[Estimation of ATP-dependent K(+)-channel contribution to potential-dependent potassium uptake in the rat brain mitochondria].

The effect of potassium on state 4 respiration (substrate oxidation in the absence of ADP) was investigated. It was shown that potential-dependent potassium uptake in the brain mitochondria results in mitochondrial depolarization. Taking into account depolarization effect of potassium, the contribution of the endogenous proton leak as well as K(+)-uptake to the respiration rate was calculated. It was shown that such estimation allows the share of ATP-dependent potassium channel contribution to potential-dependent potassium uptake to be determined by polarographic method.

[The effect of ATP-dependent K(+)-channel opener on transmembrane potassium exchange and reactive oxygen species production upon the opening of mitochondrial pore].

The effect of mitochondrial ATP-dependent K(+)-channel (K(+)ATP-channel) opener diazoxide (DZ) on transmembrane potassium exchange and reactive oxygen species (ROS) formation under the opening of mitochondrial permeability transition pore (MPTP) was studied in rat liver mitochondria. The activation of K(+)-cycling (K(+)-uptake and K(+)/H(+)-exchange) by DZ was established with peak effect at < or = 500 nM. It was shown that MPTP opening as well resulted in the activation of K(+)-cycling together with simultaneous activation of Ca(2+)-cycle in mitochondria. In the absence of depolarization Ca(2+)-cycle is supported by MPTP and Ca(2+)-uniporter. The stimulation of K(+)/H(+)-exchange by MPTP opening led to the activation of K(+)-cycle, but further activation of K(+)/H(+)-exchange resulted in MPTP inhibition. Under the same conditions the decrease in mitochondrial ROS production was observed. It was proposed that the decrease in ROS formation together with K(+)/H(+)-exchange activation could be the constituents of the complex effect of MPTP inhibition induced by K(+)ATP-channel opener.

[The effect of ATP-dependent K(+)-channel opener on the functional state and the opening of cyclosporine-sensitive pore in rat liver mitochondria].

The effect of mitochondrial ATP-dependent K(+)-channel (K+(ATP)-channel) opener diazoxide (DZ) on the oxygen consumption, functional state and the opening of cyclosporine-sensitive pore in the rat liver mitochondria has been studied. It has been established that K+(ATP)-channel activation results in the increase of the oxygen consumption rate (V4(s)) and the uncoupling due to the acceleration of K(+)-cycling, the decrease in state 3 respiration rate (V3) and the respiratory control ratio (RCR). Under K+(ATP)-channel activation an inhibition of oxidative phosphorylation takes place which reduces the rate of ATP synthesis and hydrolysis as well as ATP production and consequently results in the seeming increase of P/O ratio. It has been shown that the increase in ATP-dependent K(+)-uptake accompanied by the opening of mitochondrial permeability transition pore (MPTP) leads to dramatic uncoupling of the respiratory chain due to simultaneous activation of K(+)- and Ca(2+)-cycling supported by MPTP and Ca(2+)-uniporter as well as K(+)-channels and K+/H(+)-exchange. K+(ATP)-channel activation leads to the partial inhibition of MPTP, but insufficient for the restoration of mitochondrial functions. Elimination of Ca(2+)-cycling after MPTP opening is necessary to return mitochondrial functions back to the control level which shows that MPTP could serve as the mechanism of reversible modulation of bioenergetic effects of K+(ATP)-channel activation.

[The effect of potential-dependent potassium uptake on membrane potential in rat brain mitochondria].

The effect of potential-dependent potassium uptake on the transmembrane potential difference (DeltaPsi(m)) in rat brain mitochondria has been studied. It was shown that in potassium concentration range of 0-120 mM the potential-dependent K(+)-uptake into matrix leads to the increase in respiration rate and mitochondrial depolarization. ATP-dependent potassium channel (K+(ATP)-channel) blockers, glibenclamide and 5-hydroxydecanoate, block approximately 35% of potential-dependent potassium uptake in the brain mitochondria. It was shown that K+(ATP)-channel blockage results in membrane repolarization by approximately 20% of control, which is consistent with experimental dependence of DeltaPsi(m) on the rate of potential-dependent potassium uptake. Obtained experimental data give the evidence that functional activity of K+(ATP)-channel is physiologically important in the regulation of membrane potential and energy-dependent processes in brain mitochondria.

