-deficient C cluster (denoted C, S > (1)/(2)) by MCD. The three Fe atoms derived from the [Ni3Fe4S] cubane component appear to dominate the reduced C cluster MCD spectrum, while the presence of a fourth Fe center can be inferred from the ground state spin. The same underlying MCD features present in Ni-deficient CODH spectra are also observed for Ni-containing CODH, suggesting that both proteins contain the same C cluster Fe-S component. Overlooked in all spectroscopic studies to date, the D cluster was confirmed by rR to be a typical [4Fe4S] site with cysteinyl coordination. Together, MCD and rR data show that the D cluster remains in the oxidized [4Fe4S](2+) (S = 0) state at potentials > or = -530 mV (versus SHE), thus exhibiting an unusually low redox potential for a standard [4Fe4S](2+/1+) electron-transfer site.     

The extremely thermophilic eubacterium, Thermotoga maritima, contains a novel iron-hydrogenase whose cellular activity is dependent upon tungsten.

Thermotoga maritima is the most thermophilic eubacterium currently known and grows up to 90 degrees C by a fermentative metabolism in which H2, CO2, and organic acids are end products. It was shown that the production of H2 is catalyzed by a single hydrogenase located in the cytoplasm. The addition of tungsten to the growth medium was found to increase both the cellular concentration of the hydrogenase and its in vitro catalytic activity by up to 10-fold, but the purified enzyme did not contain tungsten. It is a homotetramer of Mr 280,000 and contains approximately 20 atoms of Fe and 18 atoms of acid-labile sulfide/monomer. Other transition metals, including nickel (and also selenium), were present in only trace amounts (less than 0.1 atoms/monomer). The hydrogenase was unstable at both 4 and 23 degrees C, even under anaerobic conditions, but no activity was lost in anaerobic buffer containing glycerol and dithiothreitol. Under these conditions the enzyme was also quite thermostable (t50% approximately 1 h at 90 degrees C) but extremely sensitive to irreversible inactivation by O2 (t50% approximately 10 s in air). The optimum pH ranges for H2 evolution and H2 oxidation were 8.6-9.5 and greater than or equal to 10.4, respectively, and the optimum temperature for catalytic activity was above 95 degrees C. In contrast to mesophilic Fe hydrogenases, the T. maritima enzyme had very low H2 evolution activity, did not use T. maritima ferredoxin as an electron donor for H2 evolution, was inhibited by acetylene but not by nitrite, and exhibited EPR signals typical of [2Fe-2S]1+ clusters. Moreover, the oxidized enzyme did not exhibit the rhombic EPR signal that is characteristic of the catalytic iron-sulfur cluster of mesophilic Fe hydrogenases. These data suggest that T. maritima hydrogenase has a different FeS site and/or mechanism for catalyzing H2 production. The potential role of tungsten in regulating the activity of this enzyme is discussed.     

Electron paramagnetic resonance and other properties of hydrogenases isolated from Desulfovibrio vulgaris (strain Hildenborough) and Megasphaera elsdenii

The hydrogenases of Desulfovibrio vulgaris and Megasphaera elsdenii are compared with respect to some of their physical properties. In addition to Fe the only metal ions that are present in significant amounts are Ni and Cu. From cluster extrusion experiments it follows that the D. vulgaris enzyme contains three 4 Fe-4S clusters, while M. elsdenii hydrogenase only releases part of its Fe-S clusters. The resting D. vulgaris enzyme shows only a small 3 Fe-xS type of EPR signal (maximum 5% electron equivalent). This amount can be increased to approximately 25% by treatment with ferricyanide, with a concomitant large decrease in activity. The M. elsdenii enzyme shows in its oxidized state a normal Hipip (high-potential iron-sulphur protein) type of EPR spectrum. After a reduction/oxidation cycle the D. vulgaris enzyme also shows a weak Hipip type of EPR spectrum. In the reduced state both enzymes show complex spectra. By integration of those spectra it is shown that 1.5 electron equivalents are present. The complex spectra do not arise from nuclear hyperfine interactions but are partially due to electron spin interactions. It is proposed that the spectrum of reduced D. vulgaris hydrogenase consists of a sum of three different ferredoxin-like spectra.     

