Influence of membrane potential on the sodium-dependent uptake of gamma-aminobutyric acid by presynaptic nerve terminals: experimental observations and theoretical considerations

Roles Played by the Na+/Ca2+ Exchanger and Hypothermia in the Prevention of Ischemia-Induced Carrier-Mediated Efflux of Catecholamines into the Extracellular Space: Implications for Stroke Therapy

The release of [³H]dopamine ([³H]DA) and [³H]noradrenaline ([³H]NA) in acutely perfused rat striatal and cortical slice preparations was measured at 37 °C and 17 °C under ischemic conditions. The ischemia was simulated by the removal of oxygen and glucose from the Krebs solution. At 37 °C, resting release rates in response to ischemia were increased; in contrast, at 17 °C, resting release rates were significantly reduced, or resting release was completely prevented. The removal of extracellular Ca²⁺ further increased the release rates of [³H]DA and [³H]NA induced by ischemic conditions. This finding indicated that the Na⁺/Ca²⁺ exchanger (NCX), working in reverse in the absence of extracellular Ca²⁺, fails to trigger the influx of Ca²⁺ in exchange for Na⁺ and fails to counteract ischemia by further increasing the intracellular Na⁺ concentration ([Na⁺]_i). KB-R7943, an inhibitor of NCX, significantly reduced the cytoplasmic resting release rate of catecholamines under ischemic conditions and under conditions where Ca²⁺ was removed. Hypothermia inhibited the excessive release of [³H]DA in response to ischemia, even in the absence of Ca²⁺. These findings further indicate that the NCX plays an important role in maintaining a high [Na⁺]_i, a condition that may lead to the reversal of monoamine transporter functions; this effect consequently leads to the excessive cytoplasmic tonic release of monoamines and the reversal of the NCX. Using HPLC combined with scintillation spectrometry, hypothermia, which enhances the stimulation-evoked release of DA, was found to inhibit the efflux of toxic DA metabolites, such as 3,4-dihydroxyphenylacetaldehyde (DOPAL). In slices prepared from human cortical brain tissue removed during elective neurosurgery, the uptake and release values for [³H]NA did not differ from those measured at 37 °C in slices that were previously maintained under hypoxic conditions at 8 °C for 20 h. This result indicates that hypothermia preserves the functions of the transport and release mechanisms, even under hypoxic conditions. Oxidative stress (H₂O₂), a mediator of ischemic brain injury enhanced the striatal resting release of [³H]DA and its toxic metabolites (DOPAL, quinone). The study supports our earlier findings that during ischemia transmitters are released from the cytoplasm. In addition, the major findings of this study that hypothermia of brain slice preparations prevents the extracellular calcium concentration ([Ca²⁺]_o)-independent non-vesicular transmitter release induced by ischemic insults, inhibiting Na⁺/Cl⁻-dependent membrane transport of monoamines and their toxic metabolites into the extracellular space, where they can exert toxic effects.

Revised Ion/Substrate Coupling Stoichiometry of GABA Transporters

The purpose of this review is to highlight recent evidence in support of a 3 Na⁺: 1 Cl^-: 1 GABA coupling stoichiometry for plasma membrane GABA transporters (SLC6A1 , SLC6A11 , SLC6A12 , SLC6A13 ) and how the revised stoichiometry impacts our understanding of the contribution of GABA transporters to GABA homeostasis in synaptic and extrasynaptic regions in the brain under physiological and pathophysiological states. Recently, our laboratory probed the GABA transporter stoichiometry by analyzing the results of six independent measurements, which included the shifts in the thermodynamic transporter reversal potential caused by changes in the extracellular Na⁺, Cl^-, and GABA concentrations, as well as the ratio of charge flux to substrate flux for Na⁺, Cl^-, and GABA under voltage-clamp conditions. The shifts in the transporter reversal potential for a tenfold change in the external concentration of Na⁺, Cl^-, and GABA were 84 ± 4, 30 ± 1, and 29 ± 1 mV, respectively. Charge flux to substrate flux ratios were 0.7 ± 0.1 charges/Na⁺, 2.0 ± 0.2 charges/Cl^-, and 2.1 ± 0.1 charges/GABA. We then compared these experimental results with the predictions of 150 different transporter stoichiometry models, which included 1-5 Na⁺, 0-5 Cl^-, and 1-5 GABA per transport cycle. Only the 3 Na⁺: 1 Cl^-: 1 GABA stoichiometry model correctly predicts the results of all six experimental measurements. Using the revised 3 Na⁺: 1 Cl^-: 1 GABA stoichiometry, we propose that the GABA transporters mediate GABA uptake under most physiological conditions. Transporter-mediated GABA release likely takes place under pathophysiological or extreme physiological conditions.

Coexistence and function of different neurotransmitter transporters in the plasma membrane of CNS neurons

Transporters able to recapture released neurotransmitters into neurons can no longer be considered as cell-specific neuronal markers. In fact, colocalization on one nerve terminal of transporters able to selectively recapture the released endogenously synthesized transmitter (homotransporters) and of transporters that can selectively take up transmitters/modulators originating from neighboring structures (heterotransporters) has been demonstrated to occur on several families of nerve terminals. Activation of heterotransporters often increases the release of the transmitter stored in the terminals on which the heterotransporters are localized. The release caused by heterotransporter activation takes place through multiple mechanisms including exocytosis, either dependent on external Ca(2+) or on Ca(2+) mobilized from intraterminal stores, and homotransporter reversal. Homocarrier-mediated release elicited by heterocarrier activation represents a clear case of transporter-transporter interaction. Although the functional significance of transporter coexpression on one nerve terminal remains to be established, it may in some instances reflect cotransmission. In other cases, heterotransporters may mediate modulation of basal transmitter release in addition to the modulation of the evoked release brought about by presynaptic heteroreceptors. Heterotransporters are also increasingly reported to exist on neuronal soma/dendrites. With the exception of EAAT4, the glutamate transporter/chloride channel situated on GABAergic Purkinje cells in the cerebellum, the functions of somatodendritic heterocarriers is not understood.

Chronic and acute regulation of Na+/Cl- -dependent neurotransmitter transporters: drugs, substrates, presynaptic receptors, and signaling systems

Na+/Cl- -dependent neurotransmitter transporters, which constitute a gene superfamily, are crucial for limiting neurotransmitter activity. Thus, it is critical to understand their regulation. This review focuses primarily on the norepinephrine transporter, the dopamine transporter, the serotonin transporter, and the gamma-aminobutyric acid transporter GAT1. Chronic administration of drugs that alter neurotransmitter release or inhibit transporter activity can produce persistent compensatory changes in brain transporter number and activity. However, regulation has not been universally observed. Transient alterations in norepinephrine transporter, dopamine transporter, serotonin transporter, and GAT1 function and/or number occur in response to more acute manipulations, including membrane potential changes, substrate exposure, ethanol exposure, and presynaptic receptor activation/inhibition. In many cases, acute regulation has been shown to result from a rapid redistribution of the transporter between the cell surface and intracellular sites. Second messenger systems involved in this rapid regulation include protein kinases and phosphatases, of which protein kinase C has been the best characterized. These signaling systems share the common characteristic of altering maximal transport velocity and/or cell surface expression, consistent with regulation of transporter trafficking. Although less well characterized, arachidonic acid, reactive oxygen species, and nitric oxide also alter transporter function. In addition to post-translational modifications, cytoskeleton interactions and transporter oligomerization regulate transporter activity and trafficking. Furthermore, promoter regions involved in transporter transcriptional regulation have begun to be identified. Together, these findings suggest that Na+/Cl- -dependent neurotransmitter transporters are regulated both long-term and in a more dynamic manner, thereby providing several distinct mechanisms for altering synaptic neurotransmitter concentrations and neurotransmission.

