Roles for Mitochondrial and Reverse Mode Na+/Ca2+ Exchange and the Plasmalemma Ca2+ ATPase in Post-Tetanic Potentiation at Crayfish Neuromuscular Junctions

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The Journal of Neuroscience, December 15, 2001, 21(24):9598-9607

Roles for Mitochondrial and Reverse Mode Na⁺/Ca²⁺ Exchange and the Plasmalemma Ca²⁺ ATPase in Post-Tetanic Potentiation at Crayfish Neuromuscular Junctions
Ning Zhong, Vahri Beaumont, and Robert S. Zucker
Department of Molecular and Cell Biology, University of California, Berkeley, California, 94720-3200

  ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

We have explored the processes regulating presynaptic calcium concentration ([Ca²⁺]_i) in the generation of post-tetanic potentiation (PTP) at crayfishneuromuscular junctions, using spectrophotometric dyes to measurechanges in [Ca²⁺]_i and [Na⁺]_i and effects of inhibitors of Ca²⁺-transport processes. The mitochondrial Na⁺/Ca²⁺ exchange inhibitor CGP 37157 was without effect, whereas thereverse mode plasmalemmal Na⁺/Ca²⁺ exchange inhibitor KB R7943 reduced PTP and Ca²⁺ accumulation caused by increased [Na⁺]_i. Exchange inhibitory peptide and C28R2 had opposite effects,consistent with their block of the plasma membrane Ca²⁺ ATPase. All drugs except CGP 37157 reduced Ca²⁺ accumulation caused by Na⁺ accumulation, which occurred on block of the Na⁺/K⁺ pump, acting in proportion to their effects on plasmalemmal Na⁺/Ca²⁺ exchange. We find no role for mitochondrial Na⁺/Ca²⁺ exchange in presynaptic Ca²⁺ regulation. The plasma membrane Na⁺/Ca²⁺ exchanger acts in reverse mode to admit Ca²⁺ into nerve terminals during and for some minutes after tetanicstimulation, while at the same time the plasma membrane Ca²⁺ ATPase operates as an important Ca²⁺ removal process. The interplay of these two Ca²⁺ transport processes with Na⁺-independent mitochondrial Ca²⁺ fluxes and the plasmalemma Na⁺/K⁺ pump determines the magnitude of tetanic [Ca²⁺]_i accumulation and potentiation of excitatory transmission, andthe post-tetanic time courses of decay of elevated [Ca²⁺]_i andPTP.

Key words: post-tetanic potentiation; Na⁺/Ca²⁺ exchange; Ca²⁺ ATPase; mitochondria; transmitter release; crayfish; neuromuscular junction; synaptic transmission

  INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

When presynaptic activity persists at high levels for several minutes, many synapses display a gradual potentiation of synaptictransmission. After activity subsides, individual action potentialscontinue to evoke potentiated postsynaptic potentials for severalminutes, a process called post-tetanic potentiation (PTP) (Zucker,1989). At crayfish neuromuscular junctions, PTP reflects an increasein the number of quanta released by action potentials (Wojtowiczand Atwood, 1986) that is caused by a persistent increase in presynapticcalcium concentration ([Ca²⁺]_i) (Delaney et al., 1989). This so-called "residual Ca²⁺" remaining in nerve terminals after bouts of activity arisesprimarily from efflux of Ca²⁺ from mitochondria that become Ca²⁺ loaded during the conditioning activity (Tang and Zucker, 1997).It appears to induce PTP by acting on a presynaptic Ca²⁺ target distinct from those involved in exocytosis and short-termsynaptic facilitation (Kamiya and Zucker, 1994). Excessive Na⁺ loading of presynaptic terminals also enhances and prolongs PTPand the persistence of residual Ca²⁺ (Mulkey and Zucker, 1992), suggesting that accumulation of Na⁺ retards Ca²⁺ extrusion by Na⁺/Ca²⁺ exchange, contributing to the genesis ofPTP.

There are two Na⁺/Ca²⁺ exchangers that could mediate an influence of Na⁺ on [Ca²⁺]_i: plasmalemmal Na⁺/Ca²⁺ exchange (Blaustein and Lederer, 1999) and mitochondrial Na⁺/Ca²⁺ exchange (Friel, 2000; Gunter et al., 2000). In the first case,tetanic [Na⁺]_i elevation could retard or even reverse the direction of Ca²⁺ flux through the plasmalemmal Na⁺/Ca²⁺ exchanger, resulting in Ca²⁺ influx into cytoplasm from the external medium. In the secondcase, [Na⁺]_i elevation could activate mitochondrial Ca²⁺ efflux into cytoplasm. Both plasmalemmal Na⁺/Ca²⁺ exchange (Luther et al., 1992; Gleason et al., 1994; Kobayashiand Tachibana, 1995; Regehr, 1997; Scotti et al., 1999) and mitochondrialCa²⁺ fluxes (Alnaes and Rahamimoff, 1975; David et al., 1998; Peng,1998; Brodin et al., 1999) are known to be involved in Ca²⁺ regulation at nerveterminals.

Two other important Ca²⁺ regulatory processes are the plasmalemma Ca²⁺ ATPase (Garcia and Strehler, 1999) and Ca²⁺ channels in endoplasmic reticulum (Pozzan et al., 1994; Simpsonet al., 1995). Both have been implicated in controlling [Ca²⁺]_i at nerve terminals (Fossier et al., 1994; Kobayashi and Tachibana,1995; Tucker and Fettiplace, 1995; Peng, 1996; Smith and Cunnane,1996; Morgans et al., 1998; Juhaszova et al., 2000; Zenisek andMatthews, 2000).

Here we explore roles for these processes in controlling the residual Ca²⁺ responsible for the induction of PTP at crayfish motor nerveterminals. We report effects of drugs that target the plasmalemmalor mitochondrial Na⁺/Ca²⁺ exchanger or the Ca²⁺ ATPase. Although these drugs were developed in mammalian preparations,the high genetic and immunological conservation of these moleculesacross vertebrates and invertebrates, particularly for the plasmalemmalNa⁺/Ca²⁺ exchanger (Blaustein and Lederer, 1999), encouraged us to applythem to this preparation. We observe important effects of plasmalemmalNa⁺/Ca²⁺ exchange and the Ca²⁺ ATPase, whereas we could detect no role for mitochondrial Ca²⁺ efflux via Na⁺/Ca²⁺exchange.

