Mo Active Site Research Articles

The Electron‐Rich Interface Regulated MBene by S‐Bridge Guided to Enhance Nitrogen Fixation under Environmental Conditions

AbstractThe underutilization of active sites limits the performance enhancement of 2D transition metal boride (MBene) in electrocatalytic nitrogen reduction reaction (NRR). Herein, a highly efficient NRR electrocatalyst with S atoms bridging Fe and Mo atoms on the surface of MBene is successfully constructed by using an active site electron optimization strategy, which increases the charge density around the Mo active site and enhances the activation ability of the catalyst to N2 molecules. It is noteworthy that FeS2‐MBene demonstrates a low intrinsic potential for NRR (−0.2 V vs RHE). It is more favorable for the adsorption of nitrogen atoms in comparison to hydrogen atoms, thereby it can effectively inhibit the hydrogen evolution reaction (HER). Under a potential of −0.2 V versus RHE, the ammonia yield rate is 37.13 ± 1.31 µg h−1 mg−1, and the FE is 55.97 ± 2.63%. Density functional theory (DFT) calculations demonstrate that Mo on the surface of MBene serves as a site for the adsorption of N2. The formation of the heterostructure enhances electron transfer, resulting in the Mo active site becoming an electron‐rich state in favor of subsequent hydrogenation steps. This work offers significant insights into the design and utilization of 2D MBene‐based catalysts in NRR.

Facile synthesis of defect-rich interfacial Mo/MoO2 for efficient peroxymonosulfate activation and refractory pollutants degradation

Peroxymonosulfate-based advanced oxidation process (PMS-AOP) has shown great potential in sewage purification, and catalyst development capable of efficient PMS activation is a key while challenging element. Herein we reported a facile electro-explosive route to synthesize the oxygen vacancy (Vo)-enriched Mo/MoO2 without using chemical reagents. The detailed studies suggested that the synergy of Mo active site and Vo in the catalyst significantly boosted the activation kinetics of PMS. Evidently, the Mo site of different oxidation states contributed to chemical activation of PMS, while the Vo favored the activation of PMS and the generation of non-radical 1O2 species. As a result, the Mo/MoO2-10 h/PMS system delivered a complete removal of acid orange 7 (AO7) within 4 min, significantly exceeding the activity of Mo/PMS (16%), MoO2-H/PMS (25%) and most of other PMS-based systems. Moreover, the current system showed high potential for removal of different pollutants including antibiotics and organic dyes. Radical quenching experiments and electron paramagneticresonance (EPR) studies revealed that the 1O2 species was significant for AO7 decomposition. This work provided a novel strategy to a batch-scale synthesis of high-performance PMS activator for water remediation in practice.

Phase-Transition of Mo2C Induced by Tungsten Doping as Heterointerface-Rich Electrocatalyst for Optimizing Hydrogen Evolution Activity.

Electrochemical hydrogen evolution reaction (HER) from water splitting driven by renewable energy is considered a promising method for large-scale hydrogen production, and as an alternative to noble-metal electrocatalysts, molybdenum carbide (Mo2C) has exhibited effective HER performance. However, the strong bonding strength of intermediate adsorbed H (Hads) with Mo active site slows down the HER kinetics of Mo2C. Herein, using phase-transition strategy, hexagonal β-Mo2C could be easily transferred to cubic δ-Mo2C through electron injection triggered by tungsten (W) doping, and heterointerface-rich Mo2C-based composites, including β-Mo2C, δ-Mo2C, and MoO2, are presented. Experimental results and density functional theory calculations reveal that W doping mainly contributes to the phase-transition process, and the generated heterointerfaces are the dominant factor in inducing remarkable electron accumulation around Mo active sites, thus weakening the Mo─H coupling. Wherein, the β-Mo2C/MoO2 interface plays an important role in optimizing the electronic structure of Mo 3d orbital and hydrogen adsorption Gibbs free energy (ΔGH*), enabling these Mo2C-based composites to have excellent intrinsic catalytic activity like low overpotential (η10 = 99.8mV), small Tafel slope (60.16 dec-1), and good stability in 1m KOH. This work sheds light on phase-transition engineering and offers a convenient route to construct heterointerfaces for large-scale HER production.

Double-single-atom MoCu-embedded porous carbons boost the electrocatalytic N2 reduction reaction.

