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.     

The effect of alteration of extracellular Na+ or Ca2+ and inhibition of Ca2+ entry, Na(+)-H+ exchange, and Na(+)-Ca2+ exchange by diltiazem, amiloride, and dichlorobenzamil on the response of cardiac cell aggregates to epidermal growth factor

The purpose of this study was to examine the effect of epidermal growth factor (EGF) on cardiac function and to explore ionic mechanisms as potential explanations for EGF-induced changes in cardiac contractile frequency. Cardiac cell aggregates were prepared from 7-day-old chick embryo hearts and were maintained in culture. EGF over a concentration range of 5 to 20 ng/ml produced a dose-dependent increase in cardiac contractile frequency. Inhibition of Na(+)-H+ exchange by amiloride antagonized the action of EGF. Inhibition of Na(+)-Ca2+ exchange by dichlorobenzamil prevented the effects of EGF. Inhibition of voltage-dependent calcium influx by diltiazem also antagonized the effect of EGF. The positive chronotropic action of EGF was significantly enhanced when the concentration of Na+ or Ca2+ was increased in the medium. These data indicate that EGF has a definite dose-dependent effect on the cardiac contractile frequency that is operative through ionic transport mechanisms that include increased calcium entry through voltage-dependent calcium channels and stimulation of Na(+)-H+ and Na(+)-Ca2+ exchange. The similarity in the effects of inhibition of these three ionic mechanisms suggests they are interrelated so that interference at any step in the process inhibits the action of EGF on cardiac myocytes.     

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.     

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).     

Purification, subunit structure and pharmacological effects on cardiac and smooth muscle cells of a polypeptide toxin isolated from the marine snail Conus tessulatus

The most active component in smooth muscle contraction, isolated from the whole venom of the marine snail Conus tessulatus, has a molecular mass of about 55 kDa. The toxin protein, tessulatus toxin, appeared to be constituted by two distinct polypeptide bands of 26 kDa and 29 kDa. The pure toxin caused a marked contraction of both guinea-pig ileum and rabbit aorta at nanomolar concentrations. Tessulatus-toxin-induced contraction was indirectly prevented by classical inhibitors of the voltage-dependent Ca2+ channel. Tessulatus toxin caused a large increase in the initial rate of 45Ca2+ uptake by cardiac cells. This uptake was insensitive to Ca2+ channel blockers at concentrations 100-1000 fold higher than those known to block voltage-dependent Ca2+ channels in these cells. Voltage clamp experiments have confirmed that tessulatus toxin was not directly active on the Ca2+ current. Tessulatus-toxin-stimulated 45Ca2+ influx was inhibited by dichlorobenzamil and suppressed when Na+ was substituted by Li+, indicating that the toxin acted via activation of the Na+/Ca2+ exchange system in cardiac cells. Activation by tessulatus toxin of the Na+/Ca2+ exchange system occurred via a toxin-stimulated Na+ entry into cardiac cells and was observed in the same range of toxin concentration which produced 45Ca2+ entry. The Na+ entry system that was activated by tessulatus toxin was insensitive to classic inhibitors of known Na+ entry systems in cardiac cells. Possible mechanisms by which tessulatus toxin induced Na+ entry into cardiac cells and contractions in smooth muscles are discussed. Tessulatus toxin is cytotoxic when used at high concentrations.     

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.     

Inhibition of Na+-Ca2+ exchange in heart sarcolemmal vesicles by phosphatidylethanolamine N-methylation

The effect of phosphatidylethanolamine N-methylation on Na+-Ca2+ exchange was studied in sarcolemmal vesicles isolated from rat heart. Phosphatidylethanolamine N-methylation following incubation of membranes with S-adenosyl-L-methionine, a methyl donor for the enzymatic N-methylation, inhibited Nai+-dependent Ca2+ uptake by about 50%. The N-methylation reaction did not alter the passive permeability of the sarcolemmal vesicles to Na+ and Ca2+ and did not modify the electrogenic characteristics of the exchanger. The depressant effect of phosphatidylethanolamine N-methylation on Nai+-dependent Ca2+ uptake was prevented by S-adenosyl-L-homocysteine, an inhibitor of the N-methylation. Pretreatment of sarcolemma with methyl acetimidate hydrochloride, an amino-group-blocking agent, also prevented methylation-induced inhibition of Ca2+ uptake. In the presence of exogenous phospholipid substrate, the phospholipid N-methylation process in methyl-acetimidate-treated sarcolemmal vesicles was restored and the inhibitory effect on Ca2+ uptake was evident. These results suggest that phosphatidylethanolamine N-methylation influences the heart sarcolemmal Na+-Ca2+ exchange system.     

