Effects of 2-chloroadenosine on electrical potentials in brain synaptic membrane vesicles

Isolated synaptic plasma membrane vesicles developed an internal negative membrane potential (ΔΨ) following loading with potassium succinate and incubation in NaCl, sodium succinate, or Tris succinate media. Membrane ΔΨ was monitored by measuring triphenyl[³H]methylphosphonium ion ([³H]TPMP⁺) accumulation by these vesicles. Estimates of ΔΨ ranged from ?6.9 mV for vesicles incubated in sodium succinate to ?28 mV for membranes incubated in NaCl. Intravesicular TPMP⁺ accumulation was strongly dependent on the K⁺ diffusion potential and was enhanced by the K⁺ ionophore valinomycin and by the adenosine analog 2-chloroadenosine (2-Cl-Ado). The stimulation of TPMP⁺ influx by 2-Cl-Ado was dependent on the concentration of this agent, independent of Cl^? fluxes, and sensitive to inhibition by the methylxanthine theophylline. The increase in ΔΨ of the synaptic membrane vesicles caused by 2-Cl-Ado paralleled the hyperpolarization of neurons produced by adenosine and 2-Cl-Ado in physiological systems.     

L-glutamate stimulation of Na+ efflux from brain synaptic membrane vesicles

The characteristics of 22Na efflux from 22NaCl-preloaded synaptic plasma membrane vesicles and the stimulation of such efflux by gramicidin D and L-glutamate were determined. The rate and magnitude of passive Na+ efflux were dependent on the initial intravesicular NaCl concentration. A Na+:cation exchange process was also observed. Gramicidin D markedly enhanced Na+ efflux in a concentration-dependent manner and at 10 microM it caused total loss of intravesicular 22Na. The neuroexcitatory amino acids L-glutamate and D-glutamate, and the amino acid analog kainic acid, also stimulated Na+ efflux in a dose-dependent fashion, but their effects were weaker than those of gramicidin D. The mechanism of glutamate stimulation of Na+ flux is presumed to be through the activation of the glutamate receptor . Na+ channel complex in these membranes.     

Spatial distribution of synaptic vesicles in presynaptic terminals: Computer simulation

A procedure for computer simulation is proposed, which allows one to quantitatively characterize the spatial distribution of synaptic vesicles in presynaptic terminals (PST) using ultrathin sections of such terminals. The procedure includes three stages: simulation, topographical analysis, and comparison. At the first stage, the spatial distribution of vesicles within a PST and the process of random sectioning of it are simulated using the corresponding mathematical model. At the second stage, the topographical distribution of vesicle profiles within the plane of PST section is estimated; three respective approaches have been used: (i) nearest neighbor distance distribution; (ii) minimal spanning tree; and (iii) Voronoi paving. At the third stage, the simulated parameters are compared with the parameters of native terminal sections; when the coincidence of these two parameter groups is satisfactory, we believe that the simulated spatial distribution agrees with the real distribution. The software for the procedure is written in C++ programing langage. The results of a pilot study on ultrathin sections of cultured rat hippocampal neurons showed that the method offers broad possibilities for spatial interpretation and quantitative characterization of distributions of synaptic vesicles.     

Interaction of isolated synaptic vesicles with synaptic contacts in the rat brain

The effects of Mg-ATP, EGTA, EDTA and dicyclohexylcarbodiimide on the changes in the intensity of light scattering were studied in rat brain synaptic vesicles (SV) suspended in saccharose-buffer medium. Specific interactions between SV and isolated synaptic junctional complex were observed in the presence of Mg-ATP and calmodulin. An in vitro model of exocytosis is discussed.     

