Phenylacetaldehyde reductase (PAR) is suitable for the conversion of various aryl ketones and 2-alkanones to corresponding chiral alcohols. 2-Propanol acts as a substrate solvent and hydrogen donor of coupled cofactor regeneration during the conversion of substrates catalyzed by PAR. To improve the conversion efficiency in high concentrations of substrate and 2-propanol, selection of a PAR mutant library and the subsequent rearrangement of mutations were attempted. With only a single selection round and following the manual combination of advantageous mutations, PAR was successfully adapted for the conversion of high concentrations of substrate with concentrated 2-propanol. This method will be widely applicable for the engineering of enzymes potentially valuable for industry.The demand for enzymes in the chemical industry has expanded rapidly. Most enzymes can catalyze reactions at room temperature in a mild aqueous solution and have great substrate, stereo-, regio-, and chemoselectivity (12,15,16). Such properties are ideal for fine chemical production, particularly as chiral drug intermediates and agrochemicals.Alcohol dehydrogenase (ADH) (EC 1.1.1.1) can catalyze the asymmetric reduction of aldehyde or ketone to chiral alcohols. Phenylacetaldehyde reductase (PAR) from styrene-assimilating bacteria Rhodococcus sp. (formerly identified as Corynebacterium sp.) ST-10 belongs to the family of zinc-containing medium-chain ADHs (8). PAR has broad substrate specificity and catalyzes asymmetric reduction at high enantioselectivity in an NADH-dependent manner (8-10).Various examples of ADH applications for asymmetric reduction have been reported that use a cofactor regeneration system with additional enzymes such as formate dehydrogenase or glucose dehydrogenase (15). Recent reports have used the advantage of ADHs for NADH self regeneration with secondary alcohols as hydrogen donors (13, 21). We previously reported the ability of PAR to reduce various carbonyl compounds coupled with NADH self regeneration in the presence of 2-propanol as a proton donor (8). 2-Propanol can also profitably act as a solvent for the PAR substrates that cannot dissolve in aqueous media. However, at high concentrations of 2-propanol, the efficiency of substrate conversion by PAR clearly fell. Consequently, the conversion yields with high substrate concentrations were relatively low and insufficient for industrial application.Here, we attempted to engineer PAR that can operate in relatively high concentrations of 2-propanol (Ͼ20% [vol/vol]) to achieve efficient conversion of concentrated substrates without altering the substrate specificity. Using our method with the combination of advantageous mutations, PAR was successfully improved with six amino acid replacements with significant enhancement of the substrate conversion. Although relative yield of conversion at high concentration of 2-propanol was enhanced, little change of substrate specificity was observed.
MATERIALS AND METHODSMaterials. All chemicals were of reagent grade. Taq DNA poly...