Sarcoplasmic Reticulum Ca Pump Research Articles

Contractile arrest increases sarcoplasmic reticulum calcium uptake and SERCA2 gene expression in cultured neonatal rat heart cells.

We developed protocols with intact cultured neonatal rat myocytes to directly evaluate the function of the sarcoplasmic reticulum (SR) Ca-ATPase (or SERCA2), Na-Ca exchange (Na-CaX), and slow Ca transport systems (mitochondria and sarcolemmal Ca-ATPase). Spontaneously beating control cells were compared with cells cultured for 2 days in the presence of verapamil (verapamil-arrested cells, VA). Intracellular calcium (Cai) transients were measured by use of indo-1 during (1) spontaneous twitches, (2) contractures induced by rapid application of caffeine (CafC, with and without Nao), and (3) twitches induced by brief depolarizations with high [K]o solution (K-twitches). We also measured mRNA levels for the SR Ca-ATPase and Na-CaX in the same experimental preparations. The t1/2 for [Ca]i decline when both the SR Ca uptake and Na-CaX were prevented was the same for control and VA cells (approximately 20 seconds), indicating unaltered slow Ca transport systems. Similarly, there was no significant difference in the t1/2 of CafC when Na-CaX was the main mechanism responsible for [Ca]i decline (t1/2 approximately 1.5 seconds), indicating unaltered Na-CaX. Conversely, we found nearly a twofold increase in the rate of [Ca]i decline during K-twitches (control t1/2, 0.84 +/- 0.05 seconds; VA t1/2, 0.48 +/- 0.06 second; P < .001), indicating an increase in SR Ca-pumping activity in VA cells. This was also reflected by a 56% increase in the peak [Ca]i reached during CafC used to assess maximal SR Ca content (427 +/- 49 nmol/L in control versus 665 +/- 75 nmol/L in VA cells).(ABSTRACT TRUNCATED AT 250 WORDS)

Compensatory downregulation of myocardial Ca channel in SR from dogs with heart failure

In this study we tested the hypothesis that the ryanodine-binding Ca-release channel activity and density of the sarcoplasmic reticulum (SR) terminal cisternae were decreased in congestive heart failure (CHF) that occurs spontaneously in doberman pinschers or experimentally with rapid ventricular pacing of mongrels. We used a novel, sensitive, and easy-to-perform microassay and demonstrated a 50% decrease in activity of the myocardial SR Ca pump and a 75% reduction in SR Ca-release channel activity in CHF. Decreases in Ca channel content were associated with increases in net Ca sequestration. 45Ca-release experiments from passively loaded SR terminal cisternae and ryanodine-binding studies confirmed a 53-68% downregulation of the Ca-release channel activity. As a consequence of release channel downregulation, there was partial restoration of net Ca sequestration activity in dogs with CHF and complete compensation in dogs with mild cardiac dysfunction. Deterioration of Ca cycling correlated with deterioration of myocardial performance, apparently due to decreased Ca-adenosinetriphosphatase (ATPase) pump and not Ca channel content. One-half the reduction in Ca-release activity could be attributed to decreased Ca sequestration and one-half to decreased Ca channel density. Downregulation of Ca channel content decreases the amplitude of the Ca cycle and maximizes the downregulation of Ca pumps that may occur. Although these adaptations may reduce cellular energy expenditure, they are likely to render the myocardium more susceptible to fatigue and failure.

Physiological functions of endoplasmic and sarcoplasmic reticulum Ca pump and pharmacology of inhibitors of the pump

This review is derived from the symposium held at the 66th Annual Meeting of the Japanese Pharmacological Society (March, 1993). The symposium consisted of six invited papers whose general theme was the application of recently found ATPase inhibitors selective to SR- and ER-Ca(2+)-ATPase to the analyses of the physiological and pharmacological roles of endoplasmic and sarcoplasmic reticulum Ca stores. Inhibitors used were: thapsigargin, cyclopiazonic acid, 2,5-di-(t-butyl)-1,4-benzohydroquinone and 3',3",5',5"-tetraiodosulfophthalein. Gingerol was found to facilitate the action of the ATPase. In either smooth, cardiac or skeletal muscle, sympathetic neurons or several cell lines these inhibitors affected a variety of cell functions and conditions such as contraction, ionic conductance and excitability of the plasma membrane, regulation of intracellular free Ca2+ concentration, transport of viral glycoprotein to the cell surface. Many of these studies utilized either single or cultured cell preparations or skinned muscle. These inhibitors were shown to be useful tools for investigating the SR and ER functioning as Ca sources or Ca sequestrating pumps, and further for estimating the contribution of ER or SR to regulating the flux of Ca2+ and other ions through the plasma membrane. Results of analyses using these inhibitors are discussed.

