Ca2+ transport by intact synaptosomes: the voltage-dependent Ca2+ channel and a re-evaluation of the role of sodium/calcium exchange

Brain mitochondrial calcium transport: Origins of the set-point concept and its application to physiology and pathology

The transport of calcium across the inner mitochondrial membrane plays a key role in neuronal physiology and pathology. The kinetic responses of the uniporter and efflux pathways are such that a cytosolic free calcium 'set-point' can be established - above which there is net calcium accumulation into the matrix that is reversed when plasma membrane transport lowers cytosolic calcium. Pathological activation of N-methyl-d-aspartate receptor mediated sodium and calcium entry into the neuron, as occurs in stroke and spreading depression, places severe demands on both the ATP-generating and calcium loading capacities of the neuronal mitochondria as the set-point is exceeded. Experiments that led to the concept of the set-point are reviewed.

A constitutive, transient receptor potential-like Ca2+ influx pathway in presynaptic nerve endings independent of voltage-gated Ca2+ channels and Na+/Ca2+ exchange

Calcium levels in the presynaptic nerve terminal are altered by several pathways, including voltage-gated Ca(2+) channels, the Na(+)/Ca(2+) exchanger, Ca(2+)-ATPase, and the mitochondria. The influx pathway for homeostatic control of [Ca(2+)](i) in the nerve terminal has been unclear. One approach to detecting the pathway that maintains internal Ca(2+) is to test for activation of Ca(2+) influx following Ca(2+) depletion. Here, we demonstrate that a constitutive influx pathway for Ca(2+) exists in presynaptic terminals to maintain internal Ca(2+) independent of voltage-gated Ca(2+) channels and Na(+)/Ca(2+) exchange, as measured in intact isolated nerve endings from mouse cortex and in intact varicosities in a neuronal cell line using fluorescence spectroscopy and confocal imaging. The Mg(2+) and lanthanide sensitivity of the influx pathway, in addition to its pharmacological and short hairpin RNA sensitivity, and the results of immunostaining for transient receptor potential (TRP) channels indicate the involvement of TRPC channels, possibly TRPC5 and TRPC1. This constitutive Ca(2+) influx pathway likely serves to maintain synaptic function under widely varying levels of synaptic activity.

Rate of Na+/Ca2+ exchange across the plasma membrane of synaptosomes measured using the fluorescence of chlorotetracycline. Implications to calcium homeostasis in synaptic terminals

It is shown that the fluorescence of chlorotetracycline (CTC) can be used to continuously monitor Ca2+ fluxes mediated by the Na+/Ca2+-exchanger of the plasma membrane of synaptosomes. The kinetics of Ca2+ uptake can be followed from the kinetics of the increase of CTC fluorescence with external Ca2+ concentrations in the micromolar range. Since the fluorescence of CTC is not sensitive to Ca2+ concentration below 20 microM this avoids any significant contribution of Ca2+ flux through Ca2+ channels to CTC fluorescence. By replacing KCl by choline chloride in the buffer to avoid plasma membrane depolarization it is shown that the amplitude of the CTC fluorescence change is dependent upon the Na(+)-gradient preimposed across the plasma membrane, and the rate constant of the kinetic process is dependent upon the Ca2+ concentration. The rate constant of the Ca2+ influx measured with depolarized and non-depolarized synaptic plasma membrane vesicles at 37 degrees C and pH 7.4 were 0.55 +/- 0.10 and 0.25 +/- 0.02 min-1, respectively. The overall rate of Na+/Ca2+ exchange calculated under conditions close to physiological Na+ and Ca2+ gradients and membrane resting potential ranged from 15 to 25% of the activity of the plasma membrane Ca2+ pump under these experimental conditions. The results also point out that membrane depolarization increases approx. 2-fold the rate of Na+/Ca2+ exchange in synaptic plasma membrane vesicles.

Biophysical shunt theory for neuropsychopathology: Part I

We present a new model of the origin of schizophrenia based on biophysical ionic shunts in neuronal (electrical) pathways. Microstructural and molecular evidence is presented for the way in which changes in the neuronal membrane ionic channels may facilitate membrane property rearrangement, leading to a change in the density and composition of the ion channel charge which in turn causes a change in ionic flow orientation and distribution. We suggest that, under abnormal conditions, ionic flow shunts are created which redirect the biophysical collateral neuronal (electrical) pathways, resulting in psychiatric signs and symptoms. This model is complementary to the biological basis of schizophrenia.

Differential inhibition of neuronal calcium entry and [3H]-D-aspartate release by the quaternary derivatives of verapamil and emopamil

1. Verapamil and emopamil are structurally related phenylalkylamine calcium channel/5-HT2 receptor antagonists that differ in their anti-ischaemic properties in experimental studies. The quaternary ammonium derivatives of these compounds were prepared and tested in assays of neuronal voltage-sensitive calcium channel (VSCC) function to determine whether the compounds act at intra- or extracellular sites. 2. The compounds were tested in K(+)-evoked: (1) rat brain synaptosomal 45Ca2+ influx, (2) release of [3H]-D-aspartate from rat hippocampal brain slices and (3) increase of intracellular calcium in rat cortical neurones in primary culture. 3. Verapamil, emopamil and the emopamil quaternary derivative caused concentration-dependent and comparable (IC50 values approximately 30 microM) inhibition of synaptosomal 45Ca2+ influx and [3H]-D-aspartate release. The verapamil quaternary derivative was considerably less active in these assays (IC50 > 300 microM). 4. The evoked increase of intracellular calcium in cortical neurones was inhibited with the following rank order of potency (IC50 value, microM): emopamil (3.6) > verapamil (17) > emopamil quaternary derivative (38) > verapamil quaternary derivative (200). 5. The results suggest that verapamil and emopamil inhibit nerve terminal VSCC function (synaptosomal 45Ca2+ influx and [3H]-D-aspartate release) by acting at distinct intracellular and extracellular sites, respectively. Verapamil and emopamil may inhibit cell body VSCC function (evoked increase of intracellular calcium in neocortical neurones) by acting at both intracellular and extracellular sites. 6. The different 'sidedness' of action of emopamil and verapamil on nerve terminal VSCC function and/or the preferential inhibition of cell body VSCC function by emopamil may at least partially explain the relatively greater neuroprotective efficacy of emopamil in experimental models of ischaemia.

