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.     

Enzymatic activity of dystrophic chicken sarcoplasmic reticulum

We have isolated sarcoplasmic reticulum from normal and dystrophic chicken muscle, using an improved isolation procedure. Dystrophic sarcoplasmic reticulum has a reduced level of calcium-sensitive ATPase activity, phosphoenzyme formation, and steady-state calcium transport. Anion-stimulated calcium transport by dystrophic sarcoplasmic reticulum is also reduced when measured under the proper conditions, and dystrophic sarcoplasmic reticulum shows no alteration in calcium efflux rate. Active calcium phosphate loading of the normal and dystrophic sarcoplasmic reticulum preparations indicates that a reduced percentage jof the dystrophic vesicles are capable of active calcium transport. The loaded dystrophic sarcoplasmic reticulum vesicles exhibit the same relative reductions in enzymatic activity as the starting sarcoplasmic reticulum preparations. However, the enzyme activities of normal and dystrophic sarcoplasmic reticulum are similar in the presence of detergent and exogenous phospholipid. On the basis of these results, we suggest that the lipid microenvironment of the dystrophic enzyme is altered.     

The formation of intravesicular calcium phosphate deposits in microsomes of smooth muscle

Summary The calcium uptake in the microsomial fraction isolated from the smooth muscle of the antrum of the pig stomach is stimulated by phosphate. The microsomial vesicles which are loaded with calcium phosphate can be purified by differential centrifugation. A purification of 36 times in terms of calcium content was reached. Electron microscopy of the freshly prepared material revealed calcium phosphate deposits in the form of needles of crystalline calcium phosphate. This structure differs from that of the deposits which appear in the fragmented sarcoplasmic reticulum of skeletal muscle. Their morphology is that of non-crystalline calcium phosphate. However, on standing these deposits convert slowly into crystalline calcium phosphate. This difference reflects different kinetics of crystallization of the precipitates in the two preparations. After negative staining of the calcium phosphate loaded microsomes of skeletal and of smooth muscle, only few deposits are preserved because a release of calcium occurs as a consequence of the action of the stain and also of the dilution and warming up of the suspension. Smooth muscle microsomes partially purified by loading with calcium phosphate were studied by freeze etching and rotary replication. Membrane fragments displaying subunit intramembrane particles similar to those observed in sarcoplasmic reticulum of skeletal muscle could be identified. However, in the smooth muscle microsomes the intramembrane particles were much less densely packed. Part of these particles could correspond to calcium transport sites.     

Acetylcholinesterase in membrane fractions derived from sarcotubular system of skeletal muscle: presence of monomeric acetylcholinesterase in sarcoplasmic reticulum and transverse tubule membranes

Microsomes were isolated from white rabbit muscle and separated into several fractions by centrifugation in a discontinuous sucrose density gradient. Four membrane fractions were obtained namely surface membrane, light, intermediate and heavy sarcoplasmic reticulum. The origin of these microsomal vesicles was investigated by studying biochemical markers of sarcoplasmic reticulum and surface and T-tubular membranes. The transverse tubule derived membranes were further purified by using a discontinuous sucrose density gradient after loading contaminating light sarcoplasmic reticulum vesicles with calcium phosphate in the presence of ATP. All membrane preparations displayed acetylcholinesterase activity (AChE, EC 3.1.1.7), this being relatively more concentrated in T-tubule membranes than in those derived from sarcoplasmic reticulum. The membrane-bound AChE of unfractioned microsomes notably increased its activity by aging, treatment with detergents and low trypsin concentrations indicating that the enzyme is probably attached to the membrane in an occluded form, the unconstrained enzyme displaying higher activity than the vesicular acetylcholinesterase.Sedimentation analysis of Triton-solubilized AChE from different membrane fractions revealed enzymic multiple forms of 13.5S, 9–10S and 4.5–4.8S, the lightest form being the predominant one in all membrane preparations. Therefore, in both sarcoplasmic reticulum and T-tubule membrane the major component of AChE appears to be a membrane-bound component, probably a G₁ form.     