Protein insertion into the inner membrane of mitochondria

The inner membrane of mitochondria harbours a large number of polypeptides, many of which have evolved from proteins of the prokaryotic progenitors of mitochondria. The sorting routes on which these proteins are integrated into the mitochondrial inner membrane reflect their phylogenetic origin: Proteins of eukaryotic descent typically reach their destination following arrest of import at the level of the inner membrane. In contrast, many proteins inherited from the prokaryotic progenitor cell are inserted into the inner membrane in an export step following translocation into the matrix. Recently, three different insertion pathways from the matrix into the inner membrane were identified which show considerable parallels to the protein insertion processes in bacteria and chloroplasts. Two of these pathways depend on the related inner membrane proteins Oxa1 and Cox18. A third route is less well defined and depends on the membrane-associated matrix protein Mba1.     

Evidence for the presence of H+-ATPase in the membrane of brain synaptic vesicles in the rat

Mg-ATPase of rat brain synaptic vesicles (SV) is considerably (by 85%) inhibited by dicyclohexyl carbodiimide (200 microM), a blocker of proton pumps, whereas orthovanadate (100 microM) does not produce any influence on the enzyme. Oligomycin (5 micrograms/ml) does not alter Mg-ATPase activity of the SV, whereas N-ethylmaleimide (300 microM) reduces it to a moderate degree, namely by 35%. This indicates that Mg-ATPase of the SV differs from mitochondrial ATPase. The protonophore p-trichloromethoxycarbonyl cyanide phenylhydrazone (20 microM) and bicarbonate anions (20 mM) stimulate slightly (by 12 to 25%) Mg-ATPase of the SV. Bicarbonate (20 mM) raises 1.8-2.1-fold Mg-ATPase activity of the mitochondria isolated from rat brain. It is assumed that the membrane of brain SV contains proton ATPase (H+-ATPase) differing from mitochondrial H+-ATPase in some of the properties.     

Oxidative stress is involved in the permeabilization of the inner membrane of brain mitochondria exposed to hypoxia/reoxygenation and low micromolar Ca2+

From in vivo models of stroke it is known that ischemia/reperfusion induces oxidative stress that is accompanied by deterioration of brain mitochondria. Previously, we reported that the increase in Ca2+ induces functional breakdown and morphological disintegration in brain mitochondria subjected to hypoxia/reoxygenation (H/R). Protection by ADP indicated the involvement of the mitochondrial permeability transition pore in the mechanism of membrane permeabilization. Until now it has been unclear how reactive oxygen species (ROS) contribute to this process. We now report that brain mitochondria which had been subjected to H/R in the presence of low micromolar Ca2+ display low state 3 respiration (20% of control), loss of cytochrome c, and reduced glutathione levels (75% of control). During reoxygenation, significant mitochondrial generation of hydrogen peroxide (H2O2) was detected. The addition of the membrane permeant superoxide anion scavenger TEMPOL (4-hydroxy-2,2,6,6-tetramethylpiperidine-N-oxyl) suppressed the production of H2O2 by brain mitochondria metabolizing glutamate plus malate by 80% under normoxic conditions. TEMPOL partially protected brain mitochondria exposed to H/R and low micromolar Ca2+ from decrease in state 3 respiration (from 25% of control to 60% of control with TEMPOL) and permeabilization of the inner membrane. Membrane permeabilization was obvious, because state 3 respiration could be stimulated by extramitochondrial NADH. Our data suggest that ROS and Ca2+ synergistically induce permeabilization of the inner membrane of brain mitochondria exposed to H/R. However, permeabilization can only partially be prevented by suppressing mitochondrial generation of ROS. We conclude that transient deprivation of oxygen and glucose during temporary ischemia coupled with elevation in cytosolic Ca2+ concentration triggers ROS generation and mitochondrial permeabilization, resulting in neural cell death.     

Action of triftazin on the physicochemical properties and the membrane proton pump of the synaptic vesicles in the rat brain

The effects of trifluoperazine (TFP) on some membrane processes were studied in the isolated rat brain synaptic vesicles (SV). TFP (10(-5)-10(-4) M) was found to cause a sharp rise in the intensity of light scattering by SV suspension which was due both to an increased vesicle aggregation and to changes in the refraction index of the membrane. In addition, TFP blocked the ATP-dependent proton transport into the vesicles (K0.5 = 10(-6) M) with the concomitant stimulation of the ATPase activity which suggests an uncoupling effect caused by the permeation of this weak base through the membrane and subsequent protonation in an acid interior medium resulting in the elimination of a proton gradient. Thus, the neuroleptic drug--TFP has various effects on membrane processes which are apparently unrelated to its recognized role as a calmodulin antagonist.     

