The active site of the [FeFe]-hydrogenase from Desulfovibrio desulfuricans. II. Redox properties, light sensitivity and CO-ligand exchange as observed by infrared spectroscopy

In [FeFe]-hydrogenases, the H cluster (hydrogen-activating cluster) contains a di-iron centre ([2Fe]_H subcluster, a (L)(CO)(CN)Fe(μ-RS₂)(μ-CO)Fe(CysS)(CO)(CN) group) covalently attached to a cubane iron-sulphur cluster ([4Fe-4S]_H subcluster). The Cys-thiol functions as the link between one iron (called Fe1) of the [2Fe]_H subcluster and one iron of the cubane subcluster. The other iron in the [2Fe]_H subcluster is called Fe2. The light sensitivity of the Desulfovibrio desulfuricans enzyme in a variety of states has been studied with infrared (IR) spectroscopy. The aerobic inactive enzyme (H_inact state) and the CO-inhibited active form (H_ox–CO state) were stable in light. Illumination of the H_ox state led to a kind of cannibalization; in some enzyme molecules the H cluster was destroyed and the released CO was captured by the H clusters in other molecules to form the light-stable H_ox–CO state. Illumination of active enzyme under ¹³CO resulted in the complete exchange of the two intrinsic COs bound to Fe2. At cryogenic temperatures, light induced the photodissociation of the extrinsic CO and the bridging CO of the enzyme in the H_ox–CO state. Electrochemical redox titrations showed that the enzyme in the H_inact state converts to the transition state (H_trans) in a reversible one-electron redox step (E _{m, pH 7}=–75 mV). IR spectra demonstrate that the added redox equivalent not only affects the [4Fe-4S]_H subcluster, but also the di-iron centre. Enzyme in the H_trans state reacts with extrinsic CO, which binds to Fe2. The H_trans state converts irreversibly into the H_ox state in a redox-dependent reaction most likely involving two electrons (E _{m, pH 7}=–261 mV). These electrons do not end up on any of the six Fe atoms of the H cluster; the possible destiny of the two redox equivalents is discussed. An additional reversible one-electron redox reaction leads to the H_red state (E _{m, pH 7}=–354 mV), where both Fe atoms of the [2Fe]_H subcluster have the same formal oxidation state. The possible oxidation states of Fe1 and Fe2 in the various enzyme states are discussed. Low redox potentials (below –500 mV) lead to destruction of the [2Fe]_H subcluster.     

Spin distribution of the H-cluster in the Hox–CO state of the [FeFe] hydrogenase from Desulfovibrio desulfuricans: HYSCORE and ENDOR study of 14N and 13C nuclear interactions

Hydrogenases are enzymes which catalyze the reversible cleavage of molecular hydrogen into protons and electrons. In [FeFe] hydrogenases the active center is a 6Fe6S cluster, referred to as the “H-cluster.” It consists of the redox-active binuclear subcluster ([2Fe]_H) coordinated by CN⁻ and CO ligands and the cubane-like [4Fe–4S]_H subcluster which is connected to the protein via Cys ligands. One of these Cys ligands bridges to the [2Fe]_H subcluster. The CO-inhibited form of [FeFe] hydrogenase isolated from Desulfovibrio desulfuricans was studied using advanced EPR methods. In the H_ox–CO state the open coordination site at the [2Fe]_H subcluster is blocked by extrinsic CO, giving rise to an EPR-active S = 1/2 species. The CO inhibited state was prepared with ¹³CO and illuminated under white light at 273 K. In this case scrambling of the CO ligands occurs. Three ¹³C hyperfine couplings of 17.1, 7.4, and 3.8 MHz (isotropic part) were observed and assigned to ¹³CO at the extrinsic, the bridging, and the terminal CO-ligand positions of the distal iron, respectively. No ¹³CO exchange of the CO ligand to the proximal iron was observed. The hyperfine interactions detected indicate a rather large distribution of the spin density over the terminal and bridging CO ligands attached to the distal iron. Furthermore, ¹⁴N nuclear spin interactions were measured. On the basis of the observed ¹⁴N hyperfine couplings, which result from the CN⁻ ligands of the [2Fe]_H subcluster, it has been concluded that there is very little unpaired spin density on the cyanides of the binuclear subcluster.

