Mechanism of the calcium pump in the endoplasmic reticulum of liver: phosphoproteins as reaction intermediates

Microsomal fractions, highly enriched with endoplasmic reticulum of rat and human liver exhibit Ca2+ uptake catalyzed by a Ca2+-pumping ATPase. The mechanism of Ca2+-translocation involves: (i) reversible Ca2+-dependent formation of an acyl-phosphoenzyme intermediate (Mr 116,000 to 118,000) with bound Ca2+, which in the reversed reaction can transphosphorylate its Pi to ADP to re-synthesize ATP; (ii) reversible transition of the ADP-reactive phosphoenzyme into an isomer without bound Ca2+, not further reactive to ADP; (iii) hydrolytic cleavage, stimulated by Mg2+, K+, and ATP of the ADP-unreactive phosphoenzyme with liberation of Pi. By analogy to a mechanism proposed for the Ca2+ pump of sarcoplasmic reticulum, the translocation of Ca2+ to and dissociation from the inner side of the membrane is suggested to occur by a conformational change, coupled with a decrease in Ca2+-affinity of the phosphoenzyme during its transition into the ADP-unreactive isomer. With CaATP as the effective substrate the reactions proceed normally but at a considerably slower rate.     

Ca2+-activated ATPase in microsomes from human liver

Human liver microsomal fractions exhibit ATP-supported Ca2+ uptake which is half-maximal at 7 X 10(-7) M free Ca2+ in the presence of oxalate. Ca2+ uptake is coupled to a Ca2+-stimulated ATPase activity, which is half-maximal at 4 X 10(-7) M free Ca2+. Catalysis involves formation of an Mr = 116,000 phosphoprotein with stability characteristics of an acylphosphate compound suggested to represent a phosphoryl protein intermediate of the Ca2+-ATPase. Phosphorylation is half-maximal at about 10(-6) M free Ca2+. The Mr = 116,000 protein is highly susceptible to proteolysis with trypsin. The phosphorylated active site was localized in an Mr = 58,000 primary tryptic fragment and in an Mr = 34,000 subfragment. Analyses on the mechanism of the Ca2+-ATPase suggest the following reaction sequence: formation of an ADP-reactive phosphoenzyme (Mr = 116,000) with bound Ca2+, which can transphosphorylate its Pi to ADP, giving rise to synthesis of ATP; reversible transformation of the ADP-reactive phosphoenzyme into an isomer without bound Ca2+, which cannot further react with ADP; hydrolytical cleavage, probably catalyzed by Mg2+, of the ADP-unreactive phosphoenzyme with liberation of Pi. Comparison with the Ca2+-transport ATPase in sarcoplasmic reticulum of skeletal muscle led us to suggest that the Mr = 116,000 Ca2+-ATPase belongs to the class of E1P . E2P-ATPases and might be operative as a Ca2+-transport ATPase at the level of the endoplasmic reticulum in human liver.     

Role of divalent cation bound to phosphoenzyme intermediate of sarcoplasmic reticulum ATPase

Effect of divalent cations bound to the phosphoenzyme intermediate of the ATPase of sarcoplasmic reticulum was investigated at 0 degree C and pH 7.0 using the purified ATPase preparations. Our previous study (Shigekawa, M., Wakabayashi, S., and Nakamura, H. (1983) J. Biol. Chem. 258, 14157-14161) indicated that 1 mol of the ADP-sensitive phosphoenzyme (E1P) formed from CaATP has 3 mol of high affinity binding sites for Ca2+, of which two are transport sites for calcium while the remainder is the acceptor site for calcium derived from the substrate, CaATP ("substrate site"). When incubated with a chelator of divalent cation, E1P formed from CaATP released all of its bound calcium to form a divalent cation-free phosphoenzyme. Evidence was presented that calcium dissociation from the substrate site was faster than that from the transport sites and primarily responsible for the ADP sensitivity loss of E1P induced by the chelator. Divalent cation-free phosphoenzyme was kinetically stable but when treated with divalent cations, it behaved similarly to the ADP-insensitive phosphoenzyme (E2P) which is the normal reaction intermediate of ATP hydrolysis. 45Ca bound at the substrate site on E1P formed from 45CaATP exchanged readily with nonradioactive ionized Ca2+ in the reaction medium whereas 45Ca at the transport sites on E1P was displaced only at a very slow rate which was almost the same as that for the phosphoenzyme hydrolysis. It was suggested that calcium at the transport sites on E1P formed from CaATP is released only after the rate-limiting conformational transition of the phosphoenzyme from E1P to E2P and that removal of calcium by a chelator from the substrate site facilitates this conformational transition, thereby allowing calcium bound at the transport sites to be released readily from the phosphoenzyme.     