Abundance of heteronuclear and messenger RNA for internal Ca pump in stomach smooth muscle and myocardium

The sarcoplasmic reticulum Ca pump gene SERCA2 is alternatively spliced to express mRNA encoding the protein SERCA2a in heart and SERCA2b in stomach smooth muscle. The expression of SERCA2 protein in heart is 70±10 fold that in stomach smooth muscle. To understand the mechanism underlying this tissue difference in the expression level, a comparison is made of their mRNA and heteronuclear RNA (hn-RNA) contents. A 72 bp intron present in the gene encoding SERCA2 a b was cloned and sequenced. By reverse transcription of total RNA followed by PCR using primers based on the sequence of this intron and the cDNA sequences flanking it, a value of 0.37 ± 0.03 was obtained for the ratio heart hn-RNA mRNA :stomach hn-RNA mRNA . Similarly, a ratio of 3.4 ± 0.5 was obtained for heart:stomach mRNA 28S values. This value was slightly lower but statistically similar to a value of 5.7 ± 1.8 obtained for the heart:stomach mRNA poly A + RNA obtained by Northern blot analysis using a conserved region SERCA2 cDNA probe. Based on mRNA 28S ratio of 3.4 ± 0.5 and hn mRNA ratio of 0.37 ± 0.03, the ratio of heart:stomach for hn-RNA 28S was 1.2 ± 0.2. Thus, heart which expresses SERCA2a contains 70 ± 10 times more protein, 3.4 ± 0.5 times more mRNA and only 1.2 ± 0.2 times more hn-RNA for this message than the stomach smooth muscle which expresses SERCA2b.

Increased leakage of calcium ion from the sarcoplasmic reticulum of the mdx mouse

Using a single skinned muscle fiber, the function of the contractile system and the sarcoplasmic reticulum (SR) were analyzed in the skeletal muscle of the mdx mouse. Activation of the contractile system by calcium ion and the maximum force generation was normal. Ca 2+ uptake of the SR was normal as well as regulation of the Ca-induced Ca release (CICR) by Ca 2+. However, contracture by caffeine was more prominent in mdx than in control mice. Ca 2+ leaked more from the SR of mdx in the presence of EGTA and ATP or its analogue. These abnormalities are probably interrelated; increased leakage of Ca 2+ might cause the enhanced response to caffeine, since Ca 2+ itself facilitates Ca release by caffeine. The abnormal leakage of Ca 2+ might also activate the Ca pump of SR in the resting state, which consume extra ATP and disturb energy metabolism.

Ca2+ movement in smooth muscle cells studied with one- and two-dimensional diffusion models

Although many of the processes involved in the regulation of Ca2+ in smooth muscle have been studied separately, it is still not well known how they are integrated into an overall regulatory system. To examine this question and to study the time course and spatial distribution of Ca2+ in cells after activation, one- and two-dimensional diffusion models of the cell that included the major processes thought to be involved in Ca regulation were developed. The models included terms describing Ca influx, buffering, plasma membrane extrusion, and release and reuptake by the sarcoplasmic reticulum. When possible these processes were described with known parameters. Simulations with the models indicated that the sarcoplasmic reticulum Ca pump is probably primarily responsible for the removal of cytoplasmic Ca2+ after cell activation. The plasma membrane Ca-ATPase and Na/Ca exchange appeared more likely to be involved in the long term regulation of Ca2+. Pumping processes in general had little influence on the rate of rise of Ca transients. The models also showed that spatial inhomogeneities in Ca2+ probably occur in cells during the spread of the Ca signal following activation and during the subsequent return of Ca2+ to its resting level.

