Your search keyword '"Vincent, Kylie A."' showing total 21 results

1. Replacing a Cysteine Ligand by Selenocysteine in a [NiFe]-Hydrogenase Unlocks Hydrogen Production Activity and Addresses the Role of Concerted Proton-Coupled Electron Transfer in Electrocatalytic Reversibility.

Author

Evans RM, Krahn N, Weiss J, Vincent KA, Söll D, and Armstrong FA

Subjects

Electron Transport, Ligands, Catalysis, Electrochemical Techniques, Oxidation-Reduction, Hydrogenase metabolism, Hydrogenase chemistry, Hydrogen chemistry, Hydrogen metabolism, Protons, Cysteine chemistry, Cysteine metabolism, Selenocysteine chemistry, Selenocysteine metabolism

Abstract

Hydrogenases catalyze hydrogen/proton interconversion that is normally electrochemically reversible (having minimal overpotential requirement), a special property otherwise almost exclusive to platinum metals. The mechanism of [NiFe]-hydrogenases includes a long-range proton-coupled electron-transfer process involving a specific Ni-coordinated cysteine and the carboxylate of a nearby glutamate. A variant in which this cysteine has been exchanged for selenocysteine displays two distinct changes in electrocatalytic properties, as determined by protein film voltammetry. First, proton reduction, even in the presence of H 2 (a strong product inhibitor), is greatly enhanced relative to H 2 oxidation: this result parallels a characteristic of natural [NiFeSe]-hydrogenases which are superior H 2 production catalysts. Second, an inflection (an S -shaped "twist" in the trace) appears around the formal potential, the small overpotentials introduced in each direction (oxidation and reduction) signaling a departure from electrocatalytic reversibility. Concerted proton-electron transfer offers a lower energy pathway compared to stepwise transfers. Given the much lower proton affinity of Se compared to that of S, the inflection provides compelling evidence that concerted proton-electron transfer is important in determining why [NiFe]-hydrogenases are reversible electrocatalysts.

Published

2024

2. Structural basis for bacterial energy extraction from atmospheric hydrogen.

Author

Grinter R, Kropp A, Venugopal H, Senger M, Badley J, Cabotaje PR, Jia R, Duan Z, Huang P, Stripp ST, Barlow CK, Belousoff M, Shafaat HS, Cook GM, Schittenhelm RB, Vincent KA, Khalid S, Berggren G, and Greening C

Subjects

Cryoelectron Microscopy, Oxidation-Reduction, Oxygen, Vitamin K 2 metabolism, Hydrogenation, Hydrogen chemistry, Hydrogen metabolism, Hydrogenase chemistry, Hydrogenase metabolism, Hydrogenase ultrastructure, Atmosphere chemistry, Mycobacterium smegmatis enzymology, Mycobacterium smegmatis metabolism

Abstract

Diverse aerobic bacteria use atmospheric H 2 as an energy source for growth and survival 1 . This globally significant process regulates the composition of the atmosphere, enhances soil biodiversity and drives primary production in extreme environments 2,3 . Atmospheric H 2 oxidation is attributed to uncharacterized members of the [NiFe] hydrogenase superfamily 4,5 . However, it remains unresolved how these enzymes overcome the extraordinary catalytic challenge of oxidizing picomolar levels of H 2 amid ambient levels of the catalytic poison O 2 and how the derived electrons are transferred to the respiratory chain 1 . Here we determined the cryo-electron microscopy structure of the Mycobacterium smegmatis hydrogenase Huc and investigated its mechanism. Huc is a highly efficient oxygen-insensitive enzyme that couples oxidation of atmospheric H 2 to the hydrogenation of the respiratory electron carrier menaquinone. Huc uses narrow hydrophobic gas channels to selectively bind atmospheric H 2 at the expense of O 2 , and 3 [3Fe-4S] clusters modulate the properties of the enzyme so that atmospheric H 2 oxidation is energetically feasible. The Huc catalytic subunits form an octameric 833 kDa complex around a membrane-associated stalk, which transports and reduces menaquinone 94 Å from the membrane. These findings provide a mechanistic basis for the biogeochemically and ecologically important process of atmospheric H 2 oxidation, uncover a mode of energy coupling dependent on long-range quinone transport, and pave the way for the development of catalysts that oxidize H 2 in ambient air., (© 2023. The Author(s).)

