Energetics of the calcium-transporting ATPase

A thermodynamic cycle for catalysis of calcium transport by the sarcoplasmic reticulum ATPase is described, based on equilibrium constants for the microscopic steps of the reaction shown in Equation 1 under a single set of experimental (formula; see text) conditions (pH 7.0, 25 degrees C, 100 mM KCl, 5 mM MgSO4): KCa = 5.9 X 10(-12) M2, K alpha ATP = 15 microM, Kint = 0.47, K alpha ADP = 0.73 mM, K'int = 1.7, K"Ca = 2.2 X 10(-6) M2, and Kp = 37 mM. The value of K"Ca was calculated by difference, from the free energy of hydrolysis of ATP. The spontaneous formation of an acylphosphate from Pi and E is made possible by the expression of 12.5 kcal mol-1 of noncovalent binding energy in E-P. Only 1.9 kcal mol-1 of binding energy is expressed in E X Pi. There is a mutual destabilization of bound phosphate and calcium in E-P X Ca2, with delta GD = 7.6 kcal mol-1, that permits transfer of phosphate to ADP and transfer of calcium to a concentrated calcium pool inside the vesicle. It is suggested that the ordered kinetic mechanism for the dissociation of E-P X Ca2, with phosphate transfer to ADP before calcium dissociation outside and phosphate transfer to water after calcium dissociation inside, preserves the Gibbs energies of these ligands and makes a major contribution to the coupling in the transport process. A lag (approximately 5 ms) before the appearance of E-P after mixing E and Pi at pH 6 is diminished by ATP and by increased [Pi]. This suggests that ATP accelerates the binding of Pi. The weak inhibition by ATP of E-P formation at equilibrium also suggests that ATP and phosphate can bind simultaneously to the enzyme at pH 6. Rate constants are greater than or equal to 115 s-1 for all the steps in the reaction sequence to form E-32P X Ca2 from E-P, Ca2+ and [32P]ATP at pH 7. E-P X Ca2 decomposes with kappa = 17 s-1, which shows that it is a kinetically competent intermediate. The value of kappa decreases to 4 s-1 if the intermediate is formed in the presence of 2 mM Ca2+. This decrease and inhibition of turnover by greater than 0.1 mM Ca2+ may result from slow decomposition of E-P X Ca3.     

Interdependence of H+, Ca2+, and Pi (or vanadate) sites in sarcoplasmic reticulum ATPase

The phosphorylation of sarcoplasmic reticulum ATPase with Pi in the absence of Ca2+ was studied by equilibrium and kinetic experimentation. The combination of these measurements was then subjected to analysis without assumptions on the stoichiometry of the reactive sites. The analysis indicates that the species undergoing covalent interaction is the tertiary complex E X Pi X Mg formed by independent interaction of the two ligands with the enzyme. The binding constant of Pi or Mg2+ to either free or partially associated enzyme is approximately equal to 10(2) M-1, and no significant synergistic effect is produced by one ligand on the binding of the other; the equilibrium constant (Keq) for the covalent reaction E X Pi X Mg E-P X Mg is approximately equal to 16, with kphosph = 53 s-1, and khyd = 3-4 s-1 (25 degrees C, pH 6.0, no K+). The phosphorylation reaction of sarcoplasmic reticulum ATPase with Pi is highly H+ dependent. Such a pH dependence involves the affinity of enzyme for different ionization states of Pi, as well as protonation of two protein residues per enzyme unit in order to obtain optimal phosphorylation. The experimental data can then be fitted satisfactorily assuming pK values of 5.7 and 8.5 for the two residues in the nonphosphorylated enzyme (changing to 7.7 for one of the two residues, following phosphorylation) and values of 50.0 and 0.58 for the equilibrium constants of the H2(E X HPO4) in equilibrium with H(E-PO3) + H2O and H(E X HPO4) in equilibrium with E-PO3 + H2O reactions, respectively. In addition to the interdependence of H+ and phosphorylation sites, an interdependence of Ca2+ and phosphorylation sites is revealed by total inhibition of the Pi reaction when two high affinity calcium sites per enzyme unit are occupied by calcium. Conversely, occupancy of the phosphate site by vanadate (a stable transition state analogue of phosphate) inhibits high affinity calcium binding. The known binding competition between the two cations and their opposite effects on the phosphorylation reaction suggest that interdependence of phosphorylation site, H+ sites, and Ca2+ sites is a basic mechanistic feature of enzyme catalysis and cation transport.     

