Characterization of Carboxylic Acid Reductases for Biocatalytic Synthesis of Industrial Chemicals

Carboxylic acid reductases (CARs) catalyze the reduction of a broad range of carboxylic acids into aldehydes, which can serve as common biosynthetic precursors to many industrial chemicals. This work presents the systematic biochemical characterization of five carboxylic acid reductases from different microorganisms, including two known and three new ones, by using a panel of short‐chain dicarboxylic acids and hydroxy acids, which are common cellular metabolites. All enzymes displayed broad substrate specificities. Higher catalytic efficiencies were observed when the carbon chain length, either of the dicarboxylates or of the terminal hydroxy acids, was increased from C2 to C6. In addition, when substrates of the same carbon chain length are compared, carboxylic acid reductases favor hydroxy acids over dicarboxylates as their substrates. Whole‐cell bioconversions of eleven carboxylic acid substrates into the corresponding alcohols were investigated by coupling the CAR activity with that of an aldehyde reductase in Escherichia coli hosts. Alcohol products were obtained in yields ranging from 0.5 % to 71 %. The de novo stereospecific biosynthesis of propane‐1,2‐diol enantiomer was successfully demonstrated with use of CARs as the key pathway enzymes. E. coli strains accumulated 7.0 mm (R)‐1,2‐PDO (1.0 % yield) or 9.6 mm (S)‐1,2‐PDO (1.4 % yield) from glucose. This study consolidates carboxylic acid reductases as promising enzymes for sustainable synthesis of industrial chemicals. Dream CARs: Carboxylic acid reductases (CARs) from different sources were characterized with a panel of short‐chain dicarboxylic acids and hydroxy acids. Whole‐cell bioconversions of eleven of these substrates into the corresponding alcohols, based on coupling CAR activity with an aldehyde reductase in E. coli, were investigated. The de novo stereospecific biosynthesis of propane‐1,2‐diol enantiomers was successfully demonstrated.