EPR, electron spin echo envelope modulation, and electron nuclear double resonance studies of the 2Fe2S centers of the 2-halobenzoate 1,2-dioxygenase from Burkholderia (Pseudomonas) cepacia 2CBS

Probing the coordination and function of Fe4S4 modules in nitrogenase assembly protein NifB

NifB is an essential radical S-adenosylmethionine (SAM) enzyme for nitrogenase cofactor assembly. Previous studies show that NifB couples a putative pair of [Fe₄S₄] modules (designated K1 and K2) into an [Fe₈S₉C] cofactor precursor concomitant with radical SAM-dependent carbide insertion through the action of its SAM-binding [Fe₄S₄] module. However, the coordination and function of the NifB cluster modules remain unknown. Here, we use continuous wave and pulse electron paramagnetic resonance spectroscopy to show that K1- and K2-modules are 3-cysteine-coordinated [Fe₄S₄] clusters, with a histidine-derived nitrogen serving as the fourth ligand to K1 that is lost upon K1/K2-coupling. Further, we demonstrate that coexistence of SAM/K2-modules is a prerequisite for methyltransfer to K2 and hydrogen abstraction from the K2-associated methyl by a 5′-deoxyadenosyl radical. These results establish an important framework for mechanistic explorations of NifB while highlighting the utility of a synthetic-cluster-based reconstitution approach employed herein in functional analyses of iron–sulfur (FeS) enzymes.

NifB is a key enzyme in the biosynthesis pathway of the nitrogenase FeMo cofactor. Here, the authors investigate the maturation of its iron-sulfur clusters by EPR and biochemical analyses, showing how individual precursor clusters participate in the formation of the final iron-sulfur cluster.

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.

Binding of histidine in the (Cys)3(His)1-coordinated [2Fe-2S] cluster of human mitoNEET

Human mitoNEET is a homodimeric iron-sulfur protein located in the outer mitochondrial membrane with unknown function, but which is known to interact with thiazolidinedione diabetes drugs. Each monomer houses a [2Fe-2S] cluster with an unusual (Cys)(3)(His)(1) ligation. The His ligand is important for enabling cluster release and for tuning the redox potential. We use multifrequency (X-, Ka-, and Q-band) and multitechnique (continuous-wave, electron spin-echo envelope modulation (ESEEM), pulsed electron-nuclear double resonance (ENDOR), and hyperfine sublevel correlation (HYSCORE)) electron paramagnetic resonance spectroscopy to investigate the cluster in its paramagnetic reduced [Fe(2+)Fe(3+)] (S = 1/2) state. It has a rhombic g tensor (2.007, 1.937, 1.897) with an average g value of 1.947 that falls between those of Rieske-type and ferredoxin-type [2Fe-2S] clusters. Simulation and least-squares fitting of orientation-selective Ka- and Q-band ENDOR, 1D ESEEM, and HYSCORE spectra of (14)N and (15)N-labeled mitoNEET yield the principal values and orientations of both the hyperfine tensor ((14)N, A(iso) = -6.25 MHz, T = -0.94 MHz) and the quadrupolar tensor (e(2)Qq/h = -2.47 MHz, eta = 0.38) of the ligating histidine nitrogen N(delta). From these, we can infer the absolute g tensor orientation with respect to the cluster: The g(2) axis is close to perpendicular to the [2Fe-2S] plane, and g(1) and g(3) are in-plane, but skewed from the Fe-Fe and S-S axes. In X-band ENDOR and ESEEM spectra, a weakly coupled nitrogen is visible, most likely the N(epsilon) of the histidine in the protonated state. We find that the cluster is in a valence-localized state, where Fe(2+) is His-bound. The field-sweep spectra show evidence of intercluster dipolar coupling that can be simulated using an uncoupled spin model for each cluster (S(Fe(2+)) = 2, S(Fe(3+)) = 5/2). The parameters determined in this work can function as reporters on how the cluster structure is altered upon pH changes and drug binding.