Oxidation-reduction properties of the iron-sulfur cluster in Bacillus subtilis glutamine phosphoribosylpyrophosphate amidotransferase

Native Bacillus subtilis glutamine phosphoribosylpyrophosphate amidotransferase contains a [4Fe-4S] cluster in the diamagnetic (+2) state. The cluster is essential for catalytic function, even though amidotransferase does not catalyze a redox reaction. The ability of the Fe-S cluster to undergo oxidation and reduction reactions and the consequences of changes in the redox state of the cluster for enzyme activity were studied. Treatment of the enzyme with oxidants resulted in either no reaction or complete dissolution of the Fe-S cluster and loss of activity. A stable +3 oxidation state was not detected. A small amount of paramagnetic species, probably an oxidized 3Fe cluster, was formed transiently during oxidation. The native cluster was poorly reduced by dithionite, but it could be readily reduced to the +1 state by photoreduction with 5-deazaflavin and oxalate. The reduced enzyme did not display an EPR spectrum typical of [4Fe-4S] ferredoxins in the +1 state, unless it was prepared under denaturing conditions. M?ssbauer spectroscopy of reduced 57Fe-enriched amidotransferase confirmed that the cluster was in the +1 state, but the magnetic properties of the reduced cluster observed at 4.2 K indicated that it is characterized by a ground state spin S greater than or equal to 3/2. The midpoint potential of the +1/+2 couple was too low to measure accurately by conventional techniques, but it was below -600 mV, which is 100 mV more negative than reported for [4Fe-4S] clusters in bacterial ferredoxins. Fully reduced amidotransferase had about 40% of the activity of the native enzyme in glutamine-dependent phosphoribosylamine formation. The fact that both the +1 and +2 forms of the enzyme are active indicates that the cluster does not function as a site of reversible electron transfer during catalysis.     

An EPR and electron nuclear double resonance investigation of carbon monoxide binding to hydrogenase I (bidirectional) from Clostridium pasteurianum W5

Previous M?ssbauer and electron nuclear double resonance (ENDOR) studies of oxidized hydrogenase I (bidirectional) from Clostridium pasteurianum W5 demonstrated that this enzyme contains two diamagnetic [4Fe-4S]2+ clusters and an iron-sulfur center of unknown structure and composition that is characterized by its novel M?ssbauer and ENDOR properties. In the present study we combine ENDOR and EPR measurements to show that the novel cluster contains 3-4 iron atoms. In addition, we have used EPR and ENDOR spectroscopies to investigate the effect of binding the competitive inhibitor carbon monoxide to oxidized hydrogenase I, using 13C-labeled CO and enzyme isotopically enriched in 57Fe. Treatment of oxidized enzyme with CO causes the g-tensor of the paramagnetic center to change from rhombic to axial symmetry. The observation of a 13C signal by ENDOR spectroscopy and analysis of the EPR broadening show that a single CO covalently binds to the paramagnetic center. The 13C hyperfine coupling constant (Ac approximately equal to 21 MHz) is within the range observed for inorganic iron-carbonyl clusters. The observation of 57Fe ENDOR signals from two types of iron site ([A1c] approximately 30-34 MHz; [A2c] approximately 6 MHz) and resolved 57Fe hyperfine interactions in the EPR spectrum from two nuclei characterized by [A1c] confirm that the iron-sulfur cluster remains intact upon CO coordination, but show that CO binding greatly changes the 57Fe hyperfine coupling constants.     

