Na+-Ca2+ exchanger in the soluble fraction of crayfish striated muscle

Proteins with Na+-Ca2+ exchange activity from the soluble fraction of crayfish striated muscle were inserted into asolectin proteoliposomes. A pH dependent calcium uptake with an optimum at the alkaline side and inhibition in the presence of sodium or strontium ions in the external medium was observed. When expressed per tissue wet weight the capacity for Na+-Ca2+ exchange of proteoliposomes with inserted soluble proteins was by one half higher than that of the membrane fraction and more than twice higher in comparison with the reconstituted membrane bound exchanger. Using polyacrylamide gel electrophoresis two most prominent proteins with Mr over 200 and 43 kDa could be detected in proteoliposomes with the highest Na+-Ca2+ exchange. It is assumed that protein(s) with Mr 43 kDa could represent the soluble Na+-Ca2+ exchanger in crayfish striated muscle soluble fraction.     

Effect of amiloride on diaphragmatic contractility: evidence of a role for Na(+)-Ca2+ exchange

Extracellular Ca2+ has been shown to be important for the normal function of the diaphragm. In this study we have examined the potential importance of Na(+)-Ca2+ exchange as a mechanism for Ca2+ influx during the contractile process by studying the effect of inhibition or stimulation of Na(+)-Ca2+ exchange. Blockade of Na(+)-Ca2+ exchange with amiloride attenuated the twitch response, altered the force-frequency response curve, and enhanced the development of fatigue. The effect of amiloride could be partially reversed by increasing the extracellular Ca2+ concentration. The ability of amiloride to decrease force was associated with decreased Ca2+ uptake by the diaphragm. Enhancing intracellular Na(+)-extracellular Ca2+ exchange by inhibiting the Na(+)-K+ pump significantly decreased the rate of the development of muscle fatigue (89%). The maximal inhibition of diaphragmatic force produced by the amiloride analogue benzamil, which possesses 10-fold greater selectivity for Na(+)-Ca2+ exchange, was not significantly different from that produced by amiloride (76.2 +/- 1.1%), with a concentration that decreased maximum force by 50% equal to 46 microM compared with 460 microM for amiloride. Both agents slowed the maximal rate of relaxation up to 90%. Benzamil elevated resting tension during continuous stimulation of the diaphragm at 0.15 Hz. The results suggest that Na(+)-Ca2+ exchange may have a role in the normal function of the diaphragm.     

Rapid charge translocation by the cardiac Na(+)-Ca2+ exchanger after a Ca2+ concentration jump.

The kinetics of Na(+)-Ca2+ exchange current after a cytoplasmic Ca2+ concentration jump (achieved by photolysis of DM-nitrophen) was measured in excised giant membrane patches from guinea pig or rat heart. Increasing the cytoplasmic Ca2+ concentration from 0.5 microM in the presence of 100 mM extracellular Na+ elicits an inward current that rises with a time constant tau 1 < 50 microseconds and decays to a plateau with a time constant tau 2 = 0.65 +/- 0.18 ms (n = 101) at 21 degrees C. These current signals are suppressed by Ni2+ and dichlorobenzamil. No stationary current, but a transient inward current that rises with tau 1 < 50 microseconds and decays with tau 2 = 0.28 +/- 0.06 ms (n = 53, T = 21 degrees C) is observed if the Ca2+ concentration jump is performed under conditions that promote Ca(2+)-Ca2+ exchange (i.e., no extracellular Na+, 5 mM extracellular Ca2+). The transient and stationary inward current is not observed in the absence of extracellular Ca2+ and Na+. The application of alpha-chymotrypsin reveals the influence of the cytoplasmic regulatory Ca2+ binding site on Ca(2+)-Ca2+ and forward Na(+)-Ca2+ exchange and shows that this site regulates both the transient and stationary current. The temperature dependence of the stationary current exhibits an activation energy of 70 kj/mol for temperatures between 21 degrees C and 38 degrees C, and 138 kj/mol between 10 degrees C and 21 degrees C. For the decay time constant an activation energy of 70 kj/mol is observed in the Na(+)-Ca2+ and the Ca(2+)-Ca2+ exchange mode between 13 degrees C and 35 degrees C. The data indicate that partial reactions of the Na(+)-Ca2+ exchanger associated with Ca2+ binding and translocation are very fast at 35 degrees C, with relaxation time constants of about 6700 s-1 in the forward Na(+)-Ca2+ exchange and about 12,500 s-1 in the Ca(2+)-Ca2+ exchange mode and that net negative charge is moved during Ca2+ translocation. According to model calculations, the turnover number, however, has to be at least 2-4 times smaller than the decay rate of the transient current, and Na+ inward translocation appears to be slower than Ca2+ outward movement.     