Cluster N1 of complex I from Yarrowia lipolytica studied by pulsed EPR spectroscopy

After reduction with nicotinamide adenine dinucleotide (NADH), NADH:ubiquinone oxidoreductase (complex I) of the strictly aerobic yeast Yarrowia lipolytica shows clear signals from five different paramagnetic iron-sulfur (FeS) clusters (N1-N5) which can be detected using electron paramagnetic resonance (EPR) spectroscopy. The ligand environment and the assignment of several FeS clusters to specific binding motifs found in several subunits of the complex are still under debate. In order to characterize the hyperfine interaction of the surrounding nuclei with FeS cluster N1, one- and two-dimensional electron spin echo envelope modulation experiments were performed at a temperature of 30 K. At this temperature only cluster N1 contributes to the overall signal in a pulsed EPR experiment. The hyperfine and quadrupole tensors of a nitrogen nucleus and the isotropic and dipolar hyperfine couplings of two sets of protons could be determined by numerical simulation of the one- and two-dimensional spectra. The values obtained are in perfect agreement with a ferredoxin-like binding structure by four cysteine amino acid residues and allow the assignment of the nitrogen couplings to a backbone nitrogen nucleus and the proton couplings to the beta-protons of the bound cysteine residues.

Reconstitution and Characterization of Aminopyrrolnitrin Oxygenase, a Rieske N-Oxygenase That Catalyzes Unusual Arylamine Oxidation

Rieske oxygenases catalyze a wide variety of important oxidation reactions. Here we report the characterization of a novel Rieske N-oxygenase, aminopyrrolnitrin oxygenase (PrnD) that catalyzes the unusual oxidation of an arylamine to an arylnitro group. PrnD from Pseudomonas fluorescens Pf5 was functionally expressed in Escherichia coli, and the activity of the purified PrnD was reconstituted, which required in vitro assembly of the Rieske iron-sulfur cluster into the protein and the presence of NADPH, FMN, and an E. coli flavin reductase SsuE. Biochemical and bioinformatics studies indicated that the reconstituted PrnD contains a Rieske iron-sulfur cluster and a mononuclear iron center that are formed by residues Cys(69), Cys(88), His(71), His(91), Asp(323), His(186), and His(191), respectively. The enzyme showed a limited range of substrate specificity and catalyzed the conversion of aminopyrrolnitrin into pyrrolnitrin with K(m) = 191 microM and k(cat) = 6.8 min(-1). Isotope labeling experiments with (18)O(2) and H(2)(18)O suggested that the oxygen atoms in the pyrrolnitrin product are derived exclusively from molecular oxygen. In addition, it was found that the oxygenation of the arylamine substrates catalyzed by PrnD occurs at the enzyme active site and does not involve free radical chain reactions. By analogy to known examples of arylamine oxidation, a catalytic mechanism for the bioconversion of amino pyrrolnitrin into pyrrolnitrin was proposed. Our results should facilitate further mechanistic and crystallographic studies of this arylamine oxygenase and may provide a new enzymatic route for the synthesis of aromatic nitro compounds from their corresponding aromatic amines.

NO binding and dynamics in reduced heme-copper oxidases aa3 from Paracoccus denitrificans and ba3 from Thermus thermophilus

