Robust Carbon-Based Electrodes for Hydrogen Evolution through Site-Selective Covalent Attachment of an Artificial Metalloenzyme

Treviño, Regina E.; Slater, Jeffrey W.; Shafaat, Hannah S.

doi:10.1021/acsaem.0c02069

Cited by 12 publications

(21 citation statements)

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“…[NiFe 3 S 4 ] Fd was adsorbed to the surface of a pyrolytic graphite electrode (PGE). To mitigate the electrostatic repulsion expected between the negatively charged graphite surface and Fd (p I ∼ 3.6) and stabilize films, the coadsorbant neomycin was used. , Cyclic voltammetry revealed a reversible electrochemical transition with E 1/2 = +6 ± 4 mV [vs normal hydrogen electrode (NHE)] at pH 7 and a small peak separation of 31 mV between the anodic and cathodic waves (Figure A, inset). Analogous to [Fe 4 S 4 ] Fd, this midpoint potential is independent of the pH (Figure S2).…”

Section: Resultsmentioning

confidence: 99%

Reversible Electron Transfer and Substrate Binding Support [NiFe₃S₄] Ferredoxin as a Protein-Based Model for [NiFe] Carbon Monoxide Dehydrogenase

Lewis

Shafaat

2021

Inorg. Chem.

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The nickel–iron carbon monoxide dehydrogenase (CODH) enzyme catalyzes the reversible and selective interconversion of carbon dioxide (CO2) to carbon monoxide (CO) with high rates and negligible overpotential. Despite decades of research, many questions remain about this complex metalloenzyme system. A simplified model enzyme could provide substantial insight into biological carbon cycling. Here, we demonstrate reversible electron transfer and binding of both CO and cyanide, a substrate and an inhibitor of CODH, respectively, in a Pyrococcus furiosus (Pf) ferredoxin (Fd) protein that has been reconstituted with a nickel–iron sulfide cluster ([NiFe3S4] Fd). The [NiFe3S4] cluster mimics the core of the native CODH active site and thus serves as a protein-based structural model of the CODH subsite. Notably, despite binding cyanide, no CO binding is observed for the physiological [Fe4S4] clusters in Pf Fd, providing chemical rationale underlying the evolution of a site-differentiated cluster for substrate conversion in native CODH. The demonstration of a substrate-binding metalloprotein model of CODH sets the stage for high-resolution spectroscopic and mechanistic studies correlating the subsite structure and function, ultimately guiding the design of anthropogenic catalysts that harness the advantages of CODH for effective CO2 reduction.

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Section: Resultsmentioning

confidence: 99%

Reversible Electron Transfer and Substrate Binding Support [NiFe₃S₄] Ferredoxin as a Protein-Based Model for [NiFe] Carbon Monoxide Dehydrogenase

Lewis

Shafaat

2021

Inorg. Chem.

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“…Expression and purification of chemically reconstituted rubredoxin as well as construction of the N07P mutant were performed as described previously. ,,, All expression was carried out under aerobic growth conditions.…”

Section: Methodsmentioning

confidence: 99%

“…The NiRd enzyme generated by in vivo metalation is indistinguishable from NiRd prepared through the standard metal substitution procedure, as evidenced by optical spectroscopy and protein electrochemistry (Figure G). Electrocatalysis by NiRd shows a distinct voltammetric signature, with currents in the cathodic region of the voltammogram exhibiting a linear response with increasing applied potential, characteristic of slow electron transfer relative to chemical processes, and parallel waves in the cathodic and anodic directions, indicating an absence of low-potential inactivation processes. , The currents directly correspond to the catalytic H 2 evolution activity, while the position of the onset of the catalytic current indicates the overpotential for the reaction. In the purified wild-type (WT) NiRd, the onset potential for catalysis occurs at −800 mV vs NHE at pH 4.0 (Figure G).…”

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In Vivo Assembly of a Genetically Encoded Artificial Metalloenzyme for Hydrogen Production

et al. 2021

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The genetic encoding of artificial enzymes represents a substantial advantage relative to traditional molecular catalyst optimization, as laboratory-based directed evolution coupled with high-throughput screening methods can provide rapid development and functional characterization of enzyme libraries. However, these techniques have been of limited utility in the field of artificial metalloenzymes due to the need for in vitro cofactor metalation. Here, we report the development of methodology for in vivo production of nickel-substituted rubredoxin, an artificial metalloenzyme that is a structural, functional, and mechanistic mimic of the [NiFe] hydrogenases. Direct voltammetry on cell lysate establishes precedent for the development of an electrochemical screen. This technique will be broadly applicable to the in vivo generation of artificial metalloenzymes that require a non-native metal cofactor, offering a route for rapid enzyme optimization and setting the stage for integration of artificial metalloenzymes into biochemical pathways within diverse hosts.

