[The possible role of the inner mitochondrial membrane in regulating oxidative phosphorylation in cells in vivo]. / O vozmozhnoi roli vneshnei membrany mitokhondrii v reguliatsii okislitel'nogo fosphorilirovaniia v kletkakh in vivo.

It has been shown for the first time that the outer mitochondrial membrane has a low permeability for ADP and can control its diffusion into cells in vivo. Respiration of saponin-skinned cardiac and skeletal muscle fibers is maximally stimulated by millimolar concentrations of external ADP. The apparent Km values for ADP are equal to 297 +/- 35 and 334 +/- 54 microM, respectively. After complete extraction of myosin with 0.8 M KCl, which fully preserves the intact structure of the mitochondria, the apparent Km values for exogenously added ADP does not change. However, disruption of the outer mitochondrial membrane by osmotic shock (treatment with 40 mOsM KCl) causes a reduction of the apparent Km value down to 32.3 +/- 5.0 microM of ADP. The apparent Km for ADP in isolated heart mitochondria is 17.6 +/- 1.0 microM. It is concluded that there exists an intracellular factor in the cells in vivo which controls the outer mitochondrial membrane and notably decreases its permeability for ADP. After isolation of mitochondria this factor is lost. When mitochondrial creatine kinase is activated, weak intracellular fluxes of ADP passing through the outer mitochondrial membrane in the skinned fibers are amplified manifold due to the tight functional coupling between mitochondrial creatine kinase and the oxidative phosphorylation system. This coupling is considered to be the central mechanism in the control of cell respiration.

[Specific limitations for intracellular diffusion of ADP in cardiomyocytes]. / Spetsificheskie ogranicheniia dlia vnutrikletochnoi diffuzii ADP v kardiomiotsitakh.

Isolated cardiomyocytes and bundles of cardiac fibers were studied after lysis of their sarcolemma by saponin (40-50 micrograms/ml). 60-70% of cardiomyocytes were rod-like and Ca2(+)-tolerant. The kinetics of stimulation of oxidative phosphorylation by ADP and creatine via the mitochondrial creatine kinase reaction: MgATP + creatine----MgADP + phosphocreatine, was investigated after perforation of sarcolemma. The criterion for sarcolemmal perforation was an almost complete (80-100%) leakage of lactate dehydrogenase. It was shown that the Km values for ADP during stimulation of oxidative phosphorylation in cardiomyocytes are 250 +/- 39 microM (264 +/- 57 microM in cardiac bundles) which exceeds by one order of magnitude the Km value for ADP in isolated mitochondria (18 +/- 5 microM). On the contrary, Km for creatine is the same for all preparations studied (6-6.9 mM). The data obtained suggest the absence of diffusion difficulties for creatine inside the cells. In contrast, intracellular diffusion of ADP is restricted, most probably, dye to its binding to intracellular structures. These data emphasize the crucial role of the creatine kinase system in energy transfer processes. In the presence of 25 mM creatine Km for ADP is decreased to 36 +/- 6 mM due to a manyfold use of ADP in the coupled creatine kinase-oxidative phosphorylation reaction occurring in mitochondria.

[Oxaloacetate keto-enol tautomerase from bovine heart mitochondrial matrix]. / Oksaloatsetat keto-enol tautomerazy matriksa mitokhondrii serdtsa byka.

Bovine heart mitochondrial matrix contains two proteins possessing the oxaloacetate keto-enol tautomerase (EC 5.3.2.2) activity. A procedure for the isolation and purification of the enzymes to an electrophoretically homogeneous state has been developed. The purified proteins have molecular masses of 37 kD and 80 kD and catalyze the keto-enol oxaloacetate tautomerization reaction with the turnover numbers of approximately 3000 and approximately 2000 min-1. The both enzymes were found to differ significantly in all their physicochemical and kinetic properties. Fractionation of rat liver mitochondria revealed that the oxaloacetate keto-enol tautomerase activity is predominantly localized in the mitochondrial matrix. The essential role of oxaloacetate keto-enol tautomerase in the operation of the Krebs cycle is discussed.

[Malate oxidation by mitochondrial succinate:ubiquinone-reductase]. / Okislenie malata mitokhondrial'noi suktsinat:ubikhinon-reduktazoi.

Succinate:ubiquinone reductase was shown to catalyze the oxidation of L- and D-stereoisomers of malate by artificial electron acceptors and ubiquinone. The rate of malate oxidation by succinate:ubiquinone reductase is by two orders of magnitude lower than that for the natural substrate--succinate. The values of kinetic constants for the oxidation of D- and L-stereoisomers of malate are equal to: V infinity = 0.1 mumol/min/mg protein, Km = 2 mM and V infinity = 0.05 mumol/min/mg protein, Km = 2 mM, respectively. The malate dehydrogenase activity is fully inhibited by the inhibitors of the dicarboxylate-binding site of the enzyme, i.e., N-ethylmaleimide and malonate and is practically insensitive to carboxin, a specific inhibitor of the ubiquinone-binding center. The enol form of oxaloacetate was shown to be the product of malate oxidation by succinate:ubiquinone reductase. The kinetics of inhibition of the enzyme activity by the ketone and enol forms of oxaloacetate was studied. Both forms of oxaloacetate effectively inhibit the succinate:ubiquinone reductase reaction.