Effect of triiodo-L-thyronine treatment on Ca2+ sequestration in rat liver microsomes

T3 administration to rats exerts quite different effects on enzyme activities associated to liver microsomal membranes such as G-6-Pase, Mg ATPase and Ca2(+)-dependent ATPase: in fact G-6-Pase activity is significantly enhanced, Mg ATPase is not affected whereas Ca2(+)-dependent ATPase is drastically inhibited. The T3 induced decrease in Ca2(+)-dependent ATPase activity is associated with a net reduction (to about 50% with respect to controls) of the Ca2+ sequestration in liver microsomal vesicles. The enhanced level of inorganic phosphate in the endoplasmic reticulum due to the stimulation of G-6-Pase activity does not significantly affect the uptake of calcium in microsomal vesicles. The decreased Ca2(+)-dependent ATPase activity is associated to an enhanced level of the enzyme in the phosphorylated form (E-P). This suggests that in liver preparations from T3 treated rats the turnover of ATP and cleavage of E-P is reduced, thus resulting in the accumulation of the phosphorylated intermediate. The accumulation of E-P is in agreement with the inhibition of the calcium sequestration since the active transport of this cation in microsomal membranes requires the hydrolysis of the E-P complex.     

Activation of sarcoplasmic reticular Ca2+ transport ATPase by phosphorylation of an associated phosphatidylinositol

Approximately 1 mol phosphatidylinositol phosphate is formed per mol isolated Ca2+ transport ATPase when the enzyme is incubated with ATP/Mg2+. The phosphorylation of this enzyme-associated phosphatidylinositol represents the alkylphosphate formation described earlier. The phosphatidylinositol phosphate has been found in the hydrophobic core of the enzyme. A complex of phosphatidylinositol phosphate with protein can be extracted with acidic chloroform/methanol. The protein behaves like proteolipid during chromatography on Sephadex LH 60 and binds the radioactively labelled phosphatidylinositol phosphate. The phosphorylation of approximately 1 mol phosphatidylinositol per 100,000 g protein correlates with an enhancement of the Ca2+ transport ATPase activity which is due to an approximately 7-fold enhanced affinity for Ca2+ and an approximately 2-fold enhanced maximal turnover.     

Mechanism of inhibition of sarcoplasmic reticulum Ca2(+)-ATPase by active site cross-linking. Impairment of nucleotide binding slows nucleotide-dependent phosphoryl transfer, and loss of active site flexibility stabilizes occluded forms and blocks E2-P formation

Investigation of the properties of Ca2(+)-ATPase of sarcoplasmic reticulum cross-linked at the active site with glutaraldehyde showed that ATP binding affinity and rate of ATP-dependent phosphorylation and Ca2+ occlusion were decreased 2-3 orders of magnitude compared with the native enzyme. Cross-linkage had little effect on or marginally increased the rate of acetyl phosphate- and p-nitrophenyl phosphate-supported Ca2+ occlusion. Ca2+ binding or Ca2(+)-induced changes in tryptophan fluorescence were unaffected. High levels of phosphoenzyme (up to 4 nmol/mg of protein) were obtained, with 2 mol of Ca2+ occluded/mol of E-P. Dephosphorylation and deocclusion occurred together at a slow rate (k = 0.01 s-1) and were stimulated in a monophasic manner up to 20-fold by ADP. Cross-linking inhibited E2-P formation from Pi in 30% (v/v) dimethyl sulfoxide by more than 95%. Induction of turnover of the native ATPase, under conditions designed to yield high steady state levels of E1 approximately P(2Ca), results in a 3-4-fold increase in reactivity of active site residues to glutaraldehyde. The results show that cross-linkage sterically impairs nucleotide binding, changing ATP and ADP into relatively poor substrates, slowing nucleotide-dependent phosphoryl transfer and Ca2+ occlusion and deocclusion. The forward reaction with smaller substrates is unaffected. Another major effect of the cross-link is to inhibit E2-P formation, causing accumulation of E1 approximately P(2Ca) during enzyme turnover and preventing phosphorylation by Pi in the reverse direction. We suggest that occlusion and deocclusion of cations at the transport site of the native enzyme are linked to a two-step cleft closure movement at the active site and that the crosslink stabilizes occluded forms of the pump because it blocks part of this tertiary structural change. The latter could normally be propagated through linking helices to the distal side of the pump to destabilize the cations and open the transport sites to the lumen.     