Sodium-dependent GABA-induced currents in GAT1-transfected HeLa cells

1. HeLa cells were infected with recombinant vaccinia virus containing the T7 RNA polymerase gene and transfected with the cDNA for a rat GABA transporter, GAT1, cloned downstream of a T7 RNA polymerase promoter. Six to sixteen hours after transfection, whole-cell recording with a voltage ramp in the range -90 to 50 mV revealed GABA-induced currents (approximately -100 pA at -60 mV in 100 microM GABA, 16 h after transfection at room temperature). No GABA-induced currents were observed in parental HeLa cells or in mock-transfected cells. 2. GABA-induced currents were suppressed by extracellular perfusion with GABA-free solutions or addition of GAT1 inhibitors SKF89976-A or SKF100330-A. At fixed voltage the GABA dependence of the inward current fitted the Michaelis-Menten equation with a Hill coefficient, n, near unity and an equilibrium constant, K(m), near 3 microM. The Na+ dependence of the inward currents fitted the Michaelis-Menten equation with n approximately equal to 2 and K(m) approximately equal to 10 mM. The constants n and K(m) for GABA and Na+ were independent of voltage in the range -90 to -30 mV. 3. GABA-induced currents reverse direction in the range 5-10 mV. The implication of this result is that GAT1 can mediate electrogenic (electrophoretic) influx or efflux of GABA depending on the membrane voltage. The presence of an outward current in our experiments is consistent with radioactive-labelled flux data from resealed vesicle studies. However, it is inconsistent with frog oocyte expression experiments using the sample clone. In oocytes, GAT1 generates no outward current in a similar voltage range. Smaller intracellular volume or higher turnover rates in the mammalian expression system may explain the outward currents. 4. External GABA induces inward current, and internal GABA induces outward current. However, in cells initially devoid of internal GABA, external GABA can also facilitate an outward current. This GAT1-mediated outward current occurs only after applying negative potentials to the cell. These data are consistent with the concept that negative potentials drive GABA and Na+ into the cell, which then leads to electrogenic efflux through GAT1 at positive voltages. 5. Assuming coupled transport, we estimate the number of transporters, N, times the turnover rate, r, to be Nr approximately 10(9) s-1 under nominal conditions (V = -60 mV, 30 microM GABA, 130 mM Na+ and room temperature). This indicates either very high levels of expression (approximately 10(4) microns-2), assuming published turnover rates (approximately 10 s-1), or turnover rates that are significantly greater than previously reported. As an alternative, a channel may exist in the GAT1 protein that is gated by GABA and Na+ and blocked by GAT1 antagonists. The channel mode of conduction would exist in addition to the coupled, fixed-stoichiometry transporter mode of conduction.

Autoprotective mechanisms in the CNS: some new lessons from white matter

Anoxia/ischemia in the CNS is a common and devastating phenomenon. It is possible that the best hopes for protection against anoxic/ischemic injury may involve recruiting and/or augmenting any autoprotective systems that evolution has provided for the CNS. We describe here the existence of such an autoprotective system present in CNS white matter. White matter is both well suited to studying extrasynaptic systems, such as the system we describe here, and is a highly appropriate target for research into anoxic-ischemic injury in its own right. We show that white matter contains functional GABAB and adenosine receptors that respond to an anoxic efflux of GABA and adenosine by recruiting a convergent intracellular mechanism involving protein kinase C (PKC). The net result of this receptor-mediated cascade is an increase in resistance to anoxia, which presumably allows CNS white matter to tolerate better a common class of ischemic events that are located solely in white matter and that comprises approximately 25% of all strokes seen clinically.

Dual role of K+ and Na+ on the transport of [3H]-gamma-aminobutyric acid by synaptic plasma membrane vesicles

The influence of the monovalent cations (Na+ and K+) and of the electrical gradient on the high-affinity [3H]-gamma-aminobutyric acid ([3H]GABA) transport was investigated in synaptic plasma membrane (SPM) vesicles isolated from sheep brain cortex. This process specifically requires internal K+, since when it is replaced by Li+, the delta psi remains of the same order of magnitude, but no uptake of [3H]GABA occurs. The influence of the external Na+ concentration on the rate of [3H]GABA uptake suggests that this mechanism exhibits two components, whose characteristics are determined by the delta psi. Depolarization reduces the Jmax of [3H]GABA influx and enhances the binding of Na+ associated to [3H]GABA transport. Nevertheless, depolarization does not affect the K0.5 of binding sites for Na+ and the stoichiometry of translocation. These results suggest that intravesicular K+ and external Na+ have a dual role on the mechanism of [3H]GABA uptake: K+ acts directly on the carrier and determines the membrane polarization; Na+ is cotransported with GABA and, according to the polarization state of the membrane, it modulates the operation of the carrier in its inward GABA translocation.

Characterization of the carrier-mediated [3H]GABA release from isolated synaptic plasma membrane vesicles

Synaptic plasma membrane (SPM) vesicles were isolated under conditions which preserve most of their biochemical properties. Therefore, they appeared particularly useful to study the cytoplasmic GABA release mechanism through its neuronal transporter without interference of the exocytotic mechanism. In this work, we utilized SPM vesicles isolated from sheep brain cortex to investigate the process of [3H]GABA release induced by ouabain, veratridine and Na+ substitution by other monovalent cations (K+, Rb+, Li+, and choline). We observed that ouabain is unable to release [3H]GABA previously accumulated in the vesicles and, in our experimental conditions, it does not act as a depolarizing agent. In contrast, synaptic plasma membrane vesicles release [3H]GABA when veratridine is present in the external medium, and this process is sensitive to extravesicular Na+ and it is inhibited by extravesicular Ca2+ (1mM) under conditions which appear to permit its entry. However, veratridine-induced [3H]GABA release does not require membrane depolarization, since this drug does not induce any significant alteration in the membrane potential, which is determined by the magnitude of the ionic gradients artificially imposed to the vesicles. The substitution of Na+ by other monovalent cations promotes [3H]GABA release by altering the Na+ concentration gradient and the membrane potential of SPM vesicles. In the case of choline and Li+, we observed that the fraction of [3H]GABA released relatively to the total amount of neurotransmitter released by K+ or Rb+ is about 28% and 68%, respectively.(ABSTRACT TRUNCATED AT 250 WORDS)

