The effect of calcium load on the calcium permeability of sarcoplasmic reticulum

The effect of intravesicular and extravesicular calcium concentration on the passive efflux from sarcoplasmic reticulum (SR) vesicles isolated from cardiac and skeletal muscle was determined by measuring net efflux of calcium after stopping pump-mediated fluxes. The apparent permeability, calculated as the passive efflux divided by the total intravesicular calcium, depended on calcium load. This dependence of the apparent permeability on calcium load could be explained by the presence of intravesicular calcium-binding sites with a dissociation constant less than 10(-3) M. When the intravesicular bound calcium was taken into account, passive calcium efflux was found to be linearly related to the difference in calcium concentration across the SR membrane. Thus the permeability of the SR membrane is independent of intravesicular and extravesicular calcium concentration in the ranges investigated. The average first order rate constant for passive calcium efflux for six preparations was 0.8 +/- 0.2 min-1 for skeletal and 0.7 +/- 0.1 min-1 for cardiac SR. The amount of intravesicular bound calcium for the same preparations was 33 +/- 6 nmol mg-1 for skeletal and 13 +/- 2 nmol mg-1 for cardiac SR. The first order rate constants were unaffected by Mg concentration between 0.1 +/- 15.1 mM and by the presence of an ATP-regenerating system. The results suggest that some minimal calcium load may be required in order to observe a substantial passive calcium efflux, the passive calcium efflux is not carrier mediated, and passive calcium efflux is not a likely route of calcium release during excitation-contraction coupling.     

Sidedness of K+ activation of calcium transport in the reconstituted sarcoplasmic reticulum calcium pump

Sidedness of the effect of K+ on Ca transport by the sarcoplasmic reticulum Ca pump reconstituted into soybean phospholipid vesicles was investigated. The reconstituted vesicles which sustained a high rate of Ca transport even in the absence of Ca-precipitating anions exhibited low passive permeabilities to 42K+, 86Rb+, or 45Ca2+. Evidence was presented that K+ activated the Ca pump on the external surface of the vesicles and that it was not taken up by the vesicles during the pump activity. In the presence of high externally added K+, the reconstituted vesicles preloaded with K+ exhibited a significantly higher Ca transport activity than the vesicles preloaded with Tris+ but not the ones preloaded with Li+. Ca transport by the K+-loaded vesicles was accompanied by a small amount of K+ efflux, which corresponded to about 20% of the amount of Ca+ taken up. Since the intravesicular K+ did not affect the turnover of the ADP-insensitive component (E2P) of the phosphoenzyme intermediate formed during the pump cycle, it was concluded that the intravesicular K+ stimulated the Ca pump activity indirectly by compensating the charge imbalance caused by the electrogenic Ca2+ movement. These results thus indicate that K+ activates the Ca pump only on the cytoplasmic side of the sarcoplasmic reticulum membrane, but it is not obligately transported across the membrane under conditions where K+ fully activates the Ca pump.     

Ca2+ uptake, Ca2+-ATPase activity, phosphoprotein formation and phosphate turnover in a microsomal fraction of smooth muscle

Vesicles capable of phosphate-stimulated calcium uptake were isolated from the microsomal fraction of the smooth muscle of the pig stomach according to a previously described procedure which consists in increasing the density of the vesicles by loading them with calcium phosphate and isolating them by centrifugation [Raeymaekers, L., Agostini, B., and Hasselbach, W. (1981) Histochemistry, 70, 139--150]. These vesicles, which contain calcium phosphate deposits, are able to accumulate an additional amount of calcium. This calcium uptake is accompanied by calcium-stimulated ATPase activity and by the formation of an acid-stable phosphoprotein. The acid-denatured phosphoprotein is dephosphorylated by hydroxylamine, which indicates that an acylphosphate is formed. This phosphoprotein probably represents a phosphorylated transport intermediate similar to that seen with the Ca2+-ATPase of sarcoplasmic reticulum of skeletal muscle. As with the Ca2+-ATPase of sarcoplasmic reticulum vesicles, this vesicular fraction catalyses an exchange between inorganic phosphate and the gamma-phosphate of ATP (ATP-Pi exchange) which is dependent on the presence of intravesicular calcium, and an exchange of phosphate between ATP and ADP (ATP-ADP exchange). The results further indicate that the turnover rate of the calcium pump, calculated from the ratio of calcium-stimulated ATPase activity to the steady-state level of phosphoprotein, is similar to that of Ca2+-ATPase of sarcoplasmic reticulum of skeletal muscle.     

