Copper-Oxygen Dynamics in the Tyrosinase Mechanism.
Nobutaka FujiedaKyohei UmakoshiYuta OchiYosuke NishikawaSachiko YanagisawaMinoru KuboGenji KurisuShinobu ItohPublished in: Angewandte Chemie (International ed. in English) (2020)
The dinuclear copper enzyme, tyrosinase, activates O2 to form a (μ-η2 :η2 -peroxido)dicopper(II) species, which hydroxylates phenols to catechols. However, the exact mechanism of phenolase reaction in the catalytic site of tyrosinase is still under debate. We herein report the near atomic resolution X-ray crystal structures of the active tyrosinases with substrate l-tyrosine. At their catalytic sites, CuA moved toward l-tyrosine (CuA1 → CuA2), whose phenol oxygen directly coordinates to CuA2, involving the movement of CuB (CuB1 → CuB2). The crystal structures and spectroscopic analyses of the dioxygen-bound tyrosinases demonstrated that the peroxide ligand rotated, spontaneously weakening its O-O bond. Thus, the copper migration induced by the substrate-binding is accompanied by rearrangement of the bound peroxide species so as to provide one of the peroxide oxygen atoms with access to the phenol substrate's ϵ carbon atom.