Does the environment around the H-cluster allow coordination of the pendant amine to the catalytic iron center in [FeFe] hydrogenases? Answers from theory

[FeFe] hydrogenases are H₂-evolving enzymes that feature a diiron cluster in their active site (the [2Fe]_H cluster). One of the iron atoms has a vacant coordination site that directly interacts with H₂, thus favoring its splitting in cooperation with the secondary amine group of a neighboring, flexible azadithiolate ligand. The vacant site is also the primary target of the inhibitor O₂. The [2Fe]_H cluster can span various redox states. The active-ready form (H_ox) attains the Fe^IIFe^I state. States more oxidized than H_ox were shown to be inactive and/or resistant to O₂. In this work, we used density functional theory to evaluate whether azadithiolate-to-iron coordination is involved in oxidative inhibition and protection against O₂, a hypothesis supported by recent results on biomimetic compounds. Our study shows that Fe–N(azadithiolate) bond formation is favored for an Fe^IIFe^II active-site model which disregards explicit treatment of the surrounding protein matrix, in line with the case of the corresponding Fe^IIFe^II synthetic system. However, the study of density functional theory models with explicit inclusion of the amino acid environment around the [2Fe]_H cluster indicates that the protein matrix prevents the formation of such a bond. Our results suggest that mechanisms other than the binding of the azadithiolate nitrogen protect the active site from oxygen in the so-called H _ox ^inact state.     

Rhodobacter capsulatus magnesium chelatase subunit BchH contains an oxygen sensitive iron–sulfur cluster

Magnesium chelatase is the first unique enzyme of the bacteriochlorophyll biosynthetic pathway. It consists of three subunits (BchI, BchD, and BchH). Amino acid sequence analysis of the Rhodobacter capsulatus BchH revealed a novel cysteine motif (³⁹³CX₂CX₃CX₁₄C) that was found in only six other proteobacteria (CX₂CX₃CX_11–14C). The cysteine motif is likely to coordinate an unprecedented [Fe–S] cluster. Purified BchH demonstrated absorbance in the 460 nm region. This absorbance was abolished in BchH proteins with alanine substitutions at positions Cys396 and Cys414. These modified proteins were also EPR silent. In contrast, wild type BchH protein in the reduced state showed EPR signals resembling those of a [4Fe–4S] cluster with rhombic symmetry and g values at 1.90, 1.93, and 2.09, superimposed with a [3Fe–4S] cluster centered at g = 2.02. The [3Fe–4S] signal was observed independently of the [4Fe–4S] signal under oxidizing conditions. Mg-chelatase activity assays showed that the cluster is not catalytic. We suggest that the [4Fe–4S] and [3Fe–4S] signals originate from a single coordination site on the monomeric BchH protein and that the [4Fe–4S] cluster is sensitive to oxidation. It is speculated that the cluster participates in the switching between aerobic and anaerobic life of the proteobacteria.     

The exchange activities of [Fe] hydrogenase (iron–sulfur-cluster-free hydrogenase) from methanogenic archaea in comparison with the exchange activities of [FeFe] and [NiFe] hydrogenases