Reaction mechanism of the Ca(2)+-dependent ATPase of sarcoplasmic reticulum from skeletal muscle. XI. Re-evaluation of the transition of ATPase activity during the initial phase.

We previously reported (J. Biochem. 70,95--123 (1971) that the time course of Pi liberation in the reaction of Ca2+, Mg2+--dependent ATPase [EC 3.6.1.3.] of fragmented sarcoplasmic reticulum (SR) consists of a lag phase, a burst phase, and a steady phase. We also showed that the rate constant, kd, of decomposition of the phosphorylated intermediate (E approximately P) decreases during the initial phase, and suggested that the burst phase is due to transition of the kd value. Recently, Froehlich and Taylor (J. Biol. Chem. 250, 2013--2021 (1975)) claimed that the Pi burst is caused by the formation of an acid-labile intermediate containing phosphate (E.P) formed by rapid hydrolysis of E approximately P. In the present study, the transition of the kd value during the initial phase was measured precisely, and the results showed that the burst phase is due to a transition in the kd value, not to the existence of E-P. The main results obtained were as follows: 1. After the SR had been phosphorylated with [gamma-32P]ATP in the presence of Mg2+ and Ca2+ ions, further phosphorylated was stopped by the addition of EGTA. The concentration of E approximately 32P then decreased exponentially with time. 2. The first-order rate constants, kd, of decomposition of E aproximately 32P after adding EGTA decreased with increase in the interval, t, between the start of E approximately 32P formation and the time of adding EGTA...     

Binding of two Sr2+ ions changes the chemical specificities for phosphorylation of the sarcoplasmic reticulum calcium ATPase through a stepwise mechanism.

The sequential binding of Sr2+ and Ca2+ to the cytoplasmic transport sites of the sarcoplasmic reticulum calcium ATPase allows the formation of two different mixed complexes: cE.Sr.Ca, with Sr2+ bound to the "inner" site and Ca2+ bound to the "outer" site, and cE. Ca.Sr, with Ca2+ bound to the inner site and Sr2+ bound to the outer site (pH 7.0, 25 degrees C, 10 mM MgCl2, 100 mM KCl). Both cE.Sr.45Ca and cE.45Ca.Sr react with ATP to internalize one 45Ca/phosphoenzyme. The value of K0.5 = 83 microM Sr2+ for activation of the enzyme for phosphorylation by ATP is much larger than K0.5 = 28 microM Sr2+ for inhibition of phosphoenzyme formation from inorganic phosphate (eta H = 1.0-1.3). These results are consistent with the sequential binding of two strontium ions with negative cooperativity and dissociation constants of KSr1 = 35 microM and KSr2 = 55 microM. The species cE.Sr2 and cE.Ca2 react rapidly with ATP but not inorganic phosphate. However, enzyme with one strontium bound, cE.Sr, does not react with either inorganic phosphate or ATP. Therefore, the conformational changes in the enzyme that alter the chemical specificity for phosphorylation by ATP and by inorganic phosphate are different. This requires the existence of at least three forms of the unphosphorylated enzyme with three different chemical specificities for catalysis.     