Vanadate oligomer inhibition of passive and active Ca2+ translocation by the Ca2+ pump of sarcoplasmic reticulum

'Monovanadate' containing mainly monomeric, dimeric and tetrameric vanadate species or 'decavanadate', containing mainly decameric vanadate species inhibits the passive and the active efflux of Ca2+ through the sarcoplasmic reticulum calcium pump. When the efflux of Ca2+ by sarcoplasmic reticulum vesicles is not associated with ATP synthesis both vanadate solutions inhibit the passive efflux of Ca2+. However, only 'decavanadate' exerts noticeable effects when the efflux of Ca2+ is associated with ATP synthesis being the active efflux of Ca2+ almost completely inhibited by decameric species concentration as low as 40 microM.     

Calcium fluxes across the membrane of sarcoplasmic reticulum vesicles

The relationship between calcium exchange across the membrane of sarcoplasmic reticulum vesicles and phosphoenzyme (EP) was examined in calcium transport reactions using a limited amount of ATP as substrate. Rapid calcium influx and efflux (approximately 385 nmol.(mg.min)-1), measured in reactions in which ATP concentration fell from 20 microM, was accompanied by a shift in the equilibrium between an ADP-sensitive EP and an ADP-insensitive EP toward the former. Rapid exchange between ATP and ADP (approximately 1500 nmol.(mg.min)-1) was also observed under conditions where no significant incorporation of Pi into ATP took place, suggesting that ATP in equilibrium ADP exchange can occur without Cao in equilibrium Cai exchange. Ca2+ permeability during the calcium transport reaction was estimated in reactions carried out with acetylphosphate, which produces a hydrolytic product that does not participate in the backward reaction of the calcium pump. Under conditions where the calcium content exceeded 43 nmol.mg-1, a level that may reflect the binding of calcium ions to sites inside the sarcoplasmic reticulum, the rate constant for Ca2+ efflux was 0.33 min-1. These data allow the rate of passive Ca2+ efflux to be estimated as approximately 17 nmol.(mg.min)-1 at the time when calcium content was maximal and a rapid Cao in equilibrium Cai was observed. It is concluded that the majority of the rapid Ca2+ efflux is mediated by partial backward reactions of the calcium pump ATPase.     

Lack of effects of calcium X calmodulin-dependent phosphorylation on Ca2+ release from cardiac sarcoplasmic reticulum

Canine cardiac sarcoplasmic reticulum is phosphorylated by an endogenous calcium X calmodulin-dependent protein kinase and phosphorylation occurs mainly on a 27 kDa proteolipid, called phospholamban. To determine whether this phosphorylation has any effect on Ca2+ release, sarcoplasmic reticulum vesicles were phosphorylated by the calcium X calmodulin-dependent protein kinase, while non-phosphorylated vesicles were preincubated under identical conditions but in the absence of ATP to avoid phosphorylation. Both non-phosphorylated and phosphorylated vesicles were centrifuged to remove calmodulin, and subsequently used for Ca2+ release studies. Calcium loading was carried out either by the active calcium pump or by incubation with high (5 mM) calcium for longer periods. Phosphorylation of sarcoplasmic reticulum by calcium X calmodulin-dependent protein kinase had no appreciable effect on the initial rates of Ca2+ released from cardiac sarcoplasmic reticulum vesicles loaded under passive conditions and on the apparent 45Ca2+-40Ca2+ exchange from cardiac sarcoplasmic reticulum vesicles loaded under active conditions. Thus, it appears that calcium X calmodulin-dependent protein kinase mediated phosphorylation of cardiac sarcoplasmic reticulum is not involved in the regulation of Ca2+ release and 45Ca2+-40Ca2+ exchange.     