  MATERIALS AND METHODS

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Animals, solutions, and drugs. Experiments used isolated opener muscles of the first walking leg of crayfish (Procambarusclarkii, 2-2.5 inches) obtained from KLM Bioscientific (San Diego,CA) and Niles Biological (Sacramento, CA). Autotomized first walkinglegs were pinned in a Sylgard-lined chamber continuously perfusedwith a solution containing (in mM): 195 NaCl, 13.5 CaCl₂, 5.4KCl, 2.6 MgCl₂, and 10 Na-HEPES, pH 7.4, at 15-17°C. Opener musclesand exciter axons were exposed as described previously (Delaneyand Tank, 1991; Landò and Zucker, 1994). Chemicals were obtainedfrom the following suppliers: 2-[2-[4-(4-nitrobenzyloxy)phenyl]ethyl]isothiourea(KB R7943) and 7-chloro-5-(2-chlorophenyl)-1,5-dihydro-4,1-benzothiazepin-2(³H)-one (CGP 37157) from Tocris (Ballwin, MO); exchange inhibitorypeptide (XIP) (RRLLFYKYVYKRYRAGKQRG) and C28R2 (Ca²⁺ ATPase inhibitor, LRRGQILWFRGLNRIQTQIRVVKAFRSS) from Alpha DiagnosticInternational (San Antonio, TX); ouabain and palytoxin from Sigma(St. Louis, MO); fura-2 pentapotassium salt from Molecular Probes(Eugene, OR); sodium-binding benzofuran isophthalate (SBFI) fromTefLabs (Austin, TX); and gramicidin D and monensin from Calbiochem(San Diego, CA). Stock solutions of KB R7943 (100 mM) and CGP37157 (25 mM) were made in dimethyl sulfoxide and diluted to thedesired concentration in crayfish saline before experiments. Thefinal concentration of solvent did not exceed 0.1%. Ouabain wasfreshly prepared in crayfish saline before eachexperiment.

Electrophysiology. The exciter motor neuron to the opener muscle was stimulated with a suction electrode on the leg nerveexposed in the meropodite while excitatory junction potentials(EJPs) were recorded via microelectrodes (12-25 M $Omega$ ) filled with3 M KCl impaled in central-proximal or proximal muscle fibers.Electrical signals were amplified and filtered at 2 kHz (Neuroprobe1600, A-M Systems, Everett, WA) and digitized at 5 kHz (DigiData1200A, Axon Instruments, Foster City, CA). In some experiments,axon action potentials were recorded using a beveled microelectrode(25-45 M $Omega$ ) penetrating a primary or secondary branch of the exciteraxon and amplified (Getting Microelectrode Amplifier Model 5,Iowa City, IA) before digitization. After penetrating a nerveterminal, a second microelectrode was placed into an adjacentpostsynaptic muscle fiber within 100-200 µm of the presynapticimpalement site to measure EJPs. Intracellular recordings fromsynaptic terminals and muscle fibers were stable for several hours.Recordings from the Y branch or a secondary branch were within0.3-0.5 space constants of imaged sites of excitatory transmitterrelease (Baxter and Bittner, 1981, 1991). The average restingmembrane potential was $-$ 71 ± 3 mV (n = 4). EJPs and action potentialswere stored on a personal computer using pClamp7 software (AxonInstruments). EJP amplitudes were analyzed off-line (Clampfit6.05, Axon Instruments).

Presynaptic peptide injection. The primary or secondary branch of the excitatory axon was penetrated with a beveled electrodecontaining XIP (0.33 mM) or C28R2 (0.23 mM) in a dye-marked carriersolution (6 mM fura-2, 200 mM KCl, 10 mM HEPES, pH 7.4). Pressureinjection used trains of pressure pulses (30-40 psi, 400 msecduration, 0.33 Hz) for 1 hr. From the fluorescence intensity offura-2, the dye concentration was estimated as described previously(Mulkey and Zucker, 1992) and used to estimate peptide concentrationsin presynaptic terminals. For EJP measurements, responses to acontrol tetanus were obtained before peptide injection and thenafter injection responses to a second tetanus were recorded. [Ca²⁺]_i measurements were obtained from another group of animals inwhich peptide with fura-2 was injected and effects of tetanicstimulation were recorded. Controls consisted of identical experimentsperformed in different cells injected with fura-2 but no peptide.In these experiments, fura-2 (17 mM in 200 mM KCl) was iontophoresedinto the axon using 10-15 nA of continuous hyperpolarizing currentfor ~30 min. The final concentration of fura-2 was ~150 µM.

[Ca²⁺]_i measurement. Fura-2 fluorescence was detected with a silicon-intensified target (SIT) camera (Dage MTI, model 66), viaa 40× 0.7 numerical aperture water immersion objective (Olympus,Lake Success, NY). Fluorescence was alternately excited through350 ± 10 and 382 ± 5 nm filters (Omega Optical, Battleboro, VT).A dichroic mirror (455 nm; Nikon, Tokyo, Japan) separated excitationand emission wavelengths, and a barrier filter (530 ± 20 nm) (OmegaOptical) limited interference by autofluorescence. An area nearthe imaged bouton with uniform intensity similar to that aroundthe bouton was chosen for obtaining tissue background. Backgroundsubtraction and shading correction were performed automaticallyin an image processor (FD5000; Gould Inc., Fremont, CA). Shadingcorrection removes errors attributable to changes in the colorof the excitation illumination with age of the bulb or other variableoptical chromaticdistortions.

Averages of 32 sequential images excited at 350 and 385 nm were stored on an optical disk recorder (TQ-2028F, Panasonic, Secaucus,NJ). The imaging processor, optical disk recorder, and filterchanger were under the control of a Scientific Microsystems SMS1000 computer (Mountain View, CA), using software written by Dr.Roger Tsien (Pharmacology Department, University of California,San Diego). Fura-2 images were calibrated by measuring the fluorescenceratio obtained with 50 µM fura-2 in solutions at 280 mM ionicstrength, resembling crayfish cytoplasmic solution (250 mM K-gluconate,15 mM NaCl, 15 mM K-HEPES, pH 7.02) with zero-calcium (10 mM K₂EGTA),5 mM Ca²⁺, or [Ca²⁺]_i buffered to 500 nM with 10 mM K₂EGTA and 5 mM CaCl₂. Ratiosmeasured in terminals were converted to [Ca²⁺ ]_i (Grynkiewicz et al., 1985) after application of a viscositycorrection corresponding to a 30% reduction in the minimum andmaximum 350 nm/385 nm fluorescence ratios (Mulkey and Zucker,1992). Calibrations used values of R_max/R_min = 22.9 and K_D = 523nM.