[Fe] hydrogenase (iron–sulfur-cluster-free hydrogenase) catalyzes the reversible reduction of methenyltetrahydromethanopterin (methenyl-H₄MPT⁺) with H₂ to methylene-H₄MPT, a reaction involved in methanogenesis from H₂ and CO₂ in many methanogenic archaea. The enzyme harbors an iron-containing cofactor, in which a low-spin iron is complexed by a pyridone, two CO and a cysteine sulfur. [Fe] hydrogenase is thus similar to [NiFe] and [FeFe] hydrogenases, in which a low-spin iron carbonyl complex, albeit in a dinuclear metal center, is also involved in H₂ activation. Like the [NiFe] and [FeFe] hydrogenases, [Fe] hydrogenase catalyzes an active exchange of H₂ with protons of water; however, this activity is dependent on the presence of the hydride-accepting methenyl-H₄MPT⁺. In its absence the exchange activity is only 0.01% of that in its presence. The residual activity has been attributed to the presence of traces of methenyl-H₄MPT⁺ in the enzyme preparations, but it could also reflect a weak binding of H₂ to the iron in the absence of methenyl-H₄MPT⁺. To test this we reinvestigated the exchange activity with [Fe] hydrogenase reconstituted from apoprotein heterologously produced in Escherichia coli and highly purified iron-containing cofactor and found that in the absence of added methenyl-H₄MPT⁺ the exchange activity was below the detection limit of the tritium method employed (0.1 nmol min⁻¹ mg⁻¹). The finding reiterates that for H₂ activation by [Fe] hydrogenase the presence of the hydride-accepting methenyl-H₄MPT⁺ is essentially required. This differentiates [Fe] hydrogenase from [FeFe] and [NiFe] hydrogenases, which actively catalyze H₂/H₂O exchange in the absence of exogenous electron acceptors.     

Characterization of a HoxEFUYH type of [NiFe] hydrogenase from <Emphasis Type="Italic">Allochromatium vinosum</Emphasis> and some EPR and IR properties of the hydrogenase module

A soluble hydrogenase from Allochromatium vinosum was purified. It consisted of a large (M _r = 52 kDa) and a small (M _r = 23 kDa) subunit. The genes encoding for both subunits were identified. They belong to an open reading frame where they are preceded by three more genes. A DNA fragment containing all five genes was cloned and sequenced. The deduced amino acid sequences of the products characterized the complex as a member of the HoxEFUYH type of [NiFe] hydrogenases. Detailed sequence analyses revealed binding sites for eight Fe–S clusters, three [2Fe–2S] clusters and five [4Fe–4S] clusters, six of which are also present in homologous subunits of [FeFe] hydrogenases and NADH:ubiquione oxidoreductases (complex I). This makes the HoxEFUYH type of hydrogenases the one that is evolutionary closest to complex I. The relative positions of six of the potential Fe–S clusters are predicted on the basis of the X-ray structures of the Clostridium pasteurianum [FeFe] hydrogenase I and the hydrophilic domain of complex I from Thermus thermophilus. Although the HoxF subunit contains binding sites for flavin mononucleotide and NAD(H), cell-free extracts of A. vinosum did not catalyse a H₂-dependent reduction of NAD⁺. Only the hydrogenase module (HoxYH) could be purified. Its electron paramagnetic resonance (EPR) and IR spectral properties showed the presence of a Ni–Fe active site and a [4Fe–4S] cluster. Its activity was sensitive to carbon monoxide. No EPR signals from a light-sensitive Ni_a–C* state could be observed. This study presents the first IR spectroscopic data on the HoxYH module of a HoxEFUYH type of [NiFe] hydrogenase.     

Synthesis and physicochemical characterization of a novel precursor for covalently bound macromolecular MRI contrast agents