NH3 is an essential ingredient of chemical, fertilizer, and energy storage products. Industrial nitrogen fixation consumes an enormous amount of energy, which is counter to the concept of carbon neutrality, hence eNRR ought to be implemented as a clean alternative. Herein, we propose a double-single-atom MoCu-embedded porous carbon material derived from uio-66 (MoCu@C) by plasma-enhanced chemical vapor deposition (PECVD) to boost eNRR capabilities, with an NH3 yield rate of 52.4 μg h-1 gcat.-1 and a faradaic efficiency (FE) of 27.4%. Advanced XANES shows that the Mo active site receives electrons from Cu, modifies the electronic structure of the Mo active site and enhances N2 adsorption activation. The invention of rational MoCu double-single-atom materials and the utilization of effective eNRR approaches furnish the necessary building blocks for the fundamental study and practical application of Mo-based materials.

Selectivity of Mo[sbnd]N[sbnd]C sites for electrocatalytic N2 reduction: A function of the single atom position on the surface and local carbon topologies

Transition metal (TM) doped two-dimensional single-atom catalysts are known as a promising class of catalysts for electrocatalytic gas conversion. However, the detailed mechanisms that occur at the surface of these catalysts are still unknown. In the present work, we simulate three Mo-doped nitrogenated graphene structures. In each catalyst, the position of the Mo active site and the corresponding local carbon topologies are different, i.e. MoN4C10 with in-plane Mo atom, MoN4C8 in which Mo atom bridges two adjacent armchair-like graphitic edges, and MoN2C3 in which Mo is doped at the edge of the graphene sheet. Using Density Functional Theory (DFT) calculations we discuss the electrocatalytic activity of MoNC structures for nitrogen reduction reaction (NRR) with a focus on unraveling the corresponding mechanisms concerning different Mo site positions and C topologies. Our results indicate that the position of the active site centers has a great effect on its electrocatalytic behavior. The gas phase N2 efficiently reduces to ammonia on MoN4C8 via the distal mechanism with an onset potential of −0.51 V. We confirm that the proposed pyridinic structure, MoN4C8, can catalyze NRR effectively with a low overpotential of 0.35 V.

Gating of Substrate Access and Long-Range Proton Transfer in Escherichia coli Nitrate Reductase A: The Essential Role of a Remote Glutamate Residue

The Mo/W-bisPGD enzyme superfamily comprises a vast number of mononuclear molybdenum and tungsten enzymes that catalyze a great diversity of vital reactions in prokaryotes. In the past decades, much attention has been devoted to the immediate surroundings of the metal atom highlighting the importance of the inner coordination sphere but has failed to identify molecular determinants of the reactivity. Here, we report the mechanistic importance of a set of conserved residues that line the substrate entry tunnel in Escherichia coli nitrate reductase A (Nar), a paradigmatic enzyme of the Mo/W-bisPGD superfamily. Using mutagenesis, enzyme kinetics, electron paramagnetic resonance spectroscopy, and molecular dynamics, we unveil the pivotal role of Glu-581 motion and a number of polar residues in its close proximity in substrate affinity and proton transfer to the Mo active site. Motion of the side chain of Glu-581 exhibiting a strong acid–base cooperativity with Asp-801 and surrounded by several polar interactions controls the hydration inside the protein core, proton transfer, and substrate selectivity toward the active site. Overall, we identify an additional determinant that fine-tunes the reactivity and selectivity in Nar and propose that a gating mechanism is at play in several other members of the superfamily.

Electrochemical Studies of CO2 -Reducing Metalloenzymes.

Only two enzymes are capable of directly reducing CO2 : CO dehydrogenase, which produces CO at a [NiFe4 S4 ] active site, and formate dehydrogenase, which produces formate at a mononuclear W or Mo active site. Both metalloenzymes are very rapid, energy-efficient and specific in terms of product. They have been connected to electrodes with two different objectives. A series of studies used protein film electrochemistry to learn about different aspects of the mechanism of these enzymes (reactivity with substrates, inhibitors…). Another series focused on taking advantage of the catalytic performance of these enzymes to build biotechnological devices, from CO2 -reducing electrodes to full photochemical devices performing artificial photosynthesis. Here, we review all these works.

Regulating Electronic Spin Moments of Single-Atom Catalyst Sites via Single-Atom Promoter Tuning on S-Vacancy MoS2 for Efficient Nitrogen Fixation.