Molecular biology of microbial hydrogenases

Hydrogenases (H2ases) are metalloproteins. The great majority of them contain iron-sulfur clusters and two metal atoms at their active center, either a Ni and an Fe atom, the [NiFe]-H2ases, or two Fe atoms, the [FeFe]-H2ases. Enzymes of these two classes catalyze the reversible oxidation of hydrogen gas (H2 <--> 2 H+ + 2 e-) and play a central role in microbial energy metabolism; in addition to their role in fermentation and H2 respiration, H2ases may interact with membrane-bound electron transport systems in order to maintain redox poise, particularly in some photosynthetic microorganisms such as cyanobacteria. Recent work has revealed that some H2ases, by acting as H2-sensors, participate in the regulation of gene expression and that H2-evolving H2ases, thought to be involved in purely fermentative processes, play a role in membrane-linked energy conservation through the generation of a protonmotive force. The Hmd hydrogenases of some methanogenic archaea constitute a third class of H2ases, characterized by the absence of Fe-S cluster and the presence of an iron-containing cofactor with catalytic properties different from those of [NiFe]- and [FeFe]-H2ases. In this review, we emphasise recent advances that have greatly increased our knowledge of microbial H2ases, their diversity, the structure of their active site, how the metallocenters are synthesized and assembled, how they function, how the synthesis of these enzymes is controlled by external signals, and their potential use in biological H2 production.     

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.     

Fe-S centers in lactyl-CoA dehydratase

Lactyl-CoA dehydratase consists of two enzymes, E1 and E2, and requires catalytic quantities of ATP for activity [Kuchta, R. D., & Abeles, R. H. (1985) J. Biol. Chem. 260, 13181-13189]. In contrast to E1, which contains no Fe, E2 contains 8.20 +/- 0.04 mol of Fe/mol of E2, one of which can be removed by 1,10-phenanthroline. E2 also contains 7.33 +/- 0.68 mol of inorganic sulfur/mol of E2, indicating that at least seven of the Fe atoms are present as Fe-S clusters. E1 and E2 contain less than 0.14 mol of Cu, Co, Zn, Mn, and Ni/mol of E1 or E2. Both reduced and oxidized E1 are EPR silent over a 10,000-G scan range at 4 K, while two signals in E2 are observable at 4 K. Identical spectra were obtained with E2 containing either seven or eight Fe atoms, and both signals were only observable at T less than 30 K. Signal 1 has axial symmetry with g = 2.0232 and g = 2.0006. Signal 2 is orthorhombic with g1 = 1.982, g2 = 1.995, and g3 = 2.019. Computer simulation of these spectra with a S = 1/2 spin Hamiltonian was used to extract the g matrices. The intensity of both signals decreases when E2 is reduced with Na2S2O4. We propose that signal 1 is due to an unusual [4Fe-4S] cluster and signal 2 to a [3Fe-3/4S] cluster. Addition of either acrylyl-CoA or lactyl-CoA dramatically alters signal 2.(ABSTRACT TRUNCATED AT 250 WORDS)     

The crystal structure of a reduced [NiFeSe] hydrogenase provides an image of the activated catalytic center.

BACKGROUND: [NiFeSe] hydrogenases are metalloenzymes that catalyze the reaction H2<-->2H+ + 2e-. They are generally heterodimeric, contain three iron-sulfur clusters in their small subunit and a nickel-iron-containing active site in their large subunit that includes a selenocysteine (SeCys) ligand. RESULTS: We report here the X-ray structure at 2.15 A resolution of the periplasmic [NiFeSe] hydrogenase from Desulfomicrobium baculatum in its reduced, active form. A comparison of active sites of the oxidized, as-prepared, Desulfovibrio gigas and the reduced D. baculatum hydrogenases shows that in the reduced enzyme the nickel-iron distance is 0.4 A shorter than in the oxidized enzyme. In addition, the putative oxo ligand, detected in the as-prepared D. gigas enzyme, is absent from the D. baculatum hydrogenase. We also observe higher-than-average temperature factors for both the active site nickel-selenocysteine ligand and the neighboring Glu18 residue, suggesting that both these moieties are involved in proton transfer between the active site and the molecular surface. Other differences between [NiFeSe] and [NiFe] hydrogenases are the presence of a third [4Fe4S] cluster replacing the [3Fe4S] cluster found in the D. gigas enzyme, and a putative iron center that substitutes the magnesium ion that has already been described at the C terminus of the large subunit of two [NiFe] hydrogenases. CONCLUSIONS: The heterolytic cleavage of molecular hydrogen seems to be mediated by the nickel center and the selenocysteine residue. Beside modifying the catalytic properties of the enzyme, the selenium ligand might protect the nickel atom from oxidation. We conclude that the putative oxo ligand is a signature of inactive 'unready' [NiFe] hydrogenases.     