Cytochrome c oxidase (CcO) has a high affinity for nitric oxide (NO), a property involved in the regulation of respiration. It has been shown that the recombination kinetics of photolyzed NO with reduced CcO from Paracoccus denitrificans on the picosecond time scale depend strongly on the NO/enzyme stoichiometry and inferred that more than one NO can be accommodated by the active site, already at mildly suprastoichiometric NO concentrations. We have largely extended these studies by monitoring rebinding dynamics from the picosecond to the microsecond time scale, by performing parallel steady-state low-temperature electron paramagnetic resonance (EPR) characterizations on samples prepared similarly as for the optical experiments and comparing them with molecular-modeling results. A comparative study was performed on CcO ba(3) from Thermus thermophilus, where two NO molecules cannot be copresent in the active site in the steady state because of its NO reductase activity. The kinetic results allow discrimination between different models of NO-dependent recombination and show that the overall NO escape probability out of the protein is high when only one NO is bound to CcO aa(3), whereas strong rebinding on the 15-ns time scale was observed for CcO ba(3). The EPR characterizations show similar results for aa(3) at substoichiometric NO/enzyme ratios and for ba(3), indicating formation of a 6-coordinate heme-NO complex. The presence of a second NO molecule in the aa(3) active site strongly modifies the heme-NO EPR spectrum and can be rationalized by a rotation of the Fe-N-O plane with respect to the histidine that coordinates the heme iron. This proposal is supported by molecular-modeling studies that indicate a approximately 63 degrees rotation of heme-bound NO upon binding of a second NO to the close-lying copper center CuB. It is argued that the second NO binds to CuB.

Relaxation filtered hyperfine (REFINE) spectroscopy: a novel tool for studying overlapping biological electron paramagnetic resonance signals applied to mitochondrial complex I

A simple strategy to separate overlapping electron paramagnetic resonance (EPR) signals in biological systems is presented. Pulsed EPR methods (inversion- and saturation-recovery) allow the determination of the T(1) spin-lattice relaxation times of paramagnetic centers. T(1) may vary by several orders of magnitude depending on the species under investigation. These variations can be employed to study selectively individual species from a spectrum that results from an overlap of two species using an inversion-recovery filtered (IRf) pulsed EPR technique. The feasibility of such an IRf field-swept technique is demonstrated on model compounds (alpha,gamma-bisphenylene-beta-phenylallyl-benzolate, BDPA, and 2,2,6,6-tetramethyl-piperidine-1-oxyl, TEMPO) and a simple strategy for the successful analysis of such mixtures is presented. Complex I is a multisubunit membrane protein of the respiratory chain containing several iron-sulfur (FeS) centers, which are observable with EPR spectroscopy. It is not possible to investigate the functionally important FeS cluster N2 separately because this EPR signal always overlaps with the other FeS signals. This cluster can be studied selectively using the IRf field-swept technique and its EPR spectrum is in excellent agreement with previous cw-EPR data from the literature. In addition, the possibility to separate the hyperfine spectra of two spectrally overlapping paramagnetic species is demonstrated by applying this relaxation filter together with hyperfine spectroscopy (REFINE). For the first time, the application of this filter to a three-pulse electron spin-echo envelope modulation (ESEEM) pulse sequence is demonstrated to selectively observe hyperfine spectra on a system containing two paramagnetic species. Finally, REFINE is used to assign the observed nitrogen modulation in complex I to an individual iron-sulfur cluster.

Apparent redundancy of electron transfer pathways via bc(1) complexes and terminal oxidases in the extremophilic chemolithoautotrophic Acidithiobacillus ferrooxidans

Acidithiobacillus ferrooxidans is an acidophilic chemolithoautotrophic bacterium that can grow in the presence of either the weak reductant Fe(2+), or reducing sulfur compounds that provide more energy for growth than Fe(2+). We have previously shown that the uphill electron transfer pathway between Fe(2+) and NAD(+) involved a bc(1) complex that functions only in the reverse direction [J. Bacteriol. 182, (2000) 3602]. In the present work, we demonstrate both the existence of a bc(1) complex functioning in the forward direction, expressed when the cells are grown on sulfur, and the presence of two terminal oxidases, a bd and a ba(3) type oxidase expressed more in sulfur than in iron-grown cells, besides the cytochrome aa(3) that was found to be expressed only in iron-grown cells. Sulfur-grown cells exhibit a branching point for electron flow at the level of the quinol pool leading on the one hand to a bd type oxidase, and on the other hand to a bc(1)-->ba(3) pathway. We have also demonstrated the presence in the genome of transcriptionally active genes potentially encoding the subunits of a bo(3) type oxidase. A scheme for the electron transfer chains has been established that shows the existence of multiple respiratory routes to a single electron acceptor O(2). Possible reasons for these apparently redundant pathways are discussed.

