Electrochemical study of the redox properties of [2Fe-2S] ferredoxins. Evidence for superreduction of the Rieske [2Fe-2S] cluster

Resonance Raman spectroscopy of Fe-S proteins and their redox properties

Resonance Raman spectra of Fe-S proteins are sensitive to the cluster type, structure and symmetry. Furthermore, bands that originate from bridging and terminal Fe-S vibrations in the 2Fe-2S, 3Fe-4S and 4Fe-4S clusters can be sensitively distinguished in the spectra, as well as the type of non-cysteinyl coordinating ligands, if present. For these reasons, resonance Raman spectroscopy has been playing an exceptionally active role in the studies of Fe-S proteins of diverse structures and functions. We provide here a concise overview of the structural information that can be obtained from resonance Raman spectroscopy on Fe-S clusters, and in parallel, refer to their thermodynamic properties (e.g., reduction potential), which together define the physiological roles of Fe-S proteins. We demonstrate how the knowledge gained over the past several decades on simple clusters nowadays enables studies of complex structures that include Fe-S clusters coupled to other centers and transient processes that involve cluster inter-conversion, biogenesis, disassembly and catalysis.

Oxidized and reduced [2Fe-2S] clusters from an iron(I) synthon

Synthetic [2Fe-2S] clusters are often used to elucidate ligand effects on the reduction potentials and spectroscopy of natural electron-transfer sites, which can have anionic Cys ligands or neutral His ligands. Current synthetic routes to [2Fe-2S] clusters are limited in their feasibility with a range of supporting ligands. Here, we report a new synthetic route to synthetic [2Fe-2S] clusters, through oxidation of an iron(I) source with elemental sulfur. This method yields a neutral diketiminate-supported [2Fe-2S] cluster in the diiron(III)-oxidized form. The oxidized [2Fe-2S] cluster can be reduced to a mixed valent iron(II)-iron(III) compound. Both the diferric and reduced mixed valent clusters are characterized using X-ray crystallography, Mössbauer spectroscopy, EPR spectroscopy and cyclic voltammetry. The reduced compound is particularly interesting because its X-ray crystal structure shows a difference in Fe-S bond lengths to one of the iron atoms, consistent with valence localization. The valence localization is also evident from Mössbauer spectroscopy.

Aqueous Fe2S2 cluster: structure, magnetic coupling, and hydration behaviour from Hubbard U density functional theory

We present a DFT + U investigation of the all-ferrous Fe2S2 cluster in aqueous solution. We determine the value of U by tuning the geometry of the cluster in the gas-phase to that obtained by the highly accurate CCSD(T) method. When the optimised value of U is employed for the aqueous Fe2S2 cluster (Fe2S2(aq)), the resulting geometry agrees well with the X-ray diffraction structure, while the magnetic coupling is in line with the estimate from Mössbauer data. Molecular dynamics trajectories predict Fe2S2(aq) to be stable in water, regardless of the introduction of U. However, significant differences arise in the geometry, hydration, and exchange constant of the solvated clusters.

Thermodynamic constraints shape the structure of carbon fixation pathways

Thermodynamics impose a major constraint on the structure of metabolic pathways. Here, we use carbon fixation pathways to demonstrate how thermodynamics shape the structure of pathways and determine the cellular resources they consume. We analyze the energetic profile of prototypical reactions and show that each reaction type displays a characteristic change in Gibbs energy. Specifically, although carbon fixation pathways display a considerable structural variability, they are all energetically constrained by two types of reactions: carboxylation and carboxyl reduction. In fact, all adenosine triphosphate (ATP) molecules consumed by carbon fixation pathways - with a single exception - are used, directly or indirectly, to power one of these unfavorable reactions. When an indirect coupling is employed, the energy released by ATP hydrolysis is used to establish another chemical bond with high energy of hydrolysis, e.g. a thioester. This bond is cleaved by a downstream enzyme to energize an unfavorable reaction. Notably, many pathways exhibit reduced ATP requirement as they couple unfavorable carboxylation or carboxyl reduction reactions to exergonic reactions other than ATP hydrolysis. In the most extreme example, the reductive acetyl coenzyme A (acetyl-CoA) pathway bypasses almost all ATP-consuming reactions. On the other hand, the reductive pentose phosphate pathway appears to be the least ATP-efficient because it is the only carbon fixation pathway that invests ATP in metabolic aims other than carboxylation and carboxyl reduction. Altogether, our analysis indicates that basic thermodynamic considerations accurately predict the resource investment required to support a metabolic pathway and further identifies biochemical mechanisms that can decrease this requirement.

