Recombinant tyrosinase from Streptomyces avermitilis MA4680, MelC2 (gi:499291317), was heterologously expressed in Escherichia coli BL21 (DE3). The expression level of active MelC2 was increased by the codon-optimized MelC1 caddie protein (KP198295.1). By performing saturation mutagenesis of the Y91 residue of MelC1, it was found that aromatic residues such as Y, F, and W at the 91st position help produce a correctly folded conformation of MelC2. The recombinant MelC2 was utilized as a biocatalyst to convert trans-resveratrol into piceatannol. In order to improve the product yield through suppression of the formation of melanin, a by-product, an increase in the ratio of monooxygenation (k (1)) to dioxygenation (k (2)) of MelC2 is desirable. This was achieved by a combination of protein engineering and regeneration of NADH with glucose dehydrogenase (GDH). Saturation mutagenesis was performed at 15 residues within 8- radius from copper ions of MelC2. A total of 2760 mutants were examined (99.7 % probability for NNK codon) and I41Y, a mutant, was screened. The ratio of k (1) to k (2) of the mutant increased sevenfold on tyrosine and fivefold on resveratrol, when compared to wild-type MelC2. As a result, the overall product yield from 500 mu M resveratrol in 50-mL reaction was 15.4 % (77.4 mu M piceatannol), 1.7 times higher than wild type. When I41Y was incorporated with the NADH regeneration system, the total product yield was 58.0 %, an eightfold increase (290.2 mu M of piceatannol).