A spectroelectrochemical cell designed for low temperature electron paramagnetic resonance titration of oxygen-sensitive proteins

Prospects for electroactive and conducting framework materials

Electroactive and conducting framework materials, encompassing coordination polymers and metal-organic frameworks, have captured the imagination of the scientific community owing to their highly designable nanoporous structures and their potential applications in electrochromic devices, electrocatalysts, porous conductors, batteries and solar energy harvesting systems, among many others. While they are now considered integral members of the broader field of inorganic materials, it is timely to reflect upon their strengths and challenges compared with 'traditional' solid-state materials such as minerals, pigments and zeolites. Indeed, the latter have been known since ancient times and have been prized for centuries in fields as diverse as art, archaeology and industrial catalysis. This opinion piece considers a brief historical perspective of traditional electroactive and conducting inorganic materials, with a view towards very recent experimental progress and new directions for future progress in the burgeoning area of coordination polymers and metal-organic frameworks. Overall, this article bears testament to the rich history of electroactive solids and looks at the challenges inspiring a new generation of scientists. This article is part of the theme issue 'Mineralomimesis: natural and synthetic frameworks in science and technology'.

Production and properties of enzymes that activate and produce carbon monoxide

The chapter focuses on the methods involved in producing and characterizing two key nickel-iron-sulfur enzymes in the Wood-Ljungdahl pathway (WLP) of anaerobic conversion of carbon dioxide fixation into acetyl-CoA: carbon monoxide dehydrogenase (CODH) and acetyl-CoA synthase (ACS). The WLP is used for biosynthesis of cell material and energy conservation by anaerobic bacteria and archaea, and it is central to several industrial biotechnology processes aimed at using syngas and waste gases for the production of fuels and chemicals. The pathway can run in reverse to allow organisms, e. g., methanogens and sulfate reducers, to grow on acetate. The CODH and ACS intertwine to form a tenacious CODH/ACS complex that converts CO2, a methyl group, and coenzyme A into acetyl-CoA. CODH also behaves as a modular unit that can function as an independent homodimer. Besides coupling to ACS, CODH can interact with hydrogenases to couple CO oxidation to H2 formation. These enzymes have been purified and characterized from several microbes.

Sodium-dependent movement of covalently bound FMN residue(s) in Na(+)-translocating NADH:quinone oxidoreductase

Na(+)-translocating NADH:quinone oxidoreductase (Na(+)-NQR) is a component of respiratory electron-transport chain of various bacteria generating redox-driven transmembrane electrochemical Na(+) potential. We found that the change in Na(+) concentration in the reaction medium has no effect on the thermodynamic properties of prosthetic groups of Na(+)-NQR from Vibrio harveyi, as was revealed by the anaerobic equilibrium redox titration of the enzyme's EPR spectra. On the other hand, the change in Na(+) concentration strongly alters the EPR spectral properties of the radical pair formed by the two anionic semiquinones of FMN residues bound to the NqrB and NqrC subunits (FMN(NqrB) and FMN(NqrC)). Using data obtained by pulse X- and Q-band EPR as well as by pulse ENDOR and ELDOR spectroscopy, the interspin distance between FMN(NqrB) and FMN(NqrC) was found to be 15.3 Å in the absence and 20.4 Å in the presence of Na(+), respectively. Thus, the distance between the covalently bound FMN residues can vary by about 5 Å upon changes in Na(+) concentration. Using these results, we propose a scheme of the sodium potential generation by Na(+)-NQR based on the redox- and sodium-dependent conformational changes in the enzyme.

Evidence that ferredoxin interfaces with an internal redox shuttle in Acetyl-CoA synthase during reductive activation and catalysis

Acetyl-CoA synthase (ACS), a subunit of the bifunctional CO dehydrogenase/acetyl-CoA synthase (CODH/ACS) complex of Moorella thermoacetica requires reductive activation in order to catalyze acetyl-CoA synthesis and related partial reactions, including the CO/[1-(14)C]-acetyl-CoA exchange reaction. We show that the M. thermoacetica ferredoxin(II) (Fd-II), which harbors two [4Fe-4S] clusters and is an electron acceptor for CODH, serves as a redox activator of ACS. The level of activation depends on the oxidation states of both ACS and Fd-II, which strongly suggests that Fd-II acts as a reducing agent. By the use of controlled potential enzymology, the midpoint reduction potential for the catalytic one-electron redox-active species in the CO/acetyl-CoA exchange reaction is -511 mV, which is similar to the midpoint reduction potential that was earlier measured for other reactions involving ACS. Incubation of ACS with Fd-II and CO leads to the formation of the NiFeC species, which also supports the role of Fd-II as a reductant for ACS. In addition to being a reductant, Fd-II can accept electrons from acetylated ACS, as observed by the increased intensity of the EPR spectrum of reduced Fd-II, indicating that there is a stored electron within an "electron shuttle" in the acetyl-Ni(II) form of ACS. This "shuttle" is proposed to serve as a redox mediator during activation and at different steps of the ACS catalytic cycle.