Sarcoplasmic reticulum ATPase phosphorylation from inorganic phosphate in the absence of a calcium gradient. Steady state and kinetic fluorescence studies

The intrinsic fluorescence of sarcoplasmic reticulum vesicles was measured under conditions allowing ATPase phosphorylation from inorganic phosphate. Significant fluorescence enhancement of up to 4% resulted from gradient-independent enzyme phosphorylation at pH 6, in the absence of KCl. The equilibrium fluorescence data obtained at various magnesium and phosphate concentrations agree with a reaction scheme in which Mg2+, as direct activator, and free phosphate, as the true substrate, bind to the enzyme in random order to give a noncovalent ternary complex (Mg.*E.Pi), in equilibrium with the covalent phosphoenzyme (Mg.*E-P). The transient kinetics of the fluorescence rise was also studied, and the resulting data were generally consistent with the above scheme, assuming that binding reactions are fast compared to covalent phosphoenzyme formation. This, however, might be valid only as a first approximation. At 20 degrees C and pH 6, the phosphate concentration for half-maximum phosphorylation rate constant, at 20 mM magnesium, was higher than 20 mM. Similarly, the magnesium concentration for half-maximum phosphorylation rate constant, at 20 mM phosphate, was also higher than 20 mM. The maximum phosphorylation rate was faster than 25 s-1, and the phosphoenzyme hydrolysis rate constant was 1.5-2 s-1 under these conditions, so that the equilibrium constant between Mg.*E.Pi and Mg.*E-P largely favors the phosphoenzyme.     

Quercetin interaction with the (Ca2+ + Mg2+)-ATPase of sarcoplasmic reticulum

In sarcoplasmic reticulum vesicles or in the (Ca2+ + Mg2+)-ATPase purified from sarcoplasmic reticulum, quercetin inhibited ATP hydrolysis, Ca2+ uptake, ATP-Pi exchange, ATP synthesis coupled to Ca2+ efflux, ATP-ADP exchange, and steady state phosphorylation of the ATPase by inorganic phosphate. Steady state phosphorylation of the ATPase by ATP was not inhibited. Quercetin also inhibited ATP and ADP binding but not the binding of Ca2+. The inhibition of ATP-dependent Ca2+ transport by quercetin was reversible, and ATP, Ca2+, and dithiothreitol did not affect the inhibitory action of quercetin.     

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)     

Interference with phosphoenzyme isomerization and inhibition of the sarco-endoplasmic reticulum Ca2+ ATPase by 1,3-dibromo-2,4,6-tris(methylisothiouronium) benzene

ATP hydrolysis and Ca(2+) transport by the sarco-endoplasmic reticulum Ca(2+) ATPase (SERCA) are inhibited by 1,3-dibromo-2,4,6-tris(methylisothiouronium) benzene (Br(2)-TITU) in the micromolar range (Berman, M. C., and Karlish, S. J. (2003) Biochemistry 42, 3556-3566). In a study of the mechanism of inhibition, we found that Br(2)-TITU allows the enzyme to bind Ca(2+) and undergo phosphorylation by ATP. The level of ADP-sensitive phosphoenzyme (i.e. E1P-2Ca(2+)) observed in the transient state following addition of ATP is much higher in the presence than in the absence of the inhibitor. Br(2)-TITU does not interfere with enzyme phosphorylation by P(i) in the reverse direction of the cycle (i.e. E2P) and produces only a slight inhibition of its hydrolytic cleavage. The inhibitory effect of Br(2)-TITU on steady state ATPase velocity is attributed to interference with the E1P-2Ca(2+) to E2P-2Ca(2+) transition. In fact, experiments on conformation-dependent protection from proteolytic digestion suggest that, in the presence of Br(2)-TITU, the loops connecting the "A" domain to the ATPase transmembrane region undergo greater fluctuation than expected in the E2 and E2P states. Optimal stability of the gathered headpiece domains is thereby prevented. These effects are opposite to those of thapsigargin, in which the mechanism of inhibition is related to stabilization of a highly compact ATPase conformation and interference with Ca(2+) binding and phosphoenzyme formation. Our experiments with Br(2)-TITU provide the first demonstration of a kinetic limit posed by an inhibitor on the E1P-2Ca(2+) to E2P-2Ca(2+) transition in the wild-type enzyme.     