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“…[1,2] One significant issue in electrolysis and photocatalysis is the diffusion-limited transport of the catalytic centre to the electrode, that is necessary for an effective electron transfer. [3,4] Immobilizing [FeFe] H 2 ase enzymes or model complexes on the electrode surface to attain chemically modified electrodes were realized by electrostatic adsorption, [5] embedding in redoxactive hydrogels or polymers, [6] absorption into mesoporous electrodes, [7] reduction of diazonium salt spacers on carbon electrodes, [8,9] by carboxylic acid group on fluorine-doped tin oxide (FTO) or nickel oxide electrodes, [10,11] and thiol spacer groups on gold electrodes, with a functional moieties for further modification with the [FeFe] H 2 ase mimic or enzyme, amongst others. [4,12] However, [FeFe] H 2 ase mimics attached to electrodes lack consistency and high activity during the catalytic process, due to their sensitivity regarding high pH values or oxygen and irreversible electrocatalytic behaviour.…”

Section: Introductionmentioning

confidence: 99%

Synthesis of [FeFe] Hydrogenase Mimics with Lipoic acid and its Selenium Analogue as Anchor Groups

et al. 2023

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FeFe] hydrogenase (H 2 ase) mimicking complexes containing lipoic and selenolipoic acid moieties connected to 2-hydroxy-1,3-dithiopropane and 2-hydroxy-1,3-diselenopropane bridging ligands were synthesized and characterized using different spectroscopic methods. X-ray diffraction analysis was utilized to determine the molecular structure of a triphenylphosphane substituted analogue. Cyclic voltammetry (CV) investigations on the redox chemistry in presence and absence of acetic acid (AcOH) revealed differing behaviours among the mimics. IR spectroelectrochemistry (IR SEC) enabled deeper insights of structural changes during electrochemical measurements. The elaboration of surface confined systems was studied in preliminary experiments. CV experiments showed that the lipoic acid derivatives of the [FeFe] H 2 ase mimics formed wellorganized self-assembled monolayers (SAMs) on Pt electrodes, a promising result for future work.

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Robust Carbon-Based Electrodes for Hydrogen Evolution through Site-Selective Covalent Attachment of an Artificial Metalloenzyme

Cited by 12 publications

References 70 publications

Reversible Electron Transfer and Substrate Binding Support [NiFe₃S₄] Ferredoxin as a Protein-Based Model for [NiFe] Carbon Monoxide Dehydrogenase

Reversible Electron Transfer and Substrate Binding Support [NiFe₃S₄] Ferredoxin as a Protein-Based Model for [NiFe] Carbon Monoxide Dehydrogenase

In Vivo Assembly of a Genetically Encoded Artificial Metalloenzyme for Hydrogen Production

Synthesis of [FeFe] Hydrogenase Mimics with Lipoic acid and its Selenium Analogue as Anchor Groups

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Robust Carbon-Based Electrodes for Hydrogen Evolution through Site-Selective Covalent Attachment of an Artificial Metalloenzyme

Cited by 12 publications

References 70 publications

Reversible Electron Transfer and Substrate Binding Support [NiFe3S4] Ferredoxin as a Protein-Based Model for [NiFe] Carbon Monoxide Dehydrogenase

Reversible Electron Transfer and Substrate Binding Support [NiFe3S4] Ferredoxin as a Protein-Based Model for [NiFe] Carbon Monoxide Dehydrogenase

In Vivo Assembly of a Genetically Encoded Artificial Metalloenzyme for Hydrogen Production

Synthesis of [FeFe] Hydrogenase Mimics with Lipoic acid and its Selenium Analogue as Anchor Groups

Contact Info

Product

Resources

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Reversible Electron Transfer and Substrate Binding Support [NiFe₃S₄] Ferredoxin as a Protein-Based Model for [NiFe] Carbon Monoxide Dehydrogenase

Reversible Electron Transfer and Substrate Binding Support [NiFe₃S₄] Ferredoxin as a Protein-Based Model for [NiFe] Carbon Monoxide Dehydrogenase