Published

2023

3. Protein Film Infrared Electrochemistry Demonstrated for Study of H2 Oxidation by a [NiFe] Hydrogenase.

Author

Ash PA, Hidalgo R, and Vincent KA

Subjects

Oxidation-Reduction, Electrochemistry methods, Hydrogen chemistry, Hydrogenase chemistry, Proteins chemistry

Abstract

Understanding the chemistry of redox proteins demands methods that provide precise control over redox centers within the protein. The technique of protein film electrochemistry, in which a protein is immobilized on an electrode surface such that the electrode replaces physiological electron donors or acceptors, has provided functional insight into the redox reactions of a range of different proteins. Full chemical understanding requires electrochemical control to be combined with other techniques that can add additional structural and mechanistic insight. Here we demonstrate a technique, protein film infrared electrochemistry, which combines protein film electrochemistry with infrared spectroscopic sampling of redox proteins. The technique uses a multiple-reflection attenuated total reflectance geometry to probe a redox protein immobilized on a high surface area carbon black electrode. Incorporation of this electrode into a flow cell allows solution pH or solute concentrations to be changed during measurements. This is particularly powerful in addressing redox enzymes, where rapid catalytic turnover can be sustained and controlled at the electrode allowing spectroscopic observation of long-lived intermediate species in the catalytic mechanism. We demonstrate the technique with experiments on E. coli hydrogenase 1 under turnover (H2 oxidation) and non-turnover conditions.

Published

2017

4. H 2 -Driven biocatalytic hydrogenation in continuous flow using enzyme-modified carbon nanotube columns.

Author

Zor C, Reeve HA, Quinson J, Thompson LA, Lonsdale TH, Dillon F, Grobert N, and Vincent KA

Subjects

Amination, Hydrogen chemistry, Hydrogenation, Ketones chemistry, Ketones metabolism, Oxidation-Reduction, Biocatalysis, Enzymes, Immobilized metabolism, Hydrogen metabolism, Hydrogenase metabolism, Nanotubes, Carbon chemistry, Oxidoreductases metabolism

Abstract

We describe the implementation of a system of immobilised enzymes for H 2 -driven NADH recycling coupled to a selective biotransformation to enable H 2 -driven biocatalysis in flow. This approach represents a platform that can be optimised for a wide range of hydrogenation steps and is shown here for enantioselective ketone reduction and reductive amination.

Published

2017

5. Enzymes as modular catalysts for redox half-reactions in H2-powered chemical synthesis: from biology to technology.

Author

Reeve HA, Ash PA, Park H, Huang A, Posidias M, Tomlinson C, Lenz O, and Vincent KA

Subjects

Bacterial Proteins metabolism, Biocatalysis, Biofuels, Biotechnology methods, Coenzymes metabolism, Electrochemistry methods, Hydrogenase metabolism, Light, NAD metabolism, Oxidation-Reduction, Photochemical Processes, Bacterial Proteins chemistry, Coenzymes chemistry, Hydrogen chemistry, Hydrogenase chemistry, NAD chemistry, Protein Engineering methods

Abstract

The present study considers the ways in which redox enzyme modules are coupled in living cells for linking reductive and oxidative half-reactions, and then reviews examples in which this concept can be exploited technologically in applications of coupled enzyme pairs. We discuss many examples in which enzymes are interfaced with electronically conductive particles to build up heterogeneous catalytic systems in an approach which could be termed synthetic biochemistry We focus on reactions involving the H + /H 2 redox couple catalysed by NiFe hydrogenase moieties in conjunction with other biocatalysed reactions to assemble systems directed towards synthesis of specialised chemicals, chemical building blocks or bio-derived fuel molecules. We review our work in which this approach is applied in designing enzyme-modified particles for H 2 -driven recycling of the nicotinamide cofactor NADH to provide a clean cofactor source for applications of NADH-dependent enzymes in chemical synthesis, presenting a combination of published and new work on these systems. We also consider related photobiocatalytic approaches for light-driven production of chemicals or H 2 as a fuel. We emphasise the techniques available for understanding detailed catalytic properties of the enzymes responsible for individual redox half-reactions, and the importance of a fundamental understanding of the enzyme characteristics in enabling effective applications of redox biocatalysis., (© 2017 The Author(s).)