The electrocatalytic activity of transition-metal (TM)-based catalysts is correlated with the spin states of metal atoms. However, developing a way to manipulate spin remains a great challenge. Using first-principles calculations, we first report the crucial role of the spin of exposed Mo atoms around an S-vacancy in the electrocatalytic dinitrogen reduction reaction on defective MoS2 nanosheets and propose a novel strategy for regulating the electronic spin moments by tuning a single-atom promoter (SAP). Single TM atoms adsorbed on a defective MoS2 basal plane serve as SAPs via a noncontact interaction with an exposed Mo active site, inducing a significant spin polarization that promotes N2 adsorption and activation. Interestingly, by changing only the adsorption site of the TM atom, we are able to change the spin moments of the Mo atom, over a wide range of tunable values. The spin moments can be tuned to largely improve the catalytic activity of MoS2 toward the reduction of N2 to NH3.

Active site architecture reveals coordination sphere flexibility and specificity determinants in a group of closely related molybdoenzymes

MtsZ is a molybdenum-containing methionine sulfoxide reductase that supports virulence in the human respiratory pathogen Haemophilus influenzae (Hi). HiMtsZ belongs to a group of structurally and spectroscopically uncharacterized S-/N-oxide reductases, all of which are found in bacterial pathogens. Here, we have solved the crystal structure of HiMtsZ, which reveals that the HiMtsZ substrate-binding site encompasses a previously unrecognized part that accommodates the methionine sulfoxide side chain via interaction with His182 and Arg166. Charge and amino acid composition of this side chain–binding region vary and, as indicated by electrochemical, kinetic, and docking studies, could explain the diverse substrate specificity seen in closely related enzymes of this type. The HiMtsZ Mo active site has an underlying structural flexibility, where dissociation of the central Ser187 ligand affected catalysis at low pH. Unexpectedly, the two main HiMtsZ electron paramagnetic resonance (EPR) species resembled not only a related dimethyl sulfoxide reductase but also a structurally unrelated nitrate reductase that possesses an Asp–Mo ligand. This suggests that contrary to current views, the geometry of the Mo center and its primary ligands, rather than the specific amino acid environment, is the main determinant of the EPR properties of mononuclear Mo enzymes. The flexibility in the electronic structure of the Mo centers is also apparent in two of three HiMtsZ EPR-active Mo(V) species being catalytically incompetent off-pathway forms that could not be fully oxidized.

Screening of catalysts for the oxidative dehydrogenation of ethyl lactate to ethyl pyruvate, and optimization of the best catalysts

This study reports on a new industrial gas-phase process to produce ethyl pyruvate, using the oxidative dehydrogenation of ethyl lactate. In an initial approach, twenty catalysts were screened under reaction conditions required for industrial applications. When evaluated in terms of their maximum selectivity to ethyl pyruvate and their productivity, the best catalyst was found to be a phosphomolybdic polyoxometalate, with iron counter-cations: FePMo12O40. To improve this catalyst, a study was carried out by including cesium counter-cations. The new catalysts exhibited higher yields because of higher Mo active surface site density related to higher specific surface area and although their intrinsic activity was lower. Their ethyl pyruvate selectivity increased with iron content but never overpass that of FePMo12O40. These results are explained in terms of changes in structure and iron counteraction coordination leading or not to electron exchange between iron and molybdenum and influencing the acidity of the catalyst's surface.

Surface chemistry and reactivity of α-MoO3 toward methane: A SCAN-functional based DFT study.

Molybdenum trioxide (α-MoO3) is a key component in the redox solid catalysts for methane activation. The wide range of interactions including van der Waals interaction and chemical bonding in α-MoO3 as well as between methane and the catalyst surface makes the accurate description of the methane chemistry a challenge. Herein, we performed a strongly constrained and appropriately normed (SCAN)-functional based density functional theory study of the surface chemistry and reactivity of α-MoO3 toward C-H bond activation of methane. With this meta-generalized-gradient approximation functional, we can predict the bulk structure of α-MoO3 more accurately while reproducing the thermal chemistry of MoO3. The results indicate that surface reduction of α-MoO3 (010) occurs preferably through releasing the terminal oxygen atoms, generating oxygen vacancies while exposing reduced Mo centers. These oxygen vacancies tend to be separated from each other at a higher density due to repulsive interactions. Furthermore, the reduced α-MoO3 (010) promotes methane activation kinetically by reducing the activation barrier for the break of the first C-H bond and thermodynamically by stabilizing the product state as compared with those on the stoichiometric surface. There is a synergy between the reduced Mo active site and surface lattice oxygen for C-H bond cleavage. Our results also show that the reactivity based on the Perdew-Burke-Ernzerhof functional is qualitatively consistent with that from the SCAN functional.