Immunological and biochemical properties of transverse tubule membranes isolated from rabbit skeletal muscle

A new method for isolating transverse tubule membranes from rabbit skeletal muscle has been developed. This procedure has the advantage of being mild, fast, and producing with good yields a purified membrane fraction. The transverse tubule membranes are purified by a discontinuous sucrose density centrifugation after loading contaminating light sarcoplasmic reticulum vesicles with calcium phosphate in the presence of ATP. Immunofluorescence staining of cryostat sections of rabbit psoas muscle with purified goat antibodies directed against the purified membranes shows that the reacting antigens are distributed at the boundary of the A and I bands of the myofibrils where transverse tubules are localized in mammalian muscle. The purified antibodies showed no cross-reactivity with sarcoplasmic reticulum, nor did they show any fluorescence staining of the muscle plasma membrane, indicating that the isolated membranes indeed originate from the transverse tubules. The transverse tubule fraction has a characteristic protein composition distinguishable from that of sarcoplasmic reticulum, a much higher cholesterol content than that of the crude microsomes, plasma membrane, and sarcoplasmic reticulum, and a phospholipid content about twice as high as that of sarcoplasmic reticulum and plasma membrane. The purified transverse tubule membrane has a distinct phospholipid composition with high contents of sphingomyelin and phosphatidylserine. A Mg2+-activated ATPase characteristic of the transverse tubule fraction undergoes a 20-30-fold increase in specific activity during purification. The levels of Ca2+-ATPase activity present in the purified transverse tubule fraction remain comparable to those of sarcoplasmic reticulum even after extensive removal of the latter.     

Determinants of calcium loading at steady state in sarcoplasmic reticulum

The determinants of steady-state calcium loading by sarcoplasmic reticulum vesicles were evaluated by measuring the contribution of different pathways of calcium flux to the total calcium flux at steady state. The diffusional passive pathway was least significant at all calcium loads studied. Diffusional passive calcium flux was evaluated by a number of methods which gave comparable results and support its designation as passive and diffusional. These methods included (a) flux measurements with the simple pump-leak system which pertains when acetyl phosphate is used to load the vesicles; (b) flux measurements made after quenching the pump with EGTA; (c) flux measurements made after quenching the pump with glucose plus hexokinase; and (d) evaluation of the effect of pump activity on the efflux of mannitol. The calcium efflux not accounted for by the diffusional pathway was assigned to non-diffusional pathways. Efflux through the non-diffusional pathways required ATP, ADP and extravesicular Ca2+. The ADP-dependent, phosphoenzyme-independent pathway described by Beirao and DeMeis (Biochim. Biophys. Acta (1976) 433, 520-530) was not significantly involved in efflux. We propose that the level of calcium loading achieved at steady state is determined by the levels of the intermediates of the calcium pump which are established at this pseudo-equilibrium condition, these levels being determined by the concentrations of intravesicular and extravesicular calcium ([Ca2+]i and [Ca2+]), ATP and ADP. The different levels of calcium loading achieved by skeletal and cardiac sarcoplasmic reticulum are attributed to different nucleotide and calcium kinetics in these two types of sarcoplasmic reticulum and possibly to different intravesicular volumes. Differences in diffusional permeability are not responsible for differences in calcium loading.     

Ionized and bound calcium inside isolated sarcoplasmic reticulum of skeletal muscle and its significance in phosphorylation of adenosine triphosphatase by orthophosphate.

Calcium loading of skeletal muscle sarcoplasmic reticulum performed passively by incubation with high calcium concentrations (0.5--15 mM) on ice gives calcium loads of 50--60 nmol/mg sarcoplasmic reticulum protein. This accumulated calcium is not released by EGTA [ethyleneglycol bis-(2-aminoethyl)-N,N,N',N'-tetraacetic acid], but almost completely released by ionophore X-537A plus EGTA or phospholipase A plus EGTA treatment and is therefore assumed to be inside the sarcoplasmic reticulum. This calcium is distributed in one saturable and one non-saturable calcium compartment, as derived from the dependence of the calcium load on the calcium concentration in the medium. These compartments are assigned to bound and ionized calcium inside the sarcoplasmic reticulum, respectively. Maximum calcium binding under these conditions was 33 nmol/mg protein with an apparent half-saturation constant of 5,8 nmol/mg free calcium inside, or between 1.2 and 0.6 mM free calcium inside, assuming an average vesicular water space of 5 or 10 microliter/mg protein, respectively. Calcium-dependent phosphorylation of sarcoplasmic reticulum calcium-transport ATPase from orthophosphate depends on the square of free calcium inside, whilst inhibition of phosphorylation depends on the square of free calcium in the medium. Calcium-dependent phosphorylation appears to be determined by the free calcium concentrations inside or outside allowing calcium binding to the ATPase according to the two classes of calcium binding constants for low affinity calcium binding or high affinity calcium binding, respectively. It is further suggested that the saturation of the low-affinity calcium-binding sites of the ATPase facing the inside of the sarcoplasmic reticulum membrane is responsible for the greater apparent orthophosphate and magnesium affinity in calcium-dependent phosphorylation than in calcium-independent phosphorylation from orthophosphate. Maximum calcium-dependent phosphoprotein formation at 20 degrees C and pH 7.0 is about 4 nmol/mg sarcoplasmic reticulum protein.     