Reaction mechanism of Ca2+-dependent adenosine triphosphatase of sarcoplasmic reticulum. ATP hydrolysis with CaATP as a substrate and role of divalent cation

ATP hydrolysis with CaATP as a substrate was characterized at 0 degrees C and pH 7.0 using purified ATPase preparations of sarcoplasmic reticulum and compared with that with MgATP as a substrate. The maximal rate of enzyme phosphorylation and the Km value for the phosphorylation were 8 to 10 times less for CaATP than for MgATP. Each substrate appeared to act as a competitive inhibitor with respect to the other in enzyme phosphorylation. The phosphoenzyme formed from CaATP turned over slowly because the conversion rate of the ADP-sensitive (E1P) to ADP-insensitive (E2P) phosphoenzyme was very slow. E2Ps, formed from both CaATP and MgATP, were similar in that KCl, MgCl2, or ATP accelerated their decomposition. Their sensitivity to KCl and/or ATP was retained even after a long incubation with excess EDTA. When the enzyme had been phosphorylated from CaATP, calcium remained bound to the enzyme even in the presence of excess EDTA. The observed parallelism between the amount and behavior of the enzyme-bound calcium and those of E2P strongly suggests that 1 mol of E2P has 1 mol of tightly bound calcium. During steady state ATP hydrolysis with CaATP as a substrate, a significant amount of the enzyme-ATP complex accumulated as a reaction intermediate because of slow dissociation of CaATP from the CaATP-enzyme complex and slow enzyme phosphorylation from the CaATP-enzyme complex. These results indicate that Mg2+ is not essential for the turnover of the calcium pump ATPase. It was proposed that the metal component of the substrate basically determines affinity of the substrate to the enzyme and the catalytic mechanism of subsequent reaction steps.     

The calcium pump of the liver nuclear membrane is identical to that of endoplasmic reticulum.

The envelope membrane of rat liver nuclei contains a P-type Ca(2+)-transporting pump, revealed by the presence of a Ca(2+)-stimulated phosphoenzyme. The level of the nuclear phosphoenzyme in autoradiographed polyacrylamide gels was decreased by lanthanum, as typically observed in the endoplasmic reticulum Ca2+ pump. It was also decreased by thapsigargin and 2,5-di-(tert-butyl)-1,4-benzohydroquinone, two accepted inhibitors of the endoplasmic reticulum Ca(2+)-ATPase. Comparative proteolysis of the phosphorylated enzyme of liver microsomes (endoplasmic reticulum) and nuclear membranes revealed an identical cleavage pattern. In addition, antibodies raised against the endoplasmic reticulum Ca2+ pump cross-reacted with the pump in the nuclear membranes. The findings show that nuclear membranes contain a Ca(2+)-transporting pump closely related to that of the endoplasmic reticulum, if not identical to it. The pump is likely to be involved in the control of nuclear free calcium.     

Functional consequences of mutations in the beta-strand sector of the Ca2(+)-ATPase of sarcoplasmic reticulum