 The ligand DOTASA was designed and synthesized in the aim of obtaining a kinetically and thermodynamically stable Gd(III) chelate which, through its uncoordinated carboxylate function, will provide an efficient pathway to couple the complex to bio- or macromolecules without affecting the coordination pattern of DOTA. Furthermore, it allows us to study the influence of an extra carboxylate arm on the parameters determining proton relaxivity in comparison to the commercial agent [Gd(DOTA)(H₂O)]^–. A combined variable-temperature ¹⁷O NMR, EPR and nuclear magnetic relaxation dispersion study on the Gd(III) chelate resulted in k ²⁹⁸ _ex=(6.3±0.2)×10⁶ s^–1 for the water exchange rate and τ²⁹⁸ _R=125±2 ps for the rotational correlation time. The slight increase in both k ²⁹⁸ _ex and τ²⁹⁸ _R, as compared to those for [Gd(DOTA)(H₂O)]^–, is attributed to the presence of the extra negative charge. The longer rotational correlation time results in a proton relaxivity of 5.03 mM^–1 s^–1 for [Gd(DOTASA)(H₂O)]^2–, which is approximately 30% higher than that for [Gd(DOTA)(H₂O)]^–. The increased water exchange rate of [Gd(DOTASA)(H₂O)]^2– has no consequence for proton relaxivity since this latter is exclusively limited by fast rotation for both complexes. However, for slowly rotating macromolecular agents, which contain a covalently coupled DOTASA unit instead of a coupled DOTA, this increased exchange rate will have a significant positive effect. Received: 31 December 1998 / Accepted: 4 March 1999     

Immobilization of the hyperthermophilic hydrogenase from Aquifex aeolicus bacterium onto gold and carbon nanotube electrodes for efficient H2 oxidation

The electrochemistry of membrane-bound [NiFe] hydrogenase I ([NiFe]-hase I) from the hyperthermophilic bacterium Aquifex aeolicus was investigated at gold and graphite electrodes. Direct and mediated H₂ oxidation were proved to be efficient in a temperature range of 25–70 °C, describing a potential window for H₂ oxidation similar to that of O₂-tolerant hydrogenases. Search for enhancement of current densities and enzyme stability was achieved by the use of carbon nanotube coatings. We report high catalytic currents for H₂ oxidation up to 1 mA cm⁻², 10 times higher than at the bare electrode. Interestingly, high stability of the direct catalytic process was observed when encapsulating A. aeolicus [NiFe]-hase I into a carboxylic functionalized single walled carbon nanotube network. This suggests a peculiar interaction between the enzyme and the electrode material. The parameters that governed the orientation of the enzyme before electron transfer were thus investigated using self-assembled-monolayer gold electrodes. No control of the orientation by the charge or the hydrophobicity of the interface was demonstrated. This behavior was explained on the basis of a structural comparison between A. aeolicus [NiFe]-hase I and Desulfovibrio fructosovorans [NiFe] hydrogenase, which revealed the absence of acidic residues and an additional loop in the environment of the [4Fe–4S] distal cluster in A. aeolicus [NiFe]-hase I. Finally, the effect of inhibitors on the direct oxidation of H₂ by A. aeolicus [NiFe]-hase I encapsulated in a single walled carbon nanotube network was investigated. No inhibition by CO and tolerance toward O₂ were observed. Discussion of the reasons for such tolerance was undertaken on the basis of structural comparison with hydrogenases from aerobic bacteria.     

Isocyanides inhibit [Fe]-hydrogenase with very high affinity

[Fe]-Hydrogenase catalyzes the reversible activation of H₂. CO and CN⁻ inhibit this enzyme with low affinity (K_i ≅ 0.1 mM) by binding to the iron site of the bound iron-guanyrylpyridinol cofactor. We report here that isocyanides, which are formally isoelectronic with CO and CN⁻, strongly inhibit [Fe]-hydrogenase (K_i as low as 1 nM). The [NiFe]- and [FeFe]-hydrogenases tested were not inhibited by isocyanides. UV–Vis and infrared spectra revealed that the isocyanides bind to the iron center of [Fe]-hydrogenase. The inhibition kinetics are in agreement with the proposed catalytic mechanism, including the open/closed conformational change of the enzyme.     