Detection of intracellular free Na+ concentration of synaptosomes by a fluorescent indicator, Na(+)-binding benzofuran isophthalate: the effect of veratridine, ouabain, and alpha-latrotoxin

A novel fluorescent Na+ indicator, Na(+)-binding benzofuran isophthalate (SBFI), was used to follow changes in the intracellular free Na+ concentration ([Na+]i) of synaptosomes. The dye, when loaded into synaptosomes in the form of its acetoxymethyl ester, was responsive to changes of [Na+]. Calibration was made using the 340/380 nm excitation ratio when the cytoplasmic Na+ concentration was equilibrated with different concentrations of extracellular Na+ in the presence of 2 microM gramicidin D. The basal value of [Na+]i in synaptosomes in the presence of 140 mM extracellular Na+ was found to be 10.9 +/- 1.8 mM. Veratridine, which opens potential-dependent Na+ channels, caused a sudden increase in [Na+]i in a concentration-dependent manner (1-20 microM), whereas the effect of ouabain (20 and 50 microM), the inhibitor of the plasma membrane Na+,K(+)-ATPase, was more gradual. The rise in the fluorescence intensity upon addition of veratridine was prevented completely by 2 microM tetrodotoxin. alpha-Latrotoxin, the black widow spider toxin, caused an increase in the fluorescence intensity, which became evident 1 min after the addition of the toxin. The rate of increase was proportional to the concentration of the toxin (0.19-1.5 nM). This report confirms our earlier finding demonstrating a Na(+)-dependent component in the action of alpha-latrotoxin, and shows that changes in [Na+]i in synaptosomes can be followed by SBFI.

Effect of depolarizing agents on the Ca(2+)-independent and Ca(2+)-dependent release of [3H]GABA from sheep brain synaptosomes

The purpose of the present study was to compare the effects of several depolarizing agents on both the membrane potential and on the release of [3H] gamma-aminobutyric acid (GABA) from sheep brain cortex synaptosomes. We examined the effects of KCl, 4-aminopyridine (4-AP), veratridine, ouabain and tetraphenylphosphonium cation (TPP+) on Ca(2+)-independent (carrier-mediated) and Ca(2+)-dependent (exocytotic) release. We found that, in the absence of Ca2+, KCl at 40 mM releases 7.57 +/- 0.65%, veratridine at 50 microM releases 45.85 +/- 2.48%, ouabain at 1 mM releases 8.62 +/- 0.93% and TPP+ at 1 mM releases 4.09 +/- 0.37% of the total accumulated neurotransmitter, provided that the external medium contains Na+. These are about the maximal values of release obtained with each depolarizing agent in a Na+ medium and in the absence of Ca2+. Replacing external Na+ with choline blocks the release observed in the presence of the depolarizing agents in the absence of Ca2+, and this divalent ion can increase [3H]GABA release only for K+ or 4-AP. Synaptosomal depolarization requires Na+ except for K+ depolarization. Furthermore, although Ca2+ stimulates the release of [3H]GABA due to K+ depolarization (13.56 +/- 0.44%) or due to 4-AP (4.26 +/- 0.51%), it inhibits the release due to the other depolarizing agents. The amount of [3H]GABA released by 4-AP in Na+ medium (4.26 +/- 0.51%) is similar to that induced by KCl in the presence of Ca2+ in the absence of Na+ (3.39 +/- 0.29%) which represents only exocytotic release. This suggests that the Ca(2+)-dependent exocytotic release of [3H]GABA can be specifically induced by 4-AP in a Na+ medium, or by KCl in the absence of Na+, as reported by us earlier. The observation that Ca2+ inhibits the Ca(2+)-independent release is of interest because it suggests that Ca2+ may modulate the release of cytoplasmic GABA probably by inhibiting the carrier-mediated release of GABA. It is of interest as to whether Ca2+ regulation depends on intracellular Ca2+.

On the mechanism of ouabain-induced release of acetylcholine from synaptosomes

Ouabain (5 x 10(-8)-5 x 10(-4) M) was confirmed to cause a dose-dependent increase in [3H]acetylcholine ([3H]ACh) release, cytosolic free Ca2+ concentration ([Ca2+]i), and 22Na+ uptake in cerebrocortical synaptosomes of rats in the presence of extracellular Ca2+. Ouabain also caused a dose-dependent decrease in membrane potential. In a low-Na+ (10 mM) medium, ouabain failed to increase [3H]ACh release and [Ca2+]i. Tetrodotoxin (10(-6) M) had no effect on the ouabain-induced increase in both [3H]ACh release and [Ca2+]i but abolished the increase in 22Na+ uptake and partially inhibited the depolarizing effect. Verapamil (10(-6)-5 x 10(-4) M) inhibited the ouabain-induced increase in both [3H]ACh release and [Ca2+]i in a dose-dependent manner. Removal of extracellular Ca2+ abolished the effect of ouabain on [Ca2+]i but not on [3H]ACh release and 22Na+ uptake, regardless of the presence or absence of EGTA. In the absence of extracellular Ca2+, 10 mM Mg2+ blocked ouabain-induced [3H]ACh release, which was resistant to verapamil. These results suggest that ouabain can increase ACh release from synaptosomes without the preceding increases in intracellular Ca2+ and/or Na+ content. It seems likely that the removal of extracellular Ca2+ unmasks mechanisms of ouabain action different from those operating in the presence of Ca2+.

Mode of action of palytoxin on the release of acetylcholine from rat cerebrocortical synaptosomes

Palytoxin (PTX; 10(-14)-10(-6) M) caused a dose-dependent increase in the release of [3H]acetylcholine ([3H]ACh), cytosolic free Ca2+ concentration ([Ca2+]i), and uptake of 22Na+ and decrease in membrane potential in rat cerebrocortical synaptosomes. The dose-response curves for the PTX-induced increases in [3H]ACh release and in [Ca2+]i were depressed by removing extracellular Ca2+ or by decreasing extracellular Na+ concentrations. The release of [3H]ACh induced by concentrations of PTX less than 10(-10) M was more dependent on the simultaneous presence of both Ca2+ and Na+ than the release induced by higher concentrations of PTX. The PTX-induced increase both in [3H]ACh release and in [Ca2+]i was almost completely abolished by the combination of Ca2+ deprivation and Na+ concentration reduction. All responses to PTX were highly resistant to 10(-6) M tetrodotoxin. These results suggest that low concentrations of PTX cause depolarization as a result of an increase in Na+ permeability through tetrodotoxin-insensitive channels. This, in turn, increases Ca2+ influx and leads to an increase in the release of ACh. It appears that at high concentrations PTX increases the release of [3H]ACh by directly increasing the influx of Ca2+ into synaptosomes and by releasing Ca2+ from intracellular storage sites via an Na(+)-Ca2+ exchange mechanism.

Effects of monensin and veratridine on acetylcholine release and cytosolic free Ca2+ levels in cerebrocortical synaptosomes of rats

Monensin (10(-8)-10(-4) M) caused a dose-dependent increase in the release of [3H]acetylcholine ([3H]ACh) from purified rat cerebrocortical synaptosomes, with an EC50 of approximately 1.6 x 10(-6) M. Extracellular Na+, but not Ca2+, was required for a monensin-induced increase in the release of [3H]ACh. Monensin also increased the cytosolic free Ca2+ concentration ([Ca2+]i) and uptake of 22Na+ in a dose-dependent manner. Monensin continued to cause a dose-dependent increase in [Ca2+]i in the absence of extracellular Ca2+, although an approximately 50% reduction was noted at concentrations of greater than 10(-5) M. The EC50 for the monensin-induced increase in [Ca2+]i was similar to that noted in the release of [3H]ACh. Veratridine exhibited effects similar to those of monensin, but a large portion of the increase in [Ca2+]i and [3H]ACh release was dependent on extracellular Ca2+. Measurements of rhodamine 6G fluorescence indicated that monensin and veratridine caused synaptosomal hyperpolarization and depolarization, respectively. Tetrodotoxin (10(-6) M) completely blocked all the effects of veratridine but had no effect on the activity of monensin. These results suggest that monensin increases the release of ACh at least in part by increasing [Ca2+]i, resulting from the increase in the Na+ influx through tetrodotoxin-insensitive mechanisms in rat cerebrocortical synaptosomes.