Na+ influx through Ca2+ channels can promote striatal GABA efflux in Ca(2+)-deficient conditions in response to electrical field depolarization

Electrical field depolarization releases gamma-aminobutyric acid (GABA) in rat striatal slices in the absence of external Ca2+. omega-Conotoxin GVIA (omega-CgTx; 1-50 nM), a neuronal Ca2+ channel blocker, inhibits electrically evoked efflux of newly taken up [3H]GABA in a concentration-dependent manner in either normal or Ca(2+)-free medium. This suggests that ion influx occurs through Ca2+ channels in the absence of external Ca2+ and contributes to the efflux of GABA. Reducing external Na+ concentration to 27.25 mM (low [Na+]o medium) by equimolarly substituting choline chloride for sodium chloride has differential effects on electrically evoked GABA efflux depending on the external Ca2+ concentrations. In normal Ca2+ medium, electrically evoked GABA efflux increases whereas, in Ca(2+)-free medium, it is greatly inhibited when [Na+]o is reduced to 27.25 mM. In low [Na+]o medium, GABA efflux is largely tetrodotoxin (TTX)-sensitive, however, spike firing evoked by antidromic stimulation of striatal cells is inhibited. In Na(+)-free medium, resting GABA efflux increases 17-fold whereas evoked GABA efflux diminishes. In Ca(2+)-free medium, 70 min of incubation with 1-2-bis-(1-aminophenoxy)ethane-N,N,N',N' tetraacetoxy methyl ester (BATPA-AM, 1 microM), an intracellular calcium chelator, increases both resting GABA efflux and electrically evoked GABA overflow by approximately 100%. These results suggest that: (1) in Ca(2+)-free conditions, Na+ permeability of cells increases via Ca2+ channels and this profoundly affects GABA efflux. (2) Electrical field depolarization is likely to release GABA by directly depolarizing axon terminals. (3) Ca(2+)-independent GABA efflux is not promoted by an increase in intracellular free Ca2+ concentration via Na+/Ca2+ exchange processes from internal pools.

Ions required for the electrogenic transport of GABA by horizontal cells of the catfish retina

1. Solitary horizontal cells were isolated from catfish retinas. Membrane currents activated by extracellular and intracellular GABA were characterized during a whole-cell voltage clamp. 2. Extracellular GABA activated two currents: a GABAA current, and an 'influx' current mediated by a GABA transporter. The influx current was studied after the GABAA current was blocked with 0.5 mM picrotoxin. The influx current required extracellular Na+ and Cl-. Extracellular Na+ could not be replaced by another alkali metal cation. 3. The influx current also depended upon the identity of ions in the intracellular solution. Either an intracellular alkali metal cation or Cl- was required to produce an influx current. 4. The influx current was inward at -75 mV and decreased as the membrane was depolarized towards +20 mV. When the membrane was depolarized beyond +25 mV, the polarity of the current depended upon the ion composition of the intracellular solution and could be inward, zero or outward. 5. The introduction of GABA into a cell during the course of an experiment produced an outward current. This 'efflux' current was small at -75 mV and increased with depolarization. The efflux current required intracellular Na+ and Cl-. Intracellular Na+ could not be replaced by another alkali metal cation. 6. The efflux current also depended upon the identity of ions in the extracellular solution. An extracellular alkali metal cation was required to produce an efflux current. Removing extracellular Cl- did not affect the efflux current. 7. The outward movement of GABA produced a local accumulation in extracellular GABA concentration that could be detected by the activation of the GABAA current. GABA efflux only occurred during conditions that produced an efflux current. Electroneutral efflux did not occur. 8. In the absence of GABA, extracellular alkali metal cations produced a 'leakage' current. The leakage current was inward at -75 mV and decreased as the membrane was depolarized towards +20 mV. When the membrane was depolarized beyond +25 mV, the polarity of the leakage current depended, like the GABA influx current, upon the ion composition of the intracellular solution and could be inward, zero or outward. The addition of GABA to the intracellular solution produced an efflux current and suppressed the leakage current. 9. We conclude that the transporter mediates electrogenic influx, efflux and leakage. Each mode of operation depends upon ions on both sides of the membrane. Influx and efflux are not symmetrical.

Characterization of the nipecotic binding to rat brain membranes

1. The specific binding of [3H]Nip and [3H]GABA to rat brain membranes has been reexamined. 2. Specific binding of [3H]Nip and [3H]GABA was exclusively dependent on sodium ions in a cooperative manner (Hill coefficient 2.2 +/- 0.2 and 2.4 +/- 0.3 for [3H]Nip and [3H]GABA binding, respectively). Potassium, lithium or choline chloride salts were ineffective for replacing NaCl. 3. Maximal binding was observed at 2 degrees C. The association constants were K+1 = 0.033 min-1 microM-1 for [3H]GABA. The dissociation constants obtained by the addition of 1 mM of non-labeled GABA were 0.087 +/- 0.01 min-1 and 0.139 +/- 0.025 min-1 for [3H]Nip and [3H]GABA, respectively. Scatchard curves were in agreement with these constants, KD = 1.6 microM for [3H]GABA and 2.6 microM for [3H]Nip with equal Bmax = 138 pmol per mg protein. 4. The dissociation constants for [3H]Nip bound increased from 0 to 0.035, 0.18 and 0.58 min-1 at 2, 16, 26 and 37 degrees C, respectively, contrary to the hydrophobic derivate of nipecotic acid, NO 328. 5. Pharmacological characterization and regional brain distribution of [3H]Nip and [3H]GABA binding and uptake, suggest that [3H]Nip specifically labels the neuronal GABA uptake system, absent in peripheral tissues.

Regulation of carrier-mediated and exocytotic release of [3H]GABA in rat brain synaptosomes

In this study we investigated the role of external monovalent cations, and of intracellular Ca2+ concentration ([Ca2+]i) in polarized and depolarized rat cerebral cortex synaptosomes on the release of [3H]-gamma-aminobutyric acid (3H-GABA). We found that potassium-depolarization, in the absence of Ca2+, of synaptosomes loaded with 3H-GABA releases 7.4 +/- 2.1% of the accumulated neurotransmitter, provided that the external medium contains Na+, and an additional 19.0 +/- 2.5% is released upon adding 1.0 mM CaCl2 to the exterior. The Ca(2+)-independent release component does not occur in a choline medium and it is only 3.4 +/- 0.8% of the 3H-GABA accumulated in a Li+ medium, but both ions support the Ca(2+)-dependent release of 3H-GABA (13.4 +/- 0.6% in choline and 15.4 +/- 1.5% in Li+), which suggests that the exocytotic release is independent of the external monovalent cation present, whereas the carrier-mediated release specifically requires Na+ outside. Furthermore, previous release of the cytosolic 3H-GABA due to predepolarization in the absence of Ca2+ does not influence the amount of 3H-GABA subsequently released by exocytosis due to Ca2+ addition (19.1 +/- 2.5% or 19.1 +/- 1.1%, respectively). In choline or Li+ medium, the value of the [Ca2+]i is raised by Na+/Ca2+ exchange to 663 +/- 75 nM or 782 +/- 54 nM, respectively, within three minutes after adding 1.0 mM Ca2+, in the absence of depolarization, and parallel release experiments show no release of 3H-GABA in the choline medium, but a substantial release (7.1 +/- 2.1%) of 3H-GABA occurs in the Li+ medium without depolarization. Subsequent K(+)-depolarization shows normal Ca(2+)-dependent release of 3H-GABA in the choline medium (14.1 +/- 2.0%) but only 8.6 +/- 1.1% release in the Li+ medium, which suggests that raising the [Ca2+]i by Na+/Ca2+ exchange, without depolarization, supports some exocytotic release in Li+, but not in choline media. The role of [Ca2+]i and of membrane depolarization in the release process is discussed on the basis of the results obtained and other relevant observations which suggest that both Ca2+ and depolarization are essential for optimal exocytotic release of GABA.