Kinetic studies of the phosphoenzyme intermediates of site-specific mutants were used to examine the role of Gly233 in the reaction mechanism of the sarcoplasmic reticulum Ca2(+)-ATPase. When this glycine residue, which is highly conserved among cation-transporting ATPases, was replaced by valine, arginine, or glutamic acid, a complete loss of the ability to pump Ca2+ was observed. The mutant enzymes were able to form an ADP-sensitive phosphoenzyme intermediate (E1P) by reaction with ATP in the presence of Ca2+, but this intermediate decayed to the ADP-insensitive form (E2P) very slowly, relative to the wild-type enzyme. The mutant phosphoenzyme intermediate remained ADP-sensitive, even when phosphorylation from ATP was performed under conditions which permitted accumulation of the ADP-insensitive phosphoenzyme intermediate in the wild type. The mutants were also defective in their ability to form the ADP-insensitive phosphoenzyme intermediate by phosphorylation from inorganic phosphate. In addition, they displayed a higher affinity for Ca2+ and a lower cooperativity in Ca2+ binding than did the wild-type enzyme, as measured through the phosphorylation reaction with ATP. These findings can be rationalized either in terms of a parallel shift of E1 to E2 and E1P to E2P conformational equilibria toward the E1 and E1P forms, respectively, or in terms of destabilization of the phosphoryl-protein interaction in the E2P form. The roles of 7 other residues located in the vicinity of Gly233 were also examined by mutation. Although the side chains of these residues are potential Ca2+ ligands, their replacement did not affect the Ca2+ affinity of the enzyme, suggesting the lack of a role of this region of the peptide in formation of Ca2(+)-binding sites.     

Acetyl phosphate as a substrate for the calcium ATPase of sarcoplasmic reticulum

Acetyl phosphate is hydrolyzed by the calcium ATPase of leaky sarcoplasmic reticulum vesicles from rabbit skeletal muscle with Km = 6.5 mM and kcat = 7.9 s-1 in the presence of 100 microM calcium (180 mM K+, 5 mM MgSO4, pH 7.0, 25 degrees C). In the absence of calcium, hydrolysis is 6% of the calcium-dependent rate at low and 24% at saturating concentrations of acetyl phosphate. Values of K0.5 for calcium are 3.5 and 2.2 microM (n = 1.6) in the presence of 1 and 50 mM acetyl phosphate, respectively; inhibition by calcium follows K0.5 = 1.6 mM (n approximately 1.1) with 50 mM acetyl phosphate and K0.5 = 0.5 mM (n approximately 1.3) with 1.5 mM ATP. The calcium-dependent rate of phosphoenzyme formation from acetyl phosphate is consistent with Km = 43 mM and kf = 32 s-1 at saturation; decomposition of the phosphoenzyme occurs with kt = 16 s-1. The maximum fraction of phosphoenzyme formed in the steady state at saturating acetyl phosphate concentrations is 43-46%. These results are consistent with kc congruent to 30 s-1 for binding of Ca2+ to E at saturating [Ca2+], to give cE.Ca2, in the absence of activation by ATP. Phosphoenzyme formed from ATP and from acetyl phosphate shows the same biphasic reaction with ADP, rate constants for decomposition that are the same within experimental error, and similar or identical activation of decomposition by ATP. It is concluded that the reaction pathways for acetyl phosphate and ATP in the presence of Ca2+ are the same, with the exception of calcium binding and phosphorylation; an alternative, faster route that avoids the kc step is available in the presence of ATP. The existence of three different regions of dependence on ATP concentration for steady state turnover is confirmed; activation of hydrolysis at high ATP concentrations involves an ATP-induced increase in kt.     

Roles of phosphorylation and nucleotide binding domains in calcium transport by sarcoplasmic reticulum adenosinetriphosphatase

The roles of the phosphorylation (phosphorylated enzyme intermediate) and nucleotide binding domains in calcium transport were studied by comparing acetyl phosphate and ATP as substrates for the Ca2+-ATPase of sarcoplasmic reticulum vesicles. We found that the maximal level of phosphoenzyme obtained with either substrate is approximately 4 nmol/mg of protein, corresponding to the stoichiometry of catalytic sites in our preparation. The initial burst of phosphoenzyme formation observed in the transient state, following addition of either substrate, is accompanied by internalization of 2 mol of calcium per mole of phosphoenzyme. The internalized calcium is then translocated with a sequential pattern, independent of the substrate used. Following a rate-limiting step, the phosphoenzyme undergoes hydrolytic cleavage and proceeds to the steady-state activity which is soon "back inhibited" by the rise of Ca2+ concentration in the lumen of the vesicles. When the "back inhibition" is released by the addition of oxalate, substrate utilization and calcium transport occur with a ratio of 1:2, independent of the substrate and its concentration. When the nucleotide binding site is derivatized with FITP, the enzyme can still utilize acetyl phosphate (but not ATP) for calcium transport. No secondary activation of acetyl phosphate utilization by the FITC-enzyme was obtained with millimolar nucleotide. These observations demonstrate that the basic coupling mechanism of catalysis and calcium transport involves the phosphorylation and calcium binding domains, and not the nucleotide binding domain.(ABSTRACT TRUNCATED AT 250 WORDS)     

