M.Graça P Vale

Synaptic vesicle Ca2+/H+ antiport: dependence on the proton electrochemical gradient

Synaptic vesicles isolated from sheep brain cortex accumulate Ca2+ by a mechanism of secondary active transport associated to the H(+)-pump activity. The process can be visualized either by measuring Ca(2+)-induced H+ release or DeltapH-dependent Ca2+ accumulation. We observed that the amount of Ca2+ taken up by the vesicles increases with the magnitude of the DeltapH across the membrane, particularly at Ca2+ concentrations (approximately 500 microM) found optimal for the antiporter activity. Similarly, H+ release induced by Ca2+ increased with the magnitude of DeltapH. However, above 60% DeltapH (high H(+)-pump activity), the net H+ release from the vesicles decreased as the pump-mediated H+ influx exceeded the Ca(2+)-induced H+ efflux. We also observed that the Ca2+/H+ antiport activity depends, essentially, on the DeltapH component of the electrochemical gradient (approximately 3 nmol Ca2+ taken up/mg protein), although the Deltaphi component may also support some Ca2+ accumulation by the vesicles (approximately 1 nmol/mg protein) in the absence of DeltapH. Both Ca(2+)-induced H+ release and DeltapH-dependent Ca2+ uptake could be driven by an artificially imposed proton motive force. Under normal conditions (H+ pump-induced DeltapH), the electrochemical gradient dependence of Ca2+ uptake by the vesicles was checked by inhibition of the process with specific inhibitors (bafilomycin A(1), ergocryptin, folymicin, DCCD) of the H(+)-pump activity. These results indicate that synaptic vesicles Ca2+/H+ antiport is indirectly linked to ATP hydrolysis and it is essentially dependent on the chemical component (DeltapH) of the electrochemical gradient generated by the H(+)-pump activity.

Distinction between Ca2+ pump and Ca2+/H+ antiport activities in synaptic vesicles of sheep brain cortex

Synaptic vesicles, isolated from a sheep brain cortex, accumulate Ca(2+) in a manner that depends on the pH and pCa values. In the presence of 100 microM CaCl(2), most of the Ca(2+) taken up by the vesicles was vanadate-inhibited (86%) at pH 7.4, whereas at pH 8.5, part of the Ca(2+) accumulated (36%) was DeltapH-dependent (bafilomycin and CCCP inhibited) and part was insensitive to those drugs (31%). We also observed that both vanadate-sensitive and bafilomycin-sensitive Ca(2+) accumulations were completely released by the Ca(2+) ionophore, ionomycin, and that these processes work with high (K(0.5)=0.6 microM) and low (K(0.5)=217 microM) affinity for Ca(2+), respectively. The DeltapH-dependent Ca(2+) transport appears to be largely operative at Ca(2+) concentrations (>100 microM) which completely inhibited the vanadate-sensitive Ca(2+) uptake. These Ca(2+) effects on the Ca(2+) accumulation were well correlated with those observed on the vanadate-inhibited Ca(2+)-ATPase and bafilomycin-inhibited H(+)-ATPase, respectively. The Ca(2+)-ATPase activity reached a maximum at about 25 microM (pH 7.4) and sharply declined at higher Ca(2+) concentrations. In contrast, Ca(2+) had a significant stimulatory effect on the H(+)-ATPase between 250 and 500 microM Ca(2+) concentration. Furthermore, we found that DeltapH-sensitive Ca(2+) transport was associated with proton release from the vesicles. About 21% of the maximal proton gradient was dissipated by addition of 607.7 microM CaCl(2) to the reaction medium and, if CaCl(2) was present before the proton accumulation, lower pH gradients were reached. Both vanadate-inhibited and bafilomycin-inhibited systems transported Ca(2+) into the same vesicle pool of our preparation, suggesting that they belong to the same cellular compartment. These results indicate that synaptic vesicles of the sheep brain cortex contain two distinct mechanisms of Ca(2+) transport: a high Ca(2+) affinity, proton gradient-independent Ca(2+) pump that has an optimal activity at pH 7.4, and a low Ca(2+) affinity, proton gradient-dependent Ca(2+)/H(+) antiport that works maximally at pH 8.5.