Electron cytochemistry of oxalate-stimulated calcium uptake in microsomes from the smooth muscle of the pig stomach

Summary A microsomal fraction was isolated from the smooth muscle of the antrum of the pig stomach by differential centrifugation. Electron microscopy of the negatively stained material showed that this fraction is heterogeneous in composition. The microsomes accumulated calcium in the presence of ATP, magnesium and oxalate. The amount of calcium taken up per mg protein was in the same range as observed for other smooth muscle microsomal preparations. Although this amount is much smaller than that in the microsomal fraction of skeletal muscle, calcium oxalate crystals were formed in some vesicles, as occurs in the skeletal muscle fragmented sarcoplasmic reticulum. Through the presence of the calcium oxalate crystals, many of these vesicles acquired sufficient mass and density to allow them to be isolated by centrifugation. A purification of about 40 fold in terms of calcium content was reached.     

Effect of pH on calcium accumulation and release by isolated fragments of cardiac and skeletal muscle sarcoplasmic reticulum.

The ability of a sudden increase in pH to initiate a release of calcium from isolated skeletal and cardiac muscle sarcoplasmic reticulum following calcium accumulation in the absence of a precipitating anion (calcium binding) is described. In skeletal sarcoplasmic reticulum a sudden increase in pH caused a rapid release of accumulated calcium. In cardiac sarcoplasmic reticulum a sudden increase in pH before the calcium binding process was complete caused the release of a small amount of calcium at a relatively slow rate. A sudden change in pH after the completion of calcium binding failed to trigger a release of calcium. The effect of pH on oxalate supported calcium uptake and on unidirectional calcium efflux rate by cardiac sarcoplasmic reticulum was also studied. Both the rate of calcium uptake and of unidirectional calcium efflux increased as the pH was raised from 6.4 to 7.2, reflecting an increased permeability of the sarcoplasmic reticulum membrane to calcium. These results indicate that in cardiac muscle a sudden increase in pH is unlikely to be the in vivo signal for calcium release from the sarcoplasmic reticulum. However, the effect of pH on calcium uptake and efflux by cardiac sarcoplasmic reticulum may contribute to the negative inotropic effect of an acidosis on the heart.     

Characterization of cardiac sarcoplasmic reticulum ATP-ADP phosphate exchange and phosphorylation of the calcium transport adenosine triphosphatase.

1. The terminal phosphate of (gamma-32P)ATP is rapidly incorporated into cardiac sarcoplasmic reticulum membranes (0.7--1.3 mumol/g protein) in the presence of calcium and magnesium. Cardiac sarcoplasmic reticulum membranes catalize an ATP-ADP phosphate exchange in the presence of calcium and magnesium. 2. Half-maximum activation of the phosphoprotein formation and ATP-ADP phosphate exchange is reached at an ionized calcium concentration of about 0.3 muM. The Hill coefficients are 1.3. 3. Transphosphorylation and ATP-ADP phosphate exchange require magnesium and are maximally activated at magnesium concentrations close to or equal to the ATP concentration. 4. The phosphoprotein level is reduced to about 45% at an ADP/ATP ratio of 0.1. The rate of calcium-dependent ATP splitting declines, whilst the rate of the calcium-dependent ATP-ADP phosphate exchange increases when the ADP/ATP ratio is varied from 0.1 to 1. The sum of both, the rate of ATP splitting and the rate of ADP-ATP phosphate exchange remains constant. 5. Phosphoprotein formation and ATP-ADP phosphate exchange are not affected by azide, dinitrophenol, dicyclohexyl carbodiimide and oubain, whilst both activities are reduced by blockade of -SH groups localized on the outside of the sarcoplasmic reticulum membrane. 6. The isolated phosphoprotein is acid stable. The trichloroacetic acid denatured 32P-labelled membrane complex is dephosphorylated by hydroxylamine, which might indicate that the phosphorylated protein is an acyl-phosphate. 7. Polyacrylamide gel elctrophoresis (performed with phenol/acetic acid/water) of phosphorylated sarcoplasmic reticulum fractions demonstrates that the 32P-incorporation occurs into a protein of about 100000 molecular weight. 8. It is suggested that the phosphoprotein represents a phosphorylated intermediate of the calcium-dependent ATPase which formation occurs as an early step in the reaction sequence of calcium translocation by cardiac sarcoplasmic reticulum similar as in skeletal muscle.     