Iron-based redox centres of reductase and oxygenase components of phenol hydroxylase from A. radioresistens: a redox chain working at highly positive redox potentials

This is the first report of the direct electrochemistry of the reductase (PHR) and oxygenase (PHO) components of phenol hydroxylase from Acinetobacter radioresistens S13 studied by cyclic and differential pulse voltammetry. The PHR contains one 2Fe2S cluster and one FAD that mediate the transfer of electrons from NAD(P)H to the non-heme diiron cluster of PHO. Cyclic and differential pulse voltammetry (CV and DPV) on glassy carbon showed two redox pairs with midpoint potentials at +131.5 ± 13 mV and -234 ± 3 mV versus normal hydrogen electrode (NHE). The first redox couple is attributed to the FeS centre, while the second one corresponds to free FAD released by the protein. DPV scans on native and guanidinium chloride treated PHR highlighted the presence of a split signal (ΔE ≈ 100 mV) attributed to heterogeneous properties of the 2Fe2S cluster interacting with the electrode, possibly due to the presence of two protein conformers and consistently with the large peak-to-peak separation and the peak broadening observed in CV. DPV experiments on gold electrodes performed on PHO confirm a consistently higher reduction potential at +396 mV vs. NHE. The positive redox potentials measured by direct electrochemistry for the FeS cluster in PHR and for the non-heme diiron cluster of PHO show that the entire phenol hydroxylase system works at higher potentials than those reported for structurally similar enzymes, for example methane monooxygenases.

Formation and characterization of an all-ferrous Rieske cluster and stabilization of the [2Fe-2S]0 core by protonation

The all-ferrous Rieske cluster, [2Fe-2S](0), has been produced in solution and characterized by protein-film voltammetry and UV-visible, EPR, and Mössbauer spectroscopies. The [2Fe-2S](0) cluster, in the overexpressed soluble domain of the Rieske protein from the bovine cytochrome bc(1) complex, is formed at -0.73 V at pH 7. Therefore, at pH 7, the [2Fe-2S](1+/0) couple is 1.0 V below the [2Fe-2S](2+/1+) couple. The two cluster-bound ferrous irons are both high spin (S = 2), and they are coupled antiferromagnetically (-J > or = 30 cm(-1), H =-2JS1.S2) to give a diamagnetic (S = 0) ground state. The ability of the Rieske cluster to exist in three oxidation states (2+, 1+, and 0) without an accompanying coupled reaction, such as a conformational change or protonation, is highly unusual. However, uncoupled reduction to the [2Fe-2S](0) state occurs at pH > 9.8 only, and at high pH the intact cluster persists in solution for <1 min. At pH < 9.8, the all-ferrous cluster is stabilized significantly by protonation. A combination of experimental data and calculations based on density functional theory suggests strongly that the proton binds to one of the cluster mu(2)-sulfides, consistent with observations that reduced [3Fe-4S] clusters are protonated also. The implications for our understanding of coupled reactions at iron-sulfur clusters and of the factors that determine the relative stabilities of their different oxidation states are discussed.

On the iron-sulfur clusters in the complex redox enzyme dihydropyrimidine dehydrogenase

