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.     

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.     

Stimulation of sodium-calcium exchange by cholesterol incorporation into isolated cardiac sarcolemmal vesicles

Modification of the cholesterol content of highly purified cardiac sarcolemma from dog ventricles was accomplished by incubation with phosphatidylcholine liposomes containing various amounts of cholesterol. The degree of cholesterol enrichment could be varied by changing the liposomal cholesterol/phospholipid ratio or varying the liposome-membrane incubation time. Na+-Ca2+ exchange measured in cholesterol-enriched sarcolemmal vesicles was increased up to 48% over control values. The stimulation of Na+-Ca2+ exchange was associated with an increased affinity of the exchanger for Ca2+ (Km = 17 microM compared with Km = 22 microM for control preparations). Na+-Ca2+ exchange measured in cholesterol-depleted membrane preparations was decreased by 15%. This depressed activity was associated with a decreased affinity of the exchanger for Ca2+ (Km = 27 microM). These changes were not due to either a change in membrane permeability to Ca2+ or an increase in the amount of Ca2+ bound to sarcolemmal vesicles. The stimulating effect of cholesterol enrichment was specific to the Na+-Ca2+ exchange process since sarcolemmal Ca2+-Mg2+ ATPase activity was depressed 40% by cholesterol enrichment. Further, K+-p-nitrophenylphosphatase and Na+-K+ ATPase activities were depressed in both cholesterol-depleted and cholesterol-enriched sarcolemmal vesicles. In situ oxidation of membrane cholesterol completely eliminated Na+-Ca2+ exchange. These results suggest that cholesterol is intimately associated with Na+-Ca2+ exchange and may interact with the exchange protein and modulate its activity.     

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.     

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.     

Alterations by saponins of passive Ca2+ permeability and Na+-Ca2+ exchange activity of canine cardiac sarcolemmal vesicles

Saponins can both permeabilize cell plasma membranes and cause positive inotropic effects in isolated cardiac muscles. Different saponins vary in their relative abilities to cause each effect suggesting that different mechanisms of action may be involved. To investigate this possibility, we have compared the effects of seven different saponins on the passive Ca2+ permeability and Na+-Ca2+ exchange activity of isolated canine cardiac sarcolemmal membranes. Saponins having hemolytic activity reversibly increased the passive efflux of Ca2+ from sarcolemmal vesicles preloaded with 45Ca2+ with the following order of potency: echinoside-A greater than echinoside-B greater than holothurin-A greater than holothurin-B greater than sakuraso-saponin. Ginsenoside-Rd and desacyl-jego-saponin, which lack hemolytic activity, had no significant effect on this variable. The saponins also stimulated Na+-Ca2+ exchange activity measured as Na+-dependent Ca2+ uptake by sarcolemmal vesicles. Ginsenoside-Rd and desacyl-jego-seponin, which did not affect passive Ca2+ permeability, stimulated the uptake, while in contrast, echinoside-A and -B only slightly increased or decreased this latter variable. Thus, the abilities of these compounds to enhance Na+-Ca2+ exchange activity seem to be inversely related to their abilities to increase the Ca2+ permeability. Effects by the echinosides on Na+-Ca2+ exchange may be masked by the loss of Ca2+ from the vesicles due to the increased permeability. These results suggest that the saponins interact with membrane constituent(s) that can influence the passive Ca2+ permeability and the Na+-Ca2+ exchange activity of cardiac sarcolemmal membranes.     

Phospholipid composition modulates the Na+-Ca2+ exchange activity of cardiac sarcolemma in reconstituted vesicles