Inhibition of sodium-potassium-ATPase: a potentially ubiquitous mechanism contributing to central nervous system neuropathology

Direct and indirect evidence suggests that Na+/K(+)-ATPase activity is reduced or insufficient to maintain ionic balances during and immediately after episodes of ischemia, hypoglycemia, epilepsy, and after administration of excitotoxins (glutamate agonists). Recent results show that inhibition of this enzyme results in neuronal death, and thus a hypothesis is proposed that a reduction and/or inhibition of this enzyme contributes to producing the central neuropathy found in the above disorders, and identifies potential mechanisms involved. While the extent of inhibition of Na+/K(+)-ATPase during ischemia, hypoglycemia and epilepsy may be insufficient to cause neuronal death by itself, unless the inhibition is severe and prolonged, there are a number of interactions which can lead to a potentiation of the neurotoxic actions of glutamate, a prime candidate for causing part of the damage following trauma. Presynaptically, inhibition of the Na+/K(+)-ATPase destroys the sodium gradient which drives the uptake of acidic amino acids and a number of other neurotransmitters. This results in both a block of reuptake and a stimulation of the release not only of glutamate but also of other neurotransmitters which modulate the neurotoxicity of glutamate. An exocytotic release of glutamate can also occur as inhibition of the enzyme causes depolarization of the membrane, but exocytosis is only possible when ATP levels are sufficiently high. Postsynaptically, the depolarization could alleviate the magnesium block of NMDA receptors, a major mechanism for glutamate-induced neurotoxicity, while massive depolarization results in seizure activity. With less severe inhibition, the retention of sodium results in osmotic swelling and possible cellular lysis. A build-up of intracellular calcium also occurs via voltage-gated calcium channels following depolarization and as a consequence of a failure of the sodium-calcium exchange system, maintained by the sodium gradient.

Phosphatidylserine vesicles increase Ca2+ uptake by rat brain synaptosomes

Phosphatidylserine (PS) vesicles incorporated into rat brain synaptosomes increased total Ca2+ uptake. Total Ca2+ uptake was resolved in three components: K+ depolarization-induced Ca2+ uptake, Na+/Ca2+ exchange, and passive Ca2+ entry, which were differently affected by PS depending on the amount of incorporated phospholipid. K+ depolarization-induced Ca2+ uptake was stimulated by 0.05-0.10 mumol PS/mg protein while 0.10-0.30 mumol PS/mg protein increased Na+/Ca2+ exchange activity and passive Ca2+ entry but not K+ depolarization-induced Ca2+ uptake. High amounts of incorporated PS also increased passive Rb+ uptake.

Inhibition of K(+)-evoked [3H]D-aspartate release and neuronal calcium influx by verapamil, diltiazem and dextromethorphan: evidence for non-L/non-N voltage-sensitive calcium channels

The effects of inhibitors of voltage-sensitive calcium channels (VSCC) on K(+)-evoked [3H]D-aspartate release from rat hippocampal slices and the K(+)-evoked increase in intracellular calcium in neocortical neurons in primary culture were examined. K+ caused a concentration-dependent release of [3H]D-aspartate that was approximately 85% dependent on the presence of extracellular calcium. Neither the marine snail toxin, omega-conotoxin GVIA, nor the dihydropyridine VSCC antagonist, nitrendipine, had any effect on K(+)-evoked release of [3H]D-aspartate. omega-Conotoxin GVIA and nitrendipine caused a relatively small (20-30%) inhibition of K(+)-evoked increase in intracellular calcium in neocortical neurons in primary culture. This suggests that K(+)-evoked [3H]D-aspartate release is not dependent on L- or N-type VSCC, whereas K(+)-evoked neuronal calcium influx was only partially dependent on L- and N-type VSCC. Verapamil, dextromethorphan and diltiazem caused a concentration-dependent inhibition of K(+)-evoked release of [3H]D-aspartate with IC50 values of 30, 100 and 120 microM, respectively. The K(+)-evoked increase in intracellular calcium was inhibited with essentially the same rank order of potency, but with slightly greater potencies (IC50 values for verapamil, diltiazem and dextromethorphan were 20, 50 and 50 microM, respectively). At 300 microM, neither verapamil, diltiazem nor dextromethorphan inhibited [3H]D-aspartate release evoked by the calcium ionophore ionomycin, suggesting that these compounds are not acting intracellularly to inhibit the ability of free cytosolic calcium to evoke release.(ABSTRACT TRUNCATED AT 250 WORDS)

Uptake and release of glycine in cerebellar granule cells and astrocytes in primary culture: potassium-stimulated release from granule cells is calcium-dependent

The properties of [3H]glycine uptake and release were studied with cerebellar granule cells, 7-9 days in vitro, (DIV) and astrocytes, 14-15 DIV, in primary cultures. The uptake of glycine in both cell types consisted of a saturable high-affinity transport and nonsaturable diffusion. The transport constant (Km) and maximal velocity (V) were significantly higher in granule cells than in astrocytes. Uptake was strictly Na+-dependent and also markedly diminished in low-Cl medium. The specificity of the uptake was similar in both cell types. The spontaneous release of glycine from granule cells and astrocytes was fast. Homoexchange with extracellularly added glycine in granule cells suggests that the efflux is at least partly mediated via membrane transport sites in these cells. Kainate stimulated the release more effectively in neurons than in glial cells, the effect apparently being mediated by specific kainate-sensitive receptors in both cell types. The release was enhanced by veratridine and by depolarization of cell membranes by high K (50 mM) in both neurons and astrocytes. The potassium-stimulated release was partially Ca-dependent in neurons but Ca-independent in glial cells. The results suggest a functional role for glycine in both cerebellar astrocytes and glutamatergic granule cells.

Effects of diltiazem on bioenergetics, K+ gradients, and free cytosolic Ca2+ levels in rat brain synaptosomes submitted to energy metabolism inhibition and depolarization

Diltiazem was able to decrease the oxygen consumption rate and lactate production in synaptosomes isolated from rat forebrains, both under control and depolarized (40 microM veratridine) conditions, starting from a concentration of 250 microM. This effect was particularly evident when synaptosomes were depolarized by veratridine. This depolarization-counteracting action was evident also when transplasma membrane K+ diffusion potentials were measured after depolarization induced by veratridine and by rotenone with a glucose shortage. The concentrations of ATP, phosphocreatine, and creatine were less sensitive to diltiazem action. The concentration/response relationships were the same as those found for the oxygen consumption were the same as those found for the oxygen consumption rate, lactate production, and K+ diffusion potentials. The effects of 0.5 mM diltiazem in counteracting inhibition of energy metabolism induced by rotenone without glucose were no longer detectable when either Ca2+ or Na+ was absent from the incubation medium of synaptosomes. Diltiazem at the same concentrations (starting from 250 microM) was able to inhibit both the veratridine-induced and the rotenone-without-glucose-induced increase in intrasynaptosomal free Ca2+ levels evaluated with the fluorescent probe quin2. The results are discussed in view of a possible effect of diltiazem on voltage-dependent Na+ channels and the possibility of utilizing this approach for counteracting neuronal failure due to derangement of energy metabolism or hyperexcitation.

