Electrified Nanoconfined Biocatalysis with Rapid Cofactor Recycling

Megarity, Clare F.; Siritanaratkul, Bhavin; Cheng, Beichen; Morello, Giorgio; Wan, Lei; Sills, Adam J.; Heath, Rachel S.; Turner, Nicholas J.; Armstrong, Fräser A.

doi:10.1002/cctc.201901245

Cited by 22 publications

(38 citation statements)

References 42 publications

(82 reference statements)

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“…The cyclic voltammograms-revealing how the steady-state catalytic velocity of the cascade varies with driving force-were obtained for a mixture of pyruvate, KHCO 3 , NH 4 Cl, NADP + , in the absence and presence of aspartate. They were measured after loading all the enzymes into a nanoporous layer of indium tin oxide (ITO) formed by depositing commercial nanoparticles electrophoretically onto a titanium foil support (area 1.89 cm 2 ITO layer, varying between 1 and 3 µm deep depending on the deposition time (2-10 min), comprises pores and cavities of less than 100 nm in diameter 33,35,36 . This procedure provides a fast, natural way of creating random nanospace (i.e., of ≪1 μm porosity) that can be energized electrochemically via the trapped FNR (E1), which serves as the transducer (Fig.…”

Section: Resultsmentioning

confidence: 99%

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The power of electrified nanoconfinement for energising, controlling and observing long enzyme cascades

2021

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Multistep enzyme-catalyzed cascade reactions are highly efficient in nature due to the confinement and concentration of the enzymes within nanocompartments. In this way, rates are exceptionally high, and loss of intermediates minimised. Similarly, extended enzyme cascades trapped and crowded within the nanoconfined environment of a porous conducting metal oxide electrode material form the basis of a powerful way to study and exploit myriad complex biocatalytic reactions and pathways. One of the confined enzymes, ferredoxin-NADP+ reductase, serves as a transducer, rapidly and reversibly recycling nicotinamide cofactors electrochemically for immediate delivery to the next enzyme along the chain, thereby making it possible to energize, control and observe extended cascade reactions driven in either direction depending on the electrode potential that is applied. Here we show as proof of concept the synthesis of aspartic acid from pyruvic acid or its reverse oxidative decarboxylation/deamination, involving five nanoconfined enzymes.

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Section: Resultsmentioning

confidence: 99%

“…The cascade is energized by direct electron transfer between the electrode and the FAD group of E1 (represented as yellow circles in Fig. 1b), which drives rapid and reversible interconversion of NADP + and NADPH and acts here as the tranducer [33][34][35][36][37][38] .…”

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The power of electrified nanoconfinement for energising, controlling and observing long enzyme cascades

2021

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“…A rapid electrochemical system that comprises nano-confined components deals with these challenges and also allows the assembly of enzyme cascades that can perform multiple steps in a single reactor. [18][19][20][21][22] In the 'electrochemical leaf', a nanoporous metal oxide electrode is used to entrap at least two enzymes operating in a cascade: one of these is ferredoxin-NADP + reductase (FNR), the small photosynthetic flavoenzyme responsible for channeling light-activated electrons into biosynthesis; [23][24] the second (E2) can be any of hundreds of NADP(H)-dependent dehydrogenases. The concept is depicted in Figure 1A.…”

Section: Introductionmentioning

confidence: 99%

“…[21] The nanopores lead to a high local concentration of the enzymes and restrict the escape of NADP(H) or (in an extended cascade) intermediates that are needed for the next stage. [21][22] The resulting overall rate and progress of a biocatalytic run are observed directly through the current that flows and the charge that is passed, respectively. The (FNR + E2 + …)@ITO/support material thus forms the basis for an inexpensive, easilyaccessible "plug-in" device able to drive, interactively, a potentially unlimited number of organic reactions depending on the identity of E2 and further enzymes.…”

Section: Introductionmentioning

confidence: 99%

Progress in Scaling up and Streamlining a Nanoconfined, Enzyme‐Catalyzed Electrochemical Nicotinamide Recycling System for Biocatalytic Synthesis