Progress and problems in understanding the involvement of calcium in heart function

In this article we have briefly reviewed the role of Ca2+ in the excitation contraction coupling in the myocardium and have indicated that cardiac contraction and relaxation are initiated upon raising and lowering the intracellular concentration of free Ca2+, respectively. Different mechanisms for the entry of Ca2+ through sarcolemma as well as release of Ca2+ from sarcoplasmic reticulum and possibly mitochondria have been outlined for initiating cardiac contraction. Relaxation of the cardiac muscle appears to be intimately dependent upon efflux of Ca2+ through sarcolemma as well as sequestration of Ca2+ by the intracellular storage sites, particularly sarcoplasmic reticulum and possibly mitochondria. The actions of some pharmacological and pathophysiological interventions have been explained on the basis of changes in subcellular Ca2+ movements in myocardium. Quinidine, which produced an initial positive inotropic action on rat heart was also found to increase sarcolemmal Ca2+-ATPase activity without any changes in the Na+-K+ ATPase. Other antiarrhythmic agents, procainamide and lidocaine, also increased sarcolemmal Ca2+-ATPase activity without affecting the Na+-K+ ATPase. On the other hand, both Ca2+-ATPase and Na+-K+ ATPase activities were increased in heart sarcolemma obtained from cardiomyopathic hamsters. In this model the increased Ca2+-ATPase activity may promote the occurrence of intracellular Ca2+ overload in the cardiac cell whereas the increased Na+-K+ ATPase activity may increase Ca2+ efflux through Na+-Ca2+ exchange systems as an adaptive mechanism. It has been suggested that some caution should be exercised while interpreting the data from in vitro experiments in terms of functional changes in the myocardium. Furthermore, it has been proposed that the pathophysiology and pharmacology of Ca2+ movements at different membrane sites be understood fully in normal and diseased myocardium in order to improve the therapy of heart disease.     

Symmetry properties of the Na+-Ca2+ exchange mechanism in cardiac sarcolemmal vesicles

The Na+-Ca2+ exchange mechanism in cardiac sarcolemmal vesicles can catalyze the exchange of Ca2+ on either side of the sarcolemmal membrane for Na+ on the opposing side. Little is known regarding the relative affinities of Na+ and Ca2+ for exchanger binding sites on the intra- and extracellular membrane surfaces. We have previously reported (Philipson, K.D. and Nishimoto, A.Y. (1982) J. Biol. Chem. 257, 5111-5117) a method for measuring the Na+-Ca2+ exchange of only the inside-out vesicles in a mixed population of sarcolemmal vesicles (predominantly right-side-out). We concluded that the apparent Km(Ca2+) for Na+i-dependent Ca2+ uptake was similar for inside-out and right-side-out vesicles. In the present study, we examine in detail Na+o-dependent Ca2+ efflux from both the inside-out and the total population of vesicles. To load vesicles with Ca2+ prior to measurement of Ca2+ efflux, four methods are used: 1, Na+-Ca2+ exchange; 2, passive Ca2+ diffusion; 3, ATP-dependent Ca2+ uptake; 4, exchange of Ca2+ for Na+ which has been actively transported into vesicles by the Na+ pump. The first two methods load all sarcolemmal vesicles with Ca2+, while the latter two methods selectively load inside-out vesicles with Ca2+. We are able to conclude that the dependence of Ca2+ efflux on the external Na+ concentration is similar in inside-out and right-side-out vesicles. Thus the apparent Km(Na+) values (approximately equal to 30 mM) of the Na+-Ca2+ exchanger are similar on the two surfaces of the sarcolemmal membrane. In other experiments, external Na+ inhibited the Na+i-dependent Ca2+ uptake of the total population of vesicles much more potently than that of the inside-out vesicles. Apparently Na+ can compete for the Ca2+ binding site more effectively on the external surface of right-side-out than on the external surface of inside-out vesicles. Thus, although affinities for Na+ or Ca2+ (in the absence of the other ion) appear symmetrical, the interactions between Na+ and Ca2+ at the two sides of the exchanger are not the same. The Na+-Ca2+ exchanger is not a completely symmetrical transport protein.     

How does regulatory Ca2+ regulate the Na+-Ca2+ exchanger?

Spatial and temporal regulation of intracellular Ca2+ concentrations is a fundamental requirement for life. The mammalian cardiac Na+-Ca2+ exchanger serves as the main mechanism for Ca2+ efflux after heart contraction. Exchange activity is highly regulated by intracellular Ca2+, which binds two regulatory domains (CBD1 and CBD2) and triggers the full activity of the exchanger. We solved the X-ray crystallographic structure of CBD2 in the presence and absence of Ca2+. Together with mutational analysis of the Ca2+ binding sites, this study reveals the crucial role of one of the two bound Ca2+ ions and helps propose hypotheses on the mechanism of regulation of the exchanger.     