Occurrence of Na(+)-Ca2+ exchange in the ciliate Euplotes crassus and its role in Ca2+ homeostasis.

Ciliates possess diverse Ca2+ homeostasis systems, but little is known about the occurrence of a Na(+)-Ca2+ exchanger. We studied Na(+)-Ca2+ exchange in the ciliate Euplotes crassus by digital imaging. Cells were loaded with fura-2/AM or SBF1/AM for fluorescence measurements of cytosolic Ca2+ and Na+ respectively. Ouabain pre-treatment and Na+o substitution in fura-2/AM-loaded cells elicited a bepridil-sensitive [Ca2+]i rise followed by partial recovery, indicating the occurrence of Na(+)-Ca2+ exchanger working in reverse mode. In experiments on prolonged effects, ouabain, Na+o substitution, and bepridil all caused Ca2+o-dependent [Ca2+]i increase, showing a role for Na(+)-Ca2+ exchange in Ca2+ homeostasis. In addition, by comparing the effect of orthovanadate (affecting not only Ca2+ ATPase, but also Na(+)-K+ ATPase and, hence, Na(+)-Ca2+ exchange) to that of bepridil on [Ca2+]i, it was shown that Na(+)-Ca2+ exchange contributes to Ca2+ homeostasis. In electrophysiological experiments, no membrane potential variation was observed after bepridil treatment suggesting compensatory mechanisms for ion effects on cell membrane voltage, which also agrees with membrane potential stability after ouabain treatment. In conclusion, data indicate the presence of a Na(+)-Ca2+ exchanger in the plasma membrane of E. crassus, which is essential for Ca2+ homeostasis, but could also promote Ca2+ entry under specific conditions.     

Voltage-dependent modulation of ion binding and translocation in the cardiac Na(+)-Ca2+ exchange system

The transport of Na+ and Ca2+ ions in the cardiac Na(+)-Ca2+ exchanger can be described as separate events (Khananshvili, D. (1990) Biochemistry 29, 2437-2442). Thus, the Na(+)-Na+ and Ca(2+)-Ca2+ exchange reactions reflect reversible partial reactions of the transport cycle. The effect of diffusion potentials (K(+)-valinomycin) on different modes of the Na(+)-Ca2+ exchanger (Na(+)-Ca2+, Ca(2+)-Ca2+, and Na(+)-Na+ exchanges) were tested in reconstituted proteoliposomes, obtained from the Triton X-100 extracts of the cardiac sarcolemmal membranes. The initial rates of the Nai-dependent 45Ca-uptake (t = 1 s) were measured in EGTA-entrapped proteoliposomes at different voltages. At the fixed values of voltage [45 Ca]o was varied from 4 to 122 microM, and [Na]i was saturating (150 mM). Upon varying delta psi from -94 to +91 mV, the Vmax values were increased from 9.5 +/- 0.5 to 26.5 +/- 1.5 nmol.mg-1.s-1 and the Km from 17.8 +/- 2.5 to 39.1 +/- 5.2 microM, while the Vmax/Km values ranged from only 0.53 +/- 0.08 to 0.73 +/- 0.17 nmol.mg-1.s-1.microM-1. The equilibrium Ca(2+)-Ca2+ exchange was voltage sensitive at very low [Ca]o = [Ca]i = 2 microM, while at saturating [Ca]o = [Ca]i = 200 microM the Ca(2+)-Ca2+ exchange became voltage-insensitive. The rates of the equilibrium Na(+)-Na+ exchange appears to be voltage insensitive at saturating [Na]o = [Na]i = 160 mM. Under the saturating ionic conditions, the rates of the Na(+)-Na+ exchange were at least 2-3-fold slower than the Ca(2+)-Ca2+ exchange. The following conclusions can be drawn. (a) The near constancy of the Vmax/Km for Na(+)-Ca2+ exchange at different voltages is compatible with the ping-pong model proposed previously. (b) The effects of voltage on Vmax of Na(+)-Ca2+ exchange are consistent with the existence of a single charge carrying transport step. (c) It is not yet possible to clearly assign this step to the Na+ or Ca2+ transport half of the cycle although it is more likely that 3Na(+)-transport is a charge carrying step. Thus, the unloaded ion-binding domain contains either -2 or -3 charges (presumably carboxyl groups). (d) The binding of Na+ and Ca2+ appears to be weakly voltage-sensitive. The Ca(2+)-binding site may form a small ion-well (less than 2-3 A).     