Na+-Ca2+ exchange activity in cardiac sarcolemmal vesicles is known to be sensitive to charged, membrane lipid components. To examine the interactions between membrane components and the exchanger in more detail, we have solubilized and reconstituted the Na+-Ca2+ exchanger into membranes of defined lipid composition. Our results indicate that optimal Na+-Ca2+ exchange activity requires the presence of certain anionic phospholipids. In particular, phosphatidylserine (PS), cardiolipin, or phosphatidic acid at 50% by weight results in high Na+-Ca2+ exchange activity, whereas phosphatidylinositol and phosphatidylglycerol provide a poor environment for exchange. In addition, incorporation of cholesterol at 20% by weight greatly facilitates Na+-Ca2+ exchange activity. Thus, for example, an optimal lipid environment for Na+-Ca2+ exchange is phosphatidylcholine (PC, 30%)/PS (50%)/cholesterol (20%). Na+-Ca2+ exchange activity is also high when cardiac sarcolemma is solubilized and then reconstituted into asolectin liposomes. We fractionated the lipids of asolectin into subclasses for further reconstitution studies. When sarcolemma is reconstituted into vesicles formed from the phospholipid component of asolectin, Na+-Ca2+ exchange activity is low. When the neutral lipid fraction of asolectin (including sterols) is also included in the reconstitution medium, Na+-Ca2+ exchange activity is greatly stimulated. This result is consistent with the requirement for cholesterol described above. Proteinase treatment, high pH, intravesicular Ca2+ and dodecyl sulfate all stimulate Na+-Ca2+ exchange in native sarcolemmal vesicles. We examined the effects of these interventions on exchange activity in reconstituted vesicles of varying lipid composition. In general, Na+-Ca2+ exchange could be stimulated only when reconstituted into vesicles of a suboptimal lipid composition. That is, when reconstituted into asolectin or PC/PS/cholesterol (30:50:20), the exchanger is already in an activated state and can no longer be stimulated. The one exception was that the Na+-Ca2+ exchanger responded to altered pH in an identical manner, independent of vesicle lipid composition. The mechanism of action of altered pH on the exchanger thus appears to be different from other interventions.     

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.     

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.     

Inhibition by taurine of Na(+)-Ca2+ exchange in sarcolemmal membrane vesicles from bovine and guinea pig hearts

1. Taurine, but not GABA, beta-alanine and glycine, inhibited Na(+)-dependent Ca2+ uptake in bovine cardiac sarcolemmal membrane vesicles in a dose-dependent manner. 2. The inhibition of Na(+)-dependent Ca2+ uptake was noncompetitive with respect to Ca2+ concentration. 3. The inhibitory effect of taurine on the exchange was also observed in cardiac sarcolemmal vesicles prepared from guinea pig, but not from rat. 4. Taurine did not affect Na(+)-dependent Ca2+ efflux nor ATP-dependent Ca2+ uptake in the bovine cardiac membranes.     

Reconstitution of the sodium-calcium exchanger from cardiac sarcolemmal vesicles

The Na+-Ca2+ exchanger was extracted from cardiac sarcolemmal vesicles and reconstituted into phospholipid vesicles by a cholate-dialysis method. Reconstitution was attempted with different phospholipids. Phosphatidylcholine alone was ineffective, whereas phosphatidylcholine and phosphatidylethanolamine (1:1, w/w) showed high activity, but a significant Ca2+ uptake in the absence of Na+ gradient. Optimal reconstitution was obtained with a mixture of phosphatidylcholine and phosphatidylserine (9:1, mol/mol). The reconstituted proteoliposomes showed an ouabain-sensitive (Na+ + K+)-ATPase activity and a Na+-Ca2+ exchange with a specific activity comparable to that of the original vesicles. The specificity toward Na+ was also recovered. A partial purification of the exchanger was obtained by the method of transport-specificity fractionation ( Goldin , S.M. and Rhoden , V. (1978) J. Biol. Chem. 253, 2575-2583). When proteoliposomes were reconstituted with sodium oxalate inside and incubated with calcium in the presence of an outwardly directed Na+ gradient, the vesicles containing the Na+-Ca2+ exchanger specifically accumulated calcium which precipitated inside as calcium oxalate. The resulting increase in density allowed separation of the proteoliposomes containing the Na+-Ca2+ exchanger from the rest of the vesicles on a sucrose density gradient.     