Ionic selectivity of the Ca2+/H+ antiport in synaptic vesicles of sheep brain cortex

As we previously reported, synaptic vesicles isolated from sheep brain cortex contain a Ca2+/H+ antiport that permits Ca2+ accumulation inside the vesicles ( approximately 5 nmol/mg protein) at expenses of the pH gradient generated by the H+-pumping ATPase. We observed that the system associates Ca2+ influx to H+ release and operates with low affinity for Ca2+. In the present work, we found that Ca2+/H+ antiport mediates exchange of protons with other cations such as Zn2+ and Cd2+, suggesting that these cations and Ca2+ share the same transporter molecules to enter the intravesicular space. Zn2+ and Cd2+ induce H+ release in a concentration-dependent manner (fluorimetrically evaluated) and they inhibit the antiport-mediated Ca2+ uptake by the vesicles (isotopically measured). In contrast, large cations such as Ba2+ and Cs+ do not alter Ca2+ influx and they are unable to induce proton release from the vesicles. With respect to Sr2+, which has an intermediary size relatively to the other groups of cations, we found that it does not induce H+ liberation from the vesicles, but it has a concentration-dependent inhibitory effect on the Ca2+-induced H+ release and Ca2+ uptake by the vesicles. These results indicate that the cation selectivity of the synaptic vesicles Ca2+/H+ antiport is essentially determined by the size of the cation transported into the vesicles.

Action of antiestrogens on the (Ca2+, +Mg2+)- ATPase and Na+/Ca2+ exchange of brain cortex membranes

The effect of tamoxifen (TAM) and other antiestrogens on the Ca2+ transport activity of synaptic plasma membranes (SPM) and microsomal membranes isolated from sheep brain cortex was investigated. The maximal (Ca2+ + Mg2+)-ATPase activity of SPM, which is reached at a pCa of about 6.0-6.5, is decreased by about 30% in the presence of 50 microM TAM, whereas the (Ca2+ + Mg2+)-ATPase activity of microsomes, which is maximal at a pCa of about 5.0, is decreased by about 90% by 50 microM TAM. In parallel experiments, we observed that the ATP-dependent Ca2+ uptake is also affected differently by TAM in the two membrane preparations. We found that 50 microM TAM inhibits SPM Ca2+ uptake by about 25-30%, whereas the ATP-dependent Ca2+ uptake by the microsomal fraction is inhibited by about 60%. No significant effect of TAM was observed on the Na+/Ca2+ exchange of either membrane system. The results indicate that TAM is a more potent inhibitor of the active, calmodulin-independent Ca2+ transport system of the intracellular membranes than of that of the plasma membranes, which is calmodulin-dependent. It appears that TAM inhibits calmodulin-mediated reactions, probably through its binding to calmodulin, as we showed previously. However, the Ca2+ transport system of microsomes, which does not depend on calmodulin, is also particularly sensitive to TAM.

Ca2+ regulation of the carrier-mediated γ-aminobutyric acid release from isolated synaptic plasma membrane vesicles

The regulation of the carrier-mediated g-aminobutyric acid (GABA) efflux was studied in isolated synaptic plasma membrane (SPM) vesicles, which are particularly useful to study neurotransmitter release without interference of the exocytotic machinery. We investigated the effect of micromolar intravesicular Ca 2 on the GABA release from SPM vesicles under conditions of basal release (superfusion with 150 mM NaCl), homoexchange (superfusion with 500 mM GABA) and K depolarization-induced release (superfusion with 150 mM KCl). We observed that, in the presence of intravesicular Ca 2 (10 mM), the maximal velocity (Jmax )o f K depolarization-induced GABA release is decreased by about 64%, and this effect was abolished in the presence of the channel blocker, La 3 . In contrast, the other mechanisms were not significantly altered by these cations. In agreement with our earlier results, inhibition of GABA uptake by intravesicular Ca 2 was also observed by determining the kinetic parameters (K0.5 and Jmax) of influx into the SPM vesicles. Under these conditions, the Jmax of GABA uptake was 17.4 pmol:s per mg protein, whereas in control experiments (absence of Ca 2 ), this value achieved 25.5 pmol:s per mg protein. The inhibitory effect of Ca 2 on translocation of GABA across SPM appears to be mediated by calcium:calmodulin activation of protein phosphatase 2B (calcineurin), since it was completely relieved by W7 (calmodulin antagonist) and by cyclosporin A (calcineurin inhibitor). These results show that the GABA transport system, operating either in forward or backward directions, requires phosphorylation of internally localized calcineurin-sensitive sites to achieve maximal net translocation velocity.