Histidine ligand protonation and redox potential in the rieske dioxygenases: role of a conserved aspartate in anthranilate 1,2-dioxygenase

The Rieske dioxygenase, anthranilate 1,2-dioxygenase, catalyzes the 1,2-dihydroxylation of anthranilate (2-aminobenzoate). As in all characterized Rieske dioxygenases, the catalytic conversion to the diol occurs within the dioxygenase component, AntAB, at a mononuclear iron site which accepts electrons from a proximal Rieske [2Fe-2S] center. In the related naphthalene dioxygenase (NDO), a conserved aspartate residue lies between the mononuclear and Rieske iron centers, and is hydrogen-bonded to a histidine ligand of the Rieske center. Engineered substitutions of this aspartate residue led to complete inactivation, which was proposed to arise from elimination of a productive intersite electron transfer pathway [Parales, R. E., Parales, J. V., and Gibson, D. T. (1999) J. Bacteriol. 181, 1831-1837]. Substitutions of the corresponding aspartate, D218, in AntAB with alanine, asparagine, or glutamate also resulted in enzymes that were completely inactive over a wide pH range despite retention of the hexameric quaternary structure and iron center occupancy. The Rieske center reduction potential of this variant was measured to be approximately 100 mV more negative than that for the wild-type enzyme at neutral pH. The wild-type AntAB became completely inactive at pH 9 and exhibited an altered Rieske center absorption spectrum which resembled that of the D218 variants at neutral pH. These results support a role for this aspartate in maintaining the protonated state and reduction potential of the Rieske center. Both the wild-type and D218A variant AntABs exhibited substrate-dependent rapid phases of Rieske center oxidations in stopped-flow time courses. This observation does not support a role for this aspartate in a facile intersite electron transfer pathway or in productive substrate gating of the Rieske center reduction potential. However, since the single turnovers resulted in anthranilate dihydroxylation by the wild-type enzyme but not by the D218A variant, this aspartate must also play a crucial role in substrate dihydroxylation at or near the mononuclear iron site.

Redox-dependent structural changes in archaeal and bacterial Rieske-type [2Fe-2S] clusters

Proteins containing Rieske-type [2Fe-2S] clusters play important roles in many biological electron transfer reactions. Typically, [2Fe-2S] clusters are not directly involved in the catalytic transformation of substrate, but rather supply electrons to the active site. We report herein X-ray absorption spectroscopic (XAS) data that directly demonstrate an average increase in the iron-histidine bond length of at least 0.1 A upon reduction of two distantly related Rieske-type clusters in archaeal Rieske ferredoxin from Sulfolobus solfataricus strain P-1 and bacterial anthranilate dioxygenases from Acinetobacter sp. strain ADP1. This localized redox-dependent structural change may fine tune the protein-protein interaction (in the case of ARF) or the interdomain interaction (in AntDO) to facilitate rapid electron transfer between a lower potential Rieske-type cluster and its redox partners, thereby regulating overall oxygenase reactions in the cells.

A comprehensive phylogenetic analysis of Rieske and Rieske-type iron-sulfur proteins

The Rieske iron-sulfur center consists of a [2Fe-2S] cluster liganded to a protein via two histidine and two cysteine residues present in conserved sequences called Rieske motifs. Two protein families possessing Rieske centers have been defined. The Rieske proteins occur as subunits in the cytochrome bc1 and cytochrome b6f complexes of prokaryotes and eukaryotes or form components of archaeal electron transport systems. The Rieske-type proteins encompass a group of bacterial oxygenases and ferredoxins. Recent studies have uncovered several new proteins containing Rieske centers, including archaeal Rieske proteins, bacterial oxygenases, bacterial ferredoxins, and, intriguingly, eukaryotic Rieske oxygenases. Since all these proteins contain a Rieske motif, they probably form a superfamily with one common ancestor. Phylogenetic analyses have, however, been generally limited to similar sequences, providing little information about relationships within the whole group of these proteins. The aim of this work is, therefore, to construct a dendrogram including representatives from all Rieske and Rieske-type protein classes in order to gain insight into their evolutionary relationships and to further define the phylogenetic niches occupied by the recently discovered proteins mentioned above.