[Na⁺]_i measurement. The [Na⁺]_i measurements were done in separate preparations from those used for EJP and [Ca²⁺]_i measurements. The exciter axon was penetrated with a beveledmicroelectrode (25-45 M $Omega$ ) containing 20 mM SBFI in 200 mM KCl,10 mM HEPES, pH 8.5. Dye was iontophoresed ( $-$ 10 nA for 30 min)to a final concentration of ~0.5 mM. Ratiometric SBFI images wereproduced in the same manner as that used for fura-2. A 50% neutraldensity filter reduced excitation light intensity to minimizephotobleach.

SBFI was calibrated in situ (Harootunian et al., 1989). Axons injected with SBFI were permeabilized by addition of sodiumionophores palytoxin (0.1 µM), gramicidin D (10 µM), and monensin(10 µM) and subsequently perfused with solutions comprising varying[Na⁺]. This was achieved by mixing a "high Na⁺" solution [containing (in mM): 13 NaCl, 244 Na-gluconate, 10Cs-HEPES, 5 CaCl₂, 1 MgCl₂, pH 7.00] with a "Na-free" solution[containing (in mM): 13 KCl, 244 K-gluconate, 10 Cs-HEPES, 5 CaCl₂,1 MgCl₂, pH 7.00] so that ionic strength remained at 280 and [Na⁺] could be set from 0-257 mM. Palytoxin also inhibits the Na⁺/K⁺ ATPase (Habermann, 1989), permitting [Na⁺]_i to rise to high levels when external [Na⁺] is high. Ratiometric fluorescence images were obtained at different[Na⁺]. R_max/R_min was 1.88 and the K_D of Na⁺ binding to SBFI was determined as 21 ± 2 mM (n = 3) using Equation5 of Grynkiewicz et al.(1985).

Data analysis. Curve-fitting algorithms in Prism (GraphPad Software, San Diego, CA) were used to determine the decay timeconstants of PTP and [Ca²⁺ ]_i. EJP amplitudes normally showed a double exponential decay.We quantified PTP by fitting an exponential function to the slowlydecaying component of the post-tetanic decay in EJP amplitude.A two-sided Student's t test on percentage changes from controlin each pair was used to estimate statistical significance unlessindicatedotherwise.

  RESULTS

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

To investigate roles played by Ca²⁺ removal processes in PTP, we normally compared the effects of PTP-inducing tetani on presynaptic[Ca²⁺]_i accumulation and removal, and the induction of PTP, in thesame preparation before and after administration of specific blockingagents. [Na⁺]_i was determined in some preparations. We first needed to showthat repetition of PTP-inducing tetani produced repeatable effectson [Ca²⁺]_i, [Na⁺]_i, and transmission when there was no drug present for eithertetanus. Figure 1 illustrates two control experiments, and theresults of eight experiments are tabulated in Table 1. PTP wasinduced by stimulation of the exciter motor neuron at 20 Hz for10 min, and EJPs were sampled at 2 Hz before and after the tetanus,and one ratiometric fura-2 image of [Ca²⁺]_i or SBFI image of [Na⁺]_i was produced every minute. The second tetanus followed thefirst by at least 90 min, to allow for full recovery. Pretetanic,tetanic, and post-tetanic EJP amplitudes, and the decay of PTP,remained constant on repetition of PTP induction. [Ca²⁺]_i was measured in four experiments and [Na⁺]_i in one, and pretetanic, tetanic, and post-tetanic [Ca²⁺]_i and [Na⁺]_i levels and their rate of decay also were unchanged.

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Figure 1. EJP amplitude (A), [Ca²⁺]_i (B), and [Na⁺]_i (C) measured before, during, and after 10 min, 20 Hz tetanic stimulation (Tet). The [Na⁺]_i measurements were from a separate experiment.


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Table 1. Effects of KB R7943 and CGP 37157 on presynaptic [Ca²⁺]_i and short-term synaptic enhancement

Plasmalemmal Na⁺/Ca²⁺ exchange does influence PTP

As one probe of plasma membrane Na⁺/Ca²⁺ exchange we used the relatively specific blocker KB R7943. This agent is much more effectiveagainst the reverse mode of transport, in which Ca²⁺ enters in exchange for Na⁺ efflux (IC₅₀ = 0.3-2 µM cytoplasmic concentration) (Iwamoto etal., 1996; Watano et al., 1996), than against forward transport,in which Ca²⁺ is extruded in exchange for Na⁺ influx (IC₅₀ = 17-30 µM). However, at these higher concentrationsKB R7943 (>30 µM) also affected currents through voltage-dependention channels, including Ca²⁺ channels (Watano et al., 1996). At 10 µM bath concentration,KB R7943 was without effect on PTP in our preparations. At concentrationsof 50 µM and higher, baseline synaptic transmission and tetanicpresynaptic [Ca²⁺]_i accumulation were strongly reduced, probably because of presynapticCa²⁺ channel block. At 20 µM, such nonspecific effects on baselinetransmission were not observed, but there was a modest reductionin tetanic Ca²⁺ accumulation and tetanic EJP amplitude, and the post-tetanicdecay of [Ca²⁺]_i and EJP amplitude were accelerated (Fig. 2, Table 1). To confirminhibition by KB R7943 of Na⁺/Ca²⁺ exchange, effects on [Na⁺]_i were observed. KB R7943 (20 µM) had no clear effect on [Na⁺]_i accumulation during tetanic stimulation, but it did slow post-tetanic[Na⁺]_i decay (Fig. 2E,F, Table 1).

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Figure 2. Effects of KB R7943 on [Ca²⁺]_i, [Na⁺]_i, and PTP. The first tetanus was given in normal saline and the second one in the presence of 20 µM KB R7943 (reverse mode plasmalemmal Na⁺/Ca²⁺ exchange inhibitor). A, B, Tetanic [Ca²⁺]_i and EJP amplitude were reduced in 20 µM KB R7943. C, D, Running averages of five post-tetanic [Ca²⁺]_i measurements and eight post-tetanic EJP amplitudes in control saline () and 20 µM KB R7943 ( $open circle$ ). E, F, Tetanic [Na⁺]_i and running average of three post-tetanic [Na⁺]_i measurements in control crayfish saline () and 20 µM KB R7943 ( $open circle$ ).

