Improved strategies for electrochemical 1,4-NAD(P)H2 regeneration: A new era of bioreactors for industrial biocatalysis

Industrial enzymatic reactions requiring 1,4-NAD(P)H₂ to perform redox transformations often require convoluted coupled enzyme regeneration systems to regenerate 1,4-NAD(P)H₂ from NAD(P) and recycle the cofactor for as many turnovers as possible. Renewed interest in recycling the cofactor via electrochemical means is motivated by the low cost of performing electrochemical reactions, easy monitoring of the reaction progress, and straightforward product recovery. However, electrochemical cofactor regeneration methods invariably produce adventitious reduced cofactor side products which result in unproductive loss of input NAD(P). We review various literature strategies for mitigating adventitious product formation by electrochemical cofactor regeneration systems, and offer insight as to how a successful electrochemical bioreactor system could be constructed to engineer efficient 1,4-NAD(P)H₂-dependent enzyme reactions of interest to the industrial biocatalysis community.     

The primary acid product of DPNH

Analysis of the proton magnetic resonance spectra obtained at 220 MHz confirms the axial conformation of the C-6 hydroxyl in the model primary acid product 1-n-(2,6-dichlorobenzyl)-6-hydroxy-1,4,5,6-tetrahydronicotinamide. In the primary acid product of DPNH however the reaction occurs stereospecifically with the substitution at the C-6 position equatorial and on the B-side of the pyridine ring and the C-4A proton axial. A cyclic structure α,O^2′-6B cyclotetrahydronicotinamide is proposed for the primary acid product of DPNH, formed by epimerization of βDPNH to the α configuration followed by protonation at C-5 and subsequent attack of the ribose C-2′-OH on the C-6 position forming a new five membered ring.