Redox components of cytochrome bc-type enzymes in acidophilic prokaryotes. II. The Rieske protein of phylogenetically distant acidophilic organisms

The Rieske proteins of two phylogenetically distant acidophilic organisms, i.e. the proteobacterium Thiobacillus ferrooxidans and the crenarchaeon Sulfolobus acidocaldarius, were studied by EPR. Redox titrations at a range of pH values showed that the Rieske centers of both organisms are characterized by redox midpoint potential-versus-pH curves featuring a common pK value of 6.2. This pK value is significantly more acidic (by almost 2 pH units) than that of Rieske proteins in neutrophilic species. The orientations of the Rieske center's g tensors with respect to the plane of the membrane were studied between pH 4 and 8 using partially ordered samples. At pH 4, the Sulfolobus Rieske cluster was found in the "typical" orientation of chemically reduced Rieske centers, whereas this orientation changed significantly on going toward high pH values. The Thiobacillus protein, by contrast, appeared to be in the "standard" orientation at both low and high pH values. The results are discussed with respect to the molecular parameters conveying acid resistance and in light of the recently demonstrated long-range conformational movement of the Rieske protein during enzyme turnover in cytochrome bc1 complexes.

Conserved nonliganding residues of the Rhodobacter capsulatus Rieske iron-sulfur protein of the bc1 complex are essential for protein structure, properties of the [2Fe-2S] cluster, and communication with the quinone pool

The iron-sulfur (Fe-S) protein subunit of the bc1 complex, known as the Rieske protein, contains a high-potential [2Fe-2S] cluster ligated by two nitrogen and two sulfur atoms to its apoprotein. Earlier work indicated that in Rhodobacter capsulatus these atoms are provided by two cysteine (C133 and C153) and two histidine (H135 and H156) residues, located at the carboxyl-terminal end of the protein [Davidson, E., Ohnishi, T., Atta-Asafo-Adjei, E., & Daldal, F. (1992) Biochemistry 31, 3342-3351]. These ligands are part of the conserved sequences C133THLGC138 (box I) and C153PCHGS158 (box II) and affect the properties of the Fe-S protein and its [2Fe-2S] cluster. In this work, the role of amino acid side chains at positions 134 and 136, adjacent to the cluster ligands in box I, was probed by using site-directed mutagenesis and biophysical analyses. These positions were substituted with R, D, H, and G to probe the effect of charged, polar, large, and small amino acid side chains on the properties of the [2Fe-2S] cluster. Of the mutants obtained T134R, -H, and -G were photosynthetically competent (Ps+) but contained Fe-S proteins with redox midpoint potentials (Em7) 50-100 mV lower than that of a wild type strain. In contrast, T134D was Ps- and contained no detectable [2Fe-2S] cluster, although it reverted frequently to Ps+ by substitution of D with N. On the other hand, all L136 mutants were Ps-, the EPR characteristics of their [2Fe-2S] cluster were perturbed, and they were unable to sense the Qpool redox state or to bind stigmatellin properly. The overall data indicated that replacement of the amino acid side chain at position 134 of the Fe-S protein affects mainly the Em7 and oxygen sensitivity of the [2Fe-2S] cluster without abolishing its function, while substitutions at position 136 perturb drastically its ability to monitor the Qpool redox state and its interaction with the Qo site inhibitor stigmatellin. These two distinct phenotypes of box I T134 and L136 mutants are discussed with regard to the recently published three-dimensional structure of the water soluble part of the bovine heart mitochondrial Rieske Fe-S protein.