The acceleration of post-tetanic [Ca²⁺]_i decay and slowing of [Na⁺]_i removal are consistent with a block of Na⁺/Ca²⁺ exchange occurring in reverse mode. However, the effects on Ca²⁺ accumulation and tetanic EJP amplitude could be attributableto a reduction of Ca²⁺ influx through Ca²⁺ channels. This could result in reduced mitochondrial Ca²⁺ accumulation and therefore a reduction in both PTP and in post-tetanic[Ca²⁺]_i (Tang and Zucker, 1997), but the effect on Na⁺ removal is difficult to explain this way and suggests insteadan action on Na⁺/Ca²⁺ exchange. To distinguish effects on tetanic Ca²⁺ influx from effects on Na⁺/Ca²⁺ exchange, KB R7943 was applied at the end of the tetanus. A solutioncontaining 20 µM KB R7943 was washed in during the last minuteof tetanic stimulation. The peak EJP amplitude (12.7 mV in thesecond tetanus vs 11.9 mV in the first tetanus) and [Ca²⁺]_i accumulation (1.09 µM in the second tetanus vs 1.07 µM in thefirst tetanus) were not influenced. Nevertheless, KB R7943 stillaccelerated Ca²⁺ removal ( $tau$ _slow = 3.41 min in the second tetanus vs 4.69 min inthe first tetanus) and PTP decay ( $tau$ = 2.79 min vs the controlvalue of 3.4 min) (Fig. 3). These effects are similar to thoseoccurring when KB R7943 was present throughout the second tetanus(Fig. 2, Table 1).

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Figure 3. KB R7943 application delayed until the end of tetanic stimulation. A, B, Tetanic [Ca²⁺]_i and EJP amplitude were unchanged when applying 20 µM KB R7943 at the end of a 20 Hz tetanus. C, D, Running averages of three post-tetanic [Ca²⁺]_i measurements and two post-tetanic EJP amplitudes in control saline () and 20 µM KB R7943 ( $open circle$ ). E, F, Tetanic [Na⁺]_i and post-tetanic [Na⁺]_i measurements in control crayfish saline () and when applying 20 µM KB R7943 at the end of the tetanus ( $open circle$ ).

Taken together our results show that plasma membrane Na⁺/Ca²⁺ exchange operates in reverse mode (admitting Ca²⁺ into nerve terminals) during and for some minutes after tetanicstimulation, attributable to the presynaptic accumulation of Na⁺, contributing to tetanic [Ca²⁺]_i accumulation and EJP potentiation and slowing post-tetanicCa²⁺ removal and PTP decay. Blocking this process then reduces tetanic[Ca²⁺]_i accumulation and EJP potentiation and speeds Ca²⁺ removal and PTPdecay.

Tetanic Na⁺ accumulation reverses plasmalemmal Na⁺/Ca²⁺ exchange and prolongs PTP

The operation of Na⁺/Ca²⁺ exchange in reverse mode in PTP is further supported by our measurements of [Na⁺]_i and [Ca²⁺]_i changes during and after tetanic stimulation (Fig. 4, Table1). We have performed such measurements on small individual presynapticboutons and with greater accuracy on larger preterminal nervebranches. Tetanic stimulation causes [Na⁺]_i to rise from 7 to 80 mM and [Ca²⁺]_i to rise from 0.13 to 1.15 µM. [Ca²⁺]_i recovers to only slightly above resting levels within 2-5 minafter the tetanus (Tang and Zucker, 1997), whereas [Na⁺]_i relaxes more slowly to pretetanic levels ( $tau$ _Na = 8.52 ± 1.92min, p < 0.05, vs $tau$ _Ca = 5.71 ± 0.69 min).

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Figure 4. Relationship between the membrane potential (V_m) and calculated Na⁺/Ca²⁺ exchange equilibrium potential (E_Na/Ca) before, during, and after 10 min, 20 Hz tetanic stimulation. Top panel shows average [Na⁺]_i ( $open circle$ , n = 7) and [Ca²⁺]_i (, n = 8) in primary and secondary branches of the exciter axon (left) or in terminal boutons (right). Bottom panel shows the calculated E_Na/Ca ( $open circle$ ) and measured V_m (, n = 4); it indicates that during the tetanus and PTP phase, the Na⁺/Ca²⁺ exchange operates in reverse mode. Tetanic and PTP periods are indicated by different shading patterns (tetanic period ; PTP ).

Na⁺/Ca²⁺ exchange involves the movement of three Na⁺ ions in one direction in exchange for one Ca²⁺ ion in the opposite direction. Because there is a net transportof charge, the process is not electroneutral and depends on membranepotential as well as the Na⁺ and Ca²⁺ gradients across the membrane (Blaustein and Lederer, 1999).The direction of Ca²⁺ flux can be outward (normal mode) or inward (reverse mode), accordingto whether the difference ( $Delta$ $nu$ ) between membrane potential (V_m)and the equilibrium potential for Na⁺/Ca²⁺ exchange (E_Na/Ca) is negative or positive:

where E_Na/Ca depends on the Nernst potentials for Na⁺ (E_Na) and Ca²⁺ (E_Ca):

From measurements of changes in [Na⁺]_i, and [Ca²⁺]_i during and after stimulation, and with [Na⁺]_o = 205 mM and [Ca²⁺]_o = 13.5 mM, E_Na/Ca can be calculated. When compared with measurementsof V_m (Fig. 4), it can be seen that the $Delta$ $nu$ is negative at rest(when V_m = $-$ 70 mV and E_Na/Ca = $-$ 42 mV, $Delta$ $nu$ = $-$ 28 mV), but rapidlygoes positive during tetanic stimulation (when V_m = $-$ 80 mV andE_Na/Ca = $-$ 177 mV, $Delta$ $nu$ = +93 mV). The hyperpolarization of nerveterminals during tetanic stimulation is caused by operation ofthe Na⁺/K⁺ pump (Wojtowicz and Atwood, 1985), which extrudes three Na⁺ ions for each two K⁺ ions admitted. $Delta$ $nu$ remains positive for some 15 min after stimulation,even rising slightly immediately post-tetanically because [Ca²⁺]_i recovers more rapidly than [Na⁺]_i. These data show that the plasma membrane Na⁺/Ca²⁺ exchanger should run in normal mode at rest, extruding Ca²⁺ from cytoplasm, but in reverse mode during and for some timeafter tetanic stimulation, admitting Ca²⁺ ions from outside, increasing the tetanic rise in [Ca²⁺]_i, potentiating synaptic transmission, slowing the post-tetanicrecovery of [Ca²⁺]_i, and prolongingPTP.