Redox properties of the prosthetic groups of Na(+)-translocating nadh:quinone oxidoreductase. 1. Electron paramagnetic resonance study of the enzyme

Redox properties of all EPR-detectable prosthetic groups of Na(+)-translocating NADH:quinone oxidoreductase (Na(+)-NQR) from Vibrio harveyi were studied at pH 7.5 using cryo-EPR spectroelectrochemistry. Titration shows five redox transitions. One with E(m) = -275 mV belongs to the reduction of the [2Fe-2S] cluster, and the four others reflect redox transitions of flavin cofactors. Two transitions (E(m)(1) = -190 mV and E(m)(2) = -275 mV) originate from the formation of FMN anion radical, covalently bound to the NqrC subunit, and its subsequent reduction. The remaining two transitions arise from the two other flavin cofactors. A high potential (E(m) = -10 mV) transition corresponds to the reduction of riboflavin neutral radical, which is stable at rather high redox potentials. An E(m) = -130 mV transition reflects the formation of FMN anion radical from a flavin covalently bound to the NqrB subunit, which stays as a radical down to very low potentials. Taking into account the EPR-silent, two-electron transition of noncovalently bound FAD located in the NqrF subunit, there are four flavins in Na(+)-NQR all together. Defined by dipole-dipole magnetic interaction measurements, the interspin distance between the [2Fe-2S](+) cluster and the NqrB subunit-bound FMN anion radical is found to be 22.5 +/- 1.5 A, which means that for the functional electron transfer between these two centers another cofactor, most likely FMN bound to the NqrC subunit, should be located.

Acetogenesis and the Wood-Ljungdahl pathway of CO(2) fixation

Conceptually, the simplest way to synthesize an organic molecule is to construct it one carbon at a time. The Wood-Ljungdahl pathway of CO(2) fixation involves this type of stepwise process. The biochemical events that underlie the condensation of two one-carbon units to form the two-carbon compound, acetate, have intrigued chemists, biochemists, and microbiologists for many decades. We begin this review with a description of the biology of acetogenesis. Then, we provide a short history of the important discoveries that have led to the identification of the key components and steps of this usual mechanism of CO and CO(2) fixation. In this historical perspective, we have included reflections that hopefully will sketch the landscape of the controversies, hypotheses, and opinions that led to the key experiments and discoveries. We then describe the properties of the genes and enzymes involved in the pathway and conclude with a section describing some major questions that remain unanswered.

Electrostatic interactions between FeS clusters in NADH:ubiquinone oxidoreductase (Complex I) from Escherichia coli

The redox properties of the cofactors of NADH:ubiquinone oxidoreductase (complex I) from Escherichia coli were studied by following the changes in electron paramagnetic resonance (EPR) and optical spectra upon electrochemical redox titration of the purified protein. At neutral pH, the FMN cofactor had a midpoint redox potential ( E m) approximately -350 mV ( n = 2). Binuclear FeS clusters were well-characterized: N1a was titrated with a single ( n = 1) transition, and E m = -235 mV. In contrast, the titration of N1b can only be fitted with the sum of at least two one-electron Nernstian curves with E m values of -245 and -320 mV. The tetranuclear clusters can also be separated into two groups, either having a single, n = 1, or more complex redox titration curves. The titration curves of the EPR bands attributed to the tetranuclear clusters N2 ( g = 2.045 and g = 1.895) and N6b ( g = 2.089 and g = 1.877) can be presented by the sum of at least two components, each with E m (app) approximately -200/-300 mV and -235/-315 mV, respectively. The titration of the signals at g = 1.956-1.947 (N3 or N7, E m = -315 mV), g = 2.022, and g = 1.932 (Nx, -365 mV) and the low temperature signal at g = 1.929 (N4 or N5, -330 mV) followed Nernstian n = 1 curves. The observed redox titration curves are discussed in terms of intrinsic electrostatic interactions between FeS centers in complex I. A model showing shifts of E m due to the electrostatic interaction between the centers is presented.