Anion regulation of active transport of protons across the membrane of the synaptic vesicles of the brain

The dependence of active transport of H+ on the presence of anions in synaptic vesicle membranes from rat brain was studied. The H+ transport was measured by monitoring the acidification of the vesicles with a permeant weak base-acridine orange. The fluorescence changes in the latter were proportional to the magnitude of artificially imposed pH gradients (delta pH). The ATP-dependent generation of delta pH was completely dependent on the presence of a permeant anion, was maximal at 150 mM Cl- and was inhibited, when the medium osmolarity was further increased by sucrose or KCl. At 150 mM only Br-, similar to Cl-, behaved as permeant anions, whereas I- was effective only at low (5-20 mM) concentrations. The anions--SCN-, ClO4-, HSO3- and I-(10-20 mM) as well as 4-acetamido-4'-isothiocyanatostilbene-2.2'-disulfonate (K0.5 = 14 microM) blocked the ATP-dependent generation of delta pH observed in the presence of Cl-, while other anions tested (F-, phosphate, bicarbonate, some organic anions) were virtually without effect and did not support the H+ transport. The dependence of the rate and extent of H+ accumulation on Cl- concentration was sigmoidal with a Hill coefficient of 2.8 and a Km value of 85-90 mM. The effects of anions point to the presence in the membrane of synaptic vesicles of an anion (chloride) channel whose conductance can regulate the H+ transport by switching it from an electrogenic to an electroneutral (coupled entry of H+ and Cl-) mode of operation.     

Properties of the inner membrane anion channel in intact mitochondria

The mitochondrial inner membrane possesses an anion channel (IMAC) which mediates the electrophoretic transport of a wide variety of anions and is believed to be an important component of the volume homeostatic mechanism. IMAC is regulated by matrix Mg²⁺ (IC₅₀=38 µM at pH 7.4) and by matrix H⁺ (pIC₅₀=7.7). Moreover, inhibition by Mg²⁺ is pH-dependent. IMAC is also reversibly inhibited by many cationic amphiphilic drugs, including propranolol, and irreversibly inhibited byN,N-dicyclohexylcarbodiimide. Mercurials have two effects on its activity: (1) they increase the IC₅₀ values for Mg²⁺, H⁺, and propranolol, and (2) they inhibit transport. The most potent inhibitor of IMAC is tributyltin, which blocks anion uniport in liver mitochondria at about 1 nmol/mg. The inhibitory dose is increased by mercurials; however, this effect appears to be unrelated to the other mercurial effects. IMAC also appears to be present in plant mitochondria; however, it is insensitive to inhibition by Mg²⁺, mercurials, andN,N-dicyclohexylcarbodiimide. Some inhibitors of the adenine nucleotide translocase also inhibit IMAC, including Cibacron Blue, agaric acid, and palmitoyl CoA; however, atractyloside has no effect.     

A maxi-chloride channel in the inner membrane of mammalian mitochondria

Patch-clamp experiments on swollen mitochondria of human, mouse and rat origins have revealed activity by an approximately 400 pS (in 150 mM KCl), voltage-dependent and anion-selective channel. This channel is located in the inner membrane, as shown by experiments with mitochondria from cells expressing a fluorescent mitochondrial tag protein and by the co-presence of the 107 pS channel and of the permeability transition pore (PTP). The frequency of appearance was inversely related to the presence of the PTP. This and the comparison of its electrophysiological characteristics with those of the PTP indicate that it is closely related to the latter, possibly corresponding to a monomeric unit whose dimer constitutes the full PTP. The channel is similar but not identical to isolated-and-reconstituted mitochondrial porin, and it is present also in mitochondria from cells lacking porin isoforms. Its identification with porin is therefore to be excluded. It most likely coincides instead with the “maxi-chloride channel” characterized in the plasma membrane of various cell types.     