Mitochondrial Na⁺/Ca²⁺ exchange does not appear to participate in PTP

In addition to the plasmalemmal Na⁺/Ca²⁺ exchanger, mitochondrial Na⁺/Ca²⁺ exchange might also play a role in PTP. We probed this possibilitywith CGP 37157, a specific inhibitor of mitochondrial Ca²⁺ efflux (IC₅₀ = 0.36 µM cytoplasmic concentration) (Cox et al.,1993). If mitochondrial Na⁺/Ca²⁺ exchange regulates [Ca²⁺]_i in PTP, then with sufficient tetanic Na⁺ accumulation, mitochondrial Na⁺/Ca²⁺ exchange might transport Ca²⁺ into the cytoplasm, increasing [Ca²⁺]_i accumulation and EJP potentiation and retarding the post-tetanicdecay of [Ca²⁺]_i and PTP. Block of this process would then reduce tetanic cytoplasmic[Ca²⁺]_i accumulation and synaptic transmission, and [Ca²⁺]_i and PTP would decay more rapidly. Contrary to this scenario,we found that 25 µM CGP 37157 applied 20 min before a tetanusand left on until at least 20 min after the end of the tetanuswas completely without effect on the pretetanic, tetanic, andpost-tetanic [Ca²⁺]_i changes and baseline transmission or PTP (Fig. 5, Table 1).Because the EJP during tetanic stimulation reflects facilitationand augmentation as well as potentiation (Zucker, 1989), theseprocesses were all apparently unaffected.

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Figure 5. Effects of mitochondrial Na⁺/Ca²⁺ transport inhibitor CGP 37157 on [Ca²⁺]_i and PTP. The first tetanus was given in normal saline and the second one in the presence of 25 µM CGP 37157. In 25 µM CGP 37157, [Ca²⁺]_i (A) and EJP amplitude (B) were unchanged.

Plasmalemma Ca²⁺ ATPase does influence PTP

Transport inhibitory peptide (XIP) is another blocker of Na⁺/Ca²⁺ exchange (Li et al., 1991), which binds to a cytoplasmic autoinhibitorycalmodulin-binding domain of the exchanger with IC₅₀ = 1.7 µM(Xu et al., 1997). This agent must be injected into presynapticnerve terminals, so it is impractical to measure [Ca²⁺]_i and synaptic transmission in the same preparations before andafter drug administration. We therefore compared [Ca²⁺]_i responses with tetanic stimulation in two groups of experiments(different from those used to record effects on EJPs), in oneof which XIP had been injected to an estimated concentration of~5-10 µM. If Na⁺/Ca²⁺ exchange operates in reverse mode in a tetanus, we would expectblock of this process to reduce [Ca²⁺]_i accumulation and EJP potentiation and speed post-tetanic Ca²⁺ removal and PTP decay. In fact, we observed just the oppositeeffects (Fig. 6A, Table 2).

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Figure 6. XIP and C28R2 increase [Ca²⁺]_i accumulation and potentiation and retard [Ca²⁺]_i decay in PTP. A, B, EJP amplitudes during the first control tetanus and the second tetanus after presynaptic injection of inhibitors of plasma membrane Na⁺/Ca²⁺ exchange and Ca²⁺ ATPase: XIP (A) or C28R2 (B). C, D, Running averages of five (C) or four (D) post-tetanic EJP amplitudes in control saline () and in the presence of inhibitory peptide ( $open circle$ ). E, F, [Ca²⁺]_i, averages with SEs in controls (; with no presynaptic peptide injection; n = 7), XIP injections ( $open circle$ in E; n = 4), or C28R2 injections ( $open circle$ in F; n = 4).


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Table 2. Effects of XIP and C28R2 on presynaptic [Ca²⁺]_i and short-term synaptic enhancement

One explanation of these results is that XIP also blocks the plasma membrane Ca²⁺ ATPase at similar levels (2.5 µM) to those blocking Na⁺/Ca²⁺ exchange (Enyedi and Penniston, 1993). Block of Ca²⁺ efflux by this route should increase [Ca²⁺]_i accumulation and EJP potentiation and retard post-tetanic Ca²⁺ removal and PTP decay, as we observed. To test this explanation,we used a different inhibitory peptide, C28R2, an agent that issomewhat more effective in blocking the plasmalemma Ca²⁺ ATPase (IC₅₀ = 1 µM) (Enyedi and Penniston, 1993) than Na⁺/Ca²⁺ exchange (IC₅₀ = 6.2 µM) (Xu et al., 1997). Presynaptic injectionof this inhibitor to ~1-5 µM had effects identical to those ofXIP (Fig. 6B, Table 2), suggesting that both act mainly on theCa²⁺ ATPase to increase [Ca²⁺]_i accumulation and EJP potentiation and retard post-tetanic Ca²⁺ removal and PTPdecay.

Increasing [Na⁺]_i with ouabain acts on plasmalemmal Na⁺/Ca²⁺ exchange

The results of Figures 2-4 and Table 1 suggest that tetanic Na⁺ accumulation activates the Na⁺/Ca²⁺ exchanger in reverse mode, enhancing tetanic Ca²⁺ accumulation and prolonging its post-tetanic decay. Previousresults also implicated Na⁺/Ca²⁺ exchange as a target for Na⁺ action in PTP, but they did not distinguish mitochondrial fromplasmalemmal Na⁺/Ca²⁺ exchange (Mulkey and Zucker, 1992). It was shown, for example,that elevation of presynaptic [Na⁺]_i by block of the Na⁺/K⁺ ATPase with ouabain (Delaney and Tank, 1994) led to an increasein [Ca²⁺]_i and EJP amplitude. We have now used the mitochondrial Na⁺/Ca²⁺ exchange inhibitor CGP 37157 and the plasmalemmal Na⁺/Ca²⁺ exchange inhibitors KB R7943 and XIP to identify the target ofNa⁺ action on [Ca²⁺]_i when ouabain is used to elevate [Na⁺]_i (Fig. 7).

