[The cytochrome c oxidase activity in mitochondria of cardiomyocytes of isolated cardiac tissue under long-term hypoxic incubation].

Using method of electron microscopic histochemistry based upon the oxidative polymerization of 3,3'-diaminobenzidine (DAB) to reveal cytochrome c oxidase activity we identified that long hypoxic incubation of isolated small pieces of cardiac tissue during 72 h caused changes in mitochondrial ultrastructure followed by a breach of functional activities of mitochondria, and, in particular, complex IV of the respiratory chain. But for all that, small electron-dense mitochondria appearing inside electron-light mitochondria ("mitochondria inside mitochondria") stained positively for cytochrome c oxidase activity along the full length of cristaes. The results obtained are discussed in connection with conception of changes in the mitochondrial reticulum ultrastructure during mitoptosis.

[Dynamics of mitochondrial ultrastructure in small pieces of cardiac tissue under long-term anoxic incubation].

Anoxic incubation of isolated small pieces of cardiac tissue for 72 h caused emergence of an unusual population of mitochondria, referred to as "mitochondrion inside mitochondrion". We studied dynamics of the origin of this event. In the most part of a mitochondrial population after a 6 h anoxic incubation of myocardial tissue, a local increase in some region of the intermembrane space was observed. Some regions of matrix with adjoined inner membrane move into these regions of intermembrane space, to be constricted eventually. After 12 h of incubation densely neighbouring layers of membrane are observed in these structures. By 24 h of incubation, inside new-formed structures well-distinguished concentric layers of membrane appear. Between these layers some electron-dense material ultrastructurally identical to mitochondrial matrix is seen. By 72 h of anoxic incubation, in cardiomyocytes of the experimental tissue structures with well-marked morphological features of mitochondria appear, which we called "mitochondrion inside mitochondrion". Results of our study are discussed in terms of a conception of changes that occur in the structure of mitochondrial reticulum during apoptosis.

[Local coupling of respiration processes and phosphorylation in rat liver mitochondria]. / O lokal'nom sopriazhenii protsessov dykhaniia i fosforilirovaniia v mitokhondriiakh pecheni krysy.

One variant of the model of the local coupling of phosphorylation and respiration in intact mitochondria was experimentally verified. The model is based on the following postulates: (1). Upon the functioning of H+ pumps, hydrogen ions bound to the outer membrane surface do not enter the aqueous phase but are utilized for ATP synthesis in the membrane supercomplex respiratory H+ pump--ATP synthetase. (2). During the functioning of H+ pumps, an appreciable part of the energy of oxidation reactions can be stored in the form of the thermodynamic (solvation) potential of H+ ions bound to the outer membrane surface. According to the model, the hydration of hydrogen ions during the transition from the outer face of the inner membrane to the aqueous phase should lead to a decrease in the efficiency of the system of the coupling of respiration and phosphorylation. The model takes into account the ability of the nonpermeating buffer to catalyze the detachment of hydrogen ions from the membrane surface to the aqueous phase and provide their complete solvation. A preparation of phosphorylating mitochondria with the covalently bound pH probe was obtained. This made it possible to register for the first time the presence of a local H+ gradient on the outer side of the inner mitochondrial membrane during the stable functioning of the oxidative phosphorylation system. It was shown on these mitochondrial preparations that a decrease in the outer local H+ gradient by the action of increased concentrations of buffer is accompanied by a significant decrease in the ADP/O parameter and a partial dissociation of oxidative phosphorylation. Conditions were determined under which increased concentrations of buffer in the incubation medium cause a partial dissociation and a decrease in the ADP/O value from 20% to twofold (depending on the quality of mitochondrial preparations). The results obtained are in full agreement with the predictions of the model.

Functional activity and ultrastructure of mitochondria isolated from myocardial apoptotic tissue.

Apoptosis in myocardial tissue slices was induced by extended incubation under anoxic conditions. Mitochondria were isolated from the studied tissue. A new method of isolation of mitochondria in special conditions by differential centrifugation at 1700, 10,000, and 17,000 g resulted in three fractions of mitochondria. According to the data of electron microscopy the heavy mitochondrial fraction (1700 g) consisted of mitochondrial clusters only, the middle mitochondrial fraction (10,000 g) consisted of mitochondria with typical for isolated mitochondria ultrastructure, and the light fraction consisted of small mitochondria (2 or 3 cristae) of various preservation. The heavy fraction contained unusual structural elements that we detected earlier in apoptotic myocardial tissue--small electron-dense mitochondria incorporated in bigger mitochondria. The structure of small mitochondria from the light fraction corresponded to that of the small mitochondria from these unusual elements--"mitochondrion in mitochondrion". The most important functions of isolated mitochondria are strongly inhibited when apoptosis is induced in our model. The detailed study of the activities of the two fractions of the apoptotic mitochondria showed that the system of malate oxidation is completely altered, the activity of cytochrome c as electron carrier is partly inhibited, while succinate oxidase activity is completely preserved (complexes II, III, and IV of the respiration chain). Succinate oxidase activity was accompanied by high permeability of the internal membrane for protons: the addition of uncoupler did not stimulate respiration. ATP synthesis in mitochondria was inhibited. We demonstrated that in our model of apoptosis cytochrome c remains in the intermembrane space, and, consequently, is not involved in the cascade of activation of effector caspases. The possible mechanisms of induction of apoptosis during anoxia are discussed.

[Detection and functional role of local gradients of H+-ions on the intracellular mitochondrial membrane with covalently linked pH-probe]. / Obnaruzhenie i funktsional'naia rol' lokal'nykh gradientov H+-ionov na vnutrennei membrane mitokhondrii s kovalentno prisoedinennym H-zondom.

The study is devoted to the registration of local H+ gradients on the inner membrane of mitochondria under conditions of H+ pump functioning were recorded. By using a covalently linked pH probe (fluorescein isothiocyanate), a local increase in the activity of hydrogen ions on the outer face of the inner mitochondrial membrane in the presence of the respiration substrate at increased permeability of the membrane for K+ was registered. It was also found that the buffer capacity of medium affects the respiration rate of completely uncoupled mitochondria; a change in respiration rate strictly correlates with changes in local H+ gradients on the mitochondrial membrane. It was concluded that local gradients of H+ activity can control the rate of functioning of H+ pumps. It was shown that, under certain conditions, the system of H+ pumps incorporated into succinate oxidase of mitochondria functions as a nonliner system.