Development of changes in endogenous GABA release during kindling epileptogenesis in rat hippocampus

The calcium-dependent gamma-aminobutyric acid (GABA) and glutamate release from rat hippocampal CA1 slices, evoked by a 1-min depolarization with 50 mM K+, was investigated in different stages of kindling epileptogenesis. Kindling was induced by tetanic stimulation of the Schaffer collateral/commissural pathway. In agreement with our previous results, we found a significantly increased calcium-dependent GABA release compared to that of implanted controls, in a group of fully kindled animals 1 day after the last seizure and also 25-36 days after the last seizure. In addition, we found that the increase in GABA release was associated with late phases of kindling epileptogenesis since no significant alterations were found in partly kindled animals that had received only 6 kindling stimulations while a significant increase was apparent in animals that had received 14 tetanic stimuli. When the release protocol was carried out in the presence of SK&F 89776-A, a blocker of the GABA uptake carrier, an additional amount of GABA was found after depolarization. This additional amount of GABA, reflecting the amount of GABA taken up under conditions without blocker, was in kindled animals not different from controls which demonstrates that a reduced GABA uptake does not account for the observed enhanced release in kindled animals. The calcium-dependent release of glutamate evoked by 1 min of high potassium depolarization was not significantly changed in the kindled groups. Only after prolonged depolarization during 4 subsequent minutes a significant increase in animals of the fully kindled group and at long-term after kindling was observed. The threshold K+ concentration for eliciting a calcium-dependent release of GABA and glutamate, was not changed in the kindled animals.(ABSTRACT TRUNCATED AT 250 WORDS)

Calcium-independent gamma-aminobutyric acid release from growth cones: role of gamma-aminobutyric acid transport

Neuronal growth cones isolated in bulk from neonatal rat forebrain have uptake and K(+)-stimulated release mechanisms for gamma-aminobutyric acid (GABA). Up to and including postnatal day 5, the K(+)-stimulated release of [3H]GABA and endogenous GABA is Ca2+ independent. At these ages, isolated growth cones neither contain synaptic vesicles nor stain for synaptic vesicle antigens. Here we examined the possibility that the release mechanism underlying Ca2(+)-independent GABA release from isolated growth cones is by reversal of the plasma membrane GABA transporter. The effects of two GABA transporter inhibitors, nipecotic acid and an analogue of nipecotic acid, SKF 89976-A, on K(+)-stimulated release of [3H]GABA from superfused growth cones were examined. Nipecotic acid both stimulated basal [3H]GABA release and enhanced K(+)-stimulated release of [3H]GABA, which indicates that this agent can stimulate GABA release and is, therefore, not a useful inhibitor with which to test the role of the GABA transporter in K(+)-stimulated GABA release from growth cones. In contrast, SKF 89976-A profoundly depressed both basal and K(+)-stimulated [3H]GABA release. This occurred at similar concentrations at which uptake was blocked. These observations provide evidence for a major role of the GABA transporter in GABA release from neuronal growth cones.

Depolarization promotes caffeine induced [3H]-noradrenaline release in calcium-free solution from peripheral sympathetic nerves

The transmitter releasing action of caffeine was studied in the absence of extracellular Ca2+ from the peripheral sympathetic nerves of the rabbit main pulmonary artery. Caffeine (10 mM) increased the release of [3H]-noradrenaline moderately, but not significantly in Ca2(+)-free (+1 mM EGTA) Krebs solution. When peripheral nerve endings/varicosities were depolarized by elevating extracellular K+ to 47.2 mM and 70.8 mM in Ca2(+)-free solution, the transmitter releasing effect of 10 mM caffeine became significant. Ca2+ removal itself transiently increased the [3H]-noradrenaline outflow. In the individual experiments the amount of the caffeine evoked transmitter release at 47.2 mM and 70.8 mM K(+)-depolarization was inversely correlated to the release evoked by Ca2(+)-removal. Our results suggest that caffeine-sensitive calcium stores are present in peripheral nerve terminals of rabbit pulmonary artery, and part of the caffeine sensitive calcium stores may discharge during Ca2(+)-removal from the extracellular solution.

Kinetics and block of dopamine uptake in synaptosomes from rat caudate nucleus

The dopamine (DA) uptake system in mammalian nerve terminals was studied by measuring the unidirectional influx of tritiated DA into synaptosomes prepared from rat caudate nucleus. Two distinct time-dependent components of DA uptake were observed. The principal component was saturable with respect to DA concentration, required both external Na and Cl, and was competitively blocked by micromolar concentrations of the psychotropic agents cocaine, benztropine, nomifensine, amphetamine, and methamphetamine. This principal component of uptake has the properties expected for a carrier-mediated transport system. The second component, which accounted for about 10-30% of the DA uptake at 2 microM DA, was not saturable, and was independent of external Na, Cl, and blockers of the carrier-mediated system. The saturable, Na-dependent component had an apparent Km(DA) of about 0.5 microM. The dependence of DA uptake on external Na was sigmoid [Hill coefficient = 2; Ka(Na) = 45 mM] whereas the dependence on Cl was best described by a rectangular hyperbola [Ka(Cl) = 15 mM]. Depolarizing conditions (elevated external K) reduced the rate of DA influx. The data are consistent with a carrier-mediated DA transport mechanism in which each DA molecule entering the nerve terminal via the carrier is accompanied by two or more Na ions and one Cl ion in a rheogenic process carrying one or more net positive charges into the cell. Net, concentrative accumulation of DA inside nerve terminals may be accomplished by utilizing the Na electrochemical gradient to drive DA against its electrochemical gradient via this carrier system.