Phosphorylation and dephosphorylation reactions of the red beet plasma membrane ATPase studied in the transient state

The reaction mechanism of the solubilized red beet (Beta vulgaris L.) plasma membrane ATPase was studied with a rapid quenching apparatus. Using a dual-labeled substrate ([γ-³²P]ATP and [5′,8-³H]ATP), the presteady-state time course of phosphoenzyme formation, phosphate liberation and ADP liberation was examined. The time course for both phosphoenzyme formation and ADP liberation showed a rapid, initial rise while the timecourse for phosphate liberation showed an initial lag. This indicated that ADP was released with formation of the phosphoenzyme while phosphate was released with phosphoenzyme breakdown. Phosphoenzyme formation was Mg²⁺-dependent and preincubation of the enzyme with free ATP followed by the addition of Mg²⁺ increased the rate of phosphoenzyme formation 2.3-fold. This implied that phosphoenzyme formation could result from a slow reaction of ATP binding followed by a more rapid reaction of phosphate group transfer. Phosphoenzyme formation was accelerated as the pH was decreased, and the relationship between pH and the apparent first-order rate constants for phosphoenzyme formation suggested the role of a histidyl residue in this process. Transient kinetics of phosphoenzyme breakdown confirmed the presence of two phosphoenzyme forms, and the discharge of the ADP-sensitive form by ADP correlated with ATP synthesis. Potassium chloride increased the rate of phosphoenzyme turnover and shifted the steady-state distribution of phosphoenzyme forms. From these results, a minimal catalytic mechanism is proposed for the red beet plasma membrane ATPase, and rate constants for several reaction steps are estimated.     

Sequential mechanism of calcium binding and translocation in sarcoplasmic reticulum adenosine triphosphatase

Cooperative calcium binding (apparent Kd = 1.04 X 10(-6) M) to the ATPase of sarcoplasmic reticulum vesicles occurs with a maximal stoichiometry of 2 mols of divalent cation/mol of enzyme in the absence of ATP. The bound calcium is distributed into two pools which undergo fast or slow isotopic exchange, respectively. The two pools retain a 1:1 molar ratio under various conditions and are both located within a protein crevice, as suggested by their cooperative interaction and exchange kinetics. Following enzyme phosphorylation by ATP, both pools of bound calcium are "internalized" (cannot be displaced by quench reagents). If following 45Ca2+ binding, isotopic dilution is obtained in the medium by adding 40Ca2+ with ATP, internalization of both pools of bound 45Ca2+ (2 mol/mol of phosphoenzyme) is still observed within the first enzyme cycle. When the cycle is reversed by addition of excess ADP soon after ATP, only half of the internalized 45Ca2+ is released from the enzyme into the medium outside the vesicles, while the other half remains with the vesicles. If half of the bound 45Ca2+ is exchanged (fast exchange) with 40Ca2+ previous to the addition of ATP, none of the remaining 45Ca2+ is released outside the vesicles upon reversal of the enzyme cycle. Therefore, the pool of bound calcium which undergoes slower exchange with the outside medium, is the first to be released inside the vesicles upon enzyme phosphorylation. A sequential mechanism of calcium binding and translocation is proposed, that accounts for binding cooperativity and exchange kinetics, presteady state transients following addition of ATP, and the Ca2+ concentration dependence of ATPase activity in steady state.     

