Influence of 8.alpha.-imidazole substitution of the FMN cofactor on the rate of electron transfer from the neutral semiquinones of two flavodoxins to cytochrome c
The effects of substituting an imidazole ring onto the 8 alpha-position of the FMN cofactor on the kinetics of electron transfer from the neutral semiquinone forms of Azotobacter and Clostridium flavodoxins to oxidized horse heart cytochrome c have been investigated by stopped-flow methods. Although 8 alpha-substitution does not alter the mechanistic pathway of the reaction, the rate constants are decreased by factors of 10-30, without significant changes in the equilibrium association constants of the intermediate electron-transfer complexes. Protonation of the imidazole ring further decreases the observed second-order rate constants for the electron-transfer reaction by factors of 20-50. The pKa values for the 8 alpha-imidazole ring in both flavodoxin semiquinones were determined to be approximately 7. In contrast, the reactions of the native flavodoxins with cytochrome c are pH independent. The results are consistent with a structural model of the intermediate complex [Simondsen, R. P., Weber, P. C., Salemme, F. R., & Tollin, G. (1982) Biochemistry 21, 6366-6375], which postulates a close fit between the exposed dimethylbenzene ring of the FMN and the heme edge within a nonpolar interface region. The results further indicate that electron transfer is uncoupled from proton transfer, that it is the rate-limiting step, and that it occurs prior to proton transfer at all pH values. Finally, the results do not provide support for a direct role of the imidazole ring in the facilitation of one-electron transfer in those enzymes containing 8 alpha-N-histidylflavin coenzymes.