A maxi-chloride channel in the inner membrane of mammalian mitochondria

Patch-clamp experiments on swollen mitochondria of human, mouse and rat origins have revealed activity by an approximately 400 pS (in 150 mM KCl), voltage-dependent and anion-selective channel. This channel is located in the inner membrane, as shown by experiments with mitochondria from cells expressing a fluorescent mitochondrial tag protein and by the co-presence of the 107 pS channel and of the permeability transition pore (PTP). The frequency of appearance was inversely related to the presence of the PTP. This and the comparison of its electrophysiological characteristics with those of the PTP indicate that it is closely related to the latter, possibly corresponding to a monomeric unit whose dimer constitutes the full PTP. The channel is similar but not identical to isolated-and-reconstituted mitochondrial porin, and it is present also in mitochondria from cells lacking porin isoforms. Its identification with porin is therefore to be excluded. It most likely coincides instead with the "maxi-chloride channel" characterized in the plasma membrane of various cell types.     

L-Glutamate effects on electrical potentials of synaptic plasma membrane vesicles

The electrogenic nature of the L-glutamate-stimulated Na+ flux was examined by measuring the distribution of the lipophilic anion [35S]thiocyanate (SCN-) into synaptic membrane vesicles that were incubated in a NaCl medium. Concentrations of L-glutamate from 10(-7) to 10(-4) M added to the incubation medium caused an enhanced intravesicular accumulation of SCN-. Based on the SCN- distribution in synaptic membrane vesicles it was calculated that 10 microM L-glutamate induced an average change in the membrane potential of + 13 mV. L-Glutamate enhanced both the Na+ and K+ conductance of these membranes as determined by increases in SCN- influx. Other neuroexcitatory amino acids and amino acid analogs (D-glutamate, L-aspartate, L-cysteine sulfinate, kainate, ibotenate, quisqualate, N-methyl-D-aspartate, and DL-homocysteate) also increased SCN- accumulation in synaptic membrane vesicles. These observations are indicative of the activation by L-glutamate and some of its analogs of excitatory amino acid receptor ion channel complexes in synaptic membranes.     

Preferential glutamine uptake in rat brain synaptic mitochondria

Glutamine uptake has been studied in purified rat brain mitochondria of synaptic or non-synaptic origin. It was taken up by an active saturable transport mechanism, with an affinity two-times higher in synaptic than in non-synaptic mitochondria (Km = 0.45 and 0.94 mM, respectively). Vmax of uptake was 7-times higher in synaptic mitochondria (Vmax = 9.2 and 1.3 nmol/min per mg protein, respectively). Glutamine transport was found to be inhibited by L-glutamate (IC50 = 0.64 mM) as well as thiol reagents (mersalyl, N-ethylmaleimide). It is suggested that differential uptake of glutamine in mitochondria of synaptic or non-synaptic origin may be a major mechanism in the regulation of the synthesis of the neurotransmitter glutamate.     

Aggregation and swelling of brain synaptic vesicles in rats

Mg-ATPase (1 mM) induces a decrease in the intensity of light scattering (I1) at 620 nm of rat brain synaptic vesicles (SV) suspended in sucrose, with this decrease being indicative of the swelling of the vesicles. The Mg-ATPase-induced swelling appears to be associated with the function of H+-ATPase of SV membranes, since it is completely abolished by the proton pump blocker dicyclohexylcarbodiimide and the protonophore carbonylcyanide m-chlorophenylhydrazone. The Mg-ATPase-induced swelling was enhanced in the presence of the permeable anion Cl- (in the range of 25-50 mM KCl). Ca2+ (and Mg2+) at high concentrations (0.1-1.0 mM) cause aggregation of the SV as measured by changes in the I1. Colchicine and cytochalasin do not affect SV swelling and aggregation whereas Mg-ATP (1 mM) lowers aggregation caused by Ca2+ (1 mM).