ATP-dependent Na+ transport in cardiac sarcolemmal vesicles

Although the enzyme (Na+ + K+)-ATPase has been extensively characterized, few studies of its major role, ATP-dependent Na+ pumping, have been reported in vesicular preparations. This is because it is extremely difficult to determine fluxes of isotopic Na+ accurately in most isolated membrane systems. Using highly purified cardiac sarcolemmal vesicles, we have developed a new technique to detect relative rates of ATP-dependent Na+ transport sensitively. This technique relies on the presence of Na+-Ca2+ exchange and ATP-driven Na+ pump activities on the same inside-out sarcolemmal vesicles. ATP-dependent Na+ uptake is monitored by a subsequent Nai+-dependent Ca2+ uptake reaction (Na+-Ca2+ exchange) using 45Ca2+. We present evidence that the Na+-Ca2+ exchange will be linearly related to the prior active Na+ uptake. Although this method is indirect, it is much more sensitive than a direct approach using Na+ isotopes. Applying this method, we measure cardiac ATP-dependent Na+ transport and (Na+ + K+)-ATPase activities in identical ionic media. We find that the (Na+ + K+)-ATPase and the Na+ pump have identical dependencies on both Na+ and ATP. The dependence on [Na+] is sigmoidal, with a Hill coefficient of 2.8. Na+ pumping is half-maximal at [Na+] = 9 mM. The Km for ATP is 0.21 mM. ADP competitively inhibits ATP-dependent Na+ pumping. This approach should allow other new investigations on ATP-dependent Na+ transport across cardiac sarcolemma.     

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.     

Site density of the sodium-calcium exchange carrier in reconstituted vesicles from bovine cardiac sarcolemma

The site density of the Na2+-Ca2+ exchanger in bovine cardiac sarcolemma was estimated from measurements of the fraction of reconstituted proteoliposomes exhibiting exchange activity. Sarcolemmal vesicles were solubilized with 1% Triton X-100 in the presence of either 100 mM NaCl or 100 mM KCl; after a 20-40-min incubation period on ice, sufficient KCl, NaCl, CaCl2, and soybean phospholipids were added to each extract to give final concentrations of 40 mM NaCl, 120 mM KCl, 0.1 mM CaCl2, and 10 mg/ml phospholipid. These mixtures were then reconstituted into proteoliposomes, and the rate of 45Ca2+ isotopic exchange was measured under equilibrium conditions. Control studies showed that Na+-Ca2+ exchange activity was completely lost if Na+ was not present during solubilization. The difference in 45Ca2+ uptake between vesicles initially solubilized in the presence or absence of NaCl therefore reflected exchange activity and corresponded to 3.1 +/- 0.3% of the total 45Ca2+ uptake by the entire population of vesicles, as measured in the presence of the Ca2+ ionophore A23187. Assuming that each vesicle with exchange activity contained 1 molecule of the Na+-Ca2+ exchange carrier, a site density of 10-20 pmol/mg of protein for the exchanger was calculated. The Vmax for Na+-Ca2+ exchange activity in the proteoliposomes was approximately 20 nmol/mg of protein.s which indicates that the turnover number of the exchange carrier is 1000 s-1 or more. Thus, the Na+-Ca2+ exchanger is a low density, high turnover transport system.     

Protein methylation inhibits Na+-Ca2+ exchange activity in cardiac sarcolemmal vesicles

We have examined the effect of membrane methylation on the Na+-Ca2+ exchange activity of canine cardiac sarcolemmal vesicles using S-adenosyl-L-methionine as methyl donor. Methylation leads to approximately 40% inhibition of the initial rate of Nai+-dependent Ca2+ uptake. The inhibition is due to a lowering of the Vmax for the reaction. The inhibition is not due to an effect on membrane permeability and is blocked by S-adenosyl-L-homocysteine, an inhibitor of methylation reactions. The following experiments indicated that inhibition of Na+-Ca2+ exchange was due to methylation of membrane protein and not due to methylated phosphatidylethanolamine (PE) compounds (i.e., phosphatidyl-N-monomethylethanolamine (PMME) or phosphatidyl-N,N'-dimethylethanolamine (PDME]: (1) We solubilized sarcolemma and reconstituted activity into vesicles containing no PE. The inhibition by S-adenosyl-L-methionine was not diminished in this environment. (2) We reconstituted sarcolemma into vesicles containing PMME or PDME. These methylated lipid components had no effect on Na+-Ca2+ exchange activity. (3) We verified that many membrane proteins, probably including the exchanger, become methylated.     