Na+-Ca2+ exchange in plasma membranes of crayfish striated muscle

Na+-Ca2+ exchange rates and some physico-chemical properties of the exchanger were studied in crayfish striated muscle membranes enriched in plasma membranes prepared by differential centrifugation of muscle microsomal fraction on discontinuous sucrose density gradient. The lightest subfraction with the highest Na+, K+-ATPase and Mg2+-ATPase activities also showed the highest Na+-Ca2+ exchange rates. A number of physico-chemical characteristics of the Na+-Ca2+ exchanger found in the present experiments were similar to those reported for excitable membranes of mammals, except for the temperature optimum (20 degrees C for the crayfish).     

Differing significance of Na(+)-Ca2+ exchange in the regulation of cytosolic Ca2+ in rat exocrine gland acini and cardiac myocytes.

In order to compare the importance of Na(+)-Ca2+ exchange in the regulation of cytosolic Ca2+ concentration (Ca2+i), acini obtained from rat pancreas and submandibular glands as well as cardiac myocytes were loaded with Na+ by inhibition of Na(+)-K+ ATPase activity then loaded with fura-2. In the exocrine tissues, incubation in K(+)-free buffer or with ouabain had no substantial effect on resting Ca2+i or on the changes in Ca2+i following exposure to carbachol as compared with acini incubated under control conditions. In contrast, rat cardiac myocytes, treated identically, showed marked changes in Ca2+i under resting and stimulated conditions as compared with controls. We conclude that the Na(+)-Ca2+ exchange systems of rat pancreatic and submandibular gland acini contribute little to the overall regulation of Ca2+i at rest during cholinergic stimulation.     

Anomalous regulation of the Drosophila Na(+)-Ca2+ exchanger by Ca2+

The Na(+)-Ca2+ exchanger from Drosophila was expressed in Xenopus and characterized electrophysiologically using the giant excised patch technique. This protein, termed Calx, shares 49% amino acid identity to the canine cardiac Na(+)-Ca2+ exchanger, NCX1. Calx exhibits properties similar to previously characterized Na(+)-Ca2+ exchangers including intracellular Na+ affinities, current-voltage relationships, and sensitivity to the peptide inhibitor, XIP. However, the Drosophila Na(+)-Ca2+ exchanger shows a completely opposite response to cytoplasmic Ca2+. Previously cloned Na(+)-Ca2+ exchangers (NCX1 and NCX2) are stimulated by cytoplasmic Ca2+ in the micromolar range (0.1- 10 microM). This stimulation of exchange current is mediated by occupancy of a regulatory Ca2+ binding site separate from the Ca2+ transport site. In contrast, Calx is inhibited by cytoplasmic Ca2+ over this same concentration range. The inhibition of exchange current is evident for both forward and reverse modes of transport. The characteristics of the inhibition are consistent with the binding of Ca2+ at a regulatory site distinct from the transport site. These data provide a rational basis for subsequent structure-function studies targeting the intracellular Ca2+ regulatory mechanism.     