Interactions of phosphate groups of ATP and Aspartyl phosphate with the sarcoplasmic reticulum Ca2+-ATPase: an FTIR study

Phosphate binding to the sarcoplasmic reticulum Ca2+-ATPase was studied by time-resolved Fourier transform infrared spectroscopy with ATP and isotopically labeled ATP ([beta-18O2, betagamma-18O]ATP and [gamma-18O3]ATP). Isotopic substitution identified several bands that can be assigned to phosphate groups of bound ATP: bands at 1260, 1207, 1145, 1110, and 1085 cm(-1) are affected by labeling of the beta-phosphate, bands likely near 1154, and 1098-1089 cm(-1) are affected by gamma-phosphate labeling. The findings indicate that the strength of interactions of beta- and gamma- phosphate with the protein are similar to those in aqueous solution. Two bands, at 1175 and 1113 cm(-1), were identified for the phosphate group of the ADP-sensitive phosphoenzyme Ca2E1P. They indicate terminal and bridging P-O bond strengths that are intermediate between those of ADP-insensitive phosphoenzyme E2P and the model compound acetyl phosphate in water. The bridging bond of Ca2E1P is weaker than for acetyl phosphate, which will facilitate phosphate transfer to ADP, but is stronger than for E2P, which will make the Ca2E1P phosphate less susceptible to attack by water.     

Phosphoenzymes formed from Mg.ATP and Ca.ATP during pre-steady state kinetics of sarcoplasmic reticulum ATPase

We have investigated here the pre-steady state kinetics of sarcoplasmic reticulum ATPase incubated under conditions where significant amounts of Mg.ATP and Ca.ATP coexist, both of them being substrates for the ATPase. We confirmed that these two substrates are independently hydrolyzed by the ATPase, which thus apparently catalyzes Pi production by two simultaneous and separate pathways. External calcium (or the Ca2+/Mg2+ ratio) determines the extent to which Ca2+ or Mg2+ is bound at the phosphorylation site, while internal calcium controls the rate of processing of both the slow, calcium-containing and the fast, magnesium-containing phosphoenzyme. Time-dependent binding of calcium at the catalytic site is correlated with the observed burst of Pi liberation, which therefore results from reequilibration during pre-steady state of magnesium- and calcium-containing phosphoenzyme pools. Independently of direct exchange of metal at the catalytic site, ADP produced by the hydrolysis reaction contributes to reequilibration of these pools through reversal of phosphorylation by the ATP-ADP exchange pathway.     

Slow dissociation of ATP from the calcium ATPase

The acyl-phosphate intermediate of the sarcoplasmic reticulum calcium ATPase reaction, formed in a brief incubation of vesicular enzyme with 5 microM [gamma-32P]ATP and calcium, reacts biphasically with added ADP (pH 7.0, 25 degrees C, 100 mM KCl, 5 mM MgSO4). Both the burst size and the rate constant for the slow phase increase with increasing ADP concentration in the way that is expected if the burst represents very rapid formation of an equilibrium amount of enzyme-bound ATP and the slow phase represents rate-limiting dissociation of ATP. Also consistent with this interpretation are the slow labeling of phosphoenzyme under conditions in which unlabeled ATP must dissociate first and the observation of a burst of ATP formation on ADP addition to phosphoenzyme. Values of the equilibrium constants for ADP dissociation from phosphoenzyme (0.75 mM), for ATP formation on the enzyme (2.3), and for the ATP dissociation rate constant (37 s-1) were obtained from a quantitative analysis of the data.     

Effect of divalent cation bound to the ATPase of sarcoplasmic reticulum. Activation of phosphoenzyme hydrolysis by Mg2+

In order to study the mechanism for activation of ATP hydrolysis by Mg2+, the stoichiometry of the high affinity calcium-binding sites with respect to each form of reaction intermediate of sarcoplasmic reticulum ATPase was determined at 0 degrees C and pH 7.0 in the presence and absence of added Mg2+ using the purified ATPase preparation. High affinity calcium binding to the enzyme-ATP complex and to ADP-sensitive (E1P) and ADP-insensitive (E2P) phosphoenzymes occurred with stoichiometric ratios of 2, 2, and 0, and 3, 3, and 1 in the presence and absence of added Mg2+, respectively. The results were interpreted to indicate that in addition to 2 mol of calcium bound to the transport sites of the ATPase, 1 mol of divalent cation, which is derived from the metal component of the substrate, the metal-ATP complex, remains bound to each mole of the enzyme at least until E2P is hydrolyzed. As activation of phosphoenzyme hydrolysis by Mg2+ was blocked by the low concentrations of Ca2+ used in the calcium binding experiments, it was concluded that it is the magnesium derived from MgATP that is responsible for rapid hydrolysis of the phosphoenzyme intermediate.     