Porcine liver dihydropyrimidine dehydrogenase is a homodimeric iron-sulfur flavoenzyme that catalyses the first and rate-limiting step of pyrimidine catabolism. The enzyme subunit contains 16 atoms each of nonheme iron and acid-labile sulfur, which are most likely arranged into four [4Fe-4S] clusters. However, the presence and role of such Fe-S clusters in dihydropyrimidine dehydrogenase is enigmatic, because they all appeared to be redox-inactive during absorbance-monitored titrations of the enzyme with its physiological substrates. In order to obtain evidence for the presence and properties of the postulated four [4Fe-4S] clusters of dihydropyrimidine dehydrogenase, a series of EPR-monitored redox titrations of the enzyme under a variety of conditions was carried out. No EPR-active species was present in the enzyme 'as isolated'. In full agreement with absorbance-monitored experiments, only a small amount of neutral flavin radical was detected when the enzyme was incubated with excess NADPH or dihydrouracil under anaerobic conditions. Reductive titrations of dihydropyrimidine dehydrogenase with dithionite at pH 9.5 and photochemical reduction at pH 7.5 and 9.5 in the presence of deazaflavin and EDTA led to the conclusion that the enzyme contains two [4Fe-4S]2+,1+ clusters, which both exhibit a midpoint potential of approximately -0.44 V (pH 9.5). The two clusters are most likely close in space, as demonstrated by the EPR signals which are consistent with dipolar interaction of two S = 1/2 species including a half-field signal around g approximately 3.9. Under no circumstances could the other two postulated Fe-S centres be detected by EPR spectroscopy. It is concluded that dihydropyrimidine dehydrogenase contains two [4Fe-4S] clusters, presumably determined by the C-terminal eight-iron ferredoxin-like module of the protein, whose participation in the enzyme-catalysed redox reaction is unlikely in light of the low midpoint potential measured. The presence of two additional [4Fe-4S] clusters in dihydropyrimidine dehydrogenase is proposed based on thorough chemical analyses on various batches of the enzyme and sequence analyses. The N-terminal region of dihydropyrimidine dehydrogenase is similar to the glutamate synthase beta subunit, which has been proposed to contain most, if not all, the cysteinyl ligands that participate in the formation of the [4Fe-4S] clusters of the glutamate synthase holoenzyme. It is proposed that the motif formed by the Cys residues at the N-terminus of the glutamate synthase beta subunit, which are conserved in dihydropyrimidine dehydrogenase and in several beta-subunit-like proteins or protein domains, corresponds to a novel fingerprint that allows the formation of [4Fe-4S] clusters of low to very low midpoint potential.

A second [2Fe-2S] ferredoxin from Sphingomonas sp. Strain RW1 can function as an electron donor for the dioxin dioxygenase

The first step in the degradation of dibenzofuran and dibenzo-p-dioxin by Sphingomonas sp. strain RW1 is carried out by dioxin dioxygenase (DxnA1A2), a ring-dihydroxylating enzyme. An open reading frame (fdx3) that could potentially specify a new ferredoxin has been identified downstream of dxnA1A2, a two-cistron gene (J. Armengaud, B. Happe, and K. N. Timmis, J. Bacteriol. 180:3954-3966, 1998). In the present study, we report a biochemical analysis of Fdx3 produced in Escherichia coli. This third ferredoxin thus far identified in Sphingomonas sp. strain RW1 contained a putidaredoxin-type [2Fe-2S] cluster which was characterized by UV-visible absorption spectrophotometry and electron paramagnetic resonance spectroscopy. The midpoint redox potential of this ferredoxin (E'(0) = -247 +/- 10 mV versus normal hydrogen electrode at pH 8.0) is similar to that exhibited by Fdx1 (-245 mV), a homologous ferredoxin previously characterized in Sphingomonas sp. strain RW1. In in vitro assays, Fdx3 can be reduced by RedA2 (a reductase similar to class I cytochrome P-450 reductases), previously isolated from Sphingomonas sp. strain RW1. RedA2 exhibits a K(m) value of 3.2 +/- 0.3 microM for Fdx3. In vivo coexpression of fdx3 and redA2 with dxnA1A2 confirmed that Fdx3 can serve as an electron donor for the dioxin dioxygenase.

Formation, Properties, and Characterization of a Fully Reduced Fe(II)Fe(II) Form of Spinach (and Parsley) [2Fe-2S] Ferredoxin with the Macrocyclic Complex [Cr(15-aneN(4))(H(2)O)(2)](2+) as Reductant