Is the augmentation of K+-evoked intrasynaptosomal Ca2+ concentration due to the influx of Ca2+ in rat brain synaptosomes?

Intraterminal free Ca2+ concentration modulates the subsequent release of neurotransmitters. Depolarization of synaptosomes with 29 mM K+ augments cytosolic free Ca2+ concentration, which is triphasic, the peak times being at 10, 60, and 180 s. We examined the characteristics of each elevation of cytosolic free Ca2+ concentration in rat brain synaptosomes which had been preincubated for 3 min with a Ca2+-channel blocker, such as La3+, diltiazem, nifedipine, or verapamil, and under conditions of hypoxia or acidosis. The concentration of free Ca2+ in the quin-2-loaded rat brain synaptosomes was detected fluorometrically. All these elevations were suppressed in the presence of 200 microM EGTA or 100 microM La3+. At the first phase, the elevation of cytosolic free Ca2+ concentration with high K+ stimuli was significantly inhibited by La3+ (20 microM) or by acidosis (pH 6.7). On the other hand, diltiazem, which is a more potent blocker of the release of Ca2+ from the mitochondria, inhibited the increasing cytosolic free Ca2+ concentration at the third phase in a concentration-dependent manner. Hypoxia also showed inhibition at the third phase. These results suggest that the augmentation of high K+-evoked cytosolic free Ca2+ concentration may be due to the influx of extracellular Ca2+. The increase in cytosolic free Ca2+ concentration at the third phase is no doubt linked to the mitochondrial function.

The effect of K+ and glutamate receptor agonists on the membrane potential of suspensions of primary cultures of rat astrocytes as measured with a cyanine dye, DiS-C2-(5)

The cyanine dye DiS-C2-(5) was used to investigate the effect of K+ and glutamate receptor agonists on the membrane potential of whole populations of primary rat astrocytes in suspension. Increasing the external K+ concentration from 5 to 40 mM caused a depolarization of the cells. Ba2+ blocked the response to K+, whereas 4-aminopyridine had no effect on the depolarization. The effect of added external K+ was enhanced by the addition of the neutral K+ ionophore valinomycin. This supports the view that the membrane potential of primary astrocytes is dependent of the K+ gradient, and suggests that the membrane is not ideally permeable to K+ ions. Glutamate caused a depolarization of the cells which was not affected by Ba2+. In the presence of veratridine and ouabain no effect of glutamate was seen. The cells were also depolarized by the glutamate receptor agonists quisqualate, kainate and N-methyl-D-aspartate (NMDA). The response to kainate was blocked by kynurenate, which also diminished the depolarization caused by glutamate. NMDA was effective when added after kainate. The effect of the glutamate receptor agonists tested was generally smaller than that of glutamate itself, and a prior addition of one of the agonists diminished the response to glutamate. The results obtained suggest that cyanine dyes are well suited for investigating the behavior of whole populations of cultured primary astrocytes.

Ca2+-dependent and Ca2+-independent glutamate release, energy status and cytosolic free Ca2+ concentration in isolated nerve terminals following metabolic inhibition: possible relevance to hypoglycaemia and anoxia

Hypoglycaemia and anoxia both cause massive release of glutamate from the brain in vivo, and the nature of this release was investigated using guinea-pig cerebral-cortical synaptosomes and iodoacetate and rotenone to simulate the energetic consequences of these conditions. Glutamate release (by continuous fluorimetry), cytoplasmic free Ca2+ (by fura-2), membrane potentials, ATP, ADP and creatine phosphate were determined in parallel, following the addition of iodoacetate or rotenone, alone or in combination. Ca2+-dependent glutamate release had a high energy requirement which could only be satisfied by aerobic glycolysis. Respiration using endogenous substrates, or anaerobic glycolysis following rotenone, caused a progressive inhibition of Ca2+-dependent release, correlating with a decline in the total ATP/ADP ratio and creatine phosphate. With rotenone, an increase in Ca2+-independent glutamate release was observed, correlating with a decline in plasma membrane potential. Only a slight increase in free Ca2+ was seen. Rotenone plus iodoacetate caused an almost immediate collapse of ATP/ADP ratio and a parallel loss of Ca2+-dependent glutamate release before free Ca2+ had risen to a level sufficient for exocytosis. In contrast, Ca2+-independent glutamate release increased. The Ca2+-dependent release of L-glutamate had the characteristics of an exocytotic transmitter release mechanism, being energy-dependent and triggered by elevated cytoplasmic free Ca2+ concentration. A distinct Ca2+-independent release of cytoplasmic glutamate occurred by reversal of the Na+-coupled uptake carrier, which was accelerated by a decline in the Na+ gradient. It is concluded that the Ca2+-independent release of cytoplasmic glutamate may make the major contribution to the excitotoxic release of glutamate in hypoglycaemic and anoxic conditions.

Depolarization-induced release of glycine and beta-alanine from plasma membrane vesicles derived from rat brain synaptosomes

Glycine and beta-alanine actively loaded into brain synaptic plasma membrane vesicles were released into the external medium by using the classical depolarization agents high K+ and veratridine. This release occurs via a Ca2+-independent process. Measurements of membrane depolarization using tetraphenylphosphonium uptake show a close correlation between changes in the membrane potential and stimulation of the efflux process. Results shown herein and previously reported by our group (Aragón, M.C. and Giménez, C. (1986) Biochim. Biophys. Acta 855, 257-264; Agulló, L., Jiménez, B., Aragón, M.C. and Giménez, C. (1986) Eur. J. Biochem. 159, 611-617), suggest that the glycine and beta-alanine transport systems in synaptic plasma membranes are susceptible of modulation by changes in ionic fluxes and hence in the membrane potential, similar to those occurring during depolarization and repolarization.

Studies on the mechanism by which tryptophan efflux from isolated synaptosomes is stimulated by depolarization

1. The efflux and influx of tryptophan across the synaptosomal plasma membrane has been studied under a variety of experimental conditions, in order to examine the mechanism by which depolarization enhances the efflux of tryptophan from superfused synaptosomes. 2. Efflux of [3H]-tryptophan from preloaded superfused synaptosomes was found to be enhanced by K+ depolarization in a Ca2+ and dose-dependent manner. In contrast, [3H]-phenylalanine efflux was only poorly stimulated by depolarization and only by very high concentrations of K+. 3. Tryptophan efflux was also enhanced by decreasing the extracellular Na+ concentration, but this effect was not dependent on extracellular Ca2+. 4. Influx of [3H]-tryptophan into synaptosomes was stimulated by extracellular Na+ removal, but the uptake of [3H]-phenylalanine was unaffected by this procedure. 5. Both the induced influx and efflux of tryptophan observed under these experimental conditions was inhibited by immobilizing the plasma membrane carrier with parachlorophenylalanine. This implied that both the enhanced influx and efflux arose as a consequence of the activation of the membrane tryptophan carrier, the direction of the observed effect being dependent upon the manner in which the experiments were conducted. 6. The relationship between depolarization, the activation of the membrane tryptophan carrier and the significance of this to the in vivo situation is discussed.