Published

2017

6. Infrared Spectroscopy During Electrocatalytic Turnover Reveals the Ni-L Active Site State During H2 Oxidation by a NiFe Hydrogenase.

Author

Hidalgo R, Ash PA, Healy AJ, and Vincent KA

Subjects

Biocatalysis, Catalytic Domain, Electrochemical Techniques, Electrodes, Electron Spin Resonance Spectroscopy, Electron Transport, Escherichia coli enzymology, Escherichia coli Proteins chemistry, Escherichia coli Proteins metabolism, Hydrogen metabolism, Hydrogenase chemistry, Ligands, Oxidation-Reduction, Protons, Spectrophotometry, Infrared, Hydrogen chemistry, Hydrogenase metabolism, Nickel chemistry

Abstract

A novel in situ IR spectroscopic approach is demonstrated for the characterization of hydrogenase during catalytic turnover. E. coli hydrogenase 1 (Hyd-1) is adsorbed on a high surface-area carbon electrode and subjected to the same electrochemical control and efficient supply of substrate as in protein film electrochemistry during spectral acquisition. The spectra reveal that the active site state known as Ni-L, observed in other NiFe hydrogenases only under illumination or at cryogenic temperatures, can be generated reversibly in the dark at ambient temperature under both turnover and non-turnover conditions. The observation that Ni-L is present at all potentials during turnover under H2 suggests that the final steps in the catalytic cycle of H2 oxidation by Hyd-1 involve sequential proton and electron transfer via Ni-L. A broadly applicable IR spectroscopic technique is presented for addressing electrode-adsorbed redox enzymes under fast catalytic turnover., (© 2015 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2015

7. Comparison of carbon materials as electrodes for enzyme electrocatalysis: hydrogenase as a case study.

Author

Quinson J, Hidalgo R, Ash PA, Dillon F, Grobert N, and Vincent KA

Subjects

Catalysis, Escherichia coli chemistry, Escherichia coli enzymology, Nanotubes, Carbon classification, Oxidation-Reduction, Surface Properties, Electrochemical Techniques, Escherichia coli Proteins chemistry, Hydrogen chemistry, Nanotubes, Carbon chemistry, Oxidoreductases chemistry

Abstract

We present a study of electrocatalysis by an enzyme adsorbed on a range of carbon materials, with different size, surface area, morphology and graphitic structure, which are either commercially available or prepared via simple, established protocols. We choose as our model enzyme the hydrogenase I from E. coli (Hyd-1), which is an active catalyst for H2 oxidation, is relatively robust and has been demonstrated in H2 fuel cells and H2-driven chemical synthesis. The carbon materials were characterised according to their surface area, surface morphology and graphitic character, and we use the electrocatalytic H2 oxidation current for Hyd-1 adsorbed on these materials to evaluate their effectiveness as enzyme electrodes. Here, we show that a variety of carbon materials are suitable for adsorbing hydrogenases in an electroactive configuration. This unified study provides insight into selection and design of carbon materials for study of redox enzymes and different applications of enzyme electrocatalysis.

Published

2014

8. H₂-driven cofactor regeneration with NAD(P)⁺-reducing hydrogenases.

Author

Lauterbach L, Lenz O, and Vincent KA

Subjects

Biocatalysis, Bioreactors microbiology, Bioreactors parasitology, Cupriavidus necator enzymology, Cupriavidus necator metabolism, Desulfovibrio enzymology, Desulfovibrio metabolism, Enzyme Stability, Enzymes, Immobilized metabolism, Oxidation-Reduction, Archaeal Proteins metabolism, Bacterial Proteins metabolism, Hydrogen metabolism, NAD metabolism, NADP metabolism, Oxidoreductases metabolism, Reducing Agents metabolism

Abstract

A large number of industrially relevant enzymes depend upon nicotinamide cofactors, which are too expensive to be added in stoichiometric amounts. Existing NAD(P)H-recycling systems suffer from low activity, or the generation of side products. H₂-driven cofactor regeneration has the advantage of 100% atom efficiency and the use of H₂ as a cheap reducing agent, in a world where sustainable energy carriers are increasingly attractive. The state of development of H₂-driven cofactor-recycling systems and examples of their integration with enzyme reactions are summarized in this article. The O₂-tolerant NAD⁺-reducing hydrogenase from Ralstonia eutropha is a particularly attractive candidate for this approach, and we therefore discuss its catalytic properties that are relevant for technical applications., (© 2013 The Authors Journal compilation © 2013 FEBS.)