Effect of temperature on sodium-calcium exchange in sarcolemma from mammalian and amphibian hearts

We have investigated temperature dependence of Ca2+ uptake by the cardiac sarcolemmal Na(+)-Ca2+ exchanger from dog, rabbit and bullfrog. In native rabbit sarcolemmal vesicles, Ca2+ affinity of the Na(+)-Ca2+ exchanger is unchanged from 7 to 37 degrees C; however, the initial velocity of Ca2+ uptake declines much more steeply below 22 degrees C than above 22 degrees C. In native dog sarcolemma, the temperature dependence of Na(+)-Ca2+ exchange velocity is similar to that of native rabbit. However, in frog heart the velocity of Na(+)-Ca2+ exchange declines much more slowly with decreasing temperature at both temperature ranges. Reconstitution of the Na(+)-Ca2+ exchanger into artificial lipid vesicles consisting of either asolectin or phosphatidylserine, phosphatidylcholine, and cholesterol has little effect on temperature dependence of Na(+)-Ca2+ exchange velocity in any of the three species. We conclude that the lesser temperature sensitivity of the cardiac sarcolemmal Na(+)-Ca2+ exchanger of a poikilothermic species is at least partly an intrinsic property of the transport protein.     

Identification of a peptide inhibitor of the cardiac sarcolemmal Na(+)-Ca2+ exchanger

The deduced amino acid sequence of the cardiac sarcolemmal Na(+)-Ca2+ exchanger has a region which could represent a calmodulin binding site. As calmodulin binding regions of proteins often have an autoinhibitory role, a synthetic peptide with this sequence was tested for functional effects on Na(+)-Ca2+ exchange activity. The peptide inhibits the Na(+)-dependent Ca2+ uptake (KI approximately 1.5 microM) and the Nao(+)-dependent Ca2+ efflux of sarcolemmal vesicles in a noncompetitive manner with respect to both Na+ and Ca2+. The peptide is also a potent inhibitor (KI approximately 0.1 microM) of the Na(+)-Ca2+ exchange current of excised sarcolemmal patches. The binding site for the peptide on the exchanger is on the cytoplasmic surface of the membrane. The exchanger inhibitory peptide binds calmodulin with a moderately high affinity. From the characteristics of the inhibition of the exchange of sarcolemmal vesicles, we deduce that only inside-out sarcolemmal vesicles participate in the usual Na(+)-Ca2+ exchange assay. This contrasts with the common assumption that both inside-out and right-side-out vesicles exhibit exchange activity.     

The modulation of rat brain Na(+)-Ca2+ exchange by K+

The involvement of potassium ions in the Na(+)-Ca2+ exchange process was studied in rat brain synaptic plasma membrane (SPM) vesicles. Addition of equimolar [K+] to the intravesicular and the extravesicular medium led to a stimulation of the Na+ gradient-dependent Ca2+ influx; this stimulation was noticeable already at 0.5 mM and reached its maximum at 2 mM K+. The magnitude of the K+ stimulation was between 1.3-2.5-fold in different SPM preparations. K+ ions also stimulated the Na(+)-dependent Ca2+ efflux. K+ stimulation of Na(+)-Ca2+ exchange is of considerable specificity, since it is not mimicked by either Li+ or H+. The following lines of evidence suggest that K+ modulation of Na(+)-Ca2+ exchange involves the catalytic moiety of the transporter itself and not an unrelated K+ channel which modulates the membrane potential. 1) K+ stimulation of the transport process was conserved following reconstitution of the transporter into phospholipid-rich liposomes, an experimental condition which presumably separates the native membrane proteins among different vesicular structures. 2) K+ stimulation of Na+ gradient-dependent Ca2+ influx persists also when the build up of negative inside membrane potential is prevented by addition of carbonyl cyanide p-trifluoromethoxy phenylhydrazone which renders the membrane highly permeable to protons both in the native and the reconstituted preparation. 3) K+ stimulation of Na+ gradient-dependent Ca2+ influx is obtained also when tetraethylammonium chloride, 2,3-diaminopyridine and Cs+ are added to the Ca2+ uptake medium. Reconstituted SPM vesicles take up 86Rb+ in response to activation of Na+ gradient-dependent Ca2+ influx. The ratio of Ca2+ taken up by SPM vesicles in a Na+ gradient-dependent manner to the corresponding amounts of Rb+ taken up varies between 8-5 in different SPM preparations. If the stoichiometry of the process is 1 Rb+/1 Ca2+, then Rb+ cotransport is mediated by 10-20% of the transporters present in the preparation.     