Differential effects of calcium entry blockers on pre- and postsynaptic influx of calcium in the rat hippocampus in vitro

A decrease in extracellular free Ca ([Ca2+]o) in response to stimulation of Schaffer collaterals could be recorded in or near the stratum pyramidale even when synaptic transmission was completely blocked. Under the same conditions, alvear stimulation also evoked a decrease in [Ca2+]o at the same site. We attributed the former to influx of Ca2+ into presynaptic terminals and the latter to influx into postsynaptic (pyramidal) cells. Both pre- and postsynaptic Ca2+ influx were completely blocked by Ni2+ (2.5 mM). Nifedipine (5-10 microM). verapamil (50-100 microM) and fendiline (100-200 microM) reduced the postsynaptic influx of Ca2+ but did not alter Ca2+ loss from the extracellular space into presynaptic terminals. The calcium channel activators, BAY-K 8644 and CGP 28,392, had no consistent effect on either pre- or postsynaptic influx. Occasional enhancement of both pre- and postsynaptic responses was seen. In most studies the agents were without effect and on occasions a reduction in both responses was seen. The results could indicate that Ca-channels at pre- and postsynaptic sites in CA1 may be of different types.

Characterization of the exocytotic release of glutamate from guinea-pig cerebral cortical synaptosomes

A continuous enzyme-linked fluorometric assay was used for determining the characteristics for glutamate exocytosis from guinea-pig cerebrocortical synaptosomes. Ca2+-dependent release can be induced not only by K+, but also by the Na+ channel activator veratridine and the Ca2+ ionophore ionomycin. K+-induced release can be inhibited by the Ca2+ channel inhibitor verapamil. Sr2+ and Ba2+ substitute for Ca2+ in promoting K+-induced release. Agents that would be predicted to transform the transvesicular pH gradient into a membrane potential are without effect on glutamate release. However, the protonophore carbonylcyanide p-trifluoromethoxyphenylhydrazone causes a time-dependent loss of exocytosis that is oligomycin insensitive and may be due to depletion of vesicular glutamate. The Ca2+-independent release of glutamate from the cytosol on depolarization is unchanged or promoted by metabolic inhibitors that lower the ATP/ADP ratio. In contrast. Ca2+-dependent release is ATP dependent and is blocked by the combined inhibition of oxidative phosphorylation and glycolysis.

Calcium and the aging nervous system

Many aspects of calcium homeostasis change with aging. Numerous calcium compartments complicate studies of altered calcium regulation. However, age-related decreases in calcium permeation across membranes and mobilization from organelles may be a common fundamental change. Deficits in ion movements appear to lead to altered coupling of calcium-dependent biochemical and neurophysiological processes and may lead to pathological and behavioral changes. The calcium-associated changes during aging probably do not occur with equal intensity in all cell types or in different parts of the same cell. Thus, cells or compartments with a high proportion of calcium activated processes would be more sensitive to diminished calcium availability. These age-related changes may predispose the brain to the development of age-related neurological disorders. The effects of decreased ion movement may be further aggravated by an age-related decline in other calcium-dependent processes. Depression of some of these calcium-dependent functions appears physiologically significant, since increasing calcium availability ameliorates age-related deficits in neurotransmission and behavior. A better understanding of the interactions between calcium homeostasis and calcium-dependent processes during aging will likely help in the design of more effective therapeutic strategies.

4-Aminobutyrate can be released exocytotically from guinea-pig cerebral cortical synaptosomes

Guinea-pig synaptosomes possess two functional pools of 4-aminobutyrate (GABA). One is rapidly labelled by added [14C]GABA, is steadily released in a Ca2+-independent manner when the Na+ electrochemical potential across the plasma membrane is collapsed, and is depleted by the GABA analogue 2,4-diaminobutyrate (DABA), all of which is consistent with a cytosolic location. A second, noncytosolic compartment only slowly equilibrates with exogenous [14C]GABA, is not depleted by DABA, but can release 350 pmol of endogenous GABA/mg of protein (8% of the total intrasynaptosomal GABA) within 15 s of depolarization in the presence of Ca2+. Ca2+-independent release occurs by thermodynamic reversal of the plasma membrane uptake pathway following artifactually prolonged depolarization, whereas Ca2+-dependent release is consistent with physiological exocytosis from vesicular stores.

The possible involvement of the phospholipid phase of membranes in mediating the effects of verapamil on Ca2+ transport

The effect of verapamil in a model system of A23187-induced Ca2+-uptake into liposomes was studied. This was done in order to separate the effects of verapamil on the lipid phase of membranes from its effects on membraneous proteins. In the absence of A23187, the liposomes exhibited a very low Ca2+ permeability, which did not change with addition of verapamil. Creation of a valinomycin-induced negative inside membrane potential combined with increased membrane permeability to Ca2+ (A23187), increased Ca2+-entry fivefold and more. Addition of verapamil under these conditions led to a further increase in Ca2+ entry. The negative inside polarization of the liposomes' membrane (as estimated from [3H]TPP+ uptake) was not affected by verapamil. [3H] Verapamil bound specifically to native synaptic plasma membranes with a Kd = 87.4 nM +/- 21.5 (SD) and Bmax = 2.19 pmol/mg protein +/- 0.92 (SD). Specific binding to the liposomes could not be demonstrated. High nonspecific binding of up to about 20% of the total verapamil in the external solution was observed (3.8 pmoles [3H]verapamil/mg phospholipid when 30 nM verapamil was used and 50 nmoles/mg phospholipid when 200 microM [3H] verapamil was used). The high nonspecific binding of verapamil to the liposomes had no detectable effect on the fluidity of their membrane, as seen in fluorescence-anisotropy studies with the fluorescent probe DPH.

Ionic dependence of membrane potential and glutamate receptor-linked responses in synaptoneurosomes as measured with a cyanine dye, DiS-C2-(5)

Membrane potentials of particles present in a subcellular brain preparation, called synaptoneurosomes, have been monitored by measurement of changes in the absorbance of a cyanine dye, DiS-C2-5. The membrane potential of the particles seems to be dependent on both Cl- and K+ diffusion potentials, as judged from dependence of the absorbance changes on the K+ equilibrium potential across the membrane in the presence of Ba2+ or when Cl- was replaced with gluconate. The apparent high Cl- permeability of the membrane preparation was reduced in the presence of picrotoxin, a finding suggesting endogenous activation of receptor-linked Cl- channels. Glutamate and kainate caused depolarization of the membranes present in the preparation. This effect was only seen if K+ channels had been blocked in the presence of Ba2+ or 4-aminopyridine. No responses were observed with other glutamate receptor agonists (quisqualate or N-methyl-D-aspartate). The membrane potential of particles present in conventional synaptosomal preparations neither had a high Cl- permeability nor reacted to glutamate or kainate in the present conditions. The results suggest that synaptoneurosome preparations may be used for functional studies on postsynaptic neurotransmitter receptor-linked membrane potential changes with optical probes of membrane potential.