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Figure 7. Effects of transport inhibitors on ouabain-induced [Ca²⁺]_i accumulation and enhancement of synaptic transmission. A, Effects of 0.5 mM ouabain on presynaptic [Ca²⁺]_i and EJP amplitude (n = 6). The preparations were stimulated at 2 Hz during the experiment, and [Ca²⁺]_i was measured every 3 min. Arrows indicate ouabain application (black arrow) and subsequent washout (gray arrow). B, C, Response of [Ca²⁺]_i and EJP amplitude to 25 µM CGP 37157 (, n = 6), 20 µM KB R7943 ( $black-square$ , n = 5), or after presynaptic injection of C28R2 (, n = 5) or XIP ( $triangle$ , n = 4), compared with controls ( $open circle$ , n = 6). Drugs blocked the [Ca²⁺]_i elevation and EJP enhancement in proportion to their efficacy in blocking plasmalemmal Na⁺/Ca²⁺ exchange.

The Na⁺-dependent increases in [Ca²⁺]_i and EJP amplitude were blocked almost completely by inhibitors of the plasma membraneexchanger but were affected very little by inhibition of mitochondrialNa⁺/Ca²⁺ exchange. We also tested the effect of C28R2 on Na⁺-dependent [Ca²⁺]_i elevation and EJP potentiation and found it to have a modestblocking effect (Fig. 7). C28R2 is most effective in blockingthe plasmalemma Ca²⁺ ATPase, but it also inhibits plasmalemmal Na⁺/Ca²⁺ exchange to some extent, as indicated above. In ouabain, withno tetanic stimulation, the only source for a rise in [Ca²⁺]_i is by reverse mode Na⁺/Ca²⁺ exchange, and its inhibition would prevent a rise in [Ca²⁺]_i. Under these circumstances, with Ca²⁺ accumulation reduced, inhibition of the Ca²⁺ ATPase should have little effect, and this accounts for our observationof reduced Ca²⁺ accumulation in ouabain in the presence of C28R2. This is theopposite of the effect of C28R2 on Ca²⁺ accumulation and EJP potentiation in a tetanus, where its majoraction is to reduce the Ca²⁺ ATPase-dependent extrusion of Ca²⁺ that has entered through voltage-dependent Ca²⁺ channels in the tetanus (Fig. 6).

  DISCUSSION

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Previous work (Tang and Zucker, 1997) showed that mitochondria accumulate Ca²⁺ during tetanic stimulation and release that Ca²⁺ back to the cytoplasm post-tetanically at crayfish neuromuscularjunctions. That work also found no role for uptake or releaseof Ca²⁺ from endoplasmic reticulum in PTP. Assuming that CGP 37157 blocksmitochondrial Na⁺/Ca²⁺ exchange in crayfish as effectively as in other preparations,the present study refines the role of mitochondrial Ca²⁺ transport by excluding Na⁺-dependent efflux of Ca²⁺ as a major route of Ca²⁺ flux in regulating the [Ca²⁺]_i responsible for PTP. Together the results suggest that Na⁺-independent modes of Ca²⁺ transport dominate in the tetanic uptake and subsequent post-tetanicrelease of Ca²⁺ by mitochondria. These modes include a Ca²⁺ uniporter and an apparently distinct rapid mode for uptake, anda Ca²⁺/H⁺ exchanger and permeability transition pore for Ca²⁺ efflux (Gunter et al., 2000; Rizzuto et al., 2000). Our resultsdo not distinguish among theseprocesses.

Previous work (Mulkey and Zucker, 1992) also implicated [Na⁺]_i accumulation and activation of Na⁺/Ca²⁺ exchange in elevating [Ca²⁺]_i accumulation in PTP and prolonging its removal. However, thatwork failed to distinguish mitochondrial from plasmalemmal Na⁺/Ca²⁺ exchange. The present work identifies the plasma membrane Na⁺/Ca²⁺ exchanger as the target of Na⁺ action and shows that this exchanger operates in reverse modeto enhance tetanic [Ca²⁺]_i accumulation and EJP potentiation and to retard post-tetanicCa²⁺ removal and the decay ofPTP.

Mulkey and Zucker (1992) tested for operation of Na⁺/Ca²⁺ exchange in reverse mode by tetanically stimulating in a Ca²⁺-free solution, then restoring external [Ca²⁺] and looking for a rise in [Ca²⁺]_i. No such rise was observed, but it may be that by the timeexternal Ca²⁺ reached normal levels, [Na⁺]_i levels had already recovered sufficiently that Ca²⁺ influx via Na⁺/Ca²⁺ exchange wasminimal.

Studies of Ca²⁺ regulation are limited by the imperfect selectivity of agents available to influence Ca²⁺ regulatory processes. Thus, in Figure 2, KB R7943 could reduceboth Ca²⁺ influx through voltage-dependent Ca²⁺ channels and the operation of the Na⁺/Ca²⁺ exchanger in reverse mode. These actions were distinguished byadministering this drug at the end of the tetanus, when most Ca²⁺ influx had already occurred normally (Fig. 3), leaving only effectsattributable to block of Na⁺/Ca²⁺ exchange. Similarly, XIP and C28R2 act on the plasmalemma ATPase,the dominant regulator of [Ca²⁺]_i, to reduce its extrusion of Ca²⁺ ions during and after tetanic stimulation (Fig. 6). However,when ouabain is used to block Na⁺ extrusion without stimulation (Fig. 7), the rise in [Ca²⁺]_i is more modest, and the Ca²⁺ ATPase is less strongly activated. Because the only source ofa rise in [Ca²⁺]_i under these circumstances is through reverse mode Na⁺/Ca²⁺ exchange, it is not surprising that the main effect of XIP andC28R2 is in blocking this exchange, thus reducing [Ca²⁺]_i accumulation. All our findings are in accord with the reportedrelative effects of KB R7943, XIP, and C28R2 on Na⁺/Ca²⁺ exchange, Ca²⁺ channels, and the Ca²⁺ ATPase, as indicated in detail inResults.