Expression of the cardiac Na(+)-Ca2+ exchanger in insect cells using a baculovirus vector.

We constructed a recombinant baculovirus containing cardiac Na(+)-Ca2+ exchanger cDNA under control of the polyhedrin promoter. When either Sf9 or Sf21 insect cells are infected with the recombinant baculovirus, both Na(+)-Ca2+ exchanger protein and Na(+)-Ca2+ exchange activity are expressed at high level. The exchanger protein can be detected either by immunoblot or by sodium dodecyl sulfate-polyacrylamide gel electrophoresis of whole cell lysate. At maximal expression, the exchanger protein comprises about 3-5% of total cell protein. The Na(+)-Ca2+ exchanger can be purified by alkaline extraction of infected cells followed by elution from a Bio-Rad Prep Cell. The expressed exchanger, in contrast to the native sarcolemmal exchanger, is not glycosylated. Sf9 cells expressing the exchanger are intensely stained by anti-exchanger antibodies as observed by immunofluorescence. The expressed exchanger is predominantly in the cell plasma membrane since it is susceptible to extracellular trypsin. In 45Ca2+ flux experiments, the expressed Na(+)-Ca2+ exchange activity is about 4-fold higher than that in cultured neonatal rat heart cells. The expressed exchanger was also analyzed electrophysiologically using whole cell patch clamp techniques. The characteristics of inward exchange currents in infected Sf21 cells are very similar to those of ventricular myocytes, although of a larger magnitude.     

Regulation of the cardiac Na(+)-Ca2+ exchanger by Ca2+. Mutational analysis of the Ca(2+)-binding domain

The sarcolemmal Na(+)-Ca2+ exchanger is regulated by intracellular Ca2+ at a high affinity Ca2+ binding site separate from the Ca2+ transport site. Previous data have suggested that the Ca2+ regulatory site is located on the large intracellular loop of the Na(+)-Ca2+ exchange protein, and we have identified a high-affinity 45Ca2+ binding domain on this loop (Levitsky, D. O., D. A. Nicoll, and K. D. Philipson. 1994. Journal of Biological Chemistry. 269:22847-22852). We now use electrophysiological and mutational analyses to further define the Ca2+ regulatory site. Wild-type and mutant exchangers were expressed in Xenopus oocytes, and the exchange current was measured using the inside- out giant membrane patch technique. Ca2+ regulation was measured as the stimulation of reverse Na(+)-Ca2+ exchange (intracellular Na+ exchanging for extracellular Ca2+) by intracellular Ca2+. Single-site mutations within two acidic clusters of the Ca2+ binding domain lowered the apparent Ca2+ affinity at the regulatory site from 0.4 to 1.1-1.8 microM. Mutations had parallel effects on the affinity of the exchanger loop for 45Ca2+ binding (Levitsky et al., 1994) and for functional Ca2+ regulation. We conclude that we have identified the functionally important Ca2+ binding domain. All mutant exchangers with decreased apparent affinities at the regulatory Ca2+ binding site also have a complex pattern of altered kinetic properties. The outward current of the wild-type Na(+)-Ca2+ exchanger declines with a half time (th) of 10.8 +/- 3.2 s upon Ca2+ removal, whereas the exchange currents of several mutants decline with th values of 0.7-4.3 s. Likewise, Ca2+ regulation mutants respond more rapidly to Ca2+ application. Study of Ca2+ regulation has previously been possible only with the exchanger operating in the reverse mode as the regulatory Ca2+ and the transported Ca2+ are then on opposite sides of the membrane. The use of exchange mutants with low affinity for Ca2+ at regulatory sites also allows demonstration of secondary Ca2+ regulation with the exchanger in the forward or Ca2+ efflux mode. In addition, we find that the affinity of wild-type and mutant Na(+)-Ca2+ exchangers for intracellular Na+ decreases at low regulatory Ca2+. This suggests that Ca2+ regulation modifies transport properties and does not only control the fraction of exchangers in an active state.     