Published

2013

9. Wiring an [FeFe]-hydrogenase with photosystem I for light-induced hydrogen production.

Author

Lubner CE, Knörzer P, Silva PJ, Vincent KA, Happe T, Bryant DA, and Golbeck JH

Subjects

Clostridium acetobutylicum enzymology, Electron Transport radiation effects, Hydrogenase chemistry, Iron-Sulfur Proteins chemistry, Models, Molecular, Photosystem I Protein Complex chemistry, Protein Conformation, Hydrogen metabolism, Hydrogenase metabolism, Iron-Sulfur Proteins metabolism, Light, Nanotechnology methods, Nanowires chemistry, Photosystem I Protein Complex metabolism

Abstract

A molecular wire is used to connect two proteins through their physiologically relevant redox cofactors to facilitate direct electron transfer. Photosystem I (PS I) and an [FeFe]-hydrogenase (H(2)ase) serve as the test bed for this new technology. By tethering a photosensitizer with a hydrogen-evolving catalyst, attached by Fe-S coordination bonds between the F(B) iron-sulfur cluster of PS I and the distal iron-sulfur cluster of H(2)ase, we assayed electron transfer between the two components via light-induced hydrogen generation. These hydrogen-producing nanoconstructs self-assemble when the PS I variant, the H(2)ase variant, and the molecular wire are combined.

Published

2010

10. Oxygen-tolerant H2 oxidation by membrane-bound [NiFe] hydrogenases of ralstonia species. Coping with low level H2 in air.

Author

Ludwig M, Cracknell JA, Vincent KA, Armstrong FA, and Lenz O

Subjects

Bacterial Proteins genetics, Bacterial Proteins metabolism, Catalytic Domain physiology, Cell Membrane genetics, Hydrogen metabolism, Hydrogenase genetics, Hydrogenase metabolism, Kinetics, Mutation, Oxidation-Reduction, Oxygen metabolism, Ralstonia growth & development, Bacterial Proteins chemistry, Cell Membrane enzymology, Hydrogen chemistry, Hydrogenase chemistry, Oxygen chemistry, Ralstonia enzymology

Abstract

Knallgas bacteria such as certain Ralstonia spp. are able to obtain metabolic energy by oxidizing trace levels of H2 using O2 as the terminal electron acceptor. The [NiFe] hydrogenases produced by these organisms are unusual in their ability to oxidize H2 in the presence of O2, which is a potent inactivator of most hydrogenases through attack at the active site. To probe the origin of this unusual O2 tolerance, we conducted a study on the membrane-bound hydrogenase from Ralstonia eutropha H16 and that of the closely related organism Ralstonia metallidurans CH34, which was purified using a new heterologous overproduction system. Direct electrochemical methods were used to determine apparent inhibition constants for O2 inhibition of H2 oxidation (K I(app)O2) for each enzyme. These values were at least 2 orders of magnitude higher than those of "standard" [NiFe] hydrogenases. Amino acids close to the active site were exchanged in the membrane-bound hydrogenase of R. eutropha H16 for those from standard hydrogenases to probe the role of individual residues in conferring O2 sensitivity. Michaelis constants for H2 (K M H2) were determined, and for some mutants these were increased more than 20-fold relative to the wild type. Mutations resulting in membrane-bound hydrogenase enzymes with increased K M H2 or decreased K I(app)O2 values were associated with impaired lithoautotrophic growth in the presence of high O2 concentrations.

Published

2009

11. Dynamic electrochemical investigations of hydrogen oxidation and production by enzymes and implications for future technology.