Specific association of bromocresol purple anions with a magnesium complex of a phosphorylated intermediate during steady-state hydrolysis of ATP by the Mg2+ + Ca2+-dependent ATPase of sarcoplasmic reticulum

The mechanism of dimeric binding of bromocresol purple (BCP) anions to Mg2+ + Ca2+-ATPase of the sarcoplasmic reticulum (SR) and the resulting partial inhibition of the ATPase activity were studied. BCP anions in three states, free monomer, bound monomer, and bound dimer, were spectrophotometrically calculated by solving simultaneous equations, delta A lambda 1-lambda 2 = sigma delta ai (epsilon i lambda 1-epsilon i lambda 2), and concentration changes of these states were analyzed. The addition of ATP caused an increase in the bound dimer and a decrease in the free monomer, but the change of the bound monomer was slight. The decrease in delta A (decrease phase) on the addition of ATP on dual-wavelength spectrophotometry at 585-610 nm was related to an increase in the amount of dimer bound to the SR membranes. The magnitude of the decrease phase increased with an increase in Mg2+ concentration and decreased with an increase in the concentration of Ca2+. BCP anions at the probe concentration partially inhibited the ATPase activity, and brought about a decrease in the ADP-sensitive E-P (E1P) and an increase in the ADP-insensitive E-P (E2P), though BCP anions did not affect the amount of total E-P. On elimination of Mg2+ at the steady-state E-P level both E2P and E2P . (BCP)2 were decomposed, suggesting that the enzyme form binding the BCP dimer was Mg . E-P. An increase in Mg2+ concentration increased E2P but an increase in Ca2+ concentration decreased E2P. Decomposition of E2P to P1 was inhibited by BCP anions. The following simple scheme was suggested to explain the partial inhibition of the ATPase activity, (Formula: see text). Application of BCP anions was discussed for use as a probe for Mg . E-P in the steady-state ATP hydrolysis.     

Intermediate phosphorylation reactions in the mechanism of ATP utilization by the copper ATPase (CopA) of Thermotoga maritima

Recombinant and purified Thermotoga maritima CopA sustains ATPase velocity of 1.78-2.73 micromol/mg/min in the presence of Cu+ (pH 6, 60 degrees C) and 0.03-0.08 micromol/mg/min in the absence of Cu+. High levels of enzyme phosphorylation are obtained by utilization of [gamma-32P]ATP in the absence of Cu+. This phosphoenzyme decays at a much slower rate than observed with Cu.E1 approximately P. In fact, the phosphoenzyme is reduced to much lower steady state levels upon addition of Cu+, due to rapid hydrolytic cleavage. Negligible ATPase turnover is sustained by CopA following deletion of its N-metal binding domain (DeltaNMBD) or mutation of NMBD cysteines (CXXC). Nevertheless, high levels of phosphoenzyme are obtained by utilization of [gamma-3)P]ATP by the DeltaNMBD and CXXC mutants, with no effect of Cu+ either on its formation or hydrolytic cleavage. Phosphoenzyme formation (E2P) can also be obtained by utilization of Pi, and this reaction is inhibited by Cu+ (E2 to E1 transition) even in the DeltaNMBD mutant, evidently due to Cu+ binding at a (transport) site other than the NMBD. E2P undergoes hydrolytic cleavage faster in DeltaNMBD and slower in CXXC mutant. We propose that Cu+ binding to the NMBD is required to produce an "active" conformation of CopA, whereby additional Cu+ bound to an alternate (transmembrane transport) site initiates faster cycles including formation of Cu.E1 approximately P, followed by the E1 approximately P to E2-P conformational transition and hydrolytic cleavage of phosphate. An H479Q mutation (analogous to one found in Wilson disease) renders CopA unable to utilize ATP, whereas phosphorylation by Pi is retained.     

