The cytochrome bc1 complex purified from beef heart mitochondria was incorporated into potassium (K+)-loaded phospholipid vesicles by a cholate dialysis method to study the reverse reaction of electron transfer in the complex. The reduction of cytochrome b in the presence of sodium ascorbate was observed on addition of valinomycin to the K(+)-loaded proteoliposomes in a medium containing no external KCl; it was followed by the gradual oxidation. Nigericin accelerated the reoxidation of reduced cytochrome b, indicating that a K+ diffusion potential (negative inside) induced the reduction of cytochrome b. The extent of the cytochrome b reduction depended on the magnitude of the diffusion potential across the liposomal membranes, and its maximal reduction was attained at more than 210 mV of the diffusion potential. It was cytochrome b562 that was reduced during the establishment of the K+ diffusion potential in the presence of ascorbate, and about 90% of cytochrome b562 was estimated to be reduced. Antimycin A and myxothiazol inhibited the diffusion potential-induced reduction of cytochrome b562, and ubiquinone was proved to be essential for the reversed electron transfer. The K+ diffusion potential also induced the partial reduction of cytochrome b566 when cytochrome b562 had previously been reduced with ascorbate plus tetramethyl-p-phenylenediamine. These results were interpreted well based on the Q cycle scheme which assumed the energy-dependent reduction of ubiquinone at center o. Dicyclohexylcarbodiimide, which did not perturb the ability of proteoliposomes to generate the K+ diffusion potential, inhibited the energy-dependent reduction of cytochrome b562 without a significant loss in the catalytic activity of the complex. The half-inhibition was brought about by 200 mol of dicyclohexylcarbodiimide/mol of cytochrome c1. These results strongly suggest the coupling of a proton flow with the reversed electron transfer in the bc1 complex.