The effect of opiate agonists and antagonists on Na(+)-Ca2+ exchange in cardiac sarcolemma vesicles.

Opiate agonists and antagonists inhibit Na(+)-Ca2+ exchange in the isolated cardiac sarcolemma vesicles. Non-opioid stereoisomers (dextrorphan, Mr 1542MS, WIN 44,441-3) display effects similar to their opioid isomers (levorphanol, Mr 1543MS, WIN 44,441-2) suggesting that inhibition is not mediated by opiate receptors. Naloxone (permeable) and methylnaloxone (impermeable) inhibit the Na(+)-Ca2+ exchange similarly, suggesting an extravesicular location of inhibitory site. The inhibitory potency of naloxone is pH-independent in the range of 7.4-9.1, suggesting that the charge-carrying properties of drug-protein interactions are not altered under the tested conditions. Opiates display similar dose-response relationships for Na(+)-Ca2+ exchange and its partial reaction, the Ca(2+)-Ca2+ exchange. The opiate-induced inhibition is complete and noncompetitive in regard to extravesicular calcium. These data suggest that opiates do not bind to the Ca(2+)-binding domain (A-site), but they may interest either with the Na(+)-binding site (B-site) or with a putative opiate-binding site, presumably located outside of the ion-binding vicinity. Further studies on structure-activity relationship might lead to the discovery of potent and more specific inhibitors of cardiac Na(+)-Ca2+ exchanger. A possible relevance of these findings to some non-opioid pharmacological effects of naloxone on the cardiac muscle is suggested.     

Dependence of Na+-Ca2+ exchange and Ca2+-Ca2+ exchange on monovalent cations

Two mechanisms of passive Ca2+ transport, Na+-Ca2+ exchange and Ca2+-Ca2+ exchange, were studied using highly-purified dog heart sarcolemmal vesicles. About 80% of the Ca2+ accumulated by Na+-Ca2+ exchange or Ca2+-Ca2+ exchange could be released as free Ca2+, while up to 20% was probably bound. Na+-Ca2+ exchange was simultaneous, coupled countertransport of Na+ and Ca2+. The movement of anions during Na+-Ca2+ exchange did not limit the initial rate of Na+-Ca2+ exchange. Na+-Ca2+ exchange was electrogenic, with a reversal potential of about -105 mV. The apparent flux ratio of Na+-Ca2+ exchange was 4 Na+:1 Ca2+. Coupled cation countertransport by the Na+-Ca2+ exchange mechanism required a monovalent cation gradient with the following sequence of ion activation: Na+ much greater than Li+ greater than Cs+ greater than K+ greater than Rb+. In contrast to Na+-Ca2+ exchange, Ca2+-Ca2+ exchange did not require a monovalent cation gradient, but required the presence of Ca2+ plus a monovalent cation on both sides of the vesicle membrane. The sequence of ion activation of Ca2+-Ca2+ exchange was: K+ much greater than Rb+ greater than Na+ greater than Li+ greater than Cs+. Na+ inhibited Ca2+-Ca2+ exchange when Ca2+-Ca2+ exchange was supported by another monovalent cation. Both Na+-Ca2+ exchange and Ca2+-Ca2+ exchange were inhibited, but with different sensitivities, by external MgCl2, quinidine, or verapamil.     