Ca2+-induced Ca2+ release from fragmented sarcoplasmic reticulum: Ca2+-dependent passive Ca2+ efflux

Characterization of the putative Ca2+-gated Ca2+ channel of sarcoplasmic reticulum, which is thought to mediate Ca2+-induced Ca2+ release, was carried out in order to elucidate the mechanism of Ca2+-induced Ca2+ release. Heavy and light fractions of fragmented sarcoplasmic reticulum isolated from rabbit skeletal muscle were loaded passively with Ca2+, and then passive Ca2+ efflux was measured under various conditions. The fast phase of the Ca2+ efflux depended on the extravesicular free Ca2+ concentration and was assigned to the Ca2+ efflux through the Ca2+-gated Ca2+ channel. Vesicles with the Ca2+-gated Ca2+ channels comprised about 85% of the heavy fraction and about 40% of the light fraction. The amount of Ca2+ loaded in FSR was found to be much larger than that estimated on the basis of vesicle inner volume and the equilibration of intravesicular with extravesicular Ca2+, indicating Ca2+ binding inside FSR. Taking this fact into account, the Ca2+ efflux curve was quantitatively analyzed and the dependence of the Ca2+ efflux rate constant on the extravesicular free Ca2+ concentration was determined. The Ca2+ efflux was maximal, with the rate constant of 0.75 s-1, when the extravesicular free Ca2+ was at 3 microM. Caffeine increased the affinity for Ca2+ of Ca2+-binding sites for opening the channel with only a slight change in the maximum rate of Ca2+ efflux. Mg2+ inhibited the Ca2+ binding to the sites for opening the channel while procaine seemed to inhibit the Ca2+ efflux by blocking the ionophore moiety of the channel.     

Characterization of the steady-state calcium fluxes in skeletal sarcoplasmic reticulum vesicles. Role of the Ca2+ pump

Unidirectional Ca2+ fluxes (influx and efflux), supported by ATP as a phosphate-donor substrate, were measured without alteration of the lumenal Ca2+ content in longitudinal sarcoplasmic reticulum vesicles. The referred fluxes are dependent on extravesicular Ca2+, ATP and ADP. They are unaffected by ruthenium red but inhibited by quercetin. The Ca2+ fluxes at steady state are drastically diminished when ATP is substituted by acetylphosphate although the addition of 10 microM ADP increases the apparent rate constants more than eight fold. The observed fluxes appear to be dependent on Ca2(+)-ATPase phosphoenzyme transitions. The results indicate that: (a) the slow Ca2+ release, due to the passive permeability of the membrane, is a minor component of the total Ca2+ efflux, and (b) the ATPase protein is basically operating as a Ca2+/Ca2+ exchanger at steady state. Kinetic resolution of the Ca2+ fluxes, measured by isotopic tracer and rapid filtration techniques can be recreated by computer simulation of the ATPase reaction cycle featuring some modifications to account for the fast Ca2+/Ca2+ exchange and the uncoupling effect observed at steady state.     

Calcium control of passive permeability to calcium in sarcoplasmic reticulum vesicles

Calcium efflux from sarcoplasmic reticulum vesicles that have been equilibrated with 1-100 mM CaCl2 in the absence of ATP has two apparently first order components. The initial calcium content of each component increases with the total Ca content of the sarcoplasmic reticulum, which reaches 5, 24, and 80 nmol/mg of protein after equilibration with 1, 10, and 100 mM CaCl2, respectively. Initial rates of Ca efflux into a medium containing 10 mM EGTA increase in proportion to Ca in the loading medium up to 20 mM. Above 20 mM, efflux from the slow component clearly saturates, whereas efflux from the fast component continues to increase. The rate constant for the smaller, faster component to efflux (k congruent to 0.5 min-1) is not affected by changing the concentration of Ca either inside or outside the vesicles. The rate constant of the larger, slower component (k congruent to 0.05 min-1) is also unaffected by changes in internal Ca concentration. However, external [Ca2+] diminishes the rate constant of the slow component 6-10-fold. Inhibition by external [Ca2+] is characterized by cooperative interaction between two sites with an apparent Kd of 5.3 X 10(-6) M. The two components may represent two populations of sarcoplasmic reticulum vesicles that differ 10-fold in passive permeability to Ca when external [Ca2+] is less than 10(-6) M, and 60-100-fold when external [Ca2+] is greater than 10(-5) M. The passive permeability in one of these populations seems to be regulated by external, high affinity Ca binding sites.     