Environmental cadmium is not sequestered by metallothionein in rainbow trout

Smooth endoplasmic reticulum vesicles from rat liver display an ATP-supported Ca²⁺ transport which is mediated by a (Ca²⁺ + Mg²⁺)-ATPase. During the catalytic cycle the terminal phosphate from ATP is incorporated to form an acid-precipitable reaction product(118 000-M_r in SDS-gel electrophoresis) with stability characteristics of an acylphosphate. Comparative studies with sarcoplasmic reticulum vesicles from fast-twitch skeletal muscle suggest that the 118 000-M_r phosphopeptide may be identified with the phosphorylated reaction intermediate of a Ca²⁺ transport ATPase in endoplasmic reticulum, similar to that in sarcoplasmic reticulum of muscle.     

Isolation and characterization of 6-phosphofructo-2-kinase/fructose-2,6-bisphosphatase from bovine liver

6-Phosphofructo-2-kinase and fructose-2,6-bisphosphatase activities were copurified to homogeneity from bovine liver. The purification scheme consisted of polyethylene glycol precipitation, anion-exchange and Blue-Sepharose chromatography, substrate elution from phosphocellulose, and gel filtration. The bifunctional enzyme had an apparent molecular weight of 102,000 and consisted of two subunits (Mr 49,000). The kinase had a Km for ATP of 12 microM and a S0.5 for fructose 6-phosphate of 150 microM while the bisphosphatase had a Km for fructose 2,6-bisphosphate of 7 microM. Both activities were subject to modulation by various effectors. Inorganic phosphate stimulated both activities, while alpha-glycerolphosphate inhibited the kinase and stimulated the bisphosphatase. The pH optimum for the 6-phosphofructo-2-kinase activity was 8.5, while the fructose-2,6-bisphosphatase reaction was maximal at pH 6.5. Incubation of the purified enzyme with [gamma-32P]ATP and the catalytic subunit of the cAMP-dependent protein kinase resulted in 32P incorporation to the extent of 0.7 mol/mol enzyme subunit with concomitant inhibition of the kinase activity and activation of the bisphosphatase activity. The mediation of the bisphosphatase reaction by a phosphoenzyme intermediate was suggested by the isolation of a stable labeled phosphoenzyme when the enzyme was incubated with fructose 2,6-[2-32P]bisphosphate. The pH dependence of hydrolysis of the phospho group suggested that it was linked to the N3 of a histidyl residue. The 6-phosphofructo-2-kinase/fructose-2,6-bisphosphatase from bovine liver has properties essentially identical to those of the rat liver enzyme, suggesting that hepatic fructose 2,6-bisphosphate metabolism is under the same control in both species.     

Functional characterization of reconstituted sarcoplasmic reticulum vesicles

A detailed functional characterization of reconstituted sarcoplasmic reticulum (SR) vesicles with similar lipid content as normal SR was obtained by studies of ATPase activity and calcium transport in transient state, steady state, and equilibrium conditions. For this purpose, enzyme phosphorylation with ATP, hydrolytic activity, calcium transport, phosphorylation with Pi, and ATP synthesis by reversal of the pump were measured, and utilized to demonstrate function and orientation of catalytic sites. The preparations used in these studies displayed the highest activity reported for reconstituted sarcoplasmic reticulum systems. The rates of phosphoenzyme formation from ATP and hydrolysis as well as steady state levels matched the values obtained with normal SR vesicles. Calcium transport and repeated cycles of ATP synthesis by reversal of the pump were also obtained. However, the efficiency of transport and ATP synthesis from a Ca2+ gradient was approximately three times lower than in native vesicles. This deficiency could not be attributed to passive calcium leak from the reconstituted vesicles but, in part, can be explained by the bidirectional alignment of the calcium pump in reconstituted SR. It is suggested that vectorial transport requires a more complex level of protein structure than that for sustaining simple ATPase activity. Time resolution of the phosphorylation reaction by rapid quench methods can be used to estimate the orientation of the calcium pump in the membrane. Such studies indicate that the calcium pump protein is largely bidirectionally oriented in reconstituted SR vesicles.     