Methods for analysis of Ca2+/H+ antiport activity in synaptic vesicles isolated from sheep brain cortex

The involvement of Ca(2+)-storage organelles in the modulation of synaptic transmission is well-established [M.K. Bennett, Ca(2+) and the regulation of neurotransmitter secretion, Curr. Opin. Neurobiol. 7 (1997) 316-322 [1]; M.J. Berridge, Neuronal calcium signaling, Neuron 21 (1998) 13-26 [2]; Ph. Fossier, L. Tauc, G. Baux, Calcium transients and neurotransmitter release at an identified synapse, Trends Neurosci. 22 (1999) 161-166 [7] ]. Various Ca(2+) sequestering reservoirs (mitochondria, endoplasmic reticulum and synaptic vesicles) have been reported at the level of brain nerve terminals [P. Kostyuk, A. Verkhratsky, Calcium stores in neurons and glia, Neuroscience 63 (1994) 381-404 [18]; V. Mizuhira, H. Hasegawa, Microwave fixation and localization of calcium in synaptic terminals using X-ray microanalysis and electron energy loss spectroscopy imaging, Brain Res. Bull. 43 (1997) 53-58 [21]; A. Parducz, Y. Dunant, Transient increase of calcium in synaptic vesicles after stimulation, Neuroscience 52 (1993) 27-33 [23]; O.H. Petersen, Can Ca(2+) be released from secretory granules or synaptic vesicles?, Trends Neurosci. 19 (1996) 411-413 [24] ]. However, the knowledge of the specific contribution of each compartment for spatial and temporal control of the cytoplasmic Ca(2+) concentration requires detailed characterization of the Ca(2+) uptake and Ca(2+) release mechanisms by the distinct intracellular stores. In this work, we described rapid and simple experimental procedures for analysis of a Ca(2+)/H(+) antiport system that transport Ca(2+) into synaptic vesicles at expenses of the energy of a DeltapH generated either by activity of the proton pump or by a pH jumping of the vesicles passively loaded with protons. This secondary active Ca(2+) transport system requires high Ca(2+)100 microM) for activation, it is dependent on the chemical component (DeltapH) of the proton electrochemical gradient across the synaptic vesicle membrane and its selectivity is essentially determined by the size of the transported cation [P.P. Gonçalves, S.M. Meireles, C. Gravato, M.G. P. Vale, Ca(2+)-H(+)-Antiport activity in synaptic vesicles isolated from sheep brain cortex, Neurosci. Lett. 247 (1998) 87-90 [10]; P.P. Gonçalves, S.M. Meireles, P. Neves, M.G.P. Vale, Ionic selectivity of the Ca(2+)/H(+) antiport in synaptic vesicles of sheep brain cortex, Mol. Brain Res. 67 (1999) 283-291 [11]; P.P. Gonçalves, S.M. Meireles, P. Neves, M.G.P. Vale, Synaptic vesicle Ca(2+)/H(+) antiport: dependence on the proton electrochemical gradient, Mol. Brain Res. 71 (1999) 178-184 [12] ]. The protocols described here allow to ascertain the characteristics of the Ca(2+)/H(+) antiport in synaptic vesicles and, therefore, may be useful for clarification of the physiological role of synaptic vesicles in fast buffering of Ca(2+) at various sites of the neurotransmission machinery.