Biologically related iron-sulfur clusters as reaction centers. Reduction of acetylene to ethylene in systems based on [Fe4S4(SR)4]3-

The possibility that clusters containing the Fe4S4 core unit found in a wide variety of proteins can effect reductive transformations of Fe-S enzyme substrates has been investigated using the reduced synthetic clusters [Fe4S4(SPh)4]3- and acetylene, an alternate nitrogenase substrate. The system [Fe4S4(SPh)4]3-/acetic acid/acetic anhydride in N-methylpyrollidinone at approximately 25 degrees was found to reduce acetylene homogeneously to ethylene, and in the presence of a deuterium source to afford as the principal stereochemical product cis-1,2-C2H2D2. No appreciable reduction was found using the oxidized cluster [Fe4S4(SPh)4]2-. The system is not catalytic and departs from the strict stoichiometry of the reaction, 2[Fe4S4(SPh)4]3- + C2H2 + 2H+ leads to 2 [Fe4S4(SPh)4]2- + C2H4, primarily because of a competing cluster oxidation reaction which could not be eliminated. Based on this reaction ca. 60% conversion of acetylene to ethylene was achieved. A reaction sequence based on absorption and 1H nmr spectral observations and product stereo-chemistry is suggested. The results demonstrate that biologically related, reduced Fe4S4 clusters can effect reduction of at least one Fe-S enzyme substrate, and raise the general possibility of substrate transformation with such clusters as reaction sites in biological systems.     

Conversion of the central [4Fe-4S] cluster into a [3Fe-4S] cluster leads to reduced hydrogen-uptake activity of the F420-reducing hydrogenase of Methanococcus voltae.

As in many other hydrogenases, the small subunit of the F420-reducing hydrogenase of Methanococcus voltae contains three iron-sulfur clusters. The arrangement of the three [4Fe-4S] clusters corresponds to the arrangement of [Fe-S] clusters in the [NiFeSe] hydrogenase of Desulfomicrobium baculatum. Many other hydrogenases contain two [4Fe-4S] clusters and one [3Fe-4S] cluster with a relatively high redox potential, which is located in the central position between a proximal and a distal [4Fe-4S] cluster. We have investigated the role of the central [4Fe-4S] cluster in M. voltae with regard to its effect on the enzyme activity and its spectroscopic properties. Using site-directed mutagenesis, we constructed a strain in which one cysteine ligand of the central [4Fe-4S] cluster was replaced by proline. The mutant protein was purified, and the [4Fe-4S] to [3Fe-4S] cluster conversion was confirmed by EPR spectroscopy. The conversion resulted in an increase in the redox potential of the [3Fe-4S] cluster by about 400 mV. The [NiFe] active site was not affected significantly by the mutation as assessed by the unchanged Ni EPR spectrum. The specific activity of the mutated enzyme did not show any significant differences with the artificial electron acceptor benzyl viologen, but its specific activity with the natural electron acceptor F420 decreased tenfold.     

氢酶结构及催化机理研究进展

氢酶是一类催化氢的氧化或质子还原的酶,它在微生物产氢过程中扮演着重要角色。根据氢酶所含的金属元素,可分为NiFe_氢酶、Fe-氢酶和不含金属元素的metal_free氢酶。大多数氢酶含有金属原子,它们参与氢酶活性中心和[Fe_S]簇的形成。氢酶的活性中心直接催化氢的氧化与质子的还原,[Fe_S]簇则参与氢酶催化过程中电子的传输。目前已有数种NiFe_氢酶和Fe_氢酶的X射线衍射晶体结构被阐明。根据metal_free氢酶的序列特征,推断其结构与NiFe_氢酶和Fe_氢酶之间存在较大差异。对氢酶活性中心和[Fe_S]簇的深入研究,揭示了氢酶催化反应的机理。     

Nitrogenase. VIII. M?ssbauer and EPR spectroscopy. The MoFe protein component from Azotobacter vinelandii OP.