ATPase activity and Ca2+ transport by reconstituted tryptic fragments of the Ca2+ pump of the erythrocyte plasma membrane

The purified Ca2+ ATPase of the erythrocyte plasma membrane has been submitted to controlled trypsin proteolysis under conditions that favor either its (putative) E1 or E2 configurations. The former configuration has been forced by treating the enzyme with Ca2+-saturated calmodulin, the latter with vanadate and Mg2+. The E1 conformation leads to the accumulation of a polypeptide of Mr 85 KDa which still binds calmodulin, the E2 conformation to the accumulation of one of Mr 81 KDa which does not. Both fragments arise from the hydrolysis of a transient 90 KDa product which has Ca2+-calmodulin dependent ATPase activity, and which retains the ability to pump Ca2+ in reconstituted liposomes. Highly enriched preparations of the 85 and 81 KDa fragments have been obtained and reconstituted into liposomes. The former has limited ATPase and Ca2+ transport ability and is not stimulated by calmodulin. The latter has much higher ATPase and Ca2+ transport activity. It is proposed that the Ca2+ pumping ATPase of erythrocytes plasma membrane contains a 9 KDa domain which is essential for the interaction of the enzyme with calmodulin and for the full expression of the hydrolytic and transport activity. This putative 9 KDa sequence contains a 4 KDa "inhibitory" domain which limits the activity of the ATPase. In the presence of this 4 KDa sequence, i.e., when the enzyme is degraded to the 85 KDa product, calmodulin can still be bound, but no longer stimulates ATPase and Ca2+ transport.     

Phosphorus-31 nuclear magnetic resonance of phosphoenzymes of sodium- and potassium-activated and of calcium-activated adenosinetriphosphatase

Prior studies identified phosphoenzyme intermediates in the turnover of sodium- and potassium-activated adenosinetriphosphatase [(Na,K)ATPase] from several sources and of the calcium-activated adenosinetriphosphatase [(Ca)-ATPase] of skeletal muscle sarcoplasmic reticulum. In both cases, the transphosphorylation is to a beta-aspartyl carboxyl group at the active site. We now report observation of a K+-sensitive phosphorylated intermediate of purified (Na,-K)ATPase from the salt gland of the duck using high-field 31P nuclear magnetic resonance. Addition of ATP to a suspension of this enzyme in the presence of Mg2+ and Na+ produced a resonance at about +17 ppm relative to 85% phosphoric acid. Addition of inorganic phosphate and Mg2+ to (Na,K)ATPase also produced a resonance at about +17 ppm which was enhanced in the presence of a saturating concentration of the inhibitor, ouabain; again, addition of K+ made this resonance disappear. These findings are consistent with earlier kinetic characterization of an acid-stable (Na,K)ATPase phosphoenzyme intermediate by 32P-labeled phosphate incorporation into a denatured precipitate of the enzyme. We attribute the +17-ppm resonance to formation of an acyl phosphate at an aspartyl residue of the catalytic site of (Na,K)ATPase. This is supported by our finding of a similar resonance at +17 ppm after phosphorylation of another membrane-bound cation transport enzyme, sarcoplasmic reticulum (Ca)ATPase, as well as by a similar resonance at about +17 ppm after phosphorylation of the model dipeptide L-seryl-L-aspartate.     

Phosphorylation of uterine smooth muscle myosin permits actin-activation.