Two pharmacologically distinct sodium- and chloride-coupled high-affinity gamma-aminobutyric acid transporters are present in plasma membrane vesicles and reconstituted preparations from rat brain

Electrogenic sodium- and chloride-dependent gamma-aminobutyric acid (GABA) transport in crude synaptosomal membrane vesicles is partly inhibited by saturating levels of either of the substrate analogues cis-3-aminocyclohexanecarboxylic acid (ACHC) or beta-alanine. However, both of them together potently and fully inhibit the process. Transport of beta-alanine, which exhibits an apparent Km of about 44 microM, is also electrogenic and sodium and chloride dependent and competitively inhibited by GABA with a Ki of about 3 microM. This value is very similar to the Km of 2-4 microM found for GABA transport. On the other hand, ACHC does not inhibit beta-alanine transport at all. Upon solubilization of the membrane proteins with cholate and fractionation with ammonium sulfate, a fraction is obtained which upon reconstitution into proteoliposomes exhibits 4- to 10-fold-increased GABA transport. This activity is fully inhibited by low concentrations of ACHC and is not sensitive at all to beta-alanine. GABA transport in this preparation exhibits an apparent Km of about 2.5 microM and it is competitively inhibited by ACHC (Ki approximately 7 microM). These data indicate the presence of two GABA transporter subtypes in the membrane vesicles: the A type, sensitive to ACHC, and the B type, sensitive to beta-alanine.

Calcium-independent GABA release from striatal slices: the role of calcium channels

We have investigated the role of Ca2+ and Ca2+ channels in the modulation of GABA release. Brain slices prepared from rat striatum were preincubated with [3H]GABA, superfused with Krebs bicarbonate buffer, and exposed to electrical field stimulation (2 Hz for 3 min). Tritium efflux was measured as an index of GABA release. Both resting and evoked efflux were greatly accelerated by deleting Ca2+ from the medium and adding EGTA (1 mM). However, when the concentration of Mg2+ in the buffer was elevated to 10 mM, no effect of the Ca2(+)-deficiency was observed on resting release and its impact on evoked overflow was diminished. Moreover, addition of verapamil (10 microM), a Ca2+ channel blocking agent, reduced evoked overflow even in the absence of external Ca2+, while 4-aminopyridine (10 microM), a K+ channel inhibitor, enhanced GABA efflux in normal buffer but had no effect in the absence of Ca2+. Finally, we have shown previously that nipecotic acid, an inhibitor of high affinity GABA transport, increases GABA overflow in normal buffer, but blocks it in Ca2(+)-free buffer. Collectively, these results suggest that Ca2+ channels may play two roles in the regulation of depolarization-induced GABA release. Firstly, these channels permit a depolarization-induced influx of Ca2+ which then promotes GABA release. In addition, these channels influence GABA release through a mechanism that does not involve external Ca2+. Although the precise nature of this latter involvement is unclear, we propose that the Ca2+ channels serve to permit an influx of Na+, which in turn promotes Ca2(+)-independent release through an influence on the high affinity GABA transport system.

Depolarization of the neuronal membrane caused by cotransport of taurine and sodium

C 1300 neuroblastoma cells were cultured and used to study the effect of sodium dependent taurine transport on the membrane potential. Measuring net accumulation of taurine and the depolarization caused by externally applied taurine, we found both processes become active at an external concentration of taurine of 1 mM or more. Net accumulation had Km of 13 mM and a Vmax of 126 nmol x mg of protein-1 x min-1. The taurine induced depolarization of the neuroblastoma cell was parallelled by a 25 per cent decrease in its membrane impedance. The transport of taurine, the depolarization caused by taurine and the effect of taurine on the membrane impedance, all, had a similar dependence on the external sodium concentration. Our results on the depolarizing cotransport between taurine and sodium at the neuronal membrane, may illustrate an additional mechanism for the control of the electrical activity of neuronal cells.

Chelation of endogenous membrane calcium inhibits gamma-aminobutyric acid uptake in synaptosomes

In a previous work, we have demonstrated that calcium chelators induce the release of gamma-aminobutyric acid (GABA) from synaptosomes in a Na+ -dependent manner and that this release is blocked by cations such as Mg2+, La3+, and ruthenium red. In the present study, we show that treatment of synaptosomes with 0.1 mM EGTA in the absence of both Ca2+ and Mg2+ inhibits the sodium-dependent high-affinity uptake of [3H]GABA by about 50%. This inhibition increased to about 65% with 1.5 mM EGTA, and it was completely prevented by an excess of Ca2+ or by 1.2 mM Mg2+. In contrast, when EDTA was used as a chelator, Mg2+ was unable to reverse the inhibition. The inhibitory effect of 0.1 mM EGTA was also prevented by 250 microM La3+ or by 20 microM ruthenium red. In the absence of chelators and the presence of Ca2+ and Mg2+, 50 microM and 200 microM La3+ inhibited GABA uptake by about 20 and 50%, respectively, whereas 20 microM ruthenium red produced a nonsignificant 25% inhibition and nifedipine was without effect. It is concluded that the membrane-surface negative charges, probably those of the sialic acid molecules that have been implicated in the functioning of the GABA carrier, must be neutralized by endogenous Ca2+ or by another cation in order to permit the adequate function of the transporter. The inhibition by La3+ in the absence of the chelators could be explained by a binding of this cation to the Na+ sites on the GABA carrier.

Triphasic effects of short chain n-alcohols on synaptic membrane transport of choline and of gamma-aminobutyric acid

n-Alcohols, when added in increasing concentrations, had an unusual triphasic effect on the uptake of choline and of gamma-aminobutyric acid by isolated synaptosomes. There was slight inhibition of these uptakes at low n-alcohol concentrations, followed by a sharp peak of uptake enhancement, and then greater inhibition. The n-alcohol concentrations required for these effects were proportional to published n-alcohol membrane/buffer partition coefficients, with the peaks of uptake enhancement occurring at 60 mM n-propanol, 20 mM n-butanol and 7.5 mM n-pentanol. Synaptosomal membrane potential, as estimated from synaptosomal accumulation of the permeant cation [3H]tetraphenylphosphonium, was not affected by n-alcohols in the concentrations used in this study, suggesting that neither the inhibitory or enhancing effects of these n-alcohols were attributable to changes in trans-synaptosomal membrane ion gradients. The inhibiting and enhancing effects of n-alcohols could be reproduced in determinations of gamma-aminobutyric acid uptake by isolated synaptic plasma membranes, suggesting that the observed effects are due to a direct action of the n-alcohols on the synaptosomal plasma membrane. These effects may be attributable to a change in membrane binding of these alcohols from the membrane core to the membrane surface as alcohol concentration is increased.

Excitatory amino acid-evoked release of [3H]GABA from hippocampal neurons in primary culture

We investigated the release of gamma-[2,3-3H(N)]aminobutyric acid ([3H]GABA) from hippocampal neurons in primary cell culture. [3H]GABA release was stimulated by the excitatory amino acid neurotransmitter glutamate as well as by N-methyl-D-aspartate (NMDA) and kainate. Cell depolarization induced by raising [K+]o or by veratridine also stimulated [3H]GABA release. NMDA-induced release was completely blocked by 3-((+/-)-2-carboxypiperazin-4-yl)-propyl-1-phosphonic acid (CPP+), Mg2+ and Zn2+ whereas the release induced by glutamate and kainate was much less susceptible to inhibition by these substances. Furthermore, removal of external Ca2+ inhibited NMDA-induced release, but not that induced by glutamate, kainate, veratridine or 50 mM K+. Removal of external Na+ reduced [3H]GABA release evoked by all stimuli, but to different extents. All of the excitatory amino acids tested increased [Ca2+]i within hippocampal neurons as assessed by fura-2 based microspectrofluorimetry. This increase in [Ca2+]i was completely dependent on the presence of external Ca2+. These results suggest that Ca2+-dependent and -independent forms of GABA release from hippocampal interneurons may occur. [3H]GABA release evoked by glutamate, kainate, veratridine or 50 mM K+, appeared to be mediated by the reversal of electrogenic, Na+-coupled GABA uptake. Release was inhibited by nipecotic acid, an inhibitor of the Na+-coupled GABA uptake system. However, release induced by NMDA may also include a Ca2+-dependent component.