Inhibition of hydrolysis of phosphorylated Ca2+,Mg2+-ATPase of the sarcoplasmic reticulum by Ca2+ inside and outside the vesicles

The effects of intra- and extravesicular calcium and magnesium ions on the hydrolysis of the phosphoenzyme (EP) intermediate formed in the reaction of Ca2+,Mg2+-dependent ATPase of the sarcoplasmic reticulum were investigated. The rate constants of EP hydrolysis were measured under conditions that allowed a single turnover of ATP hydrolysis to minimize the increase in calcium concentration inside the vesicles. The EP formed during a single turnover was hydrolyzed biphasically and could be resolved into fast- and slow-decomposing components. When free Mg2+ outside the vesicles was chelated by adding excess EDTA, EP could also be kinetically resolved into two components; EDTA-sensitive EP, which could be quickly decomposed by adding EDTA, and EDTA-insensitive EP, which could be prevented from decomposing by adding EDTA. The amount of EDTA-sensitive EP decreased rapidly during the initial phase of the reaction, while that of EDTA-insensitive EP decreased slowly with the same rate constant as that of the slow-decomposing EP. These results showed that the biphasic time course of EP hydrolysis was caused by the formation of EDTA-sensitive and -insensitive EP during the reaction. The time course of EP hydrolysis could be quantitatively analyzed in terms of the following reaction mechanism. (formula; see text) The decomposition of EDTA-insensitive EP required Mg2+ outside the vesicles and was competitively inhibited by extravesicular Ca2+. The decomposition of EDTA-sensitive EP was inhibited by Ca2+ inside the vesicles but not by external Ca2+. The linear relationships between the inverse of the rate constants of EP decomposition during the initial phase and the intravesicular CaCl2 concentrations suggested that decomposition of EDTA-sensitive EP was inhibited by the binding of 1 mol of intravesicular Ca2+ to 1 mol of EP. Furthermore, Mg2+ inside the vesicles scarcely affected the inhibition of EP hydrolysis by intravesicular Ca2+. These results suggested that magnesium ions are not counter-transported during the active transport of calcium by SR vesicles.     

Aspects of the mechanism of action of local anesthetics on the sarcoplasmic reticulum of skeletal muscle.

1. The effect was studied of local anesthetics (tetracaine, dibucaine, procaine and xylocaine) on the forward and the backward reactions of the calcium pump of skeletal muscle sarcoplasmic reticulum. 2. The inhibition of the rate of calcium uptake, the rate of calcium-dependent ATP splitting and the rate of calcium-dependent ATP-ADP phosphate exchange by sarcoplasmic reticulum in the presence of the above drugs is at least partially due to the inhibition of the phosphoprotein formation from ATP. 3. The rate of the ADP-induced calcium release from sarcoplasmic reticulum and the rate of ATP synthesis driven by the calcium efflux are inhibited on account of a reduction of the phosphoprotein formation by orthophosphate. 4. The phosphorylation of calcium transport ATPase by either ATP or orthophosphate is diminished by the local anesthetics owing to a reduction in the apparent calcium affinity of sarcoplasmic reticulum emmbranes on the outside and on the inside, respectively. 5. The drug-induced calcium efflux from calcium-preloaded sarcoplasmic reticulum vesicles, a reaction not requiring ADP, is probably not mediated by calcium transport ATPase.     

The dependence on internal pH of Ca2+-fluxes across sarcoplasmic reticulum vesicular membranes

The interdependence of the competition between Ca2+ and hydrogen ions for the internally located low-affinity Ca2+ binding sites of sarcoplasmic reticulum vesicles and the pH-dependent splitting rate of phosphoenzyme was investigated. Sarcoplasmic reticulum vesicles were preincubated at a selected pH and passive Ca2+ loading, active Ca2+ uptake at the same pH as well as active Ca2+ uptake at a distinct pH (pH-jump method) were observed. In addition, Cai-Cao exchange in the absence and presence of ADP and ATP-ADP exchange were measured. The overall ATP splitting rate was assayed with leaky vesicles in the presence of varied Ca2+ concentration and four different pH. All experiments were carried out at Ca2+ concentrations sufficient to saturate the externally located activating high-affinity binding sites at all pH and in the absence of affecting concentrations of monovalent cations. Active Ca2+ transport (particularly evident applying the pH-jump method) is facilitated at low intravesicular pH, reflecting the favoured Ca2+ release to the intravesicular space, in contrast to the reverse pH-dependence of passive Ca2+ accumulation and the initial rate of Cai-Cao exchange, both favoured by elevated internal Ca2+ binding capacity. The rates of ATP splitting, the continuing slow rate of Cai-Cao exchange, and the ATP-ADP exchange are optimal at an intermediate proton concentration, reflecting the influence of protons on partial reaction steps occurring later in the reaction cycle and the accelerated exchange of Ca2+ at the internal low-affinity sites as well as the establishment of a new pseudo equilibrium between the possible reaction intermediates. The pool of rapidly exchangeable Ca2+ is enlarged whereas the rate of slow exchange is unaltered or diminished (pH 7.8) by ADP.     

