Abstract
Rate constants for reduction of cytochrome b561 by internal ascorbate (k0A) and oxidation by external ferricyanide (k1F) were determined as a function of pH from rates of steady-state electron transfer across chromaffin-vesicle membranes. The pH dependence of electron transfer from cytochrome b561 to ferricyanide (k1F) may be attributed to the pH dependence of the membrane surface potential. The rate constant for reduction by internal ascorbate (k0A), like the previously measured rate constant for reduction by external ascorbate (k-1A), is not very pH-dependent and is not consistent with reduction of cytochrome b561 by the ascorbate dianion. The rate at which ascorbate reduces cytochrome b561 is orders of magnitude faster than the rate at which it reduces cytochrome c, despite the fact that midpoint reduction potentials favor reduction of cytochrome c. Moreover, the rate constant for oxidation of cytochrome b561 by ferricyanide (k1F) is smaller than the previously measured rate constant for oxidation by semidehydroascorbate, despite the fact that ferricyanide has a higher midpoint reduction potential. These results may be reconciled by a mechanism in which electron transfer between cytochrome b561 and ascorbate/semidehydroascorbate is accelerated by concerted transfer of a proton. This may be a general property of biologically significant electron transfer reactions of ascorbic acid.
Highlights
The pH dependence of electron transfer from cytochrome b56l to ferricyanidemaybe attributed to the pH dependence of the membrane surface potential
Like that by external ascorbate, is rapid and pH-independent.A pH dependence of thesereactions could be concealed by compensatory pH
Dependent changes in cytochrome b,5fi1or membrane surface than the previously measured rate constant for oxida- potential.These possibilities were testedand excluded by tion by semidehydroascorbate, despite the fact that examining the effect of pH on the rate of cytochrome bSel ferricyanide has a higher midpoint reductionpotential. oxidation by ferricyanide and on binding of the fluorescent
Summary
From the Departmentof Biological Sciences, Wayne State University, Detroit, Michigan48202. Rate constants for reduction of cytochrome bsel by constants for reduction by external ascorbate and for oxidainternal ascorbate (kOAa)nd oxidation by external fer- tion by external semidehydroascorbate.Ascorbatereduces ricyanide (klF)were determined as a function of pH from rates of steady-state electron transfer across chromaffin-vesicle membranes. The pH dependence of electron transfer from cytochrome b56l to ferricyanide (klF)maybe attributed to the pH dependence of the membrane surface potential. To elucidate the mechanism of electron transfer between ascorbateand cytochrome we have determinedthe effect of pH on the reduction of the cytochromeby internal ascorbate. Dependent changes in cytochrome b,5fi1or membrane surface than the previously measured rate constant for oxida- potential.These possibilities were testedand excluded by tion by semidehydroascorbate, despite the fact that examining the effect of pH on the rate of cytochrome bSel ferricyanide has a higher midpoint reductionpotential. This maybe a general property of biologically significant electron transfer reactions of ascorbic acid
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