Myosin was purified from ovine uterine smooth muscle. The 20,000 dalton myosin light chain was phosphorylated to varying degrees by an endogenous Ca2+ dependent kinase. The kinase and endogenous phosphatases were then removed via column chromatography. In the absence of actin neither the size of the initial phosphate burst nor the steady state Mg2+-dependent ATPase activity were affected by phosphorylation. However, phosphorylation was required for actin to increase the Mg2+-dependent ATPase activity and for the myosin to superprecipitate with actin. Ca2+ did not affect the Mg2+-dependent ATPase activity in the presence or absence of action or the rate or extent of superprecipitation with actin once phosphorylation was obtained. These data indicate that: 1) phosphorylation of the 20,000 dalton myosin light chain controls the uterine smooth muscle actomyosin interaction, 2) in the absence of actin, phosphorylation does not affect either the ATPase of myosin or the size of the initial burst of phosphate and, 3) Ca2+ is important in controlling the light chain kinase but not the actomyosin interaction.     

Two functional states of sarcoplasmic reticulum ATPase.

The "total" ATPase activity of rabbit sarcoplasmic reticulum (SR) vesicles includes a Ca2+-independent component ("basic") and Ca2+-dependent component ("extra"). Only the "extra" ATPase is coupled to Ca2+ transport. These activities can be measured under conditions in which the observed rates approximate maximal velocities. The "basic" ATPase is predominant in one of the various SR fractions obtained by prolonged density-gradient centrifugation of SR preparations already purified by repeated differential centrifugations and extractions at high ionic strength. This fraction (low dnesity, high cholesterol) has a protein composition nearly identical with that of other SR fractions in which the "extra" ATPase is predominant. In these other fractions the ratio of "extra" to "basic" ATPase activities is temperature dependent, being approximately 9.0 at 40 degrees C and 0.5 at 4 degrees C. In all the fractions and at all temperatures studied, similar steady-state levels of phosphorylated SR protein are obtained in the presence of ATP and Ca2+. Furthermore, in all cases the "basic" (Ca2+-independent) ATPase acquires total Ca2+ dependence upon addition of the nonionic detergent Triton X-100. This detergent also transforms the complex substrate dependence of the SRATPase into a simple dependence, displaying a single value for the apparent Km. The experimental findings indicate that the ATPase of rabbit SR exists in two distinct functional states (E1 and E2), only one of which (E2) is coupled to Ca2+ transport. The E1 in equilibrium E2 equilibrium is temperature-dependent and entropy-driven, indicative of its relation to the physical state of the ATPase protein in its membrane environment. Thenonlinearity of Arrhenius plots of Ca2+-dependent ("extra") ATPase activity and Ca2+ transport is explained in terms of simultaneous contribtuions from both the free energy of activation of enzyme catalysis and the free energy of conversion of E1 to E2. Thermal equilibrium between the two functional states is drastically altered by factors which affect membrane structure and local viscosity.     

Calcium transport ATPase of canine cardiac sarcoplasmic reticulum. A comparison with that of rabbit fast skeletal muscle sarcoplasmic reticulum.

To define the mechanism responsible for the slow rate of calcium transport by cardiac sarcoplasmic reticulum, the kinetic properties of the Ca2+-dependent ATPase of canine cardiac microsomes were characterized and compared with those of a comparable preparation from rabbit fast skeletal muscle. A phosphoprotein intermediate (E approximately P), which has the stability characteristics of an acyl phosphate, is formed during ATP hydrolysis by cardiac microsomes. Ca2+ is required for the E approximately P formation, and Mg2+ accelerates its decomposition. The Ca2+ concentration required for half-maximal activation of the ATPase is 4.7 +/- 0.2 muM for cardiac microsomes and 1.3 +/- 0.1 muM for skeletal microsomes at pH 6.8 and 0 degrees. The ATPase activities at saturating concentrations of ionized Ca2+ and pH 6.8, expressed as ATP hydrolysis per mg of protein, are 3 to 6 times lower for cardiac microsomes than for skeletal microsomes under a variety of conditions tested. The apparent Km value for MgATP at high concentrations in the presence of saturating concentrations of ionized Ca2+ is 0.18 +/- 0.03 ms at pH 6.8 and 25 degrees. The maximum velocity of ATPase activity under these conditions is 0.45 +/- 0.05 mumol per mg per min for cardiac microsomes and 1.60 +/- 0.05 mumol per mg per min for skeletal microsomes. The maximum steady state level of E approximately P for cardiac microsomes, 1.3 +/- 0.1 nmol per mg, is significantly less than the value of 4.9 +/- 0.2 nmol per mg for skeletal microsomes, so that the turnover number of the Ca2+-dependent ATPase of cardiac microsomes, calculated as the ratio of ATPase activity to the E approximately P level is similar to that of the skeletal ATPase. These findings indicate that the relatively slow rate of calcium transport by cardiac microsomes, whem compared to that of skeletal microsomes, reflects a lower density of calcium pumping sites and lower Ca2+ affinity for these sites, rather than a lower turnover rate.     