Fast release of calcium from sarcoplasmic reticulum vesicles monitored by chlortetracycline fluorescence

Rapid Ca2+ release rate from sarcoplasmic reticulum vesicles was determined by the stopped flow method in terms of chlortetracycline fluorescence. Intensity of chlortetracycline fluorescence was proportional to the intravesicular free Ca2+ concentration. Ca2+ efflux was activated by extravesicular Ca2+ with an apparent dissociation constant of 25 microM and was inhibited with an inhibition constant of 120 microM in the absence of Mg2+. Caffeine enhanced the Ca2+ release rate by increasing only the affinity of Ca2+ for the activation site. Mg2+ reduced the Ca2+ release rate by competitive binding to the activation site. ATP increased the Ca2+ release rate very much without changing the affinities of Ca2+ for the activation and inhibition sites, i.e., ATP seems to increase the pore radius or number of the Ca2+ channels without affecting the gating mechanism of the channel. These results are consistent with those reported in skinned muscle sarcoplasmic reticulum. The maximum rate of Ca2+ release in the presence of ATP reached 80 s-1. This value is considered to be sufficient to cause muscular contraction.     

Regulation of steady state filling in sarcoplasmic reticulum. Roles of back-inhibition, leakage, and slippage of the calcium pump

Calcium filling of sarcoplasmic reticulum vesicles in the steady state is greatly increased by precipitation of lumenal calcium with oxalate. We find that low concentrations (1 mM) of Pi also allow greater loading by forming a soluble complex with lumenal calcium, an effect that is likely to be of physiological relevance. Furthermore, ADP scavenging by ATP regenerating systems favors calcium loading by preventing reversal of the pump. We also find that uncoupling of ATPase and transport activities is another factor limiting calcium loading. In fact, calcium uptake and ATP utilization occur with a molar ratio of 2:1 in the transient state following addition of ATP but decrease to much lower values in the steady state. Even in the absence of the highly conductive channel which is present only in "heavy" vesicles, "light" vesicles display calcium leakage which is inhibited by medium Ca2+ in the concentration range of ATPase activation and is likely related to an ATPase channel which is involved in calcium transport. It is apparent that, under conditions of ATPase turnover and in the presence of high lumenal Ca2+ and ADP, slippage of calcium through this channel produces true uncoupling of catalytic and transport activities. Coupling is improved by complexation of lumenal Ca2+ and by ATP regeneration and is influenced by the solvent characteristics of the reaction medium. The synergistic effects of lumenal Ca2+ and ADP, and the role of alternate pathways for phosphoenzyme cleavage, are clarified by steady state analysis of a multiple step reaction mechanism. It is concluded that the ideal (2:1) stoichiometric coupling of transport and ATPase activities is not insured by an obligatory pathway of catalysis (as predicted by all reaction schemes published so far); rather, coupling is influenced by the concentrations of ligands and their effects on second order reactions and the consequent distribution of intermediate states.     

Passive Ca2+ permeability of vesicular sarcolemmal preparations from myocardium

Vesicular preparations of sarcolemma isolated from rat myocardium possessed high ATPase (4.32 +/0 0.57 micromole/min per mg), adenylate cyclase (121 +/- 11 pmole/min per mg) and creatine kinase (1.74 +/- 0.35 micromole/min per mg) activities and a Na-Ca exchange activity specific for sodium. The ATPase activity was inhibited by digitoxigenin by 50-70% and was not changed by ouabain, EGTA, ionophore A23187 and oligomycin, thus showing the absence of mitochondrial and sarcoplasmic reticulum contaminations in the sarcolemmal preparations. The preparations consisted mostly of closed inside-out vesicles. The preparation was used to study the mechanism of Ca2+ penetration across the sarcolemmal membrane. For this purpose the vesicles were load with 45Ca2+, which relatively slowly diffused from the medium into the vesicles, and which was bound to the binding sites inside the vesicles (n = 20.5 +/- 4.6 nmoles per mg of protein, Kd approximately equal to 1.8 +/- 0.21 mM). The transmembrane movement of Ca2+ was demonstrated by the following findings: 1) the ionophore A23187 only insignificantly increased the total vesicular Ca2+ content, but strongly accelerated Ca2+ efflux from the vesicles along its concentration gradient; 2) gramicidin and osmotic shock caused a similar acceleration of Ca2+ efflux. Ca2+ efflux from these vesicles along Ca2+ concentration gradient was studied under conditions, when the extravesicular Ca2+ content was lowered due to its binding to EGTA and by dilution. The gradient of Ca2+ concentration was from 2.0 mM inside to approximately 0.1 micro M outside. The rate of 45Ca2+ efflux depended hyperbolically on the intravesicular Ca2+ efflux from the vesicles was inhibited by Mn2+, Co2+ and verapamil when they acted from the inside of the vesicles. An increase in ionophore A23187 concentration increased the efflux of Ca2+ hyperbolically and enhanced only the maximal rate of the efflux. It is concluded that the passive permeability of Ca2+ across the sarcolemmal membrane along its concentration gradient is controlled by Ca2+ binding to the membrane.     