We have studied the molybdenum-iron protein (MoFe protein, also known as component I) from Azobacter vinelandi using M?ssbauer spectroscopy and electron paramagnetic resonance on samples enriched with 57Fe. These spectra can be interpreted in terms of two EPR active centers, each of which is reducible by one electron. A total of four different chemical environments of Fe can be discerned. One of them is a cluster of Fe atoms with a net electronic spin of 3/2, one of them is high-spin ferrous iron and the remaining two are iron in a reduced state (probably in clusters). The results are as follows: Chemical analysis yields 11.5 Fe atoms and 12.5 labile sulfur atoms per molybdenum atom; the molecule contains two Mo atoms per 300 000 daltons. The EPR spectrum of the MoFe protein exhibits g values at 4.32, 3.65 and 2.01, associated with the ground state doublet of a S = 3/2 spin system. The spin Hamiltonian H = D(S2/z minus 5/4 + lambda(S2/x minus S2/y)) + gbeta/o S-H fits the experimental data for go = 2.00 and lambda = 0.055. Quantitative analysis of the temperature dependence of the EPR spectrum yields D/k = 7.5 degrees K and 0.91 spins/molybdenum atom, which suggests that the MoFe protein has two EPR active centers. Quantitative evaluation of M?ssbauer spectra shows that approximately 8 iron atoms give rise to one quadrupole doublet; at lower temperatures magnetic spectra, associated with the groud electronic doublet, are observed; at least two magnetically inequivalent sites can be distinguished. Taken together the data suggest that each EPR center contains 4 iron atoms. The EPR and M?ssbauer data can only be reconciled if these iron atoms reside in a spin-coupled (S = 3/2) cluster. Under nitrogen fixing conditions the magnetic M?ssbauer spectra disappeared concurrently with the EPR signal and quadrupole doublets are obserced at all temperatures. The data suggest that each EPR active center is reduced by one electron. The M?ssbauer investigation reveals three other spectral components characteristic of iron nuclei in an environment of integer or zero electronic spin, i.e. they reside in complexes which are "EPR-silent". One of the components (3-4 iron atoms) has M?ssbauer parameters characteristic of the high-spin ferrous iron as in reduced ruberdoxin. However, measurements in strong fields indicate a diamagnetic environment. Another component, representing 9-11 iron atoms, seems to be diamagnetic also. It is suggested that these atoms are incorporated in spin-coupled clusters.     

Crystal structures of ferricyanide-oxidized [Fe-S] clusters in Azotobacter vinelandii ferredoxin I

Crystals of Azotobacter vinelandii ferredoxin I (FdI) have been soaked in solutions containing K₃Fe(CN)₆ in order to study the oxidation of the [3Fe-4S] and [4Fe-4S] clusters in the protein. Ferricyanide treatment results in partial loss of Fe and S from each cluster accompanied by alteration of Fe-S bonds. The effects of oxidation can be quantitated by crystallographic refinement when each [Fe-S] cluster is modeled as having a single, average structure with non-standard geometry. The oxidized clusters refined at 2.1-Å resolution display statistically significant deviations from geometric ideality. If interpreted in terms of atomic shifts these deviations indicate that each cluster first loses an inorganic S atom. In each case an Fe atom bonded to this S separates from the remaining atoms of the cluster such that the [3Fe-4S] and [4Fe-4S] clusters partially decompose into a single Fe plus 2Fe and 3Fe fragments. The extent of structural changes observed are essentially the same in crystals soaked at 3?:?1, 9?:?1 and 30?:?1 mole ratio of K₃ Fe(CN)₆?:?FdI, suggesting that the crystal lattice permits limited oxidation reactions to occur at a low mole ratio but restricts conformational changes from occurring that may be required for more extensive oxidative reactions at higher mole ratio. The results are relevant to understanding the transformations which may take place when [Fe-S] proteins are deliberately oxidized with ferricyanide.     

