Reeve, Holly A.Lauterbach, LarsLenz, OliverVincent, Kylie A.2017-07-142017-07-1420151867-3880https://depositonce.tu-berlin.de/handle/11303/6492http://dx.doi.org/10.14279/depositonce-6000We describe a new approach to selective H-2-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 H-2 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 (10m NAD(+)) and at H-2 partial pressures below 1bar. Total turnover numbers >130000 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.en540 Chemie und zugeordnete Wissenschaftenbiocatalysisbiotransformationsenzyme catalysishydrogenationheterogeneous catalysisArticle1867-3899