Functional evidence of a transmembrane channel within the Ca2+ transport ATPase of sarcoplasmic reticulum.

Ca2+ efflux can be studied conveniently following dilution of sarcoplasmic reticulum (SR) vesicles preloaded with 45Ca2+ by active transport. The rates of efflux are highly dependent on ATPase substrates and cofactors (Pi, Mg2+, Ca2+ and ADP) in the efflux medium. On the other hand, phenothiazines stimulate efflux through a passive permeability channel with no coupled catalytic events. Efflux activation by manipulation of catalytically active ATPase ligands, as well as by the catalytically inactive phenothiazines, can be prevented by thapsigargin, which is a highly specific inhibitor of the Ca(2+)-ATPase. This demonstrates that the passive channel activated by phenothiazines is an integral part of the ATPase, and can operate either uncoupled or coupled to catalytic events.     

Effects of alkaline pH on sarcoplasmic reticulum Ca2+ release and Ca2+ uptake.

Alkalinization-induced Ca2+ release from isolated frog or rabbit sarcoplasmic reticulum vesicles appears to consist of two distinct components: 1) a direct activation of ruthenium red-sensitive Ca2+ release channels in terminal cisternae and 2) an increased ruthenium red-insensitive Ca2+ efflux through some other efflux pathway distributed throughout the sarcoplasmic reticulum. The first of these releases exhibits an alkalinization-induced inactivation process and does not depend on the ruthenium red-insensitive form of Ca2+ release as a triggering agent for secondary Ca(2+)-induced Ca2+ release. Both releases are inhibited when the extravesicular (i.e. cytoplasmic) free [Ca2+] is reduced. This may reflect an increased sensitivity of the Ca2+ release channels to Ca2+ at alkaline pH. The pH sensitivity of the ruthenium red-sensitive Ca2+ release channels could be of significance during excitation-contraction coupling. The ruthenium red-insensitive form of Ca2+ release is less likely to be physiologically relevant, but it probably has contributed greatly to reports of alkalinization-induced decreases in net sarcoplasmic reticulum Ca2+ uptake, particularly under conditions where oxalate supported Ca2+ uptake is much less affected, as here.     

Characterization of the phosphoenzyme that is involved in the Ca2+ -Ca2+ exchange catalyzed by the Ca2+ -ATPase of sarcoplasmic reticulum vesicles

The rate of Ca2+ efflux was determined with 45Ca2+ -loaded sarcoplasmic reticulum vesicles (mainly with the light fraction of vesicles) at pH 6.5 and 0 degrees C. The efflux depended on external Ca2+, Mg2+, ATP and ADP, but it was not activated by AMP. The results indicate that the efflux is derived from Ca2+ -Ca2+ exchange mediated by the phosphoenzyme (EP) of membrane-bound Ca2+ -ATPase. EP was formed with Ca2+ -loaded vesicles (light fraction) under similar conditions without added ADP. The subsequent addition of EGTA and ADP induced triphasic EP dephosphorylation. Three species of EP (EP1, EP2, and EP3) were distinguished on the basis of this dephosphorylation kinetics, EP1, EP2, and EP3, corresponding to the first, second, and third phases of the dephosphorylation. Dephosphorylation of EP1 and EP2 resulted in stoichiometric ATP formation, while dephosphorylation of EP3 led to stoichiometric Pi liberation. The rate of Ca2+ efflux was compatible with that of EP2 dephosphorylation, whereas it was much lower than the rate of EP1 dephosphorylation and much higher than the rate of EP3 dephosphorylation. The intravesicular Ca2+ concentration dependence of the rate of EP2 dephosphorylation agreed with that of the rate of Ca2+ efflux. The results suggest that isomerization between EP1 and EP2 is the rate-limiting process in the Ca2+ -Ca2+ exchange and that EP3 is not involved in this exchange.     