Regulation of [γ-3H]aminobutyric acid transport by Ca2+ in isolated synaptic plasma membrane vesicles

Abstract We studied the effect of Ca2+ on the transport of the γ-aminobutyric acid (GABA) by synaptic plasma membrane (SPM) vesicles isolated from sheep brain cortex and observed that intravesicular Ca2+ inhibits the [3H]GABA accumulation in a concentration-dependent manner. This inhibitory effect of Ca2+ exhibited two distinct components: one in the micromolar range of Ca2+ concentration, and the other in the millimolar range. Previous EGTA washing of the membranes, or incorporation of trifluoperazine into the vesicular space reduced the inhibitory action of Ca2+, particularly at low Ca2+ (1–5 μM). Okadaic acid (1 μM) also relieved the Ca2+ inhibition at low, but not at high Ca2+ concentrations (1 mM), whereas the calpain inhibitor I did not alter the effect of the low Ca2+, but it partially reduced (∼28%) the effect of Ca2+ in the millimolar range. The results indicate that the GABA transporter is regulated by low Ca2+ concentration (μM) and probably its effect is mediated by the (Ca2+⋅calmodulin)-stimulated phosphatase 2B (calcineurin). In contrast, the GABA uptake inhibition observed at high Ca2+ concentrations (1 mM) is less specific, and probably it is partially related to the proteolytic activity of membrane bound calpain II.

Ca2+ sensitivity of synaptic vesicle dopamine, γ-aminobutyric acid, and glutamate transport systems

The effect of Ca2+ on the uptake of neurotransmitters by synaptic vesicles was investigated in a synaptic vesicle enriched fraction isolated from sheep brain cortex. We observed that dopamine uptake, which is driven at expenses of the proton concentration gradient generated across the membrane by the H+-ATPase activity, is strongly inhibited (70%) by 500 μM Ca2+. Conversely, glutamate uptake, which essentially requires the electrical potential in the presence of low Cl− concentrations, is not affected by Ca2+, even when the proton concentration gradient greatly contributes for the proton electrochemical gradient. These observations were checked by adding Ca2+ to dopamine or glutamate loaded vesicles, which promoted dopamine release, whereas glutamate remained inside the vesicles. Furthermore, similar effects were obtained by adding 150 μM Zn2+ that, like Ca2+, dissipates the proton concentration gradient by exchanging with H+. With respect to γ-aminobutyric acid transport, which utilizes either the proton concentration gradient or the electrical potential as energy sources, we observed that Ca2+ or Zn2+ do not induce great alterations in the γ-aminobutyric acid accumulation by synaptic vesicles. These results clarify the nature of the energy source for accumulation of main neurotransmitters and suggest that stressing concentrations of Ca2+ or Zn2+ inhibit the proton concentration gradient-dependent neurotransmitter accumulation by inducing H+ pump uncoupling rather than by interacting with the neurotransmitter transporter molecules.

Proton transport by a fraction of endoplasmic reticulum and Golgi membranes of corn roots: comparison with the plasma membrane and tonoplast H+ pumps

Abstract Microsomal membranes isolated from roots of Zea mays, L. were separated into three fractions (F16, F34 and F40) by sucrose gradient centrifugation. The low density membranes (F16), which were previously shown to be enriched in marker enzymes characteristic of endoplasmic reticulum (ER) and Golgi membranes, have a proton pumping system which was compared to that of the tonoplast (F34) and of the plasma membranes (F40). We observed that ER-Golgi membranes have an ATPase activity (∼100 nmol Pi/mg protein/min) which, under certain conditions, is stimulated by sulfate and it is neither sensitive to vanadate nor to nitrate. This ATPase activity generates a transmembrane proton gradient (ΔpH), which is not affected by vanadate, but it is strongly inhibited by sulfate and nitrate. In contrast, nitrate greatly stimulates, whereas vanadate strongly inhibits the H+ pumping by the plasma membrane vesicles (F40). Chloride improves ΔpH generation in the three fractions studied, but only the F16 and F34 H+-ATPase appear to be directly affected by this anion. Regarding the effect of cations, we observed that K+, in all types of membranes, is not required for the operation of the H+ pump activity, although the plasma membrane H+ pump appears to be slightly stimulated by K+. In contrast, Na+ did not alter the H+ accumulation in the three membrane fractions tested. We also observed that the H+ pumping of the ER-Golgi membranes is distinguishable from the others by its high sensitivity to the reagent for sulphydryl groups, N-ethylmaleimide (NEM), whereas the plasma membrane H+ pump is distinguished by its sensitivity to the reagent for amino groups, trinitrobenzenesulfonate (TNBS) and to an alkaline pH (7.7). The results indicate that ER-Golgi membranes contain a (V type)-H+ pump, which is distinct from the (V type)-tonoplast H+ pump and from the (P type)-plasma membrane H+ pump.