Biochemical and spectroscopic characterization of the membrane-bound nitrate reductase from Marinobacter hydrocarbonoclasticus 617

Membrane-bound nitrate reductase from Marinobacter hydrocarbonoclasticus 617 can be solubilized in either of two ways that will ultimately determine the presence or absence of the small (Ι) subunit. The enzyme complex (NarGHI) is composed of three subunits with molecular masses of 130, 65, and 20 kDa. This enzyme contains approximately 14 Fe, 0.8 Mo, and 1.3 molybdopterin guanine dinucleotides per enzyme molecule. Curiously, one heme b and 0.4 heme c per enzyme molecule have been detected. These hemes were potentiometrically characterized by optical spectroscopy at pH 7.6 and two noninteracting species were identified with respective midpoint potentials at E _m = +197 mV (heme c) and −4.5 mV (heme b). Variable-temperature (4–120 K) X-band electron paramagnetic resonance (EPR) studies performed on both as-isolated and dithionite-reduced nitrate reductase showed, respectively, an EPR signal characteristic of a [3Fe–4S]⁺ cluster and overlapping signals associated with at least three types of [4Fe–4S]⁺ centers. EPR of the as-isolated enzyme shows two distinct pH-dependent Mo(V) signals with hyperfine coupling to a solvent-exchangeable proton. These signals, called “low-pH” and “high-pH,” changed to a pH-independent Mo(V) signal upon nitrate or nitrite addition. Nitrate addition to dithionite-reduced samples at pH 6 and 7.6 yields some of the EPR signals described above and a new rhombic signal that has no hyperfine structure. The relationship between the distinct EPR-active Mo(V) species and their plausible structures is discussed on the basis of the structural information available to date for closely related membrane-bound nitrate reductases. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

Kinetic studies on the reactions of Fusarium galactose oxidase with five different substrates in the presence of dioxygen

 Reactions (25  °C) of galactose oxidase, GOase_ox from Fusarium NRRL 2903 with five different primary-alcohol-containing substrates RCH₂OH:- D-galactose (I) and 2-deoxy-d-galactose (II) (monosaccharides); methyl-β-d-galactopyranoside (III) (glycoside);d-raffinose (IV) (trisaccharide); and dihydroxyacetone (V) have been studied in the presence of O₂. The GOase_ox state has a tyrosyl radical coordinated at a square-pyramidal Cu^II active site, and is a two-equivalent oxidant. Reactant concentrations were [GOase_ox] (0.8–10 μM), RCH₂OH (1.0–6.0 mM), and O₂ (0.14–0.29 mM), with I=0.100 M (NaCl). The reactions, monitored at 450 nm by stopped-flow spectrophotometry, terminated with depletion of the O₂. Each trace was fitted to the competing reactions GOase_ox+RCH₂ OH → GOase_redH₂+RCHO (k ₁), and GOase_redH₂+O₂→ GOase_ox+H₂O₂ (k ₂), with GOase_redH₂ written as the doubly protonated two-electron-reduced Cu^I product. It was necessary to avoid auto-redox interconversion of GOase_ox and GOase_semi . Information obtained at pH 7.5 indicates a 5 : 95 (ox : semi) "native" mix equilibration complete in ∼3 h. At pH >7.5, rate constants 10^–4 k ₁ / M^–1 s^–1 for the reactions of GOase_ox with (I) (1.19), (II) (1.07), (III) (1.29), (IV) (1.81), (V) (2.94) were determined. On decreasing the pH to 5.5, k ₁ values decreased by factors of up to a half, and acid dissociation pK _as in the range 6.6–6.9 were obtained. UV-Vis spectrophotometric studies on GOase_ox gave an independently determined pK _a of 6.7. No corresponding reactions of the Tyr495Phe variant were observed, and there are no similar UV-Vis absorbance changes for this variant. The pK _a is therefore assigned to protonation of Tyr-495 which is a ligand to the Cu. The rate constant k ₂ (1.01×10⁷ M^–1 s^–1) is independent of pH in the range 5.5–9.0 investigated, suggesting that H⁺ (or H-atoms) for the O₂ → H₂O₂ change are provided by the active site of GOase_red . The Cu^I of GOase_red is less extensively complexed, and a coordination number of three is likely. Received: 4 February 1997 / Accepted: 16 May 1997     

