Abstract
We have compared the modes and rates of cytochrome c diffusion to the rates of cytochrome c-mediated electron transport in isolated inner membranes and in whole intact mitochondria. For inner membranes, an increasing ionic strength results in an increasing rate of cytochrome c diffusion, a decreasing concentration (affinity) of cytochrome c near the membrane surface as well as near its redox partners, and an increasing rate of electron transport. For intact mitochondria, an increasing ionic strength results in a parallel, increasing rate of cytochrome c-mediated electron transport. In both inner membranes and intact mitochondria the rate of cytochrome c-mediated electron transport is highest at physiological ionic strength (100-150 mM), where the diffusion rate of cytochrome c is highest and its diffusion mode is three-dimensional. In intact mitochondria, succinate and duroquinol-driven reduction of endogenous cytochrome c is greater than 95% at all ionic strengths, indicating that cytochrome c functions as a common pool irrespective of its diffusion mode. Using a new treatment to obtain bimolecular diffusion-controlled collision frequencies in a heterogenous diffusion system, where cytochrome c diffuses laterally, pseudo-laterally, or three-dimensionally while its redox partners diffuse laterally, we determined a high degree of collision efficiency (turnover/collisions) for cytochrome c with its redox partners for all diffusion modes of cytochrome c. At physiological ionic strength, the rapid diffusion of cytochrome c in three dimensions and its low concentration (affinity) near the surface of the inner membrane mediate the highest rate of electron transport through maximum collision efficiencies. These data reveal that the diffusion rate and concentration of cytochrome c near the surface of the inner membrane are rate-limiting for maximal (uncoupled) electron transport activity, approaching diffusion control.
Highlights
Electron transport.In both inner membranes and intactIn our preceding paper [15] we reported on the rates and mitochondria the rateof cytochrome c-mediated elec- modes of cytron transporits highest at physiological ionicstrength tochrome c diffusion and calculated the collision frequencies (100-150 mM), where thediffusion rate of cytochrome of cytochrome c with its redox partners for each diffusion c ishighest and its diffusion mode is three-dimensional. mode
Mitochondrial electron transport mediated by cytochrome c has been studied extensively (e.g. Refs. 1-6) and traditionally, cytochrome c and itsredox partners have been viewed as a structurally stable macromolecular aggregate, comprising the heme protein portionof the electron transport “chain”(7, Enzyme Assays-Duroquinol oxidase activity was measured polarographically with a Clark oxygen electrode [17] according to Schneider etal. [18].For an individual set of experiments, electron transport activity at each ionic strength was measured in triplicate and all samples in an individual set were statistically randomized
These results for duroquinol oxidase activity in intactinner membranes areconsistent with results obtained for purified beef heart ubiquinol-cytochrome c reductase [19] and cytochrome oxidase [20]
Summary
Sharmila Shaila Gupte and CharRle.sHackenbrock From the Laboratoriesfor Cell Biology,Department of Cell Biologyand Anatomy, University of North Carolina School of Medicine, Chapel Hill, North Carolina 27599. Cytochrome c diffuses three dimensions and its low concentration (affinity) rapidly in a three-dimensional mode and has the lowest affinnear the surface of the inner membrane mediate the ity for the inner membrane while mediating the highest rate highest rate of electron transport through maximum of electron transport through maximum collision efficiencies collision efficiencies. These data reveal that the diffu-with its redox partners. Ionic strength dependence of cytochrome c-mediated electron transport in inner membranes
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