Author

Armstrong FA, Belsey NA, Cracknell JA, Goldet G, Parkin A, Reisner E, Vincent KA, and Wait AF

Subjects

Anaerobiosis, Bacteria enzymology, Bacterial Proteins metabolism, Carbon Dioxide metabolism, Catalytic Domain, Electrodes, Energy-Generating Resources, Enzymes, Immobilized chemistry, Enzymes, Immobilized metabolism, Hydrogen Sulfide metabolism, Hydrogenase chemistry, Oxidation-Reduction, Oxygen metabolism, Photochemical Processes, Platinum chemistry, Electrochemical Techniques, Hydrogen metabolism, Hydrogenase metabolism

Abstract

This tutorial review describes studies of hydrogen production and oxidation by biological catalysts--metalloenzymes known as hydrogenases--attached to electrodes. It explains how the electrocatalytic properties of hydrogenases are studied using specialised electrochemical techniques and how the data are interpreted to allow assessments of catalytic rates and performance under different conditions, including the presence of O2, CO and H2S. It concludes by drawing some comparisons between the enzyme active sites and platinum catalysts and describing some novel proof-of-concept applications that demonstrate the high activities and selectivities of these 'alternative' catalysts for promoting H2 as a fuel.

Published

2009

12. Hydrogen production under aerobic conditions by membrane-bound hydrogenases from Ralstonia species.

Author

Goldet G, Wait AF, Cracknell JA, Vincent KA, Ludwig M, Lenz O, Friedrich B, and Armstrong FA

Subjects

Aerobiosis, Air, Carbon Monoxide chemistry, Catalysis, Crystallography, X-Ray, Electrochemistry, Electrodes, Hydrogen-Ion Concentration, Models, Molecular, Oxidation-Reduction, Oxygen chemistry, Species Specificity, Time Factors, Hydrogen chemistry, Hydrogenase chemistry, Membranes, Artificial, Ralstonia enzymology

Abstract

Studies have been carried out to establish the ability of O2-tolerant membrane-bound [NiFe] hydrogenases (MBH) from Ralstonia sp. to catalyze H2 production in addition to H2 oxidation. These hydrogenases are not noted for H2-evolution activity, and this is partly due to strong product inhibition. However, when adsorbed on a rotating disk graphite electrode the enzymes produce H2 efficiently, provided the H2 product is continuously removed by rapidly rotating the electrode and flowing N2 through the gastight electrochemical cell. Electrocatalytic H2 production proceeds with minimal overpotentiala significant observation because lowering the overpotential (the electrochemically responsive activation barrier) is seen as crucial in developing small-molecule catalysts for H2 production. A mutant having a high KM for H2 oxidation did not prove to be a better H2 producer relative to the wild type, thus suggesting that weak binding of H2 does not itself confer a tendency to be a H2 producer. Inhibition by H2 is much stronger than inhibition by CO and, most significantly, even O2. Consequently, H2 can be produced sustainably in the presence of O2 as long as the H2 is removed continuously, thereby proving the feasibility for biological H2 production in air.

Published

2008

13. Enzymatic oxidation of H2 in atmospheric O2: the electrochemistry of energy generation from trace H2 by aerobic microorganisms.

Author

Cracknell JA, Vincent KA, Ludwig M, Lenz O, Friedrich B, and Armstrong FA

Subjects

Aerobiosis, Atmosphere, Electrochemistry, Energy Metabolism, Oxidation-Reduction, Bacteria, Aerobic enzymology, Hydrogen metabolism, Hydrogenase metabolism, Oxygen metabolism, Ralstonia enzymology

Published

2008

14. Electricity from low-level H2 in still air--an ultimate test for an oxygen tolerant hydrogenase.

Author

Vincent KA, Cracknell JA, Clark JR, Ludwig M, Lenz O, Friedrich B, and Armstrong FA

Subjects

Bioelectric Energy Sources, Electrochemistry, Hydrogen Peroxide chemistry, Oxidation-Reduction, Ralstonia enzymology, Reactive Oxygen Species chemistry, Air, Electricity, Hydrogen chemistry, Hydrogenase chemistry, Oxygen chemistry

Abstract

We demonstrate an extreme test of O(2) tolerance for a biological hydrogen-cycling catalyst: the generation of electricity from just 3% H(2) released into still, ambient air using an open fuel cell comprising an anode modified with the unusual hydrogenase from Ralstonia metallidurans CH34, that oxidizes trace H(2) in atmospheric O(2), connected via a film of electrolyte to a cathode modified with the fungal O(2) reductase, laccase.