Reduction of unusual iron-sulfur clusters in the H2-sensing regulatory Ni-Fe hydrogenase from Ralstonia eutropha H16

The regulatory Ni-Fe hydrogenase (RH) from Ralstonia eutropha functions as a hydrogen sensor. The RH consists of the large subunit HoxC housing the Ni-Fe active site and the small subunit HoxB containing Fe-S clusters. The heterolytic cleavage of H(2) at the Ni-Fe active site leads to the EPR-detectable Ni-C state of the protein. For the first time, the simultaneous but EPR-invisible reduction of Fe-S clusters during Ni-C state formation was demonstrated by changes in the UV-visible absorption spectrum as well as by shifts of the iron K-edge from x-ray absorption spectroscopy in the wild-type double dimeric RH(WT) [HoxBC](2) and in a monodimeric derivative designated RH(stop) lacking the C-terminal 55 amino acids of HoxB. According to the analysis of iron EXAFS spectra, the Fe-S clusters of HoxB pronouncedly differ from the three Fe-S clusters in the small subunits of crystallized standard Ni-Fe hydrogenases. Each HoxBC unit of RH(WT) seems to harbor two [2Fe-2S] clusters in addition to a 4Fe species, which may be a [4Fe-3S-3O] cluster. The additional 4Fe-cluster was absent in RH(stop). Reduction of Fe-S clusters in the hydrogen sensor RH may be a first step in the signal transduction chain, which involves complex formation between [HoxBC](2) and tetrameric HoxJ protein, leading to the expression of the energy converting Ni-Fe hydrogenases in R. eutropha.     

Detection of a [3Fe-4S] cluster intermediate of cytosolic aconitase in yeast expressing iron regulatory protein 1. Insights into the mechanism of Fe-S cluster cycling.

Interconversion of iron regulatory protein 1 (IRP1) with cytosolic aconitase (c-aconitase) occurs via assembly/disassembly of a [4Fe-4S] cluster. Recent evidence implicates oxidants in cluster disassembly. We investigated H(2)O(2)-initiated Fe-S cluster disassembly in c-aconitase expressed in Saccharomyces cerevisiae. A signal for [3Fe-4S] c-aconitase was detected by whole-cell EPR of aerobically grown, aco1 yeast expressing wild-type IRP1 or a S138A-IRP1 mutant (IRP1(S138A)), providing the first direct evidence of a 3Fe intermediate in vivo. Exposure of yeast to H(2)O(2) increased this 3Fe c-aconitase signal up to 5-fold, coincident with inhibition of c-aconitase activity. Untreated yeast expressing IRP1(S138D) or IRP1(S138E), which mimic phosphorylated IRP1, failed to give a 3Fe signal. H(2)O(2) produced a weak 3Fe signal in yeast expressing IRP1(S138D). Yeast expressing IRP1(S138D) or IRP1(S138E) were the most sensitive to inhibition of aconitase-dependent growth by H(2)O(2) and were more responsive to changes in media iron status. Ferricyanide oxidation of anaerobically reconstituted c-aconitase yielded a strong 3Fe EPR signal with wild-type and S138A c-aconitases. Only a weak 3Fe signal was obtained with S138D c-aconitase, and no signal was obtained with S138E c-aconitase. This, paired with loss of c-aconitase activity, strongly argues that the Fe-S clusters of these phosphomimetic c-aconitase mutants undergo more complete disassembly upon oxidation. Our results demonstrate that 3Fe c-aconitase is an intermediate in H(2)O(2)-initiated Fe-S cluster disassembly in vivo and suggest that cluster assembly/disassembly in IRP1 is a dynamic process in aerobically growing yeast. Further, our results support the view that phosphorylation of IRP1 can modulate its response to iron through effects on Fe-S cluster stability and turnover.