Redox chemistry of biological tungsten: an EPR study of the aldehyde oxidoreductase from Pyrococcus furiosus

 Aldehyde:ferredoxin oxidoreductase (AOR) from the hyperthermophilic archaeon Pyrococcus furiosus is a homodimeric protein. Each subunit carries one [4Fe-4S] cubane and a novel tungsten cofactor containing two pterins. A single iron atom bridges between the subunits. AOR has previously been studied with EPR spectroscopy in an inactive form known as the red tungsten protein (RTP): reduced RTP exhibits complex EPR interaction signals. We have now investigated the active enzyme AOR with EPR, and we have found an S = 1/2 plus S = 3/2 spin mixture from a non-interacting [4Fe-4S]¹⁺ cluster in the reduced enzyme. Oxidized AOR affords EPR signals typical for W(V) with g–values of 1.982, 1.953, and 1.885. The W(V) signals disappear at a reduction potential E _m,7.5 of +180 mV. This unexpectedly high value indicates that the active-site redox chemistry is based on the pterin part of the cofactor. Received: 18 December 1995 / Accepted: 26 March 1996     

Kinetics and mechanisms of Fe(III) complexation by lipophilic 3-hydroxy-2-methyl-1(γ-stearoamidopropyl)-4-pyridinone (HMSP)

 The kinetics of Fe(III) complexation by lipophilic 3-hydroxy-2-methyl-l(γ-stearoamidopropyl)-4-pyridinone (HMSP) were studied when [Fe(III)] > [HMSP] in MeOH/H₂O mixed solvent and [Fe(III)] < [HMSP] in MeOH, respectively. When Fe(III) was in excess, the observed rate constants depend on [Fe(III)]² _tot and on the reciprocal of [H⁺] and decrease with increasing pressure. ΔV ^‡ values are around +8.0 cm³ mol^–1. A mechanism consisting of the complexations of the hydrolyzed monomer Fe(H₂O)₅OH²⁺ and dimer species Fe₂(H₂O)₇ (μ-OH)₂OH³⁺ by HMSP is proposed. This mechanism is supported by the solvent effect and the work of other researchers. When HMSP is in excess, Fe(HMSP)₃ is formed and three kinetic steps on different time-scales are observed. An "intermolecular chelate ring-closure" mechanism is proposed, differing from the "intramolecular chelate ring-closure" complexation reported for the formation of ferrioxamine B. Received: 14 February 1997 / Accepted: 1 September 1997     

Acetyl-CoA decarbonylase/synthase complex from Archaeoglobus fulgidus

The acetyl-CoA decarbonylase/synthase (ACDS) multienzyme complex catalyzes the reversible cleavage and synthesis of acetyl-CoA in methanogens. This report of the enzyme complex in Archaeoglobus fulgidus demonstrates the existence of a functional ACDS complex in an organism that is not a methanogen. The A. fulgidus enzyme complex contained five subunits of 89, 72, 50, 49.5, and 18.5 kDa, and it catalyzed the overall synthesis of acetyl-CoA according to the following reaction: w CO₂ + 2 Fd_red(Fe²⁺) + 2 H⁺ + CH₃– H₄SPt + CoA ⇌ acetyl-CoA + H₄SPt + 2 Fd_ox(Fe³⁺) + H₂O where Fd is ferredoxin, and CH₃–H₄SPt and H₄SPt denote N ⁵-methyl-tetrahydrosarcinapterin and tetrahydrosarcinapterin, respectively. Received: 27 October 1997 / Accepted: 29 January 1998     