Ca regulation in cardiac muscle

Contraction in cardiac muscle is activated by a combination of Ca influx via sarcolemmal Ca channels and release of Ca from the sarcoplasmic reticulum (SR). The release of Ca from the SR appears to be triggered by Ca influx via a Ca-induced Ca-release mechanism. The amount of Ca influx and Ca released from the SR vary with conditions and with different cardiac muscle preparations. In contrast to the Ca-induced Ca-release process in cardiac muscle, excitation-contraction coupling in skeletal muscle appears to be via a more direct coupling between sarcolemmal voltage sensors and the Ca release (sometimes referred to as depolarization-induced Ca-release). During cardiac relaxation Ca is removed from the cytoplasm by the SR Ca-pump and the sarcolemmal Na/Ca exchange (with the former being somewhat more dominant). Ca extrusion from the cell during both relaxation and diastole is predominantly via Na/Ca exchange, with the sarcolemmal Ca ATPase pump contributing very little. Thus, sarcolemmal Na/Ca exchange appears to be critically involved in the overall regulation of cardiac cellular Ca content.

Molecular mechanism of calcium uptake and release by cardiac sarcoplasmic reticulum.

Cardiac sarcoplasmic reticulum (SR) plays a special role in controlling free calcium ions (Ca) in heart muscle cells. Ca stored in the SR is released through the Ca release channels when the sarcolemmal membrane is depolarized, thereby inducing contraction, while Ca is reaccumulated by the Ca pump to induce relaxation. In the latter process, the Ca pump of cardiac SR has a regulatory system by cAMP-dependent phosphorylation of a SR protein, phospholamban. Recently, significant progress has been achieved in understanding the molecular mechanisms of Ca release and uptake and its regulation. The structures of the Ca pump and phospholamban have been defined at molecular levels. A direct interaction between these two proteins was demonstrated. The Ca release channel was identified, and turned out to be the foot structure which in situ connects the SR to the sarcolemma/transverse tubule.

Biochemical characteristics of free and junctional sarcoplasmic reticulum and of transverse tubules in human skeletal muscle

The microsomal fraction of normal human skeletal muscle was subfractionated by isopycnic sucrose-density centrifugation, using the procedure originally described by Saito et al. for rabbit fast muscle, and specific markers of the junctional face membrane of terminal cisternae (TC) (ryanodine receptor, high-molecular-weight feet proteins and membrane-associated calcium-binding protein calsequestrin), of the sarcoplasmic reticulum (SR) Ca-pump membrane (chicken antibody to rabbit Ca-ATPase), and of transverse tubules (TT) (dihydropiridine receptor, membrane cholesterol), respectively. The results show that isolated TC from human skeletal muscle share extensive morphological characteristics, protein composition, as well as Ca-release properties with rabbit TC, as tested with an inhibitor (Ruthenium red) and an activator (doxorubicin) of SR Ca-release. The Ca-pump membrane of human muscle SR, in distinction to rabbit fast muscle SR, showed a relatively low specific activity of the Ca-ATPase, as expected from the mixed fiber composition of human muscles, but shared the presence of minor protein components, such as a Con A binding protein of about 57 kDa and blue-staining peptides in the 170-120 kDa range of molecular weights. Human muscle TT, as isolated from the same sucrose gradient, demonstrated a high affinity (3H)-dihydropiridine binding activity in the range of previously reported values for purified TT from rabbit skeletal muscle.

Mitosis in sand dollar embryos is inhibited by antibodies directed against the calcium transport enzyme of muscle.

Monospecific antibodies to the calcium transport enzyme (alpha-Ca pump) inhibit mitosis when microinjected into sand dollar embryos. Immunoglobulins were raised against the calcium transport enzyme (Ca pump) of sarcoplasmic reticulum (SR) from rat skeletal muscle and guinea pig ileum smooth muscle. Specific antibodies were further isolated from IgG fractions by using electrophoretically purified SR Ca-pump protein as the immobilized ligand for immunoaffinity chromatography. ELISA demonstrated that common antigenic determinants are shared by SR, SR Ca pump (of rat skeletal and guinea pig ileum smooth muscle), and isolated membrane containing "native" mitotic apparatus (MA). Preimmune sera gave negative results in identical control assays. Triton X-100 extraction of MA removes the Ca-pump antigen. SR Ca pump and the MA Ca pump have nearly identical molecular masses as determined by NaDodSO4/PAGE. These alpha-SR Ca-pump IgGs inhibit ATP-dependent Ca2+ sequestration by purified SR and MA membranes. Indirect immunofluorescence of isolated native MA demonstrated coincident localization of the MA Ca pump, sequestered calcium, and membrane vesicles. Fluorescent foci were regionally concentrated within the volumes of the asters and spindle. Microinjection of the anti-Ca-pump IgGs into one of two sister blastomeres at second metaphase resulted in mitotic arrest of the injected cell accompanied by a rapid loss of spindle birefringence. Karyomeres formed and fused to form nuclei either at the site of the metaphase plate or at the position the chromosomes occupied during anaphase A. The cleavage furrow did not develop in the injected cell, while the sister and neighbor cells continued normal mitotic cycling. Injection later in mitosis yielded cells with two nuclei whose cleavage furrow relaxed completely. Routine control injections of boiled immune IgG, preimmune IgG, Wesson oil, buffer, or goat anti-rabbit IgG did not affect mitosis, birefringence of the MA, or cleavage furrow activity.