Effects of Hydrogen Bond Donors on Reactivity of Sulfite Oxidase

Sulfite oxidase (SO) catalyzes the conversion of sulfite to sulfate as the last step in the degradation of cysteine and methionine [1]. Severe neonatal neurological problems are caused by SO deficiency in humans [2]. The overall mechanism of SO suggested that the reductive half reaction of SO is the rate limiting step for enzyme activity [3]. Using a computational approach, first I will study the elementary steps for the half reaction to determine the rate limiting step, then by introducing mutations in the active site of SO I will determine the effects of the hydrogen donors present in the active site.SO is part of the Molybdenum cofactor family of enzymes as it contains a mononuclear Molybdenum (Mo) that is penta‐coordinated [4]. At the Mo active site, the reductive half reaction of sulfite to sulfate takes place in two steps. The first step is a nucleophilic attack by the sulfite ion to the equatorial oxygen group. The second step is the release of sulfate facilitated by the spectator oxygen group [4]. By determining the energy profiles for both steps in this reaction I will determine which step is rate limiting and determine the route, associative or dissociative interchange, of the reaction.Model enzyme complexes have suggested that hydrogen donors in the active site play a key role in mediating this reaction. In previous studies performed we determined that the product release step is facilitated by pyridinium a hydrogen donor for the reaction. Pyridinium lowers the activation energy for the product release step (ΔH~ 30 kJ/mol) and promotes a dissociative interchange reaction route. In this study I will determine if hydrogen donors in the Mo active site behave as pyridinium does in the model enzyme complexes.Using Gaussian ONIOM to perform QM/MM calculations for the reaction of sulfite to sulfate catalyzed by SO, I will determine the energy profile of the reaction to identify the rate limiting step and the role of possible hydrogen donors in the active site of SO by comparing the reaction mechanism of two variants of SO with wild type SO. The variants will demonstrate the role as possible hydrogen bond donors of Tyrosine and water that are located in the active site of MO.The role of sulfite oxidase is crucial to the degradation of sulfite in the body and prevention of the accumulation of toxic sulfite in the body. Understanding how SO functions at a molecular level is crucial for the design and implementation of treatment for SO deficiency. The elementary steps of the enzyme activity can help determine specific roles of key residues in the enzyme. These steps cannot be seen in large scale enzyme kinetics studies, but computational studies allow the study of small movements and allow the study of these small‐scale reaction mechanics.Support or Funding InformationLouis Stokes Alliance for Minority Participation (LSAMP) HRD # 1305011This abstract is from the Experimental Biology 2018 Meeting. There is no full text article associated with this abstract published in The FASEB Journal.

29 - Oxygen Inhibits Nitrite Reduction to Nitric Oxide by the Molybdenum-Dependent mARC-2 Enzyme

The mitochondrial amidoxime reducing component (mARC) enzymes are molybdenum (Mo) -dependent oxidoreductases that function as part of a three-enzyme metabolon with cytochrome b5 (CYB5) and cytochrome b5 reductase (CYB5R). Previous studies in our lab have demonstrated that nitrite reduction to nitric oxide by the mARC-1 metabolon is regulated by oxygen via superoxide. However, the effect of oxygen on mARC-2, the mARC paralog expressed in human vascular tissue, has not been reported. Therefore, this study was conducted to determine the effect of oxygen on nitrite reduction to nitric oxide by mARC-2 and determine if superoxide is involved. We used purified recombinant mARC-2, CYB5, and CYBR enzymes and kinetic nitric oxide measurements to measure the effect of anoxia, hypoxia, and normoxia on nitrite reduction. We found that the NADH-dependent CYB5/CYB5R/mARC-2 metabolon is more sensitive to oxygen than the mARC-1 metabolon. However, the role of superoxide is less pronounced. This is in contrast with previous studies on the mARC-1 metabolon. Our data suggests that mARC-2 oxygen inhibition proceeds via a superoxide-independent mechanism, possibly direct and irreversible oxidation of the Mo active site.