These results allow a qualitative, but not a quantitative, description of the regulation of [Ca²⁺]_i in PTP at crayfish motor nerve terminals (Fig. 8). At rest(Fig. 8, 1), the plasma membrane Na⁺/Ca²⁺ exchanger operates in the forward mode in concert with the Ca²⁺ ATPase to keep [Ca²⁺]_i low, whereas the Na⁺/K⁺ ATPase maintains [Na⁺]_i levels. During high-frequency stimulation, presynaptic terminalsload with Ca²⁺ and Na⁺ entering through voltage-dependent ion channels (Fig. 8, 2).As [Na⁺]_i rises, plasmalemmal Na⁺/Ca²⁺ exchange switches to reverse mode, and this becomes another sourceof Ca²⁺ entry. During this time the plasma membrane Ca²⁺ ATPase and mitochondrial uptake processes work to remove cytoplasmicCa²⁺. Blocking mitochondrial fluxes with tetraphenyl phosphonium orcarbonyl cyanide m-chlorophenyl-hydrazone (Tang and Zucker, 1997)or the plasmalemma Ca²⁺ ATPase with C28R2 or XIP leads to additional [Ca²⁺]_i accumulation and enhanced transmitter release, whereas blockingreverse mode Na⁺/Ca²⁺ exchange with KB R7943 has the opposite effects.

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Figure 8. Multiple systems regulating presynaptic [Ca²⁺]_i in PTP. Schematic represents the response of a presynaptic terminal, during four phases (1-4) of generating PTP (top panel). In the middle panel, [Na⁺]_i, [Ca²⁺]_i, and $Delta$ v (E_Na/Ca $-$ V_m) are depicted by black, gray, and dashed lines, respectively. See Discussion for details. The [Na⁺]_i and [Ca²⁺]_i traces were normalized to the same peak amplitude (respective scales are shown in Fig. 4). NCX, Na⁺/Ca²⁺ exchange; PMCA, plasma membrane Ca²⁺ ATPase.

In the first 15 min after a strong tetanus (Fig. 8, 3), the slow removal of cytoplasmic Na⁺ keeps the plasma membrane Na⁺/Ca²⁺ exchanger operating in reverse and admitting Ca²⁺. The plasma membrane Ca²⁺ ATPase works to reduce [Ca²⁺]_i, whereas Ca²⁺ exits mitochondria by Na⁺-independent processes. If mitochondria are prevented from loadingwith Ca²⁺, the ATPase can remove cytoplasmic Ca²⁺ within seconds, even in the presence of Ca²⁺ influx through the plasmalemmal Na⁺/Ca²⁺ exchanger, and so no PTP is expressed (Tang and Zucker, 1997).Blocking reverse mode plasmalemmal Na⁺/Ca²⁺ exchange speeds Ca²⁺ removal and shortens PTP, whereas blocking Ca²⁺ removal by the plasma membrane Ca²⁺ ATPase has the opposite effects. Finally, when PTP has fullydecayed (Fig. 8, 4) and [Ca²⁺]_i is restored to resting levels, [Na⁺]_i has recovered sufficiently that plasmalemmal Na⁺/Ca²⁺ exchange reverts to normal mode and works with the plasma membraneCa²⁺ ATPase to maintain [Ca²⁺]_i at low levels. At some still undetermined point in period 3or 4, mitochondria are relieved of their excess Ca²⁺ and return to their resting state. The time course and magnitudeof PTP depend, therefore, on an interplay between Na⁺-independent mitochondrial Ca²⁺ fluxes, the plasmalemmal Na⁺/Ca²⁺ exchanger operating in both normal and reverse modes, the plasmamembrane Ca²⁺ ATPase, and the plasmalemma Na⁺/K⁺pump.

  FOOTNOTES

Received July 12, 2001; revised Sept. 18, 2001; accepted Sept. 26, 2001.

The work was supported by National Institutes of Health Grant NS 15114. We thank Russell English for technicalassistance.
Correspondence should be addressed to Robert S. Zucker, Department of Molecular and Cell Biology, University of California,Berkeley, CA, 94720-3200. E-mail: zucker{at}socrates.berkeley.edu.