Probing the role of the histidine 759 ligand in cobalamin-dependent methionine synthase

Cobalamin-dependent methionine synthase (MetH) of Escherichia coli is a 136 kDa, modular enzyme that undergoes large conformational changes as it uses a cobalamin cofactor as a donor or acceptor in three separate methyl transfer reactions. At different points during the reaction cycle, the coordination to the cobalt of the cobalamin changes; most notably, the imidazole side chain of His759 that coordinates to the cobalamin in the "His-on" state can dissociate to produce a "His-off" state. Here, two distinct species of the cob(II)alamin-bound His759Gly variant have been identified and separated. Limited proteolysis with trypsin was employed to demonstrate that the two species differ in protein conformation. Magnetic circular dichroism and electron paramagnetic resonance spectroscopies were used to show that the two species also differ with respect to the axial coordination to the central cobalt ion of the cobalamin cofactor. One form appears to be in a conformation poised for reductive methylation with adenosylmethionine; this form was readily reduced to cob(I)alamin and subsequently methylated [albeit yielding a unique, five-coordinate methylcob(III)alamin species]. Our spectroscopic data revealed that this form contains a five-coordinate cob(II)alamin species, with a water molecule as an axial ligand to the cobalt. The other form appears to be in a catalytic conformation and could not be reduced to cob(I)alamin under any of the conditions tested, which precluded conversion to the methylcob(III)alamin state. This form was found to possess an effectively four-coordinate cob(II)alamin species that has neither water nor histidine coordinated to the cobalt center. The formation of this four-coordinate cob(II)alamin "dead-end" species in the His759Gly variant illustrates the importance of the His759 residue in governing the equilibria between the different conformations of MetH.

An adaptable spectroelectrochemical titrator: The midpoint reduction potential of the iron–sulfur center in lysine 2,3-aminomutase

Elaborations to an earlier design of an electron paramagnetic resonance (EPR) spectroelectrochemical titrator are described. While maintaining the anaerobic capabilities of the original design, a number of modifications and revisions have been introduced. The most significant modification is the use of a detachable spectral cell, making the apparatus modular and adaptable for multiple forms of spectroscopy. Additional modifications include removable reference, auxiliary, and working electrodes; modifications to facilitate sample transfer; and adaptations for operation within an anaerobic chamber. This apparatus has been used successfully in the coulometric titration of a [4Fe-4S] enzyme, as measured by EPR spectroscopy. The midpoint reduction potential for the 2+/1+ couple in the [4Fe-4S] cluster of lysine 2,3-aminomutase is -479+/-5mV, a value that falls within the range typical of ferredoxin-like iron-sulfur clusters.

Electrochemical and spectroscopic properties of the iron-sulfur flavoprotein from Methanosarcina thermophila

An iron-sulfur flavoprotein (Isf) from the methanoarchaeaon Methanosarcina thermophila, which participates in electron transfer reactions required for the fermentation of acetate to methane, was characterized by electrochemistry and EPR and Mössbauer spectroscopy. The midpoint potential (Em) of the FMN/FMNH2 couple was -0.277 V. No flavin semiquinone was observed during potentiometric titrations; however, low amounts of the radical were observed when Isf was quickly frozen after reaction with CO and the CO dehydrogenase/acetyl-CoA synthase complex from M. thermophila. Isf contained a [4Fe-4S]2+/1+ cluster with g values of 2.06 and 1.93 and an unusual split signal with g values at 1.86 and 1.82. The unusual morphology was attributed to microheterogeneity among Isf molecules. The Em value for the 2+/1+ redox couple of the cluster was -0.394 V. Extracts from H2-CO2-grown Methanobacterium thermoautotrophicum cells catalyzed either the H2- or CO-dependent reduction of M. thermophila Isf. In addition, Isf homologs were found in the genomic sequences of the CO2-reducing methanoarchaea M. thermoautotrophicum and Methanococcus jannaschii. These results support a general role for Isf in electron transfer reactions of both acetate-fermenting and CO2-reducing methanoarchaea. It is suggested that Isf functions to couple electron transfer from ferredoxin to membrane-bound electron carriers, such as methanophenazine and/or b-type cytochromes.