On the active site of hydrogenase from Chromatium vinosum

Isotope substitution of ⁵⁷Fe ($\text{I =}\text{1}\text{2}$) for ⁵⁶Fe has a pronounced effect on the two EPR signals of hydrogenase of Chromatium vinosum. It is proposed that signal 1, the intensity of which is increased several-fold by a deoxygenation-oxygenation cycle with a simultaneous increase of a signal from Fe³⁺, is due to a [3Fe-xS] cluster. It is further proposed that signal 2 is caused by a magnetic interaction of a [4Fe-4S]³⁺ cluster with an unidentified paramagnet. The addition of 10 μM Ni to the culture medium (already containing 1 μM Ni) increased the enzyme activity 3–6-fold, without effect on the growth of the bacterium. Addition of ⁶¹Ni ($\text{I =}\text{3}\text{2}$) to the medium did not change the EPR spectrum of hydrogenase. From a comparison of the EPR signal intensities and the enzyme activities it is concluded that, in the hydrogenase preparation as isolated, molecules containing a [3Fe-xS) cluster are not active, and that active molecules have a [4Fe-4S]^3+(3+,2+) cluster plus an as yet unidentified paramagnetic redox component. The latter is thought to be the primary site of interaction of the enzyme with H₂. Ni is considered as a possible candidate for this component.     

Desulfovibrio gigas ferredoxin II: redox structural modulation of the [3Fe–4S] cluster

Desulfovibrio gigas ferredoxin II (DgFdII) is a small protein with a polypeptide chain composed of 58 amino acids, containing one Fe₃S₄ cluster per monomer. Upon studying the redox cycle of this protein, we detected a stable intermediate (FdII_int) with four ¹H resonances at 24.1, 20.5, 20.8 and 13.7 ppm. The differences between FdII_ox and FdII_int were attributed to conformational changes resulting from the breaking/formation of an internal disulfide bridge. The same ¹H NMR methodology used to fully assign the three cysteinyl ligands of the [3Fe–4S] core in the oxidized state (DgFdII_ox) was used here for the assignment of the same three ligands in the intermediate state (DgFdII_int). The spin-coupling model used for the oxidized form of DgFdII where magnetic exchange coupling constants of around 300 cm⁻¹ and hyperfine coupling constants equal to 1 MHz for all the three iron centres were found, does not explain the isotropic shift temperature dependence for the three cysteinyl cluster ligands in DgFdII_int. This study, together with the spin delocalization mechanism proposed here for DgFdII_int, allows the detection of structural modifications at the [3Fe-4S] cluster in DgFdII_ox and DgFdII_int.     

Structural and spectroscopic studies of a model for catechol oxidase

A binuclear copper complex, [Cu₂(BPMP)(OAc)₂][ClO₄]·H₂O, has been prepared using the binucleating ligand 2,6-bis[bis(pyridin-2-ylmethylamino)methyl]-4-methylphenol (H-BPMP). The X-ray crystal structure reveals the copper centers to have a five-coordinate square pyramidal geometry, with the acetate ligands bound terminally. The bridging phenolate occupies the apical position of the square-based pyramids and magnetic susceptibility, electron paramagnetic resonance (EPR) and variable-temperature variable-field magnetic circular dichroism (MCD) measurements indicate that the two centers are very weakly antiferromagnetically coupled (J = −0.6 cm⁻¹). Simulation of the dipole–dipole-coupled EPR spectrum showed that in solution the Cu–O–Cu angle was increased from 126° to 160° and that the internuclear distance was larger than that observed crystallographically. The high-resolution spectroscopic information obtained has been correlated with a detailed ligand-field analysis to gain insight into the electronic structure of the complex. Symmetry arguments have been used to demonstrate that the sign of the MCD is characteristic of the tetragonally elongated environment. The complex also displays catecholase activity (k _cat = 15 ± 1.5 min⁻¹, K _M = 6.4 ± 1.8 mM), which is compared with other dicopper catechol oxidase models. Electronic supplementary material The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

Structural and functional reconstruction in situ of the [CuSMoO2] active site of carbon monoxide dehydrogenase from the carbon monoxide oxidizing eubacterium Oligotropha carboxidovorans