Inhibition of the Na+/Ca2+ exchange in cardiac sarcolemmal vesicles by amiloride

The pyrazine diuretic amiloride inhibits the Na+/Ca2+ exchange activity of cardiac sarcolemmal vesicles in a concentration-dependent way. A good relationship between the uptake of amiloride by the vesicles and the inhibition of the exchanger has been found. Kinetic analyses indicate that the inhibition of Na+/Ca2+ exchange activity by amiloride is non-competitively removed by Ca2+ and competitively overcome by an outwardly directed Na+ gradient.     

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.     

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).     

Influence of sterols and phospholipids on sarcolemmal and sarcoplasmic reticular cation transporters

We have examined the influence of different sterols and phospholipids on the activities of the cardiac sarcolemmal Na+-Ca2+ exchanger and Na+,K+-ATPase and the sarcoplasmic reticular Ca2+-ATPase in reconstituted proteoliposomes. When either the solubilized Na+-Ca2+ exchanger or the Na+,K+-ATPase is reconstituted into phosphatidylcholine (PC):phosphatidylserine (30:50 by weight) vesicles, high cholesterol levels (20% by weight) are required for activity to be expressed. This sterol requirement is highly specific for cholesterol. Several cholesterol analogues with minor structural changes are unable to support Na+-Ca2+ exchange or Na+,K+-ATPase activities. When solubilized sarcolemma is reconstituted into PC:cardiolipin vesicles, however, the requirement for cholesterol is lost. Substantial activity can be obtained in the complete absence of cholesterol or in the presence of several cholesterol analogues. Thus, sterol/protein interactions can be highly dependent on the phospholipid environment. In contrast, the skeletal muscle sarcoplasmic reticular Ca2+-ATPase functions equally well in the presence or absence of cholesterol after reconstitution into either PC:phosphatidylserine or PC:cardiolipin proteoliposomes. Phospholipid requirements of the transporters were also examined. The sarcolemmal Na+-Ca2+ exchanger, Na+,K+-ATPase, and the sarcoplasmic reticular Ca2+-ATPase all function optimally in the presence of phosphatidylserine or cardiolipin after reconstitution. Thus, the sarcolemmal cation transporters have similar sterol and phospholipid requirements and may have structural similarities in their hydrophobic regions. The sarcoplasmic reticular Ca2+ pump evolved in a low cholesterol membrane and has different lipid interactions. These findings may have general applicability to other plasma membrane and endoplasmic reticular enzymes.     

Purification of the cardiac Na+-Ca2+ exchange protein

We have used fractionation procedures to enrich solubilized cardiac sarcolemma in the Na+-Ca2+ exchange protein. Sarcolemma is extracted with an alkaline medium to remove peripheral proteins and is then solubilized with decylmaltoside. Next, the exchanger is applied to DEAE-Sepharose and eluted with high salt. The DEAE fraction is applied to WGA-agarose, and a small fraction of protein, enriched in the exchanger, can be eluted by changing the detergent to Triton X-100. This fraction is reconstituted into asolectin proteoliposomes for measurement of Na+-Ca2+ exchange activity and gel electrophoresis. The purified fraction has a Na+-Ca2+ exchange activity of 600 nmol Ca2+/mg of protein per s at 10 microM Ca2+ and a purification factor of about 30 as compared with control reconstituted sarcolemmal vesicles. Ca2+-Ca2+ exchange and Na+-Ca2+ exchange activities were both present in the same final reconstituted vesicles indicating that the same protein is responsible for both transport activities. SDS-PAGE reveals two prominent protein bands at 70 and 120 kDa. After mild chymotrypsin treatment (1 microgram/ml), there is no loss of exchange activity, but the 120 kDa band disappears and the 70 kDa band becomes more dense. This suggests that the 70 kDa band is due to an active proteolytic fragment of the 120 kDa protein. Under non-reducing gel conditions, only a single protein band is seen with an apparent molecular weight of 160 kDa. Antibodies to the purified exchanger preparation are able to immunoprecipitate exchange activity and confirm that the 70 kDa protein derives from the 120 kDa protein. We propose that both the 70 and 120 kDa proteins are associated with the Na+-Ca2+ exchanger.