Interactions of benztropine, atropine and ketamine with veratridine-activated sodium channels: effects on membrane depolarization, K+-efflux and neurotransmitter amino acid release

1. The effect of benztropine, atropine and ketamine on veratridine-induced efflux of K+, membrane depolarization and release of amino acid neurotransmitters was investigated in the preparation of rat brain synaptosomes. 2. All three drugs inhibited in a concentration-dependent manner the processes measured: the most effective compound was benztropine which exhibited an approximate Kd of 2 microM. The inhibition was not competitive in nature. 3. The veratridine titration curves in the presence of drugs were sigmoid with Hill coefficients of about 1.4. 4. At higher concentrations, benztropine, atropine and ketamine blocked uptake of amino acid neurotransmitters into synaptosomes. 5. It is postulated that benztropine, atropine and ketamine interfere with the veratridine-activated influx of sodium into synaptosomes through voltage-dependent channels by acting at the same site as local anaesthetics. Interactions at this site alter allosterically binding and action of veratridine. In addition, at higher concentrations the drugs interact with the carrier proteins for amino acid neurotransmitters and block their transport.

Ethanol inhibition of synaptosomal high-affinity choline uptake

Ethanol in vitro inhibited synaptosomal sodium-dependent, high-affinity choline uptake, the rate-limiting step in the synthesis of acetylcholine. This inhibition occurred with ethanol concentrations as low as 50 mM, was reversible and was not attributable to ethanol effects on synaptosomal membrane potential. In contrast, ethanol concentrations as high as 400 mM had no effect on synaptosomal high-affinity uptake of gamma-aminobutyric acid, a major inhibitory neurotransmitter in the central nervous system. The observed ethanol inhibition of choline uptake is consistent with suggestions that depression of cholinergic systems is important in acute ethanol intoxication.

Sodium-dependent suppression of gamma-aminobutyric-acid-gated chloride currents in internally perfused frog sensory neurones

1. The effects of the Na+ electrochemical potential gradient on gamma-aminobutyric acid (GABA)-induced Cl- currents (ICl) in frog sensory neurones were studied, using a suction pipette technique with which internal perfusion can be accomplished under current- and voltage-clamp conditions. 2. Under current clamp, the depolarizing response to GABA decreased in the presence of external Na+. A similar external Na+-dependent reduction in the GABA-induced inward ICl was observed under voltage clamp. The reversal potential of GABA-induced ICl (EGABA) was nearly equal to the Cl- equilibrium potential (ECl), irrespective of the presence or absence of external Na+. 3. Varying the Na+ influx by changing the holding membrane potential (VH) altered the GABA response: the GABA-induced ICl decreased progressively as VH became more negative. 4. The effects of changing the external and internal Na+ concentrations ([Na+]o and [Na+]i) on the GABA-induced ICl were also studied. Increasing [Na+]o at a constant [Na+]i reduced this current while increasing [Na+]i at a fixed [Na+]o facilitated it. 5. A high temperature coefficient of about 3 was estimated with respect to the percentage reduction in GABA-induced ICl due to [Na+]o. 6. These results indicate that the [Na+]o-dependent suppression of GABA-induced ICl was mediated chiefly by the uptake of GABA subserved by a Na-GABA co-transport mechanism. 7. GABA dose-response measurements were made with and without external Na+. The [Na+]o-induced suppression was more pronounced in relative amount at lower concentrations and in absolute amount at intermediate concentrations. Analysis of these data indicates, however, that the Na+-coupled GABA influx kept increasing at GABA concentrations high enough to nearly saturate GABA-induced ICl, and the same saturating level was observed as in the Na+-free case. This indicates that the electrogenic co-transport current was much smaller so that our measurements of GABA-induced ICl' were contaminated very little. Thus, the present method based on recording of GABA-induced ICl was legitimate for the analysis of the Na-GABA co-transport. 8. By analysing the [Na+]o-dependent suppression of GABA-induced ICl, the stoichiometric ratio of the underlying co-transport was estimated to be one: one Na+ ion per GABA molecule. 9. The ICl induced by GABA agonists such as beta-alanine, taurine, l-GABOB (l-gamma-amino-beta-hydroxybutyric acid) and muscimol was not affected by the amount of external Na+ present, suggesting difference in the affinity between receptor and transport carrier.

Relationships among ATP synthesis, K+ gradients, and neurotransmitter amino acid levels in isolated rat brain synaptosomes

Correlations were made among ATP synthesis, transmembrane K+ gradients, and leakage of three amino acid neurotransmitters, gamma-aminobutyric acid (GABA), aspartate, and glutamate, in rat brain synaptosomes incubated under normoxic and respiration-limited conditions. Even under normoxic conditions, a substantial proportion of total ATP synthesis (8%) was provided by glycolysis. Limitation of respiration by approximately 30% through addition of amobarbital (Amytal) caused a twofold decrease in the creatine phosphate/creatine ([CrP]/[Cr]) ratio, and consequently the [ATP]/[ADP] ratio, and a threefold increase in lactate production. There was a detectable decrease in intracellular [K+] and small rises in external GABA, aspartate, and glutamate concentrations. More severe limitations in ATP synthesis caused larger declines in the [CrP]/[Cr] ratio and progressive leakage of K+ and neurotransmitter amino acids. A comparison of delta GATP and delta GNa, K showed the former to be larger by 6 kcal, which indicates that the plasma membrane Na+/K+ pump operates at far from equilibrium. Under respiration-limited conditions, even when total ATP synthesis decreased by approximately 80% and [ATP] declined to less than 0.4 mM, delta GATP was still larger than delta GNa,K. It is suggested that during hypoxia and ischemia, the activity of the plasma membrane Na+/K+ pump in brain becomes limited by [ATP], which falls below the Km value for the low-affinity regulatory site on the enzyme. This failure of the pump and consequent collapse of the ion gradients may contribute to the leakage of neurotransmitter amino acids that occurs in these pathological states.