[Common features of the antigenic determinants presented on the membranes of mammalian nervous system cells and cytoplasmic tetrodotoxin-sensitive proteins]. / Obshchnost' antigennykh determinant, predstavlennykh na membranakh kletok nervnoi sistemy mlekopitaiushchikh i na tsitoplazmaticheskikh tetrodotoksinchuvstvitel'nykh belkakh.

Hypothetical antigenic similarities between nerve cell membrane structures and cytoplasmic tetrodotoxin-sensitive proteins have been studied. Indirect ELISA binding assay combined with inhibition assay has been used. The results obtained indicate that cytoplasmic tetrodotoxin-sensitive proteins do share antigenic determinants with nerve cell membrane structures. This is consistent with the speculation that cytoplasmic tetrodotoxin-sensitive proteins are relatives of membrane sodium channels.

[Study of the ion transfer in membrane vesicles by ion exchange gel chromatography and ultrafiltration]. / Izuchenie perenosa ionov v membrannykh vezikulakh s pomoshch'iu ionobmennoi gel'-khromatografii i ul'trafil'tratov.

A method involving fast ion-exchange gel chromatography and filtration through ultrafilters is suggested for studying ion transport in membrane vesicles from bovine brain gray matter. The method permits separating quantitatively the membrane vesicles from the external radioactive label and studying kinetics of ion transfer. The label transfer is characterized by the presence of fast and slow phases and cannot be described by one exponential curve.

[Interaction of p-nitrophenylphosphate with Na+,K+-ATPase]. / Izuchenie vzaimodeistviia n-nitrofenilfosfata s Na+,K+-ATP-azoi.

The vector characteristics of the interacting Na+, K+-ATPase and ouabaine were studied in experiments on the restored ghosts of erythrocytes. It is shown that the effect of K+ on the enzyme activity is the same as in cases of using ATP and p-nitrophenylphosphate (p-NPP) as phosphorylating agents. ADP removes the p-NPP induced inhibition with ouabain. This effect is explained rather by addition of ADP to the enzyme substrate centre than by a decrease in the concentration of E1 approximately P phosphoform. Incorporation of labelled orthophosphate into p-nitrophenol (NP) in the presence of Na+, K+-ATPase preparations was not detected. It is shown that antibodies against the fraction of the brain microsomes inhibit K+-NPPases to a much less extent than Na+, K+-ATPase. The digitonin treatment does not remove (Na++ATP)-dependent increase in the K+-NPPase activity. A conclusion is drawn that the mechanisms of p-NPP hydrolysis differs from the mechanism of ATP hydrolysis.

[Study of the interaction of Na+ and K+-ATPase of erythrocytes with ouabain. Effect of acetyl phosphate and p-nitrophenyl phosphate]. / Izuchenie vzaimodeistviia Na+, K+-ATPazy eritrotsitov s oyabainom. Vliianie atsetilfosfata i n-nitrofenilfosfata

Effects of ATP, acetyl phosphate (AcP) and p-nitrophenyl phosphate (p-NPP) on the inhibition of the Na+, K+-ATPase activity were studied. ATP, AcP and p-NPP were found to facilitate the ouabain-induced inhibition of the enzyme activity only after the injection of these phosphorylyzing agents into the erythrocyte ghosts. Inside the ghosts Na+ ions enhanced the effects of the phosphorylyzing agents. K+ ions in the environment removed the stimulating effects of ATP, AcP and p-NPP on the ouabain-induced inhibition of Na+, K+-ATPase activity. It is concluded that the sites of AcP and p-NPP hydrolysis as well as the active center for ATP are localized on the inner surface of the cell membrane.