Effects of Ca2+ channel blockers on Ca2+ translocation across synaptosomal membranes

The binding of [3H]nimodipine to purified synaptic plasma membranes (SPM) isolated from sheep brain cortex was characterized, and the effects of nimodipine, nifedipine, and (+)-verapamil on the [3H]nimodipine binding were compared to the effects on 45Ca2+ translocation under conditions that separate 45Ca2+ fluxes through Ca2+ channels from 45Ca2+ uptake via Na+/Ca2+ exchange. [3H]Nimodipine labels a single class of sites in SPM, with a KD of 0.64 +/- 0.1 nM, a Bmax of 161 +/- 27 fmol X mg-1 protein, and a Hill slope of 1.07, at 25 degrees C. Competition of [3H]nimodipine binding to purified SPM with unlabelled Ca2+ channel blockers shows that: nifedipine and nimodipine are potent competitors, with IC50 values of 4.7 nM and 5.9 nM, respectively; verapamil and (-)-D 600 are partial competitors, with biphasic competition behavior. Thus, (+)-verapamil shows an IC50 of 708 nM for the higher affinity component and the maximal inhibition is 50% of the specific binding, whereas for (-)-verapamil the IC50 is 120 nM, and the maximal inhibition is 30%; (-)-D 600 is even less potent than verapamil in inhibiting [3H]nimodipine binding (IC50 = 430 nM). However, (+)-verapamil, nifedipine, and nimodipine are less potent in inhibiting depolarization-induced 45Ca2+ influx into synaptosomes in the absence of Na+/Ca2+ exchange than in competing for [3H]nimodipine binding. Thus, (+)-verapamil inhibits Ca2+ influx by 50% at about 500 microM, whereas it inhibits 50% of the binding at concentrations 200-fold lower, and the discrepancy is even larger for the dihydropyridines. The Na+/Ca2+ exchange and the ATP-dependent Ca2+ uptake by SPM vesicles are also inhibited by the Ca2+ channel blockers verapamil, nifedipine, and d-cis-diltiazem, with similar IC50 values and in the same concentration range (10(-5)-10(-3) M) at which they inhibit Ca2+ influx through Ca2+ channels. We conclude that high-affinity binding of the Ca2+ blockers by SPM is not correlated with inhibition of the Ca2+ fluxes through channels in synaptosomes under conditions of minimal Na+/Ca2+ exchange. Furthermore, the relatively high concentrations of blockers required to block the channels also inhibit Ca2+ translocation through the Ca2+-ATPase and the Na+/Ca2+ exchanger. In this study, clear differentiation is made of the effects of the Ca2+ channel blockers on these three mechanisms of moving Ca2+ across the synaptosomal membrane, and particular care is taken to separate the contribution of the Na+/Ca2+ exchange from that of the Ca2+ channels under conditions of K+ depolarization.

Calcium channel agonists and antagonists regulate protein phosphorylation in intact synaptosomes

Protein phosphorylation in intact synaptosomes is highly sensitive to alterations in calcium fluxes and was used to probe the possible mechanism of action of the calcium channel agonist BAY K 8644 and antagonists verapamil and nifedipine. These agents (at 1 microM) all increased the basal phosphorylation of a specific set of 4 synaptosomal phosphoproteins termed P139, P124, P96 and P60, but did not alter depolarization-dependent protein phosphorylation. The increases could not be explained by a direct stimulation of protein kinases and appears unrelated to the known effects of these drugs on K+-stimulated neurotransmitter release. This finding may reveal a possible new mechanism of action for drugs which interact with calcium channels.

Quantitative measurements of the cytosolic Ca2+ activity within isolated guinea pig nerve-endings using entrapped arsenazo III and quin2

The absorbance changes of intrasynaptosomally entrapped arsenazo III have been converted into values of free Ca2+ concentration by correcting for the nonlinear response of arsenazo III at different concentrations of the dye as well as for changes in internal pH. An average resting value for free Ca2+ concentration around 0.4 microM is obtained. Depolarization with veratridine or gramicidin increases this value to around 3 microM. Measurements of cytosolic free Ca2+ with the quin2 method gives much lower values in similar conditions. The release of prelabelled [14C]noradrenaline from the nerve-endings is maximally activated when the internal free Ca2+ concentration rises as measured with arsenazo III to about 4 microM when titrated with increasing concentrations of ionophore A23187.

Leptinotoxin-h action in synaptosomes, neurosecretory cells, and artificial membranes: stimulation of ion fluxes

Leptinotoxin-h (LPTx), a neurotoxin (otherwise designated beta-leptinotarsin-h) known to stimulate the release of neurotransmitters from synapses, was purified from the hemolymph of the potato beetle, Leptinotarsa haldemani, by a simplification of the procedure originally developed by Crosland et al. [Biochemistry 23, 734-741, (1984)]. Highly and partially purified preparations of the toxin were applied to guinea pig synaptosomes and neurosecretory (PC12) cells. When applied in a Ca2+-containing Ringer medium, at concentrations in the 10(-11) - 10(-10) M range, the toxin induced: (a) rapid depolarization of the plasma membrane, which was not inhibited by organic blockers of voltage-dependent Na+ and Ca2+ channels (tetrodotoxin or verapamil); (b) large 45Ca influx; and (c) increased free cytosolic Ca2+ concentration. These latter two effects were unaffected by verapamil. In Ca2+-free media the effects of the toxin were different in the two systems investigated. In synaptosomes, depolarization was still observed, even if the toxin concentrations needed were higher (approximately 10X) than those effective in the complete medium. In contrast, in PC12 cells no effect of the toxin on membrane potential was observed. Binding of LPTx to its cellular targets could not be investigated directly because the toxin was inactivated by the procedures used for its labeling. Indirect evidence suggested however that Ca2+ is necessary for toxin binding to PC12 cells. Interaction of LPTx with air/water interfaces, as well as with cholesterol/phospholipid mono- and bilayer membranes was investigated. The results indicate that the toxin has affinity for hydrophobic surfaces, but lacks the capacity to insert across membranes unless transpositive voltage is applied. Our results are inconsistent with the previous conclusion of Crosland et al. (1984), who suggested opening of the Ca2+ channel as the mechanism of action of LPTx. The effects of the toxin resemble those of alpha-latrotoxin (alpha-LTx) of the black widow spider venom, and therefore the two toxins might act by similar mechanisms. However, the sites recognized by the two toxins might be different, because LPTx does not inhibit alpha-LTx binding.