Uptake, exchange, and release of GABA by cerebellar glomeruli

Glomerular particles were isolated from the bovine cerebellar vermis and studied in vitro to further assess the possibility that gamma-aminobutyric acid (GABA) is utilized as a neurotransmitter in this synaptic complex. Cerebellar glomeruli accumulated [3H]GABA at two different high affinity sites, with affinities (KT) of 2.2 X 10(-6) M and 3.0 X 10(-5) M. These uptake sites could not be distinguished on the basis of their temperature sensitivities, sodium dependence, substrate specificities or responses to metabolic inhibitors. Although an exchange process contributed to the uptake measured in these experiments, a considerable amount of the [3H]GABA accumulated by glomerular particles was stored in an osmotically-sensitive, nonexchangeable pool. Glomerular particles preloaded with [3H]GABA exhibited a Ca2+-independent release of this amino acid in response to membrane depolarization. However, when preloaded glomerular particles were exposed to unlabeled GABA, which presumably displaced [3H]GABA from the exchangeable pool, a K+-evoked and Ca2+-dependent release of the remaining [3H]GABA occurred. The observed net uptake, together with the depolarization-induced and Ca2+-dependent release, of [3H]GABA from glomerular particles supports the suggestion that functionally active GABAergic synapses are present in these structures.

Selective inhibition of synaptosomal gamma-aminobutyric acid uptake by triethyllead: role of energy transduction and chloride ion

Triethyllead (TEL) is a CNS neurotoxin producing bizarre neurobehavioral changes. The principal objective of this study was to determine if TEL-induced defects in energy metabolism were responsible for the inhibition of synaptosomal Na+-dependent high-affinity uptake of gamma-aminobutyric acid (GABA). A dose-dependent inhibition of GABA uptake (ID50 = 10 microM TEL) was found during 30-s incubations. Uptake of glutamate was more resistant to the inhibitory effects of TEL. A TEL-induced Cl(-)-dependent synaptosomal deficit of ATP was observed. Such deficit in high-energy phosphate was time-dependent and did not occur in the absence of Cl- or as early as 30 s. Inhibition of GABA uptake, on the other hand, was a Cl(-)-independent phenomenon and was observed at as early as 30 s. TEL was not competitive with Na+ or GABA itself, as the effects of TEL were not overcome with high [Na+] or [GABA]. These results indicate that the locus of TEL inhibition of GABA uptake is not a Cl(-)-dependent event and does not involve a perturbed transmembrane electrochemical gradient, due to either an observed mitochondrial defect or an inhibition of Na+, K+-ATPase directly.

Amino acid neurotransmitters in the CNS. Relationships between net uptake and exchange in rat brain synaptosomes

Carefully isolated, metabolically competent rat brain synaptosomes accumulate acidic amino acid neurotransmitters down to very low external levels. This supports the suggestion that nerve endings are involved in terminating transmission at the synapses and in maintaining low levels of these molecules in the external environment in the brain. At saturating levels of acidic amino acids, the rate of inward and outward movements of the Na+-amino acid complex (exchange) is much faster than the net uptake. The transmembrane gradients of aspartate and glutamate approach each other under all conditions explored which indicates that these two amino acids share the same transport system.

Compartmentation and release of exogenous GABA in sheep brain synaptosomes

Exogenous tritiated gamma-aminobutiric acid ([3H]GABA) is retained in two compartments in sheep cortex synaptosomes, corresponding to cytoplasmic and vesicular spaces, assuming that freeze-thawing the synaptosomes loaded with [3H]GABA releases the cytoplasmic [3H]GABA (81 +/- 3.9%), and that subsequent solubilization of the synaptosomes with 1% sodium cholate releases the vesicular [3H]GABA (19 +/- 3.9%). Depolarization of synaptosomes with 40 mM K+ in a Na+-medium, in the absence of Ca2+, releases 20.3 +/- 2.7% of the [3H]GABA retained in the synaptosomes. The [3H]GABA released under these conditions comes predominantly from the cytoplasm. The presence of 1 mM Ca2+ during depolarization releases an additional 13% (a total of about 33.5 +/- 9.9%) of the releasable [3H]GABA, and the [3H]GABA release which is Ca2+-dependent also comes mostly from the cytoplasmic compartment. When choline replaces external Na+, the [3H]GABA release is absolutely Ca2+-dependent, and the [3H]GABA released also comes mostly from the cytoplasmic pool. Therefore, it appears that [3H]GABA taken up by synaptosomes is accumulated mostly in the cytoplasmic compartment from which it is released upon depolarization. The technique described permits distinguishing the effect of different factors on the two pools of accumulated [3H]GABA.

Role of sialic acid in synaptosomal transport of amino acid transmitters

Active, high-affinity, sodium-dependent uptake of gamma-aminobutyric acid and of the acidic amino acid D-aspartate was inhibited by pretreatment of synaptosomes with neuraminidase from Vibrio cholerae. Inhibition was of a noncompetitive type and was related to the amount of sialic acid released. The maximum accumulation ratios of both amino acids (intracellular [amino acid]/extracellular [amino acid]) remained largely unaltered. Treatment with neuraminidase affected neither the synaptosomal energy levels nor the concentration of internal potassium. It is suggested that the gamma-aminobutyric acid and acidic amino acid transporters are glycosylated and that sialic acid is involved in the operation of the carrier proteins directly and not through modification of driving forces responsible for amino acid uptake.

Mechanism of transport and storage of neurotransmitters

This review will focus on the bioenergetics, mechanism, and molecular basis of neurotransmitter transport. As indicated in the next section, these processes play an important role in the overall process of synaptic transmission. During the last few years, direct evidence has been obtained that these processes are coupled chemiosmotically, i.e., the accumulation of neurotransmitters is driven by ion gradients. Two types of neurotransmitter transport systems have been identified: sodium-coupled systems located in the synaptic plasma membrane of nerves (and sometimes in the plasma membrane of glial cells) and proton-coupled systems which are part of the membrane of intracellular storage organelles. From a bioenergetic point of view, the sodium-coupled systems are especially interesting, since it has recently been discovered that many systems require other ions in addition to sodium. It has now been demonstrated in several cases that, besides sodium ions, these additional ions, such as chloride and potassium, serve as additional coupling ions. These systems will be reviewed here in considerable detail with emphasis on the role of the additional ions. In the second part of the review we shall focus on neurotransmitter transport into storage organelles. Although both sodium and proton coupled systems have been reviewed in the past, there has been a shift from a kinetic and thermodynamic to a biochemical approach. In fact, a few transporters have been identified and functionally reconstituted. These developments have of course been incorporated in this review.

gamma-Aminobutyric acid release from synaptosomes as influenced by Ca2+ and Ca2+ channel blockers