Functional consequences of mutations of conserved amino acids in the beta-strand domain of the Ca2(+)-ATPase of sarcoplasmic reticulum

The sequences Thr-Gly-Glu-Ser184 and Asp-Gln-Ser178 and individual residues Asp149, Asp157, and Asp162 in the sarcoplasmic reticulum Ca2(+)-ATPase are highly conserved throughout the family of cation-transporting ATPases. Mutant Thr181----Ala, Gly182----Ala, Glu183----Ala, and Glu183----Gln, created by in vitro mutagenesis, were devoid of Ca2+ transport activity. None of these mutations, however, affected phosphorylation of the enzyme by ATP in the presence of Ca2+ or by inorganic phosphate in the absence of Ca2+, indicating that the high affinity Ca2(+)-binding sites and the nucleotide-binding sites were intact. In each of these mutants, the ADP-sensitive phosphoenzyme intermediate (E1P) decayed to the ADP-insensitive form (E2P) very slowly relative to the wild-type enzyme, whereas E2P decayed at a rate similar to that of the wild-type enzyme. Thus, the inability of the mutants to transport Ca2+ was accounted for by an apparent block of the transport reaction at the E1P to E2P conformational transition. These results suggest that Thr181, Gly182, and Glu183 play essential roles in the conformational change between E1P and E2P. Mutation of Ser184, Asp157, or Ser178 had little or no effect on either Ca2+ transport activity or expression. Mutations of Asp149, Asp162, and Gln177, however, were poorly expressed. Where expression could be measured, in mutations to Asp162 and Gln177, Ca2+ transport activity was essentially equivalent to that of the wild-type enzyme.     

Ca2+ uptake by corpus-luteum plasma membranes. Evidence for the presence of both a Ca2+-pumping ATPase and a Ca2+-dependent nucleoside triphosphatase.

Plasma-membrane vesicles from rat corpus luteum showed an ATP-dependent uptake of Ca2+. Ca2+ was accumulated with a K1/2 (concn. giving half-maximal activity) of 0.2 microM and was released by the bivalent-cation ionophore A23187. A Ca2+-dependent phosphorylated intermediate (Mr 100,000) was detected which showed a low decomposition rate, consistent with it being the phosphorylated intermediate of the transport ATPase responsible for Ca2+ uptake. The Ca2+ uptake and the phosphorylated intermediate (E approximately P) displayed several properties that were different from those of the high-affinity Ca2+-ATPase previously observed in these membranes. Both Ca2+ uptake and E approximately P discriminated against ribonucleoside triphosphates other than ATP, whereas the ATPase split all the ribonucleoside triphosphates equally. Both Ca2+ uptake and E approximately P were sensitive to three different Hg-containing inhibitors, whereas the ATPase was inhibited much less. Ca2+ uptake required added Mg2+ (Km = 2.2 mM), whereas the ATPase required no added Mg2+. The maximum rate of Ca2+ uptake was about 400-fold less than that of ATP splitting; under different conditions, the decomposition rate of E approximately P was 1,000 times too slow to account for the ATPase activity observed. All of these features suggested that Ca2+ uptake was due to an enzyme of low activity, whose ATPase activity was not detected in the presence of the higher-specific-activity Ca2+-dependent ATPase.