O-99 - Mechanism of activation of sarcoplasmic reticulum Ca pump by alkali metal cations

O-99 - Mechanism of activation of sarcoplasmic reticulum Ca pump by alkali metal cations

Excitation of skinned muscle fibers by imposed ion gradients. II. Influence of quercetin and ATP removal on the Ca2+-insensitive component of stimulated 45Ca efflux.

Ionic gradients imposed by choline Cl replacement of K methanesulfonate (Mes) at constant [K][Cl] product stimulate 45Ca efflux from skinned muscle fibers; a small, sustained Ca2+-insensitive efflux component, observed in EGTA, appears to grade a much larger Ca2+-dependent component responsible for contractile activation and is likely to reflect intermediate steps in excitation-contraction coupling. The present studies examined ATP-related effects on the Ca2+-insensitive stimulation. 45Ca efflux was measured on segments of frog semitendinosus muscle skinned by microdissection, with isometric force monitored continuously. The Ca2+-insensitive component was potentiated by quercetin, a flavonoid thought to inhibit the sarcoplasmic reticulum (SR) Ca pump by stabilizing a phosphorylated intermediate. Quercetin increased the stimulated net 45Ca release in the absence of EGTA, as expected from inhibition of reaccumulation, but its effectiveness in EGTA indicated potentiation of unidirectional efflux as such. Quercetin also increased unstimulated (control) 45Ca efflux in EGTA, to a smaller extent; potentiation appeared to be a function of efflux, with stimulation above control loss increased approximately 2.6-fold. ATP removal before stimulation, which led to rigor force and increased stiffness, prevented all quercetin effects in EGTA. ATP removal by itself inhibited ionic stimulation of the Ca2+-insensitive component, with little residual increase above the parallel control loss. Addition of the nonhydrolyzable ATP analogue AMP-PCP ([adenylyl-beta,gamma-methylene]diphosphate) (0.8 mM) after ATP removal gave similar results to ATP-free solution, which suggests that adenine nucleotide binding alone does not support stimulation by choline Cl. These results imply a fundamental role for ATP in the excitation of skinned fibers by imposed diffusion potentials; they also suggest that ATP regulates the SR Ca efflux channel, in a manner that could provide the positive feedback in Ca2+-dependent Ca release.

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.

Thermodynamic and kinetic cooperativity in ligand binding to multiple sites on a protein: Ca2+ activation of an ATP-driven Ca pump.

Contrary to common belief, theoretical analysis does not predict any necessary relationship between cooperativity in the equilibrium binding of an ion to multiple binding sites on a protein and cooperativity in the kinetic activation of a reaction for which such binding is prerequisite. The sarcoplasmic reticulum Ca pump protein, for example, has two high-affinity binding sites for Ca2+, here considered to be nearly identical and independent. Equilibrium binding to these sites can be highly cooperative in spite of site-independence, as demonstrated by the well-known allosteric mechanism based on Wyman's principle of linked functions. We show in this paper that kinetic activation of the pump reaction cycle by binding of Ca2+ to these same sites can likewise be a cooperative function of Ca2+ concentration but that the criteria that determine cooperativity in the two situations are different. It is possible to observe kinetic cooperativity without concomitant cooperativity in equilibrium binding and vice versa. Application of these theoretical considerations to experimental data for the pump protein raises questions about the Ca2+ binding mechanism.

Tubular aggregates: Sarcoplasmic reticulum origin, calcium storage ability, and functional implications

Muscle biopsy specimens from three patients with an autosomal dominant myopathy and tubular aggregates in both type 1 and type 2 fibers were investigated for immunofluorescent staining with antibodies to sarcoplasmic reticulum (SR) Ca-pump protein and calsequestrin and for Ca2+ loading ability. The results show that type 1 and type 2 fibers are differentially reactive to anti-Ca-pump protein IgG and similarly reactive with affinity-purified antibody to calsequestrin, which is in agreement with earlier observations in rat skeletal muscle. Tubular aggregates, which are shown to be highly reactive with either kind of antibody, appear to be sites of calcium accumulation for oxalate-facilitated adenosine triphosphate (ATP) dependent Ca uptake by chemically skinned fibers and thereby increase markedly the Ca loading capacity of the affected fibers.

