An Unexpected Role for the Active Site Base in Cofactor Orientation and Flexibility in the Copper Amine Oxidase from Hansenula polymorpha

Abstract

The role of the active site aspartate base in the aminotransferase mechanism of the copper amine oxidase from the yeast Hansenula polymorpha has been probed by site-directed mutagenesis. The D319E mutant catalyzes the oxidation of methylamine and phenethylamine, but not that of benzylamine. k_cat/K_m for methylamine is found to be 80-fold reduced compared to that of the wild type. Viscosogen and substrate and solvent deuteration have no effect on this parameter for D319E, which is suggestive of limitation of k_cat/K_m by a conformational change. This conformational change is proposed to be the movement of the cofactor into a productive orientation upon the binding of substrate. In the absence of substrate, a flipped cofactor orientation is likely, on the basis of resonance Raman evidence that the C5 carbonyl of the cofactor is less solvent accessible than the C3 hydrogen. k_cat for D319E methylamine oxidase is reduced 200-fold compared to that of the wild type and is unaffected by substrate deuteration, but displays a substantial solvent isotope effect. A 428 nm absorbance is evident under conditions of saturating methylamine and oxygen with D319E. The D319N mutant is observed to produce a similar absorbance at 430 nm when treated with ammonia despite the fact that this mutant has no amine oxidase activity. Resonance Raman spectroscopy indicates the formation of a covalent ammonia adduct and identifies it as the deprotonated iminoquinone. In contrast, when the D319E mutant is reacted with ammonia, it gives predominantly a 340−350 nm species. This absorbance is ascribed to a localization of the cofactor oxyanion induced by binding of the cation at the active site and not to covalent adduct formation. Resonance Raman spectroscopic examination of the steady state species of D319E methylamine oxidation, in combination with the kinetic data, indicates that the 428 nm species is the deprotonated iminoquinone produced upon reoxidation of the reduced cofactor. A model is proposed in which a central role of the active site base is to position the free cofactor and several enzyme intermediates for optimal activity.