  REFERENCES

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Alnaes E, Rahamimoff R (1975) On the role of mitochondria in transmitter release from motor nerve terminals. J Physiol (Lond) 248:285-306[Abstract/Free Full Text].
Baxter DA, Bittner GD (1981) Intracellular recordings from crustacean motor axons during presynaptic inhibition. Brain Res 223:422-428[ISI][Medline].
Baxter DA, Bittner GD (1991) Synaptic plasticity at crayfish neuromuscular junctions: presynaptic inhibition. Synapse 7:244-251[ISI][Medline].
Blaustein MP, Lederer WJ (1999) Sodium/calcium exchange: its physiological implications. Physiol Rev 79:763-854[Abstract/Free Full Text].
Brodin L, Bakeeva L, Shupliakov O (1999) Presynaptic mitochondria and the temporal pattern of neurotransmitter release. Philos Trans R Soc Lond B Biol Sci 354:365-372[ISI][Medline].
Cox DA, Conforti L, Sperelakis N, Matlib MA (1993) Selectivity of inhibition of Na⁺-Ca²⁺ exchange of heart mitochondria by benzothiazepine CGP-37157. J Cardiovasc Pharmacol 21:595-599[ISI][Medline].
David G, Barrett JN, Barrett EF (1998) Evidence that mitochondria buffer physiological Ca²⁺ loads in lizard motor nerve terminals. J Physiol (Lond) 509:59-65[Abstract/Free Full Text].
Delaney KR, Tank DW (1991) Calcium-dependent and calcium-independent enhancement of transmitter release at the crayfish neuromuscular junction studied with fura-2 imaging. Ann NY Acad Sci 635:452-454[Medline].
Delaney KR, Tank DW (1994) A quantitative measurement of the dependence of short-term synaptic enhancement on presynaptic residual calcium. J Neurosci 14:5885-5902[Abstract].
Delaney KR, Zucker RS, Tank DW (1989) Calcium in motor nerve terminals associated with post-tetanic potentiation. J Neurosci 9:3558-3567[Abstract].
Enyedi A, Penniston JT (1993) Autoinhibitory domains of various Ca²⁺ transporters cross-react. J Biol Chem 268:17120-17125[Abstract/Free Full Text].
Fossier P, Baux G, Tauc L (1994) Presynaptic mechanisms regulating Ca²⁺ concentration triggering acetylcholine release at an identified neuro-neuronal synapse of Aplysia. Neuroscience 63:405-414[ISI][Medline].
Friel DD (2000) Mitochondria as regulators of stimulus-evoked calcium signals in neurons. Cell Calcium 28:307-316[ISI][Medline].
Garcia ML, Strehler EE (1999) Plasma membrane calcium ATPases as critical regulators of calcium homeostasis during neuronal cell function. Front Biosci 4:D869-882[Medline].
Gleason E, Borges S, Wilson M (1994) Control of transmitter release from retinal amacrine cells by Ca²⁺ influx and efflux. Neuron 13:1109-1117[ISI][Medline].
Grynkiewicz G, Poenie M, Tsien RY (1985) A new generation of Ca²⁺ indicators with greatly improved fluorescence properties. J Biol Chem 260:3440-3450[Abstract/Free Full Text].
Gunter TE, Buntinas L, Sparagna G, Eliseev R, Gunter K (2000) Mitochondrial calcium transport: mechanisms and functions. Cell Calcium 28:285-296[ISI][Medline].
Habermann E (1989) Palytoxin acts through Na⁺,K⁺-ATPase. Toxicon 27:1171-1187[Medline].
Harootunian AT, Kao JP, Eckert BK, Tsien RY (1989) Fluorescence ratio imaging of cytosolic free Na⁺ in individual fibroblasts and lymphocytes. J Biol Chem 264:19458-19467[Abstract/Free Full Text].
Iwamoto T, Watano T, Shigekawa M (1996) A novel isothiourea derivative selectively inhibits the reverse mode of Na⁺/Ca²⁺ exchange in cells expressing NCX1. J Biol Chem 271:22391-22397[Abstract/Free Full Text].
Juhaszova M, Church P, Blaustein MP, Stanley EF (2000) Location of calcium transporters at presynaptic terminals. Eur J Neurosci 12:839-846[ISI][Medline].
Kamiya H, Zucker RS (1994) Residual Ca²⁺ and short-term synaptic plasticity. Nature 371:603-606[Medline].
Kobayashi K, Tachibana M (1995) Ca²⁺ regulation in the presynaptic terminals of goldfish retinal bipolar cells. J Physiol (Lond) 483:79-94[ISI][Medline].
Landò L, Zucker RS (1994) Ca²⁺ cooperativity in neurosecretion measured using photolabile Ca²⁺ chelators. J Neurophysiol 72:825-830[Abstract/Free Full Text].
Li Z, Nicoll DA, Collins A, Hilgemann DW, Filoteo AG, Penniston JT, Weiss JN, Tomich JM, Philipson KD (1991) Identification of a peptide inhibitor of the cardiac sarcolemmal Na⁺-Ca²⁺ exchanger. J Biol Chem 266:1014-1020[Abstract/Free Full Text].
Luther PW, Yip RK, Bloch RJ, Ambesi A, Lindenmayer GE, Blaustein MP (1992) Presynaptic localization of sodium/calcium exchangers in neuromuscular preparations. J Neurosci 12:4898-4904[Abstract].
Morgans CW, El Far O, Berntson A, Wassle H, Taylor WR (1998) Calcium extrusion from mammalian photoreceptor terminals. J Neurosci 18:2467-2474[Abstract/Free Full Text].
Mulkey RM, Zucker RS (1992) Post-tetanic potentiation at the crayfish neuromuscular junction is dependent on both intracellular calcium and sodium ion accumulation. J Neurosci 12:4327-4336[Abstract].
Peng Y (1996) Ryanodine-sensitive component of calcium transients evoked by nerve firing at presynaptic nerve terminals. J Neurosci 16:6703-6712[Abstract/Free Full Text].
Peng YY (1998) Effects of mitochondrion on calcium transients at intact presynaptic terminals depend on frequency of nerve firing. J Neurophysiol 80:186-195[Abstract/Free Full Text].
Pozzan T, Rizzuto R, Volpe P, Meldolesi J (1994) Molecular and cellular physiology of intracellular calcium stores. Physiol Rev 74:595-636[Free Full Text].
Regehr WG (1997) Interplay between sodium and calcium dynamics in granule cell presynaptic terminals. Biophys J 73:2476-2488[Abstract/Free Full Text].
Rizzuto R, Bernardi P, Pozzan T (2000) Mitochondria as all-round players of the calcium game. J Physiol (Lond) 529:37-47[Abstract/Free Full Text].
Scotti AL, Chatton JY, Reuter H (1999) Roles of Na⁺-Ca²⁺ exchange and of mitochondria in the regulation of presynaptic Ca²⁺ and spontaneous glutamate release. Philos Trans R Soc Lond B Biol Sci 354:357-364[ISI][Medline].
Simpson PB, Challiss RA, Nahorski SR (1995) Neuronal Ca²⁺ stores: activation and function. Trends Neurosci 18:299-306[ISI][Medline].
Smith AB, Cunnane TC (1996) Ryanodine-sensitive calcium stores involved in neurotransmitter release from sympathetic nerve terminals of the guinea-pig. J Physiol (Lond) 497:657-664[ISI][Medline].
Tang Y, Zucker RS (1997) Mitochondrial involvement in post-tetanic potentiation of synaptic transmission. Neuron 18:483-491[ISI][Medline].
Tucker T, Fettiplace R (1995) Confocal imaging of calcium microdomains and calcium extrusion in turtle hair cells. Neuron 15:1323-1335[ISI][Medline].
Watano T, Kimura J, Morita T, Nakanishi H (1996) A novel antagonist, No. 7943, of the Na⁺/Ca²⁺ exchange current in guinea-pig cardiac ventricular cells. Br J Pharmacol 119:555-563[ISI][Medline].
Wojtowicz JM, Atwood HL (1985) Correlation of presynaptic and postsynaptic events during establishment of long-term facilitation at crayfish neuromuscular junction. J Neurophysiol 54:220-230[Abstract/Free Full Text].
Wojtowicz JM, Atwood HL (1986) Long-term facilitation alters transmitter releasing properties at the crayfish neuromuscular junction. J Neurophysiol 55:484-498[Abstract/Free Full Text].
Xu W, Denison H, Hale CC, Gatto C, Milanick MA (1997) Identification of critical positive charges in XIP, the Na/Ca exchange inhibitory peptide. Arch Biochem Biophys 341:273-279[ISI][Medline].
Zenisek D, Matthews G (2000) The role of mitochondria in presynaptic calcium handling at a ribbon synapse. Neuron 25:229-237[ISI][Medline].
Zucker RS (1989) Short-term synaptic plasticity. Annu Rev Neurosci 12:13-31[ISI][Medline].

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