In living cells, redox chains rely on nanoconfinement using tiny enclosures, such as the mitochondrial matrix or chloroplast stroma, to concentrate enzymes and limit distances that nicotinamide cofactors and other metabolites must diffuse. In a chemical analogue exploiting this principle, nicotinamide adenine dinucleotide phosphate (NADPH) and NADP
+
are cycled rapidly between ferredoxin–NADP
+
reductase and a second enzyme—the pairs being juxtaposed within the 5–100 nm scale pores of an indium tin oxide electrode. The resulting electrode material, denoted (FNR+E2)@ITO/support, can drive and exploit a potentially large number of enzyme‐catalysed reactions.
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.
Reduction
of CO2 and its direct entry into organic chemistry
is achieved efficiently and in a highly visible way using a metal
oxide electrode in which two enzyme catalysts, one for electrochemically
regenerating reduced nicotinamide adenine dinucleotide phosphate and
the other for assimilating CO2 and converting pyruvate
(C3) to malate (C4), are entrapped within its nanopores. The resulting
reversible electrocatalysis is exploited to construct a solar CO2 reduction/water-splitting device producing O2 and
C4 with high faradaic efficiency.
In living cells, the overall rates of catalytic reaction chains (cascades) are massively enhanced by nanoconfinement of enzymes in tiny enclosed volumes: presented in such a way, interdependent catalysts are highly concentrated, and distances (active site‐to‐active site) across which intermediates and cofactors must diffuse, may be tiny. In a parallel technology exploiting this principle, enzyme cascades are powered, amplified, and monitored in real time as they work in concert, being nanoconfined within the pores of an electrically conductive metal oxide electrode. The technology, nicknamed the electrochemical leaf, mimics chloroplast biosynthesis by exploiting nicotinamide adenine dinucleotide (NADP(H)) recycling catalysed by the flavoenzyme, ferredoxin NADP+ reductase (FNR). Adsorbed on the inner walls of the nanopores, FNR rapidly transfers electrons between the electrode and NADP(H). This activity is coupled to an oxidoreductase enzyme, also nanoconfined within the pores, which recycles the cofactor and selectively synthesises a desired product or senses an analyte. Use of catalyst and cofactor is very efficient. The technology is simple, inexpensive and adaptable, and scalable to both microscopic levels (diagnostics) and macroscopic levels (organic synthesis). Whereas native FNR is specific for NADP(H), the technology can be extended by genetic engineering to include NAD(H) as recycling cofactor.
Electron transport, mediated by NDA2 in H2-producing C. reinhardtii cells, shifts redox equilibria between the plastoquinone pool and PSII, and is observed as a transient fluorescence wave after a single flash.
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