Published

2006

15. Hydrogen cycling by enzymes: electrocatalysis and implications for future energy technology.

Author

Vincent KA, Cracknell JA, Parkin A, and Armstrong FA

Subjects

Carbon Monoxide chemistry, Carbon Monoxide metabolism, Carbon Monoxide pharmacology, Catalysis, Crystallography, X-Ray, Electrochemistry, Enzyme Inhibitors pharmacology, Hydrogenase antagonists & inhibitors, Models, Molecular, Oxidation-Reduction, Protein Structure, Tertiary, Electrons, Hydrogen chemistry, Hydrogen metabolism, Hydrogenase chemistry, Hydrogenase metabolism, Technology

Abstract

Hydrogenases provide an inspiration for future energy technologies. The active sites of these microbial enzymes contain Fe or Ni and Fe coordinated by CO and CN ligands: yet they have activities for hydrogen cycling that compare with Pt catalysts. Is there a future for enzymes in technological H2 cycling? There are obviously going to be disadvantages, perhaps overwhelming, as enzymes are notoriously fragile; yet what are the positive aspects and can we learn any chemistry that might be applied to produce the electrolytic and fuel cell catalysts of the future? We have developed a suite of novel electrochemical experiments to probe the chemistry of hydrogenases. The reactions are controlled and monitored at the surface of a small electrode, and characteristic catalytic properties are discernible from tiny amounts of sample material, so this approach can be used to search the microbial world for the best catalysts. Although electrochemistry does not provide structural information directly, it does give a "road map" by which to navigate the pathways and conditions that lead to particular states of the enzymes. This has prompted many interdisciplinary collaborations with other scientists who have provided microbiological, spectroscopic and structural contexts for this work. This article describes how these electrochemical experiments are set up, the data are analysed, and the results interpreted. We have determined mechanisms of catalysis, electron transfer, activation and inactivation, and defined important properties such as O2 tolerance and CO resistance in physical terms. Using an O2-tolerant hydrogenase, we have demonstrated a "proof of concept" miniature fuel cell that will run on a mixed H2/O2 feed in aqueous solution.

Published

2005

16. How Oxygen Attacks [FeFe] Hydrogenases from Photosynthetic Organisms

Author

Stripp, Sven T., Goldet, Gabrielle, Brandmayr, Caterina, Sanganas, Oliver, Vincent, Kylie A., Haumann, Michael, Armstrong, Fraser A., Happe, Thomas, and Buchanan, Bob B.

Published

2009

17. Enzyme-Modified Particles for Selective Biocatalytic Hydrogenation by Hydrogen-Driven NADH Recycling.

Author

Reeve, Holly A., Lauterbach, Lars, LENz, Oliver, and VincENt, Kylie A.

Subjects

NAD (Coenzyme), BIOCATALYSIS, HYDROGENATION, HYDROGEN, ENZYME stability

Abstract

We describe a new approach to selective H2-driven hydrogenation that exploits a sequence of enzymes immobilised on carbon particles. We used a catalyst system that comprised alcohol dehydrogenase, hydrogenase and an NAD+ reductase on carbon black to demonstrate a greater than 98 % conversion of acetophenone to phenylethanol. Oxidation of H2 by the hydrogenase provides electrons through the carbon for NAD+ reduction to recycle the NADH cofactor required by the alcohol dehydrogenase. This biocatalytic system operates over the pH range 6-8 or in un-buffered water, and can function at low concentrations of the cofactor (10 μ m NAD+) and at H2 partial pressures below 1 bar. Total turnover numbers >130 000 during acetophenone reduction indicate high enzyme stability, and the immobilised enzymes can be recovered by a simple centrifugation step and re-used several times. This offers a route to convenient, atom-efficient operation of NADH-dependent oxidoreductases for selective hydrogenation catalysis. [ABSTRACT FROM AUTHOR]

Published

2015

18. H2-driven cofactor regeneration with NAD( P)+-reducing hydrogenases.

Author

Lauterbach, Lars, Lenz, Oliver, and Vincent, Kylie A.