Bioelectrocatalysis of Sulfite Dehydrogenase from Sinorhizobium meliloti with Its Physiological Cytochrome Electron Partner

AbstractWe demonstrate electrochemically driven catalytic voltammetry of the Mo‐dependent sulfite dehydrogenase (SorT) from the α‐Proteobacterium Sinorhizobium meliloti with its physiological electron acceptor, the c‐type cytochrome (SorU), with both proteins co‐adsorbed on a chemically modified Au working electrode. Both SorT and SorU were constrained under a perm‐selective dialysis membrane with the biopolymer chitosan as a co‐adsorbate, while the electrode was modified with a 3‐mercaptopropionate self‐assembled monolayer cast on the Au electrode. Cyclic voltammetry of the SorU protein reveals a well‐defined quasireversible FeIII/II redox couple at +130 mV versus NHE in 100 mM phosphate buffer solution (pH 7.0). Introduction of wild‐type sulfite dehydrogenase (SorTWT) and sulfite transforms this transient SorU voltammetric response into a sigmoidal catalytic wave, which increases with sulfite concentration before eventually saturating. In addition to the wild‐type enzyme, the variants SorTR78K, SorTR78M, and SorTR78Q were also examined electrochemically in an effort to better understand the role of amino acid residue Arg78, which is in the vicinity of the Mo active site of SorT.

The active site structure and catalytic mechanism of arsenite oxidase

Arsenite oxidase is thought to be an ancient enzyme, originating before the divergence of the Archaea and the Bacteria. We have investigated the nature of the molybdenum active site of the arsenite oxidase from the Alphaproteobacterium Rhizobium sp. str. NT-26 using a combination of X-ray absorption spectroscopy and computational chemistry. Our analysis indicates an oxidized Mo(VI) active site with a structure that is far from equilibrium. We propose that this is an entatic state imposed by the protein on the active site through relative orientation of the two molybdopterin cofactors, in a variant of the Rây-Dutt twist of classical coordination chemistry, which we call the pterin twist hypothesis. We discuss the implications of this hypothesis for other putatively ancient molybdopterin-based enzymes.

Effect of molybdenum and tungsten on the reduction of nitrate in nitrate reductase, a DFT study

The molybdenum and tungsten active site model complexes, derived from the protein X-ray crystal structure of the first W-containing nitrate reductase isolated from Pyrobaculum aerophilum, were computed for nitrate reduction at the COSMO-B3LYP/SDDp//B3LYP/Lanl2DZ(p) energy level of density functional theory. The molybdenum containing active site model complex (Mo–Nar) has the largest activation energy (34.4 kcal/mol) for the oxygen atom transfer from the nitrate to the metal center as compared to the tungsten containing active site model complex (W–Nar) (12.0 kcal/mol). Oxidation of the educt complex is close to thermoneutral (−1.9 kcal/mol) for the Mo active site model complex but strongly exothermic (−34.7 kcal/mol) for the W containing active site model complex, however, the MVI to MIV reduction requires equal amount of reductive power for both metal complexes, Mo–Nar or W–Nar.

Direct electrochemistry of nitrate reductase from the fungus Neurospora crassa

We report the first direct (unmediated) catalytic electrochemistry of a eukaryotic nitrate reductase (NR). NR from the filamentous fungus Neurospora crassa, is a member of the mononuclear molybdenum enzyme family and contains a Mo, heme and FAD cofactor which are involved in electron transfer from NAD(P)H to the (Mo) active site where reduction of nitrate to nitrite takes place. NR was adsorbed on an edge plane pyrolytic graphite (EPG) working electrode. Non-turnover redox responses were observed in the absence of nitrate from holo NR and three variants lacking the FAD, heme or Mo cofactor. The FAD response is due to dissociated cofactor in all cases. In the presence of nitrate, NR shows a pronounced cathodic catalytic wave with an apparent Michaelis constant (KM) of 39μM (pH7). The catalytic cathodic current increases with temperature from 5 to 35°C and an activation enthalpy of 26kJmol−1 was determined. In spite of dissociation of the FAD cofactor, catalytically activity is maintained.

