INTRAMOLECULAR ELECTRON-TRANSFER IN YEAST FLAVOCYTOCHROME B(2) UPON ONE-ELECTRON PHOTOOXIDATION OF THE FULLY REDUCED ENZYME EVIDENCE FOR REDOX STATE CONTROL OF HEME-FLAVIN COMMUNICATION

Flavocytochrome b(2), which has been fully reduced using L-lactate, can be rapidly oxidized by 1 equiv using the laser-generated triplet state of 5-deazariboflavin. Parallel photoinduced oxidation occurs at the reduced heme and at the fully reduced FMN (FMNH(2)) prosthetic groups of different enzyme monomers, producing the anion semiquinone of FMN and a ferric heme. Following the initial oxidation reaction, rapid intramolecular reduction of the ferric heme occurs with concomitant oxidation of FMNH(2), generating the neutral FNM semiquinone. The observed rate constant for this intramolecular electron transfer is 2200 s(-1), which is 1 order of magnitude larger than the turnover number under these conditions. A slower reduction of the heme prosthetic group also occurs with an observed rate constant of approximately 10 s(-1), perhaps due to intersubunit electron transfer form reduced FMN to heme. The rapid intramolecular electron transfer between the FNMH(2) and ferric heme is eliminated upon addition of excess pyruvate (K-i = 3.8 mM). This latter result indicates that pyruvate inhibition of catalytic turnover apparently can occur at the FMNH(2) --> heme electron transfer step. These results markedly differ from those previously obtained (Walker, M. C., & Tollin, G. (1991) Biochemistry 30, 5546-5555) and confirmed here for electron transfer within the one-electron reduced enzyme and for the effect of pyruvate binding, suggesting that intramolecular communication between the heme and flavin prosthetic groups can be controlled by the redox stat of the enzyme and by ligand binding to the active state.