Light-dependent Na(+)-Ca2+ exchange in retinal rod discs

Experiments are described demonstrating that Na(+)-Ca2+ exchange of retinal rod disc membrane is highly sensitive to light. The Na(+)-Ca2+ exchanger was shown to possess two types of binding sites with different affinities for calcium. The low affinity binding sites (KCaD = 5.8 mumol/l) are light-insensitive. After bleaching, KD of the high affinity Ca2(+)-binding sites an Ki for Na+ changed from 0.2 to 0.3 mumol/l and from 3.2 to 0.7 nmol/l, respectively. Light inhibits the steady-state Ca2+ uptake by a factor of 1.5. Photocontrol of the Na(+)-Ca2+ exchanger affinity is observed at the physiological level of rhodopsin bleaching.     

Roles of Na(+)-Ca2+ exchange and of mitochondria in the regulation of presynaptic Ca2+ and spontaneous glutamate release

The release of neurotransmitter from presynaptic terminals depends on an increase in the intracellular Ca2+ concentration ([Ca2+]i). In addition to the opening of presynaptic Ca2+ channels during excitation, other Ca2+ transport systems may be involved in changes in [Ca2+]i. We have studied the regulation of [Ca2+]i in nerve terminals of hippocampal cells in culture by the Na(+)-Ca2+ exchanger and by mitochondria. In addition, we have measured changes in the frequency of spontaneous excitatory postsynaptic currents (sEPSC) before and after the inhibition of the exchanger and of mitochondrial metabolism. We found rather heterogeneous [Ca2+]i responses of individual presynaptic terminals after inhibition of Na(+)-Ca2+ exchange. The increase in [Ca2+]i became more uniform and much larger after additional treatment of the cells with mitochondrial inhibitors. Correspondingly, sEPSC frequencies changed very little when only Na(+)-Ca2+ exchange was inhibited, but increased dramatically after additional inhibition of mitochondria. Our results provide evidence for prominent roles of Na(+)-Ca2+ exchange and mitochondria in presynaptic Ca2+ regulation and spontaneous glutamate release.     

Na(+)-Ca2+ exchange activity in synaptic plasma membranes derived from the electric organ of Torpedo ocellata.

Synaptic plasma membranes obtained by hypo-osmotic treatment of purified Torpedo ocellata synaptosomes, contain an electrogenic Na(+)-Ca2+ exchange system. The dependence of the initial reaction rate on [Ca2+] reveals a single binding site for Ca2+ with an average apparent Km of 13.66 (S.D. = 12.07) microM [Ca2+] and maximal reaction velocity of Vmax = 11.33 (S.D. = 5.93) nmol/mg protein per s. The dependence of the initial rate of the Na+ gradient dependent Ca2+ influx on the internal [Na+] exhibits a sigmoidal curve which reaches half-maximal reaction rate at 170.8 (S.D. = 19.9) mM [Na+]. Addition of ATP gamma S does not change the K0.5 to Na+. The average Hill coefficient is 3.09 (S.D. = 0.86) indicating that 3-4 Na+ ions are exchanged for each Ca2+. Na+ gradient dependent Ca2+ uptake in Torpedo SPMs takes place also in the absence of K+ suggesting that K+ co-transport is not obligatory. The temperature dependence of the initial and steady-state rates of Na+ gradient dependent Ca2+ influx reveal that maximal reaction velocities of the Torpedo exchanger are attained between 15 and 20 degrees C. The energy of activation between 0 and 20 degrees C is 20,826 cal/mol. In comparison, rat brain synaptic plasma membrane Na(+)-Ca2+ exchanger reaches maximal reaction rates between 30 and 40 degrees C. Reconstitution of Torpedo or rat brain Na(+)-Ca2+ exchangers into a membrane composed of either Torpedo or brain phospholipids, does not alter the temperature dependence of the native Torpedo or rat brain Na(+)-Ca2+ exchangers; inspite of considerable differences in the composition of the fatty acyl chains that are esterified to brain and Torpedo phospholipid head groups and differences in membrane fluidity that were detected. An ATP-dependent Ca2+ pump, which is insensitive to FCCP, is also present in the same synaptic membrane.     