The crystal structure of human Aldehyde Oxidase in native and inhibited forms

Aldehyde oxidases (AOX; E.C. 1.2.3.1) are molybdo-flavoenzymes with broad substrate specificity, oxidizing aldehydes and N-heterocycles. AOX belongs to the xanthine oxidase (XO) family of Mo-containing enzymes. The true physiological function of AOX is still unknown, although it is recognized to play a role in the metabolism of compounds with medicinal and toxicological relevance [1]. AOX importance has increased in recent years since it is substituting Cyt-P450 as the central drug-metabolizing system in humans. We have solved the 3D structure of mouse AOX3 to 2.9 Å resolution [2] that was the first structure of an aldehyde oxidase, providing important evidences on substrate and inhibitor specificities between AOX and XO. The complement of AOX proteins in mammals varies from one in humans (hAOX1) to four in rodents (mAOX1, mAOX3, mAOX4 and mAOX3L1) as a result of evolutionary genetic events. Due to this unusual complement of AOX genes in different animal species, conclusions regarding protein metabolism in humans cannot be taken exclusively from the mouse model. Using the human aldehyde oxidase (hAOX1) purified after heterologous expression in Escherichia coli we were able to crystallize it and solve its 3D structure to 2.7 Å resolution (submitted). In addition to the native protein we also solved the structure of an inhibited form of the enzyme to 2.6Å resolution. Analysis of the protein active site and comparison with the structure of the mouse isoform (mAOX3) allowed us to identity, for the first time, the unique features that characterize hAOX1 as an important drug-metabolizing enzyme. In spite of the similarities of both enzymes, they show marked and relevant differences at the Mo active site, substrate tunnel as well as at the FAD site. The ensemble of these structures provides important insights into the role of aldehyde oxidases, contributing to elucidate the clinical metabolism implications of hAOX1 in humans which has particular relevance for novel drug design studies.

Mediated Electrochemistry of Nitrate Reductase from Arabidopsis thaliana

Herein we report the mediated electrocatalytic voltammetry of the plant molybdoenzyme nitrate reductase (NR) from Arabidopsis thaliana using the established truncated molybdenum-heme fragment at a glassy carbon (GC) electrode. Methyl viologen (MV), benzyl viologen (BV), and anthraquinone-2-sulfonic acid (AQ) are employed as effective artificial electron transfer partners for NR, differing in redox potential over a range of about 220 mV and delivering different reductive driving forces to the enzyme. Nitrate is reduced at the Mo active site of NR, yielding the oxidized form of the enzyme, which is reactivated by the electro-reduced form of the mediator. Digital simulation was performed using a single set of enzyme dependent parameters for all catalytic voltammetry obtained under different sweep rates and various substrate or mediator concentrations. The kinetic constants from digital simulation provide new insight into the kinetics of the NR catalytic mechanism.

X-ray Absorption Spectroscopy of a Quantitatively Mo(V) Dimethyl Sulfoxide Reductase Species

Molybdenum K-edge X-ray absorption spectroscopy (XAS) has been used to probe the structure of a Mo(V) species that has been suggested to be a catalytic intermediate in the reaction of dimethyl sulfoxide (DMSO) reductase with the alternative substrate trimethylamine N-oxide (Bennet et al. Eur. J. Biochem. 1994, 255, 321-331; Cobb et al. J. Biol. Chem. 2005, 280, 11007-11017; Mtei, et al. J. Am. Chem. Soc. 2011, 133, 9672-9774). The oxidized Mo(VI) state of DMSO reductase has previously been structurally characterized as being six coordinate, with four sulfurs from pyranopterin dithiolene molybdenum cofactors, a terminal oxygen ligand, and an additional oxygen coordination from a serine residue. We find the most plausible structure for the Mo(V) active site is a five-coordinate species with four sulfur donors from the two pyranopterin dithiolene ligands, with an average Mo-S bond-length of 2.35 Å, plus a single oxygen donor at 1.99 Å, very likely from an Mo-OH ligand. Our results thus suggest that the oxygen of the serine residue has dissociated from the metal ion, suggesting hitherto unsuspected flexibility of the active site, and calling into question whether this putative intermediate is catalytically relevant. The relevance to previous Mo(V) electron paramagnetic resonance and other spectroscopic studies on DMSO reductase is discussed. XAS of an extensively studied Mo(V) form of Rhodobacter sphaeroides DMSO reductase (the high-g split species) shows that previously suggested structures for the active site are likely incorrect.