Rapid reconstitution and characterization of highly-efficient sarcoplasmic reticulum Ca pump

The Ca pump was reconstituted from the purified sarcoplasmic reticulum ATPase and excess soybean phospholipids by the freeze-thaw sonication procedure in the presence of cholate. In the absence of Ca precipitating agents, the reconstituted proteoliposomes accumulated Ca 2+ at an initial rate of up to 0.7 μmol/mg per min at 25°C, and a value of 1.54 was obtained for the coupling ratio between Ca uptake and Ca 2+-dependent ATPase activities. The proteoliposomes were mainly unilamellar vesicles but were heterogeneous with respect to their size. When reconstituted at a lipid/protein ratio of 40, proteoliposomes had a buoyant density of about 1.04 and their average internal volume was 1.4–1.6 μl/mg of phospholipids. More than 95% of the ATPase was incorporated randomly into these proteoliposomes and the fraction of proteoliposomes that represented about 50% of the total intravesicular isotope space contained right-side-out oriented enzyme. 86Rb efflux from the 86Rb-loaded proteoliposomes was found to be slow even at 25°C. Therefore, the proteoliposomes prepared by the present simple method should be useful for the study of the side-specific interaction of ions such as alkali metal cations with the sarcoplasmic reticulum Ca pump.

Effect of ACTH on dehydrogenase activity of cells and tissues

During prolonged hypercholesterolemia (HCh), there was a reduction in the efficacy of Ca-pump function of the sarcoplasmic reticulum (SR) of rabbit skeletal muscles, an increase in cholesterol content, and intensification of lipid peroxidation in SR membranes. Supplementation of the cholesterol-rich diet with alpha-tocopherol effectively prevented dysfunction of the SR Ca-pump and reduced the enhanced LPO level in SR membranes without having any effect on cholesterol content in blood serum and SR membranes. The increase in the LPO level seems likely to be primarily responsible for abnormalities in the SR Ca-pump during HCh.

O2F1614) - Reconstitution of sarcoplasmic reticulum Ca pump into artificial liposomes.

O2F1614) - Reconstitution of sarcoplasmic reticulum Ca pump into artificial liposomes.

Solubilized monomeric sarcoplasmic reticulum Ca pump protein. Phosphorylation by inorganic phosphate.

Phosphorylation (by inorganic phosphate) of sarcoplasmic reticulum Ca pump protein has been studied in a detergent solution in which the protein has been previously shown to exist as a monomer. The course of the reaction is qualitatively similar to that observed for membrane-bound (possibly oligomeric) protein. In particular, the results indicate that alternation between the two principal conformational states of the Ca pump protein persists in the monomeric state, which suggests that the machinery for coupling of ATP hydrolysis to Ca2+ transport is intact. There are quantitative differences between monomeric and membrane-bound protein with respect to phosphorylation, but they are not necessarily related to the state of association.

Monomeric solubilized sarcoplasmic reticulum Ca pump protein: demonstration of Ca binding and dissociation coupled to ATP hydrolysis.

The sarcoplasmic reticulum Ca-pump protein can be solubilized in monomeric form in nonionic detergents with full retention of ATPase activity. It is impossible to prove directly that coupling between ATP hydrolysis and Ca2+ transport is maintained in the soluble state, because separate compartments for Ca2+ uptake and Ca2+ discharge are required to demonstrate this, but here we provide strong indirect evidence that coupling in fact persists, in both the forward and reverse directions of the normal pump cycle. Demonstration of coupling in the forward direction makes use of the fact that the solubilized protein is structurally labile in the absence of bound Ca2+. Loss of activity accompanying ATP hydrolysis in solution is quantitatively consistent with sequential Ca2+ binding and dissociation during the hydrolysis cycle. Coupling in the reverse direction is demonstrated by the dependence of ATP synthesis on Ca2+ concentration. Although substantial differences between solubilized (monomeric) and membrane-bound protein are shown to exist, as previously reported, they do not affect the main conclusion from this work, which is that the molecular machinery for free-energy coupling in active Ca2+ transport is an inherent property of each individual catalytic polypeptide chain of the pump protein.