Reduction of spinach and parsley ferredoxin FdI in the Fe(III)Fe(III) state with the 1,4,8,12-tetraazacyclopentadecane complex [Cr(15-aneN(4))(H(2)O)(2)](2+), here written as Cr(II)L, provides the first evidence for two 1-equiv steps yielding an Fe(II)Fe(II) product. Rate constants (25 degrees C) for spinach FdI are 2760 and 660 M(-)(1) s(-)(1), respectively, at pH 7.5, I = 0.100 M (NaCl). An important observation is that the Cr(III)L generated in the first step remains attached to the Fe(II)Fe(III) product and perturbs the protein active site sufficiently to make the second stage possible. The second Cr(II)L reduction is of the "outer-sphere" type, and the Cr(III)L generated is not attached to the protein. Anaerobic reoxidation of the fully reduced protein with [Co(NH(3))(6)](3+) is rapid and can be achieved with approximately 80% recovery of the Fe(III)Fe(III) oxidation state over 40 min. Air oxidation yields the Cr(III)L product Fe(III)Fe(III).Cr(III)L (Fe:Cr = 2:1). With Anabaena variabilis only a one-step reduction is observed and there is no Cr(III)L attachment. From a comparison of amino acid sequences with spinach (and parsley) FdI, a likely point of Cr(III)L attachment is indicated. Comparisons are made with dithionite as reductant. In addition, square-wave voltammetry on spinach Fe(III)Fe(III).Cr(III)L gives two reduction potentials -273 and -410 mV vs NHE. The different redox products have been characterized by EPR. Using (1)H NMR line-broadening techniques, evidence for Cr(III)L binding at a surface site close to Tyr-25/Tyr-82 is obtained. Also from investigations with redox-inactive [Cr(en)(3)](3+) as a competitive inhibitor for Cr(II)L reduction of spinach Fe(III)Fe(III), Tyr-25/Tyr-82 is proposed as the site for Cr(II)L reduction. From an extension of studies to include reduction of Fe(III)Fe(III).Cr(III)L with Cr(II)L, evidence is obtained for a second reaction site when that at Tyr-25/Tyr-82 is no longer available.

Reversible super-reduction of the cubane [4Fe-4S](3+;2+;1+) in the high-potential iron-sulfur protein under non-denaturing conditions. EPR spectroscopic and electrochemical studies

The reversible 2 x 1 e- reduction of the cubane cluster from oxidized to reduced to super-reduced states ([4Fe-4S]3+<-->[4Fe-4S]2+<-->[4Fe-4S]1+) was studied in high-potential iron-sulfur proteins (HiPIPs). Super-reduction to the 1+ state was not observed in any of the seven HiPIPs tested during cyclic voltammetry (down to -0.95 V). However, equilibration at low potential (pH 7.5) of Rhodopila globiformis HiPIP yields a transient peak around -0.47 V due to the oxidation of super-reduced HiPIP adsorbed at the electrode. The peak area depends on the equilibration potential according to a one-electron Nernst curve with a half-wave potential at -0.91 V. Reduction of R. globiformis HiPIP with titanium (III)citrate at pH 9.5 is very slow [pseudo-first-order half-life of 23 min with a 100-fold excess Ti(III)] but is reversible, and the EPR spectrum with g values of 2.04 and 1.92 is similar to that of reduced [4Fe-4S]1+ ferredoxins. Chemical or electrochemical reoxidation of the super-reduced form resulted in an EPR spectrum with g parallel = 2.12 and g perpendicular = 2.03, i.e. identical to that of oxidized HiPIP. From the equilibrium concentration of super-reduced HiPIP at a low concentration of Ti(III), a reduction potential of -0.64 V can be estimated. Super-reduction of the large HiPIP (iso-2) from Rhodospirillum salinarum is also possible with Ti(III)(gz = 2.05) but the super-reduced state is unstable. No super-reduction with Ti(III) was observed for the other HiPIPs. The difference between the electrochemically observed reduction potential and oxidation potential is explained by a fast and reversible conformational change upon super-reduction. The rate of super-reduction with Ti(III) is limited by the small amount (0.1%) of HiPIP in the 2+ state with the super-reduced conformation.

Direct electrochemistry and EPR spectroscopy of spinach ferredoxin mutants with modified electron transfer properties

Mutations of the conserved residue Glu-92 to lysine, glutamine, and alanine have been performed in the recombinant ferredoxin I of spinach leaves. The purified ferredoxin mutants were found twice as active with respect to wild-type protein in the NADPH-cytochrome c reductase reaction catalyzed by ferredoxin-NADP+ reductase in the presence of ferredoxin. Cyclic voltammetry and EPR measurements showed that the mutations cause a change in the [2Fe-2S] cluster geometry, whose redox potential becomes approximately 80 mV less negative. These data point to a role of the Glu-92 side-chain in determining the low redox potential typical of the [2Fe-2S] cluster of chloroplast and cyanobacterial ferredoxins. Also a ferredoxin/ferredoxin-NADP+ reductase chimeric protein obtained by gene fusion was overproduced in Escherichia coli and purified. Fusion of the ferredoxin with its reductase causes only minor effects to the iron-sulfur cluster, as judged by cyclic voltammetry and EPR measurements.