Factors influencing calcium release from the ADP-sensitive phosphoenzyme intermediate of the sarcoplasmic reticulum ATPase

Calcium release from the ADP-sensitive phosphoenzyme intermediate of the sarcoplasmic reticulum ATPase was investigated at 6 degrees C under a variety of conditions using the purified ATPase protein and the rapid membrane filtration system. The rate of calcium release measured in the presence of [ethylene bis-(oxyethylenenitrilo)]tetraacetic acid increased monotonically with increasing pH of the medium, the time at which 50% of the bound calcium was released being reduced to one third when the pH was raised from 5.5 to 9.0. Dimethyl sulfoxide at 10 or 20% (v/v) also was very effective in accelerating the calcium release. ATP at a millimolar concentration range also was stimulatory, but millimolar concentrations of Mg2+ were found to be inhibitory. Using an indirect method, i.e. by measuring the overall rate of calcium transport by the reconstituted vesicles under conditions where calcium release from the ADP-sensitive phosphoenzyme was presumably rate-limiting, the calcium release was shown to be accelerated up to 1.5-fold by the inside-negative potential imposed across the membrane using the K+-valinomycin system. As evidence was presented suggesting that the observed calcium release primarily reflects the phosphoenzyme isomerization which leads to reduction in calcium affinity of the phosphoenzyme, the results strongly suggest that this phosphoenzyme isomerization was affected significantly by each of the factors described above.     

Rate of calcium release and ATP synthesis in sarcoplasmic reticulum vesicles

Sarcoplasmic reticulum vesicles can catalyze the synthesis of ATP coupled to the efflux of calcium. The rate of this reaction is much faster when the vesicles are loaded in a medium containing phosphate than when oxalate is the precipitating agent. Two components of ATP synthesis can be observed when vesicles loaded with calcium phosphate are used. In the millisecond range and when the loaded vesicles are phosphorylated by Pi, the addition of ADP leads to an initial burst of ATP synthesis and after 50 ms approximately 3.0 nmol of ATP/mg protein are synthesized. This burst is not inhibited by ATP and is enhanced by physiological concentrations of KCl. The slow component of ATP synthesis is inhibited by both ATP and 100 mM KCl. In the physiological pH range, betaine, a trimethylamine present in different tissues, increases the level of phosphoenzyme formed by Pi and enhances the amount of ATP synthesized during the first turn of the reversal of the calcium pump.     

Occlusion of divalent cations in the phosphorylated calcium pump of sarcoplasmic reticulum

The calcium pump of sarcoplasmic reticulum possesses high-affinity calcium-binding and ATP-binding sites. At 0 degrees C pH 6.8 and in the absence of calcium, about 3.5 nmol/mg of high-affinity ATP-binding sites are titrated with a dissociation constant, Kd, of 5 microM. In the presence of Ca2+, ATP phosphorylates the enzyme at a much lower concentration: K 1/2 = 100 nM. In the absence of ATP the calcium ions reversibly bind to the high-affinity calcium sites (6.5 nmol/mg); however the following is shown in this paper. 1. Phosphorylation of the enzyme in the presence of calcium leads to the immediate occlusion of the calcium ions bound to the high-affinity sites. 2. Two moles of calcium are occluded per mole of phosphoenzyme formed. 3. Occlusion can be reversed by ADP. 4. Transport is a slower process which occurs in the presence of Mg2+ at the same rate as the spontaneous decay of the phosphoenzyme. Experiments performed in the absence of magnesium reveal another divalent cation binding site which is probably directly involved in ATP and Pi binding. The nature of the cation bound to this site determines the stability and ADP-sensitivity of the phosphoenzyme.