Na+-Ca2+ exchange in squid optic nerve membrane vesicles is activated by internal calcium

The role of intracellular Ca2+ as essential activator of the Na+-Ca2+ exchange carrier was explored in membrane vesicles containing 67% right-side-out and 10% inside-out vesicles, isolated from squid optic nerves. Vesicles containing 100 microM free calcium exhibited a 2-fold increase in the initial rate of Na+i-dependent Ca2+ uptake as compared with vesicles where intravesicular calcium was chelated by 2 mM EGTA or 10 mM HEDTA. The activatory effect exerted by intravesicular Ca2+ on the reverse mode of Na+-Ca2+ exchange (i.e. Na+i-Ca2+o exchange) is saturated at about 100 microM Ca2+i and displays an apparent K 1/2 of 12 microM. Intravesicular Ca2+ produced activation of Na+i-Ca2+i exchange activity rather than an increase in Ca2+ uptake due to Ca2+-Ca2+ exchange. The presence of Ca2+i was essential for the Na+i-dependent Na+ influx, a partial reaction of the Na+-Ca2+ exchanger. In fact, the Na+ influx levels in vesicles loaded with 2 mM EGTA were close to those expected from diffusional leak while in vesicles containing Ca2+i an additional Na+-Na+ exchange was measured. The results suggest that in nerve membrane vesicles Ca2+ at the inner aspect of the membrane acts as an activator of the Na+-Ca2+ exchange system.     

Sodium-calcium exchange: derivation of a state diagram and rate constants from experimental data.

A mechanism is developed for Na(+)-Ca2+ exchange using a new approach made possible by the availability of computer software that allows the systematic search of a large parameter space for optimum sets of parameters to fit multiple sets of experimental data. The approach was to make the experimental data dictate the form of the mechanism: the qualitative features of the data dictating the number and nature of the states of the exchanger and their interrelationship, and the quantitative aspects of the data dictating the values of the rate constants that govern the amount of each state relative to the total amount of exchanger. A single set of experimental data served this initial purpose, namely, observations of equilibrium Ca(2+)-Ca2+ exchange in cardiac sarcolemmal vesicles (Slaughter et al., 1983, J. biol. Chem. 258, 3183-3190). From this data a minimum mechanism was induced having 56 states (SYM56), which gave satisfactory quantitative fits to the experimental data. With this set of parameters additional experimental data were fitted, from the same preparation, the single cardiac cell and the squid giant axon, with some changes in parameters, but none dramatic. In spite of the symmetric nature of the mechanism, i.e. binding constants for Na+ and Ca2+ do not depend on the orientation of the binding sites, the mechanism exhibits marked asymmetric behavior similar to that observed experimentally. Finally, in accounting for Ca(2+)-Ca2+ exchange in the absence of monovalent cations, Ca2+ influx becomes dependent on intracellular Ca(2+)--an unexpected outcome--exactly in keeping with the "essential activator" role of intracellular Ca2+ observed by DiPolo & Beaugé (1987, J. gen. Physiol. 90, 505-525). Observations of Na(+)-Ca2+ exchange in the retinal rod outer segment are well fitted with a simplified version of SYM56 comprising 25 states (namely, SYM25), supporting the notion that the exchanger in the retinal rod outer segment differs from that in cardiac sarcolemma and squid axon. Maximum turnover rate of 840 sec-1 for SYM56 and 20 sec-1 for SYM25 are comparable to those reported for the exchanger in cardiac muscle and retinal rod outer segment, respectively.