Reconstitution of the 2Fe-2S center and g = 1.89 electron paramagnetic resonance signal into overproduced Nostoc sp. PCC 7906 Rieske protein

The Rieske 2Fe-2S protein is a distinguishing subunit of the photosynthetic electron transport cytochrome b6f complex in chloroplast and cyanobacterial thylakoid membranes. We have constructed plasmids for overproduction in Escherichia coli of fusion, full-length, and truncated forms of the Rieske (PetC) protein from the cyanobacterium Nostoc sp. PCC 7906. A glutathione S-transferase/Rieske fusion protein was used to prepare specific chicken egg-yolk antibodies against the Rieske protein. Expression of the nonfusion petC gene in a T7 RNA polymerase promoter vector produced copious quantities of the full-length Rieske protein predominantly as inclusion bodies. The highly enriched, Rieske protein from inclusion bodies has been denatured in guanidine hydrochloride and refolded and the characteristic 2Fe-2S cluster reconstituted in vitro by incubation with iron and sulfide under reducing conditions. Purification by chromatography on Whatman DE52 cellulose and ultrafiltration through a 30000 molecular weight cutoff membrane yielded pure and predominantly monomeric Rieske protein. Reconstituted Rieske preparations showed intense and highly characteristic gx = 1.74, gy = 1.89, and gz = 2.03 "Rieske-type" electron paramagnetic resonance signals at 15 K. Two methods of reconstitution yielded Rieske preparations in which 20-60% of the protein contained 2Fe-2S clusters as determined by EPR spin quantitation. The reconstituted Rieske protein was soluble and stable at 4 degrees C in buffers containing nonionic detergents and showed a redox midpoint potential of +321 mV at pH 7.0 as determined by optical circular dichroism (CD) spectroscopy. These data demonstrate the in vitro restoration of a Cys and His liganded 2Fe-2S cluster and provide the basis for mutational and structural analysis of a PetC Rieske protein of oxygenic photosynthesis.

Coordination of the [2Fe-2S] cluster in wild type and molecular variants of Clostridium pasteurianum ferredoxin, investigated by ESEEM spectroscopy

The [2Fe-2S] ferredoxin from Clostridium pasteurianum contains five cysteine residues in positions 11, 14, 24, 56, and 60. This pattern is unique, and a combination of site-directed mutagenesis and spectroscopy is therefore being implemented to identify the ligands of the [2Fe-2S] cluster. The possible involvement of ligands other than cysteine in some molecular variants of this ferredoxin has been considered, histidines being likely candidates. Therefore, the three histidine residues in positions 6, 7, and 90 of the amino acid sequence have been individually and collectively replaced by alanine or valine. The mutated ferredoxins have been purified and were all found to contain [2Fe-2S] clusters of which the UV-visible absorption spectra were identical to that of the wild-type protein. The H6A/H7A/ H90A triply mutated ferredoxin was further characterized by EPR and by ESEEM spectroscopy and was found to differ only marginally from the wild-type protein. The ESEEM spectra of wild-type ferredoxin displayed weak 14N hyperfine interactions at the three principal g-factors of the [2Fe-2S] center. The estimated 14N coupling constants (Aiso = 0.6 MHz; e2qQ approximately 3.3 MHz) indicate that the ESEEM effect is most likely due to 14N from the polypeptide backbone. 2H2O ESEEM spectra showed that the [2Fe-2S] cluster is accessible for exchange with solvent deuterons. ESEEM spectra of the previously characterized C24A and C14A/C24A variants have been recorded and were also found to be very similar to those of the wild-type protein. There was no evidence for coordination of the [2Fe-2S] cluster by [14N]histidine or other 14N nuclei, in either wild-type or mutant forms of the ferredoxin. By these criteria, the environment of the [2Fe-2S] center is not distinguishable from those in plant-type ferredoxins. Non-cysteinyl coordination most probably occurs only in the C14A/C24A variant, which contains no more than three cysteine residues. The data shown here indicate that the fourth ligand of the [2Fe-2S] cluster is neither a histidine residue nor another nitrogenous ligand. The possibility of oxygenic coordination for this molecular variant is discussed.