Effects of adenosine diphosphate on Ca2+ fluxes and Ca2+ accumulation of sarcoplasmic reticulum

Ca2+ transport by sarcoplasmic reticulum vesicles was examined by incubating sarcoplasmic reticulum vesicles (0.15 mg/ml) at 37 degrees C in, either normal medium that contained 0.15 M sucrose, 0.1 M KCl, 60 microM CaCl2, 2.5 mM ATP and 30 mM Tes at pH 6.8, or a modified medium for elimination of ADP formed from ATP hydrolysis by including, in addition, 3.6 mM phosphocreatine and 33 U/ml of creatine phosphokinase. In normal medium, Ca2+ uptake of sarcoplasmic reticulum vesicles reached a plateau of about 100 nmol/mg. In modified medium, after this phase of Ca2+ uptake, a second phase of Ca2+ accumulation was initiated and reached a plateau of about 300 nmol/mg. The second phase of Ca2+ accumulation was accompanied by phosphate uptake and could be inhibited by ADP. Since, under these experimental conditions, there was no significant difference of the rates of ATP hydrolysis in normal medium and modified medium, extra Ca2+ uptake in modified medium but not in normal medium could not be explained by different phosphate accumulation in the two media. Unidirectional Ca2+ influx of sarcoplasmic reticulum near steady state of Ca2+ uptake was measured by pulse labeling with 45Ca2+. The Ca2+ efflux rate was then determined by subtracting the net uptake from the influx rate. At the first plateau of Ca2+ uptake in normal medium, Ca2+ influx was balanced by Ca2+ efflux with an exchange rate of 240 nmol/mg per min. This exchange rate was maintained relatively constant at the plateau phase. In modified medium, the Ca2+ exchange rate at the first plateau of Ca2+ uptake was about half of that in normal medium. When the second phase of Ca2+ uptake was initiated, both the influx and efflux rates started to increase and reached a similar exchange rate as observed in normal medium. Also, during the second phase of Ca2+ uptake, the difference between the influx and efflux rates continued to increase until the second plateau phase was approached. In conditions where the formation of ADP and inorganic phosphate was minimized by using a low concentration of sarcoplasmic (7.5 micrograms/ml) and/or using acetyl phosphate instead of ATP, the second phase of Ca2+ uptake was also observed. These data suggest that the Ca2+ load attained by sarcoplasmic reticulum vesicles during active transport is modulated by ADP accumulated from ATP hydrolysis. ADP probably exerts its effect by facilitating Ca2+ efflux, which subsequently stimulates Ca2+ exchange.     

On the sidedness of membrane phosphorylation by Pi and ATP synthesis during reversal of the Ca2+ pump of sarcoplasmic reticulum vesicles.

The membrane sidedness of Pi interaction in reactions which characterize reversal of the Ca2+ pump of sarcoplasmic reticulum vesicles isolated from rabbit skeletal muscle was investigated. Vesicles previously loaded with calcium [32P]phosphate were incubated with 0.1 mM ADP and different concentrations of nonradioactive Pi. Alternatively, vesicles loaded with nonradioactive calcium phosphate were incubated in a medium containing 32Pi. The rates of Ca2+ efflux and ATP synthesis were siginficantly activated only when Pi was included in the assay medium. Although the Pi contained by the vesicles crosses the membrane at a rate proportional to the Ca2+ efflux, [gamma-32P]ATP was synthesized only when 32Pi interacted with the outer surface of the membrane. Similarly, ATP in equilibrium 32Pi or ITP in equilibrium 32Pi exchange could be measured only when the external pool of Pi was labeled. Both for ATP synthesis and for the ITP in equilibrium Pi exchange reaction, membrane phosphorylation by 32Pi was negligible unless the external pool of Pi was labeled. The ionophore X-537 A increased the rate of Ca2+ efflux but inhibited the synthesis of ATP. During reversal of the Ca2+ pump, Pi apparently interacts with the membrane only at the outer surface, and at a site different from that where Ca2+ crosses the membrane.