Isolation of calcium pump system and purification of calcium ion-dependent ATPase from heart muscle

The procedure for the isolation of the highly active fraction of sarcoplasmic reticulum from pigeon and dog hearts is described. The method is based on the partial loading of heart microsomes with calcium and oxalate ions and the precipitation of loaded vesicles in sucrose and potassium chloride concentration gradients. Preparations obtained possess high activity of Ca²⁺-dependent ATPase and are also able to accumulate up to 10 μmol Ca²⁺ per mg protein. Purification of sarcoplasmic reticulum membranes is accompanied by a decrease in concentration of cytochrome a+a₃ and an increase in the content of [³²P]phosphoenzyme. The basic components in “calcium-oxalate preparation” from hearts are proteins with molecular weights of about 100 000 (Ca²⁺-dependent ATPase) and 55 000 Calcium-oxalate preparation from pigeon hearts was used for subsequent purification of Ca²⁺-dependent ATPase. Specific activity of purified enzyme from pigeon hearts is 12–16 μmol P_i/min per mg protein. Enzyme activity of purified Ca²⁺-dependent ATPase is inhibited by EGTA and is not sensitive to azide, 2,4-dinitrophenol and ouabain. The data obtained demonstrate the similarity of calcium pump systems and Ca²⁺-dependent ATPases isolated from heart and skeletal muscles.     

Purification of the CaATPase of sarcoplasmic reticulum by affinity chromatography

Proteins from sarcoplasmic reticulum vesicles solubilized by a nonionic detergent were fractionated by use of a reactive red-120 agarose column. The Ca-ATPase was obtained in pure form by eluting the column with 400 microM adenyl 5'-yl imidodiphosphate, yielding an enzyme of almost twice the starting specific activity in a fraction containing half the initial protein. The conclusion that the ATPase comprises 50% of the sarcoplasmic reticulum vesicle protein agrees with estimates gained from densitometry using 7 1/2% Laemmli slab gels but not from densitometry using 7% Weber and Osborn slab gels. The mechanism of purification was found to be affinity chromatography, with the ATPase binding the reactive red-120 ligand in its nucleotide-binding site. The steady-state concentration of phosphorylated intermediate relative to the specific activity was found to be lower in the purified enzyme as compared to the starting vesicular enzyme.     

Calcium release from sarcoplasmic reticulum of normal and dystrophic mice

Contraction of skeletal muscle is triggered by release of calcium from the sarcoplasmic reticulum. In this study, highly purified normal and dystrophic mouse sarcoplasmic reticulum vesicles were compared with respect to calcium release characteristics. Sarcoplasmic reticulum vesicles were actively loaded with calcium in the presence of an ATP-regenerating system. Calcium fluxes were followed by dual wavelength spectrophotometry using the metallochromic indicators antipyrylazo III and arsenazo III, and by isotopic techniques. Calcium release from sarcoplasmic reticulum vesicles was elicited by (a) changing the free calcium concentration of the assay medium (calcium-induced calcium release); (b) addition of a permeant anion to the assay medium, following calcium loading in the presence of a relatively impermeant anion (depolarization-induced calcium release); (c) addition of the lipophilic anion tetraphenylboron (TPB^?) to the assay medium and (d) using specific experimental conditions, i.e. high phosphate levels and low magnesium (spontaneous calcium release). Drugs known to influence Ca²⁺ release were shown to differentially affect the various types of calcium release. Caffeine (10 mM) was found to enhance calcium-induced calcium release from isolated sarcoplasmic reticulum. Ruthenium red (20 μM) inhibited both calcium-induced calcium release and tetraphenylboron-induced calcium release, and partially inhibited spontaneous calcium release and depolarization-induced calcium release. Local anesthetics inhibited spontaneous calcium release in a time-dependent manner, and inhibited calcium-induced calcium release instantaneously, but did not inhibit depolarization-induced calcium release. Use of pharmacological agents indicates that several types of calcium release operate in vitro. No significant differences were found between normal and dystrophic sarcoplasmic reticulum in calcium release kinetics or drug sensitivities.     

