Structural insight into the active site of mushroom tyrosinase using phenylbenzoic acid derivatives.

So far, many inhibitors of tyrosinase have been discovered for cosmetic and clinical agents. However, the molecular mechanisms underlying the inhibition in the active site of tyrosinase have not been well understood. To explore this problem, we examined here the inhibitory effects of 4'-hydroxylation and methoxylation of phenylbenzoic acid (PBA) isomers, which have a unique scaffold to inhibit mushroom tyrosinase. The inhibitory effect of 3-PBA, which has the most potent inhibitory activity among the isomers, was slightly decreased by 4'-hydroxylation and further decreased by 4'-methoxylation against mushroom tyrosinase. Surprisingly, 4'-hydroxylation but not methoxylation of 2-PBA appeared inhibitory activity. On the other hand, both 4'-hydroxylation and methoxylation of 4-PBA increased the inhibitory activity against mushroom tyrosinase. In silico docking analyses using the crystallographic structure of mushroom tyrosinase indicated that the carboxylic acid or 4'-hydroxyl group of PBA derivatives could chelate with cupric ions in the active site of mushroom tyrosinase, and that the interactions of Asn260 and Phe264 in the active site with the adequate-angled biphenyl group are involved in the inhibitory activities of the modified PBAs, by parallel and T-shaped π-π interactions, respectively. Furthermore, Arg268 could fix the angle of the aromatic ring of Phe264, and Val248 is supposed to interact with the inhibitors as a hydrophobic manner. These results may enhance the structural insight into mushroom tyrosinase for the creation of novel tyrosinase inhibitors.

Discovery of a new type of scaffold for the creation of novel tyrosinase inhibitors.

Tyrosinase is known as the key enzyme for melanin biosynthesis, which is effective in preventing skin injury by ultra violet (UV). In past decades, tyrosinase has been well studied in the field of cosmetics, medicine, agriculture and environmental sciences, and a lot of tyrosinase inhibitors have been developed for their needs. Here, we searched for new types of tyrosinase inhibitors and found phenylbenzoic acid (PBA) as a unique scaffold. Among three isomers of PBA, 3-phenylbenzoic acid (3-PBA) was revealed to be the most potent inhibitor against mushroom tyrosinase (IC50=6.97µM, monophenolase activity; IC50=36.3µM, diphenolase activity). The kinetic studies suggested that the apparent inhibition modes for the monophenolase and diphenolase activities were noncompetitive and mixed type inhibition, respectively. Analyses by in silico docking studies using the crystallographic structure of mushroom tyrosinase indicated that the carboxylic acid group of the 3-PBA could adequately bind to two cupric ions in the tyrosinase. To prove this hypothesis, we examined the effect of modification of the carboxylic acid group of the 3-PBA on its inhibitory activity. As expected, the esterification abrogated the inhibitory activity. These observations suggest that 3-PBA is a useful lead compound for the generation of novel tyrosinase inhibitors and provides a new insight into the molecular basis of tyrosinase catalytic mechanisms.