Transient kinetics of the one-electron transfer reaction between reduced flavocytochrome b2 and oxidized cytochrome c. Evidence for the existence of a protein complex in the reaction.

Abstract

The one-electron transfer reaction from reduced flavocytochrome b2 (fully reduced by three electron equivalents) to ferricytochrome c, both purified from the yeast Hansenula anomala, has been studied using stopped-flow spectrophotometry in the course of a single turnover, for reactants initially mixed in a heme molar ratio equal to one. The cytochrome c reduction proceeded to completion through an apparently first-order process. Depending on the experimental conditions (concentrations and or ionic strength), the reduction is of second-order or first-order character. To interpret these kinetic results computer simulation studies have been performed based on a kinetic scheme involving, besides the formation of a complex before the electron transfer step, intramolecular electron transfer steps within flavocytochrome b2 to maintain the concentration of the specific electron donor center, the reduced cytochrome b2. As far as the cytochrome c reduction rate constant, ka, and its variations were concerned the simulated data showed that this complicated scheme could approximate a mechanism which is by far the simplest, involving only the two former steps. Such a scheme accounts firstly for the hyperbolic dependence of the rate of reduction of cytochrome c, ka, upon reductant concentrations which had provided clear evidence for the kinetic existence of a complex in the reaction pathway. At 5 degrees C the rate constant for the electron transfer is 380 s-1 with an activation energy of 13.8kJ mol-1 (3.3 kcal mol-1). Secondly it predicts the observed variations of ka with ionic strength and provides estimates of the rate constants of the binding step.