Carbon monoxide dehydrogenase from the bacterium Oligotropha carboxidovorans catalyzes the oxidation of CO to CO₂ at a unique [CuSMoO₂] cluster. In the bacteria the cluster is assembled post-translational. The integration of S, and particularly of Cu, is rate limiting in vivo, which leads to CO dehydrogenase preparations containing the mature and fully functional enzyme along with forms of the enzyme deficient in one or both of these elements. The active sites of mature and immature forms of CO dehydrogenase were converted into a [MoO₃] centre by treatment with potassium cyanide. We have established a method, which rescues 50% of the CO dehydrogenase activity by in vitro reconstitution of the active site through the supply of sulphide first and subsequently of Cu(I) under reducing conditions. Immature forms of CO dehydrogenase isolated from the bacterium, which were deficient in S and/or Cu at the active site, were similarly activated. X-ray crystallography and electron paramagnetic resonance spectroscopy indicated that the [CuSMoO₂] cluster was properly reconstructed. However, reconstituted CO dehydrogenase contains mature along with immature forms. The chemical reactions of the reconstitution of CO dehydrogenase are summarized in a model, which assumes resulphuration of the Mo-ion at both equatorial positions at a 1:1 molar ratio. One equatorial Mo–S group reacts with Cu(I) in a productive fashion yielding a mature, functional [CuSMoO₂] cluster. The other Mo–S group reacts with Cu(I), then Cu₂S is released and an oxo group is introduced from water, yielding an inactive [MoO₃] centre.     

Direct assessment of water exchange on a Gd(III) chelate bound to a protein

 The Gd(III) complex of 4-pentylbicyclo[2.2.2]octane-1-carboxyl-di-l-aspartyl-lysine-derived DTPA, [GdL(H₂O)]^2–, binds to serum albumin in vivo, through hydrophobic interaction. A variable temperature ¹⁷O NMR, EPR, and Nuclear Magnetic Relaxation Dispersion (NMRD) study resulted in a water exchange rate of k ²⁹⁸ _ex=4.2×10⁶ s^–1, and let us conclude that the GdL complex is identical to [Gd(DTPA)(H₂O)]^2– in respect to water exchange and electronic relaxation. The effect of albumin binding on the water exchange rate has been directly evaluated by ¹⁷O NMR. Contrary to expectations, the water exchange rate on GdL does not decrease considerably when bound to bovine serum albumin (BSA); the lowest limit can be given as k _{ex, GdL-BSA}=k _ex, GdL / 2. In the knowledge of the water exchange rate for the BSA-bound GdL complex, the analysis of its NMRD profile at 35  °C yielded a rotational correlation time of 1.0 ns, one order of magnitude shorter than that of the whole protein. This value is supported by the longitudinal ¹⁷O relaxation rates. This indicates a remarkable internal flexibility, probably due to the relatively large distance between the protein- and metal-binding moieties of the ligand. Received: 25 June 1998 / Accepted: 11 August 1998     

On the prosthetic groups of the NiFe sulfhydrogenase from Pyrococcus furiosus: topology, structure, and temperature-dependent redox chemistry

 The sulfhydrogenase complex of Pyrococcus furiosus is an αβγδ heterotetramer with both hydrogenase activity (borne by the αδ subunits) and sulfur reductase activity (carried by the βγ subunits). The β-subunit contains at least two [4Fe-4S] cubanes and the γ-subunit contains one [2Fe-2S] cluster and one FAD molecule. The δ-subunit contains three [4Fe-4S] cubanes and the α-subunit carries the NiFe dinuclear center. Only three Fe/S signals are observed in EPR-monitored reduction by dithionite, NADPH, or internal substrate upon heating. All other clusters presumably have reduction potentials well below that of the H⁺/H₂ couple. Heat-induced reduction by internal substrate allows, for the first time, EPR monitoring of the NiFe center in a hyperthermophilic hydrogenase, which passes through a number of states, some of which are similar to states previously defined for mesophilic hydrogenases. The complexity of the observed transitions reflects a combination of temperature-dependent activation and temperature-dependent reduction potentials. Received: 10 December 1998 / Accepted: 16 February 1999