Excitation-contraction coupling in myocardium: implications of calcium release and Na+-Ca2+ exchange

In this paper, we present evidence in support of the hypothesis that electrogenic Na+-Ca2+ exchange is responsible for three phenomena in rat cardiac muscle: the slow repolarization phase of the action potential, the time course of the mechanical recovery process, and the development of triggered arrhythmias. It was shown that the duration of the slow phase of repolarization of the action potential varies in proportion to the Na+ concentration gradient and inversely with the Ca2+ concentration gradient over the cell membrane. This suggested that Na+-Ca2+ exchange can generate a current of sufficient magnitude to maintain the membrane depolarized at a level of -60 mV. The mechanical restitution process of rat cardiac trabeculae was shown to exhibit three phase. The first phase, alpha, probably reflects rapid transport of calcium in the sarcoplasmic reticulum from the uptake sites to the release sites. After the initial increase of force during alpha, force rises further during phase beta and then declines during phase gamma. During all phases, force increases with the extracellular calcium concentration. beta is accelerated by preceding extrasystoles, while an increase of the heart rate causes force to increase at approximately the same rate but to a higher level during phase beta. These observations are compatible with a model in which the sarcoplasmic reticulum sequesters calcium from the cytosol, while the membrane of the sarcoplasmic reticulum is assumed to exhibit also a small leak of calcium into the cytosol.(ABSTRACT TRUNCATED AT 250 WORDS)     

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 cycling of calcium, sodium, and protons across the inner membrane of cardiac mitochondria.

A method is described that permits simultaneous determination of the net charge transfer associated with Ca2+ transport by the ruthenium-red-sensitive carrier and the ionized internal [Ca2+] in heart mitochondria. The data indicate that this carrier catalyses a charge-uncompensated flux of Ca2+. Full charge compensation for Ca2+ influx is provided by the respiration-dependent efflux of H+. The net efflux of Ca2+ induced by Na+ is analysed in terms of two other carriers, a Na+-Ca2+ antiporter and a Na+-H+ antiporter. Evidence is presented that these two carriers are separate and that the Na+-H+ exchange is the more rapid. The fluxes of Ca2+, Na+ and H+ during the Na+-induced efflux of Ca2+ support a series of events in which the Na+-H+ exchange enables unidirectional Ca2+ fluxes via the uniport and antiport systems to be integrated into a cycle.     

Stimulation of Na+-Ca2+ exchange in cardiac sarcolemmal vesicles by phospholipase D

Treatment of canine cardiac sarcolemmal vesicles with phospholipase D resulted in a large stimulation (up to 400%) of Na+-Ca2+ exchange activity. The phospholipase D treatment decreased the apparent Km (Ca2+) for the initial rate of Nai+-dependent Ca2+ uptake from 18.2 +/- 2.6 to 6.3 +/- 0.3 microM. The Vmax increased from 18.0 +/- 3.6 to 31.5 +/- 3.6 nmol of Ca2+/mg of protein/s. The effect was specific for Na+-Ca2+ exchange; other sarcolemmal transport enzymes ((Na+, K+)-ATPase; ATP-dependent Ca2+ transport) are inhibited by incubation with phospholipase D. Phospholipase D had little effect on the passive Ca2+ permeability of the sarcolemmal vesicles. After treatment with 0.4 unit/ml of phospholipase D (20 min, 37 degrees C), the sarcolemmal content of phosphatidic acid rose from 0.9 +/- 0.2 to 8.9 +/- 0.4%; simultaneously, Na+-Ca2+ exchange activity increased 327 +/- 87%. It is probable that the elevated phosphatidic acid level is responsible for the enhanced Na+-Ca2+ exchange activity. In a previous study (Philipson, K. D., Frank, J. S., and Nishimoto, A. Y. (1983) J. Biol. Chem. 258, 5905-5910), we hypothesized that negatively charged phospholipids were important in Na+-Ca2+ exchange, and the present results are consistent with this hypothesis. Stimulation of Na+-Ca2+ exchange by phosphatidic acid may be important in explaining the Ca2+ influx which accompanies the phosphatidylinositol turnover response which occurs in a wide variety of tissues.     