Subjects

REGENERATION (Biology), CATALYSIS, COFACTORS (Biochemistry), RALSTONIA eutropha, OXIDATION-reduction reaction, OXIDOREDUCTASES

Abstract

A large number of industrially relevant enzymes depend upon nicotinamide cofactors, which are too expensive to be added in stoichiometric amounts. Existing NAD( P) H-recycling systems suffer from low activity, or the generation of side products. H2-driven cofactor regeneration has the advantage of 100% atom efficiency and the use of H2 as a cheap reducing agent, in a world where sustainable energy carriers are increasingly attractive. The state of development of H2-driven cofactor-recycling systems and examples of their integration with enzyme reactions are summarized in this article. The O2-tolerant NAD+-reducing hydrogenase from Ralstonia eutropha is a particularly attractive candidate for this approach, and we therefore discuss its catalytic properties that are relevant for technical applications. [ABSTRACT FROM AUTHOR]

Published

2013

19. Oxidation of dilute H2 and H2/O2 mixtures by hydrogenases and Pt

Author

Woolerton, Thomas W. and Vincent, Kylie A.

Subjects

*HYDROGENASE, *PLATINUM compounds, *OXIDATION, *MIXTURES, *HYDROGEN, *GRAPHITE, *CARBON electrodes

Abstract

Abstract: Hydrogenase enzymes that allow micro-organisms to gain energy from oxidation of H2 undergo efficient electrocatalysis of H2 oxidation or production when adsorbed on a graphite rotating disk electrode [K.A. Vincent, A. Parkin, F.A. Armstrong, Chem. Rev. 107 (2007) 4366]. Combining potential sweeps or steps with precisely controlled gas exchanges is enabling us to build up a detailed understanding of the many factors that control the chemistry of nickel–iron membrane-bound hydrogenase (MBH) enzymes. The observation that the MBH enzymes from Ralstonia strains have extremely high affinity for H2 and continue oxidising H2 in the presence of O2 and CO has relevance for selective fuel cell catalysis [K.A. Vincent, J.A. Cracknell, J.R. Clark, M. Ludwig, O. Lenz, B. Friedrich, F.A. Armstrong, Chem. Commun. (2006) 5033; K.A. Vincent, J.A. Cracknell, O. Lenz, I. Zebger, B. Friedrich, F.A. Armstrong, Proc. Natl. Acad. Sci. U.S.A. 102 (2005) 16951], and this has led us to compare the ability of hydrogenases and platinum to oxidise low levels of H2 and mixtures of H2 and O2. We show that Pt is a poor catalyst for oxidation of sub-atmospheric levels of H2 compared to the MBH from Ralstonia eutropha H16, and that at a platinised electrode, H2 oxidation competes less favourably with reduction of O2 compared to the situation at hydrogenase-modified graphite. This should have implications for development of future selective energy catalysts able to concentrate the energy available from dilute H2. [Copyright &y& Elsevier]

Published

2009

20. Investigating and Exploiting the Electrocatalytic Properties of Hydrogenases.

Author

Vincent, Kylie A., Parkin, Alison, and Armstrong, Fraser A.

Subjects

*HYDROGENASE, *ELECTROCATALYSIS, *HYDROGEN, *OXIDATION, *FUEL cells

Abstract

The article reports a study on the electrocatalytic properties of hydrogenases. It intends to highlight the efficacy of hydrogenase as electrocatalysts in hydrogen technologies including new dihydrogen fuel cells, green dihydrogen production, and dihydrogen sensing. The authors emphasize that the study not only discloses the benefits of hydrogenase in future hydrogen technologies but also looks into the challenge of aerobic dihydrogen oxidation in biology.

Published

2007

21. Enzymatic Oxidation of H2 in Atmospheric O2: The Electrochemistry of Energy Generation from Trace H2 by Aerobic Microorganisms.

Author

Cracknell, James A., Vincent, Kylie A., Ludwig, Marcus, Lenz, Oliver, Friedrich, Bärbel, and Armstrong, Fraser A.

Subjects

*CHEMICAL research, *ENZYMATIC analysis, *HYDROGEN, *OXIDATION, *MICROORGANISMS, *ELECTROCHEMISTRY

Abstract

The article presents a research which examines the enzymatic oxidation of hydrogen (H)2 in atmospheric oxygen (O)2. In the electrochemical in vitro experiments, results revealed that a purified O2-tolerant hydrogenase can display substantial H2 oxidation activity in air. It outlines the electrochemistry of energy generation from trace H2 by aerobic microorganisms.

Published

2008