Leptinotoxin-h action in synaptosomes and neurosecretory cells: stimulation of neurotransmitter release

Guinea pig brain cortex synaptosomes and neurosecretory PC12 cells were loaded with [3H]3,4-dihydroxyphenylethylamine ([3H]DA, [3H]dopamine) and then exposed to leptinotoxin-h (LPTx) (purified and partially purified preparations, obtained from the hemolymph of Leptinotarsa haldemani). In a Ca2+-containing Ringer medium the toxin induced prompt and massive release of the neurotransmitter. Half-maximal effects were obtained at concentrations estimated of approximately 3 X 10(-11) M for synaptosomes, and 1.5 X 10(-10) M for PC12 cells. Release responses in the two experimental systems investigated were dependent to different extents on the Ca2+ concentration in the medium. In synaptosomes clear, although slow, release of [3H]DA was elicited by the toxin even in Ca2+-free, EGTA-containing medium, provided that high (in the 10(-10) M range) concentrations were used; near-maximal responses were observed at 10(-5)M Ca2+. In contrast, the toxin-induced release from PC12 cells was appreciable only at 3 X 10(-5) M Ca2+, and was maximal at 2 X 10(-4) M and above. In both synaptosomes and PC12 cells Sr2+ and Ba2+ could substitute for Ca2+; Co2+ was inhibitory, whereas Mn2+ failed to modify the release induced by the toxin in Ca2+-containing medium. Organic blockers of the voltage-dependent Ca2+ channel (verapamil and nitrendipine) and calmodulin blocking drugs (trifluoperazine and calmidazolium) failed to inhibit the toxin-induced release of [3H]DA. LPTx induced profound morphological effects. Synaptosomes treated in the Ca2+-containing medium exhibited fusion of synaptic vesicles, formation of numerous infoldings and large cisternae, and alterations of mitochondria. In the Ca2+-free medium the effects were similar, except that their appearance was delayed, and mitochondria were well preserved. Swelling was observed in PC12 cells, accompanied by enlargement of the Golgi area, accumulation of multivesicular bodies, mitochondrial alterations, and decreased number of secretion granules (Ca2+-containing medium). Morphometric analyses revealed a good correlation between the decrease of both synaptic vesicles (synaptosomes) and neurosecretory granules (PC12 cells), and the release of [3H]DA measured biochemically. This is a good indication that the release effect of the toxin is due to stimulation of exocytosis. Taken as a whole, these results confirm the similarity of the effects of LPTx with alpha-latrotoxin of the black widow spider venom, mentioned in the companion article. However, differences in effect and target specificity suggest that the two toxins are specific to separate binding sites.(ABSTRACT TRUNCATED AT 400 WORDS)

Kainate-induced uptake of calcium by synaptosomes from rat brain

Kainic acid induces a rapid increase in 45Ca2+ uptake by crude synaptosomal fractions isolated from rat brain. This enhanced Ca2+ permeability occurs with a half-time of approx. 1 s, similar to the fast phase of depolarization-induced calcium uptake. The depolarization-induced uptake of calcium is inhibited 85% by 3 mM CoCl2, 80% by 100 microM quinacrine and 50% by 15 microM trifluoperazine while these agents had little effect on the kainate-induced uptake. It is proposed that kainate induces receptor-mediated opening of a class of calcium channels with properties different from those of the voltage-dependent channels.

Preincubation of synaptosomes in the presence of sodium affects Ca2+ uptake

Preincubation of synaptosomes in standard physiological medium stimulates 2-fold Ca2+ uptake as compared to non-preincubated synaptosomes. When the sodium concentration in the preincubation medium has been halved, Ca2+ uptake was reduced by approximately 50 percent. The addition of ouabain to the preincubation medium decreases depolarization-stimulated Ca2+ uptake by about 40 percent. A steady-state level of Ca2+ uptake is achieved by synaptosomes preincubated for 0, 5 or 10 min. These findings suggest that Ca2+ uptake might depend on the Na-gradient formed during the preincubation of synaptosomes under control conditions.

Dependence of cytoplasmic calcium transients on the membrane potential in isolated nerve endings of the guinea pig

The relation of changes in internal, free Ca2+, measured with arsenazo III, to the membrane potential, measured with the cyanine dye di-S-C2(5) or 86Rb+ distribution ratio, was studied in isolated guinea pig cortical nerve endings. Depolarization of the plasma membrane with veratridine or gramicidin as well as addition of ionophore A23187 led to an increase in cytosolic Ca2+. Only the response to veratridine was inhibited by tetrodotoxin. The dependence of the depolarization-induced increase in intraterminal, free Ca2+ on the membrane potential between about -50 to 0 mV was sigmoidal. A maximal increase in cytosolic Ca2+ was reached when the membrane potential was depolarized from the resting level, about -64 mV, to about -40 mV. These results show that in isolated nerve endings the activation of voltage-sensitive Ca2+ channels concomitantly leads to an increase in cytosolic, free Ca2+. Comparison of the results of the present study with the previous electrophysiological observations indicate that Ca2+ channels in synaptosomes, presynaptic nerve terminals of the squid giant synapse and cardiac cells have essentially similar voltage dependency.

Biochemical effects of cerebral ischemia: relevance to migraine

Although decreased CBF has now been reported during the prodrome of migraine, the cause of the decreased flow is still unknown. It is particularly unclear whether these phenomena are related to vasospasm and "steal" between the extracranial and intracranial circulation or to the spreading depression of Leao and the accompanying metabolic depression. In the present paper, metabolic changes in the brain during ischemia and reperfusion are reviewed and compared with CNS biochemical changes during migraine attack. In addition, the technique of Topical Magnetic Resonance (TMR) as applied to the in vivo study of energy phosphate metabolism in extracranial tissues and brain is described and the potential of this technique to evaluate shifts in energy metabolism and pH in stroke and migraine is discussed.

Calcium efflux and cycling across the synaptosomal plasma membrane

Ca2+ efflux from intact synaptosomes is investigated. Net efflux can be induced by returning synaptosomes from media with elevated Ca2+ or high pH to a normal medium. Net Ca2+ efflux is accelerated when the Na+ electrochemical potential gradient is collapsed by veratridine plus ouabain. Under steady-state conditions at 30 degrees C, Ca2+ cycles across the plasma membrane at 0.38 nmol . min-1 . mg-1 of protein. Exchange is increased by 145% by veratridine plus ouabain, both influx and efflux being increased. Increased influx is probably due to activation of voltage-dependent Ca2+ channels, since it is abolished by verapamil. The results indicate that, at least under conditions of low Na+ electrochemical gradient, some pathway other than a Na+/Ca2+ exchange must operate in the plasma membrane to expel Ca2+.

Mechanism of depolarization of rat cortical synaptosomes at submicromolar external Ca2+ activity. The use of Ca2+ buffers to control the synaptosomal membrane potential

Rat cortical synaptosomes responded to a reduction of external Ca2+ from pCa 3.5 to pCa 4.8 in the absence of MgCl2 with a slight decrease of internal K+ and an increase of Na+. The effects were prevented by tetrodotoxin or millimolar concentrations of MgCl2. Further lowering of external pCa to 7.7 with N-hydroxyethylethylenediaminetriacetate evoked a rapid fall of internal K+, which was specifically blocked by Ruthenium Red; tetrodotoxin and nifedipine were ineffective. A linear relationship was established between K+ and methyltriphenylphosphonium cation distribution ratios by varying external pCa between 4.8 and 7.7, indicating that K+ efflux resulted from a depolarization of the plasma membrane. An increase of Na+ permeability was suggested by the synaptosomes' gain of Na+ and the disappearance of the depolarization in an Na+-free sucrose medium. According to the constant field equation, the permeability ratio PNa/PK increased from 0.029 at pCa4.8 to 0.090 at pCa 7.7 with plasma membrane potentials of -74mV and -47mV, respectively. Since the plasma membrane responded to variation of external Ca2+ activities in the micromolar range with a graded and sustained depolarization, the use of Ca2+ buffers to control membrane potentials is suggested.