Effects of fatty acids on Na+-Ca2+ exchange and Ca2+ permeability of cardiac sarcolemmal vesicles

We have previously reported that anionic phospholipids (Philipson, K.D., and Nishimoto, A.Y. (1984) J. Biol. Chem. 259, 16-19) and other anionic amphiphiles (Philipson, K.D. (1984) J. Biol. Chem. 259, 13999-14002) stimulate Na+-Ca2+ exchange in cardiac sarcolemmal vesicles. To further these studies, we have now investigated the effects of a variety of fatty acids on both Na+-Ca2+ exchange and passive Ca2+ permeability. Na+-Ca2+ exchange was stimulated by fatty acids by up to 150%. Unsaturated fatty acids were more potent than saturated fatty acids, and the stimulation was primarily due to a decrease in the apparent KM (Ca2+). There was a positive correlation between the ability of a fatty acid to stimulate Na+-Ca2+ exchange and to increase passive Ca2+ permeability. The methyl esters of fatty acids had no effects on either exchange or permeability indicating the importance of anionic charge. We conclude that the combination of local lipid disorder and anionic charge regulate Na+-Ca2+ exchange. Perturbations of the bilayer hydrophobic region and increased negative surface charge are both required for fatty acids to increase passive Ca2+ flux. Na+-Ca2+ exchange is stimulated when the ratio of membrane free fatty acid to phospholipid is about 5%. This level of fatty acid is achieved during 1 h of myocardial ischemia (Chien, K. R., Han, A., Sen, A., Buja, L. M., and Willerson, J. T. (1984) Circ. Res. 54, 313-322), indicating that ischemia could induce altered sarcolemmal Ca2+ transport due to fatty acid accumulation.     

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.     

Role of phosphatidylinositol in cardiac sarcolemmal membrane sodium-calcium exchange

The purpose of this investigation was to study the effects of a distinct type of phospholipase C on sarcolemmal Na+-Ca2+ exchange. With this phospholipase C (Staphylococcus aureus), treatment of cardiac sarcolemmal vesicles resulted in a specific hydrolysis of membrane phosphatidylinositol. This hydrolysis of phosphatidylinositol also released two proteins (110 and 36 kDa) from the sarcolemmal membrane. Phospholipase C pretreatment of the sarcolemma resulted in an unexpected stimulation of Na+-Ca2+ exchange. The Vmax of Na+-Ca2+ exchange was increased but the Km for Ca2+ was not altered. This stimulation was specific to the Na+-Ca2+ exchange pathway. ATP-dependent Ca2+ uptake was depressed after phospholipase C treatment, but passive membrane permeability to Ca2+ was unaffected. Sarcolemmal Na+,K+-ATPase activity was not altered, whereas passive Ca2+ binding was modestly decreased after phospholipase C pretreatment. The stimulation of Na+-Ca2+ exchange after phosphatidylinositol hydrolysis was greater in inside-out vesicles than in a total population of vesicles of mixed orientation. This finding suggests that the cardiac sarcolemmal Na+-Ca2+ exchanger is functionally asymmetrical. The results also suggest that membrane phosphatidylinositol is inhibitory to the Na+-Ca2+ exchanger or, alternatively, this phospholipid may anchor an endogenous inhibitory protein in the sarcolemmal membrane. The observation that a transsarcolemmal Ca2+ flux pathway may be stimulated solely by phosphatidylinositol hydrolysis independently of phosphoinositide metabolic products like inositol triphosphate is novel.     

Force-interval relationship and its response to ryanodine in streptozotocin-induced diabetic rats.

Post-quiescent potentiation (PQP), an enhanced contraction following a long pause that occurs as a result of increased Ca2+ release from intracellular stores, and post-stimulation potentiation (PSP), an enhanced contraction following a rapid series of contractions that is believed to be related to increased Ca2+ influx, were measured in streptozotocin-treated Wistar, spontaneously hypertensive (SHR), and Wistar-Kyoto (WKY) diabetic heart tissues. Decreased PQP values were found in Wistar and SHR diabetic papillary muscles (PM) in comparison with the same strain controls, which suggests a diminished degree of releasable Ca2+ from sarcoplasmic reticulum (SR) in these tissues. Decreased PSP was found in SHR diabetic PM, which may be related primarily to a depressed sarcolemmal (SL) Na(+)-Ca2+ exchange in this tissue. PSP was not decreased in diabetic Wistar or WKY cardiac preparations, indicating that Ca2+ entry via channels must be involved in the PSP mechanism. Ryanodine depressed PQP in Wistar and SHR PM, and SHR left atria in both control and diabetic tissues. It abolished PQP and SHR diabetic tissues but had no effect on WKY control and diabetic tissues. The data suggest that the ryanodine effect differs in the various strains of rat. These differences may be due to differences in the SR sensitivity to ryanodine among the strains. Diabetic SR with impaired Ca2+ uptake may contribute to these phenomena. Ryanodine depressed PSP of Wistar and SHR diabetic PM but had no effects on tissues from controls. The influence of ryanodine on diabetic SL Na(+)-Ca2+ exchange requires further investigation.     

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.