Adenosine triphosphate-induced rapid calcium release from fragmented sarcoplasmic reticulum

Calcium efflux from skeletal muscle fragmented sarcoplasmic reticulum was studied using a dilution technique and Millipore filtration. In the absence of Mg⁺⁺ and external Ca⁺⁺, addition of lmM adenosine triphosphate to the suspension resulted in an immediate loss of 26–55% of total vesicular calcium. The amount of calcium released was calculated to be sufficient to effect muscle contraction. After separation of the sarcoplasmic reticulum into light, intermediate and heavy vesicles, the light and heavy fractions were found to be only weakly responsive to adenosine triphosphate, whereas the intermediate fraction lost nearly half of its calcium. The significance of these results with respect to excitation-contraction coupling in muscle is discussed.     

Characterization of calmodulin-mediated phosphorylation of cardiac muscle sarcoplasmic reticulum

Sarcoplasmic reticulum, isolated from canine cardiac muscle, was phosphorylated in the presence of exogenous cAMP-dependent protein kinase or calmodulin. This phosphorylation has been shown previously to activate sarcoplasmic reticulum calcium uptake (LePeuch et al. (1979) Biochemistry18, 5150–5157). Calmodulin appeared to activate an endogenous protein kinase present in sarcoplasmic reticulum membranes. The incorporation of phosphate increased with time. However, once all the ATP was consumed, the level of phosphorylated protein started to decrease due to the action of an endogenous protein phosphatase. Dephosphorylation occurred even when the level of phosphorylated sarcoplasmic reticulum remained constant at high ATP concentrations. The phosphorylation of sarcoplasmic reticulum in the presence of calmodulin, increased as the pH was increased from pH 5.5 to 8.5. This phosphorylation was only inhibited by KCl concentrations greater than 100 mm. The apparent K_m of cAMP-dependent protein kinase for ATP was 5.2 ± 0.2 × 10^?5m, and of the calmodulin-dependent protein kinase for ATP was 3.67 ± 0.29 × 10^?5m. Phosphorylation was maximally activated by 5–10 mm MgCl₂; higher MgCl₂ concentrations inhibited this phosphorylation. Thus the calmodulin-dependent phosphorylation of cardiac sarcoplasmic reticulum could be maximally activated at sarcoplasmic concentrations of K⁺, Mg²⁺, and ATP. The calmodulindependent phosphorylation was half-maximally activated at Ca²⁺ concentrations that were significantly greater than those required to promote the formation of the sarcoplasmic reticulum Ca-activated ATPase phosphoprotein intermediate. Thus at sarcoplasmic Ca²⁺ concentrations that might be expected during systole, the sarcoplasmic reticulum calcium pump would be fully activated before any significant calmodul-independent sarcoplasmic reticulum phosphorylation occurred. However, under certain pathological conditions when the sarcoplasmic Ca²⁺ becomes elevated (e.g., in ischemia) the kinase could be activated so that the sarcoplasmic reticulum would be phosphorylated and calcium uptake augmented. Thus, the calmodulin-dependent protein kinase may only function when the heart needs to rescue itself from a possibly fatal calcium overload.     

Formation of adenosine triphosphate from Pi and adenosine diphosphate by purified Ca-2+-adenosine triphosphatase.

Ca-2+-ATPase purified from sarcoplasmic reticulum of rabbit muscle forms a phsophoeznyme when exposed to inorganic phosphate in the presence of Mg-2+. On addition of ADP and Ca-2+ virtually all of the phosphate bound to the enzyme is transferred to form ATP. It has been shown previously and confirmed by us that (a) the purified ATPase contains one major polypeptide and about 30% phospholipids; (b) on removal of residual detergent by passage through Sephadex the enzyme forms vesicular membranes; and (c) these vesicles are leaky and incapable of accumulating Ca-2+. Our findings therefore indicate that we have observed ATP generation from ADP and P-i without the formation of an ion gradient across a membrane. We propose that the energy derived from ion-protein interaction drives the formation of ATP.     