Mechanism of CO oxidation by carbon monoxide dehydrogenase from Clostridium thermoaceticum and its inhibition by anions

Carbon monoxide dehydrogenase (CODH) performs two distinct reactions at two different metal centers. The synthesis of acetyl-CoA from a methyl group, CO, and coenzyme A occurs at center A and the oxidation of CO to CO2 occurs at center C. In the work reported here, we have studied the mechanism of CO oxidation by CODH and its inhibition by thiocyanate. Our data are consistent with a ping-pong mechanism. A scheme to explain the first half-reaction was developed that includes binding of water and CO to the oxidized form of center C, deprotonation of coordinated water to yield enzyme-bound hydroxyl, nucleophilic attack on coordinated CO by OH- to form enzyme-bound carboxyl, and deprotonation and decarboxylation to form CO2 and the reduced form of center C. In the second half-reaction, the reduced enzyme is reoxidized by an electron acceptor. CO oxidation was pH dependent. The pH dependence of kcat/Km for CO gave a single pKa of 7.7 and a maximum value at 55 degrees C and high pH of 9.1 x 10(6) M-1 s-1. The pH dependence of kcat followed a two-phase titration curve with pKa values of 7.1 and 9.5 and maximum value of kcat at 55 degrees C and high pH of 3250 s-1 (1310 mumol of CO oxidized min-1 mg-1). The pH dependencies of kcat/Km and kcat are interpreted to reflect the ionization of enzyme-bound water from binary and ternary complexes with center C. Reaction with thiocyanate, azide, or cyanate was found to cause a striking shift in the EPR spectrum of center C from gav = 1.82 (g = 2.01, 1.81, 1.65) to a two-component spectrum with gav = 2.15 (g = 2.34, 2.067, 2.03) and gav = 2.17 (g = 2.34, 2.115, 2.047). Thiocyanate acted as a mixed partial inhibitor with respect to CO. The inhibition constants were pH and temperature dependent. The pH dependencies of the inhibition constants gave pKa values of approximately 7.7. Binding of thiocyanate to the oxidized form of center C appears to be favored by a negative enthalpy that is offset by a decrease in entropy yielding a slightly unfavorable free energy of association.

Electron paramagnetic resonance spectroscopic and electrochemical characterization of the partially purified N5-methyltetrahydromethanopterin:coenzyme M methyltransferase from Methanosarcina mazei Gö1

The N5-methyltetrahydromethanopterin:coenzyme M methyltransferase is a membrane-bound cobalamin-containing protein of Methanosarcina mazei Gö1 that couples the methylation of coenzyme M by methyltetra-hydrosarcinopterin to the translocation of Na+ across the cell membrane (B. Becher, V. Müller, and G. Gottschalk, J. Bacteriol. 174:7656-7660, 1992). We have partially purified this enzyme and shown that, in addition to the cobamide, at least one iron-sulfur cluster is essential for the transmethylation reaction. The membrane fraction or the partly purified protein contains a "base-on" cobamide with a standard reduction potential (Eo') for the Co2+/1+ couple of -426 mV. The iron-sulfur cluster appears to be a [4Fe-4S]2+/1+ type with an Eo' value of -215 mV. We have determined the methyltransferase activity at various controlled redox potentials and demonstrated that the enzyme activity is activated by a one-electron reduction with half-maximum activity occurring at -235 mV in the presence of ATP and -450 mV in its absence. No activation was observed when ATP was replaced by other nucleoside triphosphates or nonhydrolyzable ATP analogs.

Evidence from electron paramagnetic resonance spectroscopy of the participation of radical intermediates in the reaction catalyzed by methylmalonyl-coenzyme A mutase