2020

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An electrochemically driven nicotinamide recycling system, referred to as the ‘electrochemical leaf’ has unique attributes that may suit it to the small‐scale industrial synthesis of high‐value chemicals. A complete enzyme cascade can be immobilized within the channels of a nanoporous electrode, allowing complex reactions to be energized, controlled and monitored continuously in real time. The electrode is easily prepared by depositing commercially available indium tin oxide (ITO) nanoparticles on a Ti support, resulting in a network of nanopores into which enzymes enter and bind. One of the enzymes is the photosynthetic flavoenzyme, ferredoxin NADP+ reductase (FNR), which catalyzes the quasi‐reversible electrochemical recycling of NADP(H) and serves as the transducer. The second enzyme is any NADP(H)‐dependent dehydrogenase of choice, and further enzymes can be added to build elaborate cascades that are driven in either oxidation or reduction directions through the rapid recycling of NADP(H) within the pores. In this Article, we describe the measurement of key enzyme/cofactor parameters and an essentially linear scale‐up from an analytical scale 4 mL reactor with a 14 cm2 electrode to a 500 mL reactor with a 500 cm2 electrode. We discuss the advantages (energization, continuous monitoring that can be linked to a computer, natural enzyme immobilization, low costs of electrodes and low cofactor requirements) and challenges to be addressed (optimizing minimal use of enzyme applied to the electrode).

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“…Co‐immobilizing enzymes of a multistep catalytic process locally concentrates the biocatalysts in a small volume. The small distances between the catalysts can provide an advantage by allowing the fast diffusive mass transport of intermediates and cofactors between active sites, leading to higher reaction rates [32] and thus enhanced electrocatalytic properties. [7] Such confinement effect was observed when comparing a system with Ccr co‐immobilized with FNR in the hydrogel, versus Ccr freely diffusing in solution (Figure S13C,D).…”

Section: Resultsmentioning

confidence: 99%

Bioelectrocatalytic Cofactor Regeneration Coupled to CO₂ Fixation in a Redox‐Active Hydrogel for Stereoselective C−C Bond Formation

et al. 2021

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The sustainable capture and conversion of carbon dioxide (CO2) is key to achieving a circular carbon economy. Bioelectrocatalysis, which aims at using renewable energies to power the highly specific, direct transformation of CO2 into value added products, holds promise to achieve this goal. However, the functional integration of CO2‐fixing enzymes onto electrode materials for the electrosynthesis of stereochemically complex molecules remains to be demonstrated. Here, we show the electricity‐driven regio‐ and stereoselective incorporation of CO2 into crotonyl‐CoA by an NADPH‐dependent enzymatic reductive carboxylation. Co‐immobilization of a ferredoxin NADP+ reductase and crotonyl‐CoA carboxylase/reductase within a 2,2′‐viologen‐modified hydrogel enabled iterative NADPH recycling and stereoselective formation of (2S)‐ethylmalonyl‐CoA, a prospective intermediate towards multi‐carbon products from CO2, with 92±6 % faradaic efficiency and at a rate of 1.6±0.4 μmol cm−2 h−1. This approach paves the way for realizing even more complex bioelectrocatalyic cascades in the future.

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Electrified Nanoconfined Biocatalysis with Rapid Cofactor Recycling

Cited by 22 publications

References 42 publications

The power of electrified nanoconfinement for energising, controlling and observing long enzyme cascades

The power of electrified nanoconfinement for energising, controlling and observing long enzyme cascades

Progress in Scaling up and Streamlining a Nanoconfined, Enzyme‐Catalyzed Electrochemical Nicotinamide Recycling System for Biocatalytic Synthesis

Bioelectrocatalytic Cofactor Regeneration Coupled to CO₂ Fixation in a Redox‐Active Hydrogel for Stereoselective C−C Bond Formation

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Electrified Nanoconfined Biocatalysis with Rapid Cofactor Recycling

Cited by 22 publications

References 42 publications

The power of electrified nanoconfinement for energising, controlling and observing long enzyme cascades

The power of electrified nanoconfinement for energising, controlling and observing long enzyme cascades

Progress in Scaling up and Streamlining a Nanoconfined, Enzyme‐Catalyzed Electrochemical Nicotinamide Recycling System for Biocatalytic Synthesis

Bioelectrocatalytic Cofactor Regeneration Coupled to CO2 Fixation in a Redox‐Active Hydrogel for Stereoselective C−C Bond Formation

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About

Bioelectrocatalytic Cofactor Regeneration Coupled to CO₂ Fixation in a Redox‐Active Hydrogel for Stereoselective C−C Bond Formation