Reaction mechanism of the calcium-transport ATPase in endoplasmic reticulum of rat liver. Demonstration of different reactive forms of the phosphorylated intermediate

A calcium-transport ATPase is inserted into the endoplasmic reticulum of rat liver. Catalysis of calcium translocation involves transient covalent binding of the terminal phosphate residue of ATP by the enzyme, resulting in the formation of an alkali- and hydroxylamine-labile phosphorylprotein intermediate. Both MgATP as well as CaATP can be utilized in the phosphorylation reaction which requires calcium as a cofactor. Magnesium accelerates the turnover of the phosphorylprotein intermediate. An ADP-reactive and ADP-unreactive state of the phosphoenzyme could be distinguished. In the ADP-reactive state with tightly bound calcium, the phosphoenzyme can transphosphorylate its phosphate residue to ADP, giving rise to synthesis of ATP. The ADP-reactive phosphoenzyme can be converted into an ADP-unreactive state by prolonged incubation with excess EGTA (ethylene glycol bis(beta-aminoethyl ether)-N,N,N',N'-tetraacetic acid). It is suggested that this conversion is brought about by the removal of tightly bound calcium from the phosphoenzyme. A strong homology of the sequential reaction steps during calcium translocation by the calcium-transport ATPases in endoplasmic reticulum from rat liver and sarcoplasmic reticulum from skeletal muscle is suggested.     

Cytochemical studies of myocardial adenylate cyclase after its activation and inhibition

Incubation medium, as previously described (J Histochem Cytochem 27:774, 1979), was used to demonstrate the presence of adenylate cyclase (AC) in myocardium. NaF and ouabain were used to inhibit adenosine triphosphatases (ATP) and NaF and isoproterenol were used as activators of AC. The inhibitory effect of adenosine on AC was blocked by the addition of adenosine deaminase. The addition of tetramisol blocked the influence of the alkaline phosphatases on adenylyl imidodiphosphate hydrolysis. The use of these substances resulted in specific precipitation localized in junctional sarcoplasmic reticulum and sarcolemma. The reaction product was dramatically intensified after activation of AC by NaF or isoproterenol. Preincubation in 10-100 mM of propranolol, for 30 min, blocked AC stimulation by isoproterenol and prevented the appearance of the specific precipitate. The localization of specific precipitate in junctional sarcoplasmic reticulum and subsarcolemmal cisternae corresponds to the localization of Na+, K+ ATPase and may reflect the similar role that AC and Na+, K+ ATPase play in calcium release from sarcoplasmic reticulum of internal and peripheral couplings.     

Isolation of highly active preparations of sarcoplasmic reticulum and Ca2-dependent ATPase from cardiac muscle]

A microsomal preparation with a high ability for Ca2+ uptake has been isolated from pigeon heart. A method of further purification of Ca2+-accumulating system of heart, based on the ability of sarcoplasmic reticulum for the energy-dependent Ca2+ accumulation in the presence of oxalate, has been developed. Upon centrifugation in the gradient of sucrose and KCl concentration the fragments of sarcoplasmic reticulum, rendered "heavy" by calcium oxalate, can be separated from foreign cell membranes. The main component of heart "calcium pump" is Ca2+-dependent ATPase (making up to about 50% of all proteins of the purified reticulum), having a molecular weight of 100.000--105.000. Specific activity of heart Ca2+-ATPase as well as the ability of purified heart sarcoplasmic reticulum for Ca2+ uptake are only slightly less than those of the skeletal muscle reticulum. The data obtained suggest that heart sarcoplasmic reticulum may be efficient for providing heart muscle relaxation.     

Isolation of calcium pump system and purification of calcium ion-dependent ATPase from heart muscle.

The procedure for the isolation of the highly active fraction of sarcoplasmic reticulum from pigeon and dog hearts is described. The method is based on the partial loading of heart microsomes with calcium and oxalate ions and the precipitation of loaded vesicles in sucrose and potassium chloride concentration gradients. Preparations obtained possess high activity of Ca2+-dependent ATPase and are also able to accumulate up to 10 mumol Ca2+ per mg protein. Purification of sarcoplasmic reticulum membranes is accompanied by a decrease in concentration of cytochrome a+a3 and an increase in the content of [32P]phosphoenzyme. The basic components in "calcium-oxalate preparation" from hearts are proteins with molecular weights of about 100000 (Ca2+-dependent ATPase) and 55000 Calcium-oxalate preparation from pigeon hearts was used for subsequent purification of Ca2+-dependent ATPase. Specific activity of purified enzyme from pigeon hearts is 12-16 mumol Pi/min per mg protein. Enzyme activity of purified Ca2+-dependent ATPase is inhibited by EGTA and is not sensitive to azide, 2,4-dinitrophenol and ouabain. The data obtained demonstrate the similarity of calcium pump systems and Ca2+-dependent ATPases isolated from heart and skeletal muscles.