We studied the correlation between the high affinity binding of Ca2+ channel blockers to purified synaptic plasma membranes (SPM) and the effect of these drugs in blocking the 45Ca2+ uptake and the release of [3H]gamma-aminobutyric acid [( 3H]GABA) by preloaded synaptosomes. The Ca2+ channel blocker binding sites were characterized by studying the binding of the dihydropyridine, [3H]nimodipine, and of the phenylalkylamine, (-)-[3H]desmethoxyverapamil, to purified SPM isolated from sheep brain cortex synaptosomes. The purified SPM had high affinity binding sites for both Ca2+ channel blockers. The binding parameters were similar to those previously reported for whole brain homogenates: KD = 0.64 nM and Bmax = 160 fmol/mg of protein for [3H]nimodipine, and KD = 7.9 nM and Bmax = 1,500 fmol/mg of protein for (-)-[3H]desmethoxyverapamil. The Ca2+ channel blockers inhibited the release of [3H]GABA induced by K+ depolarization in the presence or in the absence of Ca2+. The Ca2+-dependent component of [3H]GABA release was inhibited by verapamil, (-)-D 600, d-cis-diltiazem, nifedipine and PY 108-86 with IC50 values of 2.2 X 10(-5) M, 6.3 X 10(-5) M, 3 X 10(-4) M, greater than 10(-4) M and 3 X 10(-5) M, respectively. Furthermore, the Ca2+ channel blockers also inhibited the Ca2+-independent [3H]GABA release which occurred in the presence, but not in the absence, of external Na+. The Ca2+ channel blockers at concentrations which inhibited [3H]GABA release inhibited the entry of Ca2+ through the Ca2+ channels and also the entry of Ca2+ by Na+/Ca2+ exchange. We conclude that the concentrations of Ca2+ blockers necessary to block Ca2+ uptake through the Ca2+ channels and by Na+/Ca2+ exchange coincide with the concentrations at which they inhibit [3H]GABA release, but that their effect on the relationship between Ca2+ uptake and [3H]GABA release is different for the various blockers. The effects of the drugs on Ca2+ movements and [3H]GABA release are not specifically mediated through the high affinity binding of the drugs since relatively high concentrations were necessary (greater than 10(-5) M) for the effects reported here.

Activation of the voltage-sensitive sodium channel by a beta-scorpion toxin in rat brain nerve-ending particles

Neurotoxins purified from scorpion venoms previously had been divided into two classes according to their binding properties in rat brain synaptosomes. However, the pharmacological action of beta-scorpion toxin (beta-ScTx) on this preparation has not yet been described. In this report we show that a beta-ScTx induced an increase in 22Na+ uptake through synaptosomal voltage-sensitive sodium channels since this stimulation was abolished by tetrodotoxin (TTX). The increase was smaller than with veratridine and no synergy was observed between beta-ScTx and veratridine, as is the case for alpha-scorpion toxin (alpha-ScTx) and veratridine. The effects of alpha- and beta-ScTx were additive and the concentration-effect curves for each type of toxin were not modified by the other, suggesting that these two types of toxins act through distinct and noninteracting receptor sites. This was confirmed by the absence of mutual modification of the equilibrium and kinetic binding properties. beta-ScTx was shown to inhibit the uptake and to stimulate the release of [3H]gamma-aminobutyric acid. These effects were blocked by TTX, and no synergy was observed with veratridine. It was concluded that all these effects are mediated by the activation of voltage-sensitive sodium channels induced by the binding of beta-ScTx to a receptor site (site 4) distinct from those for other neurotoxins acting on sodium channels.

Amino acid neurotransmitters in the CNS. Characteristics of the acidic amino acid exchange

D-Aspartate exchange, defined as amino acid-stimulated D-[3H]aspartate efflux, was investigated in a preparation of rat brain synaptosomes. The efflux of radiolabelled D-aspartate was found to be enhanced by micromolar concentrations of externally added D- and L-aspartate, L-glutamate, L-cysteate and L-cysteinesulphinate. The stimulation of release by external amino acids followed Michaelis-Menten kinetics; the apparent Km values (in microM) were: 14.65 +/- 0.98 for D-aspartate; 8.00 +/- 1.5 for L-aspartate; 22.31 +/- 1.62 for L-glutamate; 6.76 +/- 0.3 for L-cysteate and 7.89 +/- 1.23 for L-cysteinesulphinate. The Vmax values for efflux were 2.16-4.06 nmol/min per mg protein. The exchange process was found to require external NaCl but was very little affected by increase in the external [K+]. The demonstration of exchange as a part of the transport process provides support for the suggestion that in synaptosomal preparations a substantial portion of influx and efflux of amino acid neurotransmitters occurs via a reversible membrane carrier.

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.

Uptake and release of [3H]dopamine by the median eminence: evidence for presynaptic dopaminergic receptors and for dopaminergic feedback inhibition

The accumulation and release of [3H]dopamine by the median eminence in vitro was studied after treatments with different pharmacological agents, to determine whether such a procedure would be useful for measuring neuronal activity in the tuberoinfundibular dopaminergic system. The accumulation of [3H]dopamine was temperature, time, and sodium dependent, and reduced by unlabelled dopamine and by a potent dopamine uptake blocker, nomifensine. The outflow of tritium was studied after blocking the oxidative deamination of dopamine by nialamide. The outflow of tritium was elicited consistently by biphasic square wave electrical pulses and by high molarity potassium ions. The response to electrical stimulation was dependent largely on calcium and partially on sodium. The response to high molarity potassium ions was reduced in the absence of calcium ions. The response to electrical stimulation was increased by nomifensine and by a dopaminergic antagonist, haloperidol, and was reduced by dopamine and by a dopaminergic agonist, piribedil. The inhibitory action of dopamine was antagonized by haloperidol. These results indicate the existence of uptake and release mechanisms in the tuberoinfundibular dopamine neurons, and suggest that dopamine may inhibit its own release via dopaminergic receptors. This in vitro method may be useful for measuring dopamine uptake and release by tuberoinfundibular dopaminergic neurons.

Catecholamine uptake into isolated adrenal chromaffin cells: inhibition of uptake by acetylcholine

We have investigated the process of catecholamine uptake in guinea-pig chromaffin cells. Isolated guinea-pig chromaffin cells accumulate [3H]norepinephrine and [3H]epinephrine by a saturable transport system. Catecholamine uptake is dependent upon temperature, energy, and extracellular Na+. The apparent KmS for norepinephrine and epinephrine transport are approximately 1 and 3.5 microM, respectively; the transport maximum (Vmax) for both compounds is about 100 pmol/min/mg protein. The uptake of norepinephrine into chromaffin cells is inhibited by imipramine (Ki = 50 nM) and by desmethylimipramine (IC50 = 20 nM). In both its substrate specificity and its sensitivity to pharmacological inhibition, the catecholamine uptake system in chromaffin cells is similar to the catecholamine transport system previously described in sympathetic neurons. Decreasing external Na+ from 130 to 19 mM increases the apparent Km for norepinephrine to 2.8 microM. Decreasing external norepinephrine increases the Na+ concentration required for half-maximal transport. Agents that depolarize chromaffin cells, such as acetylcholine and veratridine, significantly inhibit [3H]norepinephrine uptake. This decrease in uptake is due to an increase in the apparent Km for norepinephrine. The inhibition of [3H]norepinephrine uptake by depolarizing agents cannot be accounted for by the preferential release of newly-accumulated [3H]norepinephrine, or by the competitive inhibition of [3H]norepinephrine uptake by secreted catecholamines. The inhibition of catecholamine uptake by depolarizing agents suggests that the transport system may be regulated by the membrane potential. Norepinephrine and epinephrine that are spontaneously released from the adrenal medulla may be recaptured in vivo. The inhibition of transport by acetylcholine may prevent the re-uptake of catecholamine released during the physiological stimulation of secretion.