The Journal of biological chemistry
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Activation by phenylalanine and reduction by the co-factor (6R)-tetrahydrobiopterin (BH4) are required for formation of active liver phenylalanine hydroxylase. This work describes effects of the activation and redox state on substrate and effector recognition of this enzyme, it establishes relationships among the pterin and phenylalanine binding sites on the different forms of the enzyme, and it provides a quantitative description of the enzyme's presumptive regulatory and catalytic sites. BH4, 7,8-dihydrobiopterin (BH2), 6-methyltetrahydropterin, and 5-deaza-6-methyltetrahydropterin were found to bind to unactivated phenylalanine hydroxylase with a stoichiometry of 1/enzyme subunit and with hyperbolic kinetics; all appear to compete for the same binding site on the enzyme, and all appear to bind in the proximity of, but not to, the enzyme's non-heme iron. ⋯ The pterin- and phenylalanine-binding sites on activated phenylalanine hydroxylase appear to be part of the enzyme's active site. Despite large effects on substrate binding, neither chelator binding ability nor solvent accessibility of the iron are affected by activation; activation appears to affect the nearby environment of the enzyme's iron but not the iron itself. Studies of oxidized and reduced phenylalanine hydroxylase indicate that the redox state is not a major determinant of pterin and phenylalanine association with enzyme.
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Tetrahydropterins react with phenylalanine hydroxylase at a redox site, a regulatory site, and the catalytic site, but neither the properties of nor relationships among these sites are well understood. We have studied the redox site using the fluorescent iron chelators 2,3-dihydroxynaphthalene and bathophenanthroline; these compounds act as site-specific reporter groups for reactions on oxidized and reduced enzyme, respectively. The chelators bind reversibly and specifically to the enzyme's iron with 1:1 stoichiometry, high affinity (Kd values approximately 1 nM), and complete quenching of their own fluorescence. ⋯ Studies of the reaction of tetrahydrobiopterin (BH4) at the enzyme's redox site showed that BH4 reduces the enzyme more slowly than 6-methyltetrahydropterin under catalytic and non-catalytic conditions. Reduction occurs at a distinct site whose binding determinants and reaction characteristics are different from those of the BH4 regulatory or catalytic sites, and phenylalanine-activated enzyme is reduced more rapidly than unactivated enzyme. In reducing phenylalanine activated enzyme, BH4 donates one electron/subunit (1/iron atom); the reduction kinetics suggest a trihydrobiopterin-free radical as a reaction intermediate.