Nucleophilic addition reactions of free and enzyme-bound deazaflavin.

DeazaFMN-containing glycolate oxidase has been prepared and shown to catalyze the stereospecific transfer of the alpha-hydrogen from substrate to enzyme-bound deazaFMN. The reaction of sulfite, cyanide, and hydroxylamine with several deazaflavin-containing enzymes (glycolate oxidase, D-amino acid oxidase, glucose oxidase, N-methylglutamate synthetase) and free deazaFMN has been examined. All the deazaflavin systems tested form reversible 1:1 complexes with sulfite and cyanide. The pH dependence of the reaction of free deazaFMN with cyanide indicates that cyanide anion is the reacting nucleophile. Hydroxylamine complexes are formed with deazaFMN glycolate oxidase and deazaFAD glucose oxidase. The effectiveness of the various nucleophilic reagents in complex formation decreases in the following order: sulfite greater than cyanide greater than hydroxylamine. The relative stability observed for the sulfite and cyanide complexes formed with various deazaflavin systems (glycolate oxidase greater than D-amino acid oxidase greater than free deazaFMN) follows the same trend observed for the stability of the sulfite complexes formed with the corresponding flavin system. A correlation is also observed between the reduction potential (E'o) of the deazaflavin system (glycolate oxidase (- 170 mV) greater than D-amino acid oxidase (-240 mV) greater than free deazaFMN (-178 mV) and the stability of the deazaflavin-nucleophile complexes. The following evidence indicates that deazaflavin systems are generally more susceptible toward nucleophilic attack than corresponding flavin system: (a) with the exception of glucose oxidase, the dissociation constants for the deazaflavin-sulfite complexes are at least 1 order of magnitude less than the corresponding flavin sulfite complexes; (b) the least reactive nucleophile, hydroxylamine, does not form a complex with any of the flavin systems. In the case of cyanide, a complex is formed only with native glycolate oxidase, which is the flavin-containing system most susceptible to attack by the more reactive sulfite. Formation of the various (deaza)flavin-nucleophile complexes is characterized by a bleaching of the longer wavelength absorption band of the chromophore and increases in absorption below the isosbestic point of the reaction in the near-ultraviolet region of the spectrum. These results are consistent with the formation of covalent adducts via attack of the various nucleophiles at position 5 of (deaza)flavin. The reaction with cyanide provides the first example of a reversible addition of carbanion to enzyme-bound (deaza)flavin.