Ionophore A23187, verapamil, protonophores, and veratridine influence the release of gamma-aminobutyric acid from synaptosomes by modulation of the plasma membrane potential rather than the cytosolic calcium

The release of GABA induced by veratridine shows no correlation with the synaptosomal Ca content and is therefore not mediated by the release of mitochondrial Ca. Instead, with both Ca-repleted and -depleted synaptosomes, the extent of GABA efflux is correlated with the decrease in plasma membrane potential. The slow release of GABA induced by protonophores and the Ca-dependent release induced by ionophore A23187 are also consequences of the depolarization of the plasma membrane, rather than of elevated cytosolic Ca. Finally, the ability of verapamil to inhibit the release of GABA induced by low veratridine concentrations is due to the ability of the Ca channel inhibitor to antagonize the action of veratridine, rather than to inhibit Ca entry into the synaptosome. It is concluded that it is essential to monitor plasma membrane potentials in experiments in which amino acid efflux from synaptosomes is induced.

Depolarization of the mitochondrial membrane potential increases free cytosolic calcium in synaptosomes

Intracellular calcium transients in synaptosomes, isolated from the guinea pig brain, were measured using entrapped metallochromic indicator arsenazo III. Addition of 1 microM carbonyl cyanide p-trifluoromethoxyphenyl hydrazone (FCCP) increased rapidly the absorbance of the entrapped arsenazo III, indicating an increase in the cytosolic free calcium. The FCCP-induced increase in cytoplasmic free Ca2+ was not blocked by 200 microM verapamil, while the increment in calcium caused by 40 microM veratridine was verapamil-sensitive. The absorbance changes induced by FCCP were not significantly increased when the extracellular potassium concentration was elevated from 5.4 to 50 mM. These data indicate that in nerve endings of mammalian brain, cytoplasmic free calcium, which is essential for the release of transmitter, is increased on depolarization of major intracellular calcium buffers, mitochondria.

The inhibition of Ca uptake in cardiac membrane vesicles by verapamil

Cardiac membrane vesicles take up Ca2+ in response to Na+ gradient (high inside) and negative inside membrane potential. Both components of the Ca2+ uptake, the Na+ gradient dependent uptake and the membrane potential dependent uptake are inhibited by verapamil; the action is dose-dependent and the concentrations of verapamil required to inhibit the Ca2+ uptake to 50% of its maximal value are 50 and 60 microM respectively. In the concentration ranges tested (50-750 microM Ca2+), the inhibitory effect of verapamil could not be antagonized by increasing the Ca2+ concentration of the medium. Introducing verapamil into the vesicles by rapid freezing and slow thawing of the vesicles had the same inhibitory effect as adding the same concentration of verapamil on the outside of the vesicles. Adding verapamil to both sides of the vesicle membrane led to higher inhibition of Ca2+ uptake. It is proposed that addition of verapamil can cause a change in cardiac membranes which is manifested by a decrease in the driving membrane potential and Ca2+ transport.

Membrane potential generation and calcium transport in plasma membrane enriched fractions from fetal human brain

Plasma membrane fractions isolated from fetal human brain of 14-19 weeks of gestation are capable of generating a membrane potential of 30-50 mV as a response to a gradient of K+ ions. Valinomycin, a K+ conducting ionophore, does not affect the membrane potential whereas it is markedly reduced by veratridine which opens Na+ channels in excitable membranes. The membrane fractions concentrate Ca2+ by an ATP-dependent mechanism. The uptake has a high affinity for Ca2+, it is enhanced by oxalate and abolished by the 2H+/Ca2+ exchanger A 23187. Trifluoroperazine (40 microM), a calmodulin antagonist, inhibits Ca2+ uptake by 80%. Addition of Na+ causes efflux of part of the Ca2+ taken up in the presence of ATP, suggesting that a Na+-linked Ca2+ transport is also present in the membranes. The results show that the neuronal membranes of the fetal human brain already in the early second trimester of gestation have properties similar to those of the adult animal brain.

The calmodulin antagonists, trifluoperazine and R24571, depolarize the mitochondria within guinea pig cerebral cortical synaptosomes

The effects of trifluoperazine and 1-[bis(p-chlorophenyl)methyl]-3-[2, 4-dichloro-beta-(2,4- dichlorobenzyloxy )phenethyl]imidazolium chloride ( R2457 ) upon synaptosomal calcium transport, plasma membrane potential, in situ mitochondrial membrane potential, and ATP levels are investigated in order to assess the suitability of these calmodulin antagonists for investigating calmodulin-dependent processes in the nerve terminal. Both agents appear to act selectively at the mitochondrial membrane, causing extensive depolarization at concentrations in excess of 10 microM (trifluoperazine) or 0.5 microM ( R2457 ). The extent of Ca uptake into the synaptosomes is decreased, consistent with the loss of the mitochondrial compartment. There is no inhibition of the efflux of Ca from the synaptosomes. Depolarization-dependent Ca uptake is not prevented by R24571 . Synaptosomal ATP levels decrease to an extent consistent with the collapse of the mitochondrial potential. It is concluded that the uncoupling effect of these agents on the in situ mitochondria prevents their being used to investigate the role of calmodulin in intact synaptosomes.

Calcium uptake related to K+-depolarization and Na+/Ca2+ exchange in sheep brain synaptosomes

The uptake of Ca2+ by synaptosomes induced by K+-depolarization and by Na+/Ca2+ exchange was studied in synaptosomes in which the internal Na+ and K+ contents were varied by prolonged incubation at 30 degrees C or by inhibiting the Na+, K+-ATPase with 1 mM ouabain. Increased Na+ content of the synaptosomes is associated with an increase in Ca2+ uptake when the synaptosomes are placed in depolarizing K+ media. Furthermore, reduction in the [Na+]o, when the [K+]o is increased, in substitution for [Na+]o, to depolarize the membrane, further increases the Ca2+ uptake. Under these conditions, Ca2+ entry probably occurs through voltage-sensitive channels and through the Na+/Ca2+ exchanger. Destruction of the Na+ gradient by monensin, or preloading the synaptosomes with K+, completely inhibits the Ca2+ uptake in a K+-depolarizing medium. It is shown that if the Na+ gradient is maintained constant during K+-depolarization, the Ca2+ uptake is very low and that most of the Ca2+ uptake is correlated with the Na+ gradient. Evidence is presented that K+ may stimulate the Na+/Ca2+ exchange mechanism. Furthermore, divalent cations, Mg2+, Mn2+ and Zn2+, known to block Ca2+ channels, also inhibit Na+/Ca2+ exchange.