Recombinant methylmalonyl-coenzyme A (CoA) mutase from Propionibacterium shermanii has been purified 20-fold to near homogeneity in a highly active form. Neither the apoenzyme (the form in which the enzyme is isolated) nor the holoenzyme (reconstituted with the cofactor, adenosylcobalamin) has an electron paramagnetic resonance (EPR) spectrum associated with it. However, the addition of either the substrate, methylmalonyl-CoA, or the product, succinyl-CoA, results in the appearance of a transient EPR signal. The signal has hyperfine features that indicate coupling of the unpaired electron to the cobalt nucleus. In the presence of [CD3]methylmalonyl-CoA, an EPR signal is also seen and is similar to that obtained in the presence of protiated substrate. Power saturation studies reveal the presence of two components, a slow relaxing species (with an apparent g value of 2.11) and a fast relaxing species (with an apparent g value of 2.14) that can be partially resolved at low temperature and high power. The EPR-active intermediate is observed under catalytic conditions and is approximately midway in its resonance position between a free radical and cob(II)alamin. It is postulated to represent an exchange-coupled cob(II)alamin ... free radical pair. The signal bears close resemblance to those observed with partially dehydrated polycrystalline adenosylcobalamin following laser photolysis (Ghanekar, V.D., Lin, R.J., Coffman, R.E., and Blakley, R.L. (1981) Biochem. Biophys. Res. Commun. 101, 215-221) and with the adenosylcobalamin-dependent ribonucleotide reductase under freeze-quench conditions (Orme-Johnson, W.H., Beinert, H., and Blakley, R.L. (1974) J. Biol. Chem. 249, 2338-2343). When cob(II)alamin is generated under noncatalytic conditions (i.e. in the presence of propionyl-CoA or by electrochemical reduction of enzyme-bound hydroxocob-(III)alamin), a different EPR signal is observed with g = 2.26 and g = 2.00, typical of base-on cob(II)alamin.

Enzymology of the acetyl-CoA pathway of CO2 fixation

We know of three routes that organisms have evolved to synthesize complex organic molecules from CO2: the Calvin cycle, the reverse tricarboxylic acid cycle, and the reductive acetyl-CoA pathway. This review describes the enzymatic steps involved in the acetyl-CoA pathway, also called the Wood pathway, which is the major mechanism of CO2 fixation under anaerobic conditions. The acetyl-CoA pathway is also able to form acetyl-CoA from carbon monoxide. There are two parts to the acetyl-CoA pathway: (1) reduction of CO2 to methyltetrahydrofolate (methyl-H4folate) and (2) synthesis of acetyl-CoA from methyl-H4folate, a carboxyl donor such as CO or CO2, and CoA. This pathway is unique in that the major intermediates are enzyme-bound and are often organometallic complexes. Our current understanding of the pathway is based on radioactive and stable isotope tracer studies, purification of the component enzymes (some extremely oxygen sensitive), and identification of the enzyme-bound intermediates by chromatographic, spectroscopic, and electrochemical techniques. This review describes the remarkable series of enzymatic steps involved in acetyl-CoA formation by this pathway that is a key component of the global carbon cycle.

Mechanism of reductive activation of cobalamin-dependent methionine synthase: an electron paramagnetic resonance spectroelectrochemical study

The mechanism of reductive methylation of cobalamin-dependent methionine synthase (5-methyltetrahydrofolate:homocysteine methyltransferase, EC 2.1.1.13) has been investigated by electron paramagnetic resonance (EPR) spectroelectrochemistry. The enzyme as isolated is inactive, and its UV/visible absorbance and EPR spectra are characteristic of cob(II)alamin. There is an absolute requirement for catalytic amounts of AdoMet and a reducing system for the formation and maintenance of active enzyme during in vitro turnover. The midpoint potentials of the enzyme-bound cob(II)alamin/cob(I)alamin and cob(III)alamin/cob(II)alamin couples have been determined to be -526 +/- 5 and +273 +/- 4 mV (versus the standard hydrogen electrode), respectively. The presence of either CH3-H4folate or AdoMet shifts the equilibrium distribution of cobalamin species observed during reduction by converting cob(I)alamin to methylcobalamin. The magnitude of these shifts is however vastly different, with AdoMet lowering the concentration of cob(II)alamin at equilibrium by a factor of at least 3 X 10(7), while CH3-H4folate lowers it by a factor of 19. These studies of coupled reduction/methylation reactions elucidate the absolute requirement for AdoMet in the in vitro assay system, in which the ambient potential is approximately -350 mV versus the standard hydrogen electrode. At this potential, the equilibrium distribution of cobalamin in the presence of CH3-H4folate would be greatly in favor of the cob(II)alamin species, whereas in the presence of AdoMet the equilibrium favors methylated enzyme. In these studies, a base-on form of cob(II)alamin in which the dimethylbenzimidazole substituent of the corrin ring is the lower axial ligand for the cobalt has been observed for the first time on methionine synthase.(ABSTRACT TRUNCATED AT 250 WORDS)