Stoichiometry and mapping of the nucleotide sites in sarcoplasmic reticulum ATPase with the use of UTP

Purified sarcoplasmic reticulum ATPase was phosphorylated by either ATP or UTP under otherwise identical conditions. Calcium, pH, and nucleotide concentrations were adjusted to permit maximal steady-state accumulation of phosphoenzyme (EP). Either 4 or 8.5 nmol of EP/mg of protein were obtained with ATP or UTP, respectively. Tryptic digestion of phosphorylated ATPase followed by acid gel electrophoresis showed that EP from UTP was on fragment A1, similar to the report in the literature for EP from ATP. Phosphorylation with Pi in the absence of calcium gave EP levels similar to those obtained from UTP. Thus, comparison of EP levels from different substrates measured in parallel in the same preparation reveal that with ATP half of the sites are phosphorylated. Illumination of the ATPase with UV light in the presence of [3H]UTP caused photolabeling of the ATPase at a maximal level of 1 nmol of [3H]UTP incorporated/mg of ATPase. The UTP concentration dependence for photolabeling was the same as that for promoting catalysis. ATP when present in the illumination protected with a competitive pattern against photolabeling with UTP. Tryptic digestion and autoradiography of photolabeled ATPase revealed that UTP was covalently attached to tryptic fragment A2. The data indicate that a peptide sequence of fragment A2 is involved in the binding of the nucleoside moiety of UTP and possibly belongs to the nucleotide domain of the ATPase in addition to the sequence of fragment A1 which contains the phosphorylation residue.     

Calcium release from two fractions of sarcoplasmic reticulum from rabbit skeletal muscle

Calcium release from sarcoplasmic reticulum vesicles presumably derived from longitudinal tubules (LSR) and terminal cisternae (HSR) of rabbit skeletal muscle was investigated by dual wavelength spectrophotometry using the calcium-indicator antipyrylazo III. In 120 mM KCl, 5 mM MgCl2, 30 microM, CaCl2, 50 microM MgATP, 100 microM antipyrylazo III, 40 mM histidine (pH 6.8, 25 degrees C), LSR and HSR sequestered approx. 115 nmol calcium/mg, and then spontaneously released calcium. Analysis of ATP hydrolysis and phosphoenzyme level during LSR and HSR calcium sequestration indicated that this calcium release process was passive, occurring in the virtual absence of ATP and phosphoenzyme. Moreover, subsequent addition of ATP reinitiated the calcium sequestration-release sequence. Calcium release by HSR was more than 4-times faster than that by LSR. Analysis of the calcium release phase demonstrated a biexponential decay for both LSR (0.10 and 0.63 min-1) and HSR (0.26 and 1.65 min-1), suggestive of heterogeneity within each fraction. Replacement of 120 mM KCl with either 120 mM choline chloride, 240 mM sucrose, or H2O reduced maximal calcium sequestration by LSR, but had less effect on LSR calcium release rate constants. In the case of HSR, these changes in the ionic composition of the medium drastically reduced calcium release rate constants with little effect on calcium content. These marked differences between LSR and HSR are consistent with the hypothesis that the calcium permeability of the terminal cisternae is greater and more sensitive to the ionic environment than is that of the longitudinal tubules of sarcoplasmic reticulum.     

The hydrolytic cycle of sarcoplasmic reticulum Ca2+-ATPase in the absence of calcium

The hydrolytic cycle of sarcoplasmic reticulum Ca2+-ATPase in the absence of Ca2+ was studied. At pH 6.0, 10 degrees C and in the absence of K+, the enzyme displays a very low velocity of ATP hydrolysis. Addition of up to 15% dimethyl sulfoxide increased this velocity severalfold (from 5-18 nmol of Pi X mg of protein-1 X h-1) and then decreased at higher solvent concentrations. Dimethyl sulfoxide increased both enzyme phosphorylation from ATP and the affinity for this substrate. Maximal levels of 1.0-1.2 nmol of EP X mg of protein-1 and apparent KM for ATP of 5 X 10(-6) M were obtained at a concentration of 30% dimethyl sulfoxide. The same preparation under optimal conditions (pH 7.5, 10 microM CaCl2, 100 mM KCl and no dimethyl sulfoxide at 37 degrees C) displays a velocity of ATP hydrolysis between 8 and 12 X 10(5) nmol of Pi X mg of protein-1 X h-1 while the phosphoenzyme levels varied between 3.5 and 4.0 nmol of EP X mg of protein-1. Enzyme phosphorylation from ATP in the absence of Ca2+ always preceded Pi liberation into the assay media. Two different phosphoenzyme species were formed which were kinetically distinguished by their decomposition rates. The observed steady-state velocity of ATP hydrolysis could be accounted for either by the decay of the fast component or by the simultaneous decomposition of both phosphoenzyme species. The hydrolysis of the phosphoenzyme formed in the absence of Ca2+ was KCl-stimulated and ADP-independent. The rate constant of breakdown was equal to that observed for the phosphoenzyme formed in the presence of Ca2+. It is suggested that the rapidly decaying phosphoenzyme (and possibly both rapidly and slowly decaying species) are intermediates in the reaction cycle of Mg2+-dependent ATP hydrolysis of sarcoplasmic reticulum Ca2+-ATPase and may represent a bypass of Ca2+ activation by dimethyl sulfoxide.     

Effects of Mg2+ on calcium accumulation by two fractions of sarcoplasmic reticulum from rabbit skeletal muscle

Calcium accumulation by two fractions of sarcoplasmic reticulum presumably derived from longitudinal tubules (light vesicles) and terminal cisternae (heavy vesicles) was examined radiochemically in the presence of various free Mg2+ concentrations. Both fractions of sarcoplasmic reticulum exhibited a Mg2+-dependent increase in phosphate-supported calcium uptake velocity, though half-maximal velocity in heavy vesicles occurred at a much higher free Mg2+ concentration than that in light vesicles (i.e., approx. 0.90 mM vs. approx. 0.02 mM Mg2+). Calcium uptake velocity in light vesicles correlated with Ca2+-dependent ATPase activity, suggesting that Mg2+ stimulated the calcium pump. Calcium uptake velocity in heavy vesicles did not correlate with Ca2+-dependent ATPase activity, although a Mg2+-dependent increase in calcium influx was observed. Thus, Mg2+ may increase the coupling of ATP hydrolysis to calcium transport in heavy vesicles. Analyses of calcium sequestration (in the absence of phosphate) showed a similar trend in that elevation of Mg2+ from 0.07 to 5 mM stimulated calcium sequestration in heavy vesicles much more than in light vesicles. This difference between the two fractions of sarcoplasmic reticulum was not explained by phosphoenzyme (EP) level or distribution. Analyses of calcium uptake, Ca2+-dependent ATPase activity, and unidirectional calcium flux in the presence of approx. 0.4 mM Mg2+ suggested that ruthenium red (0.5 microM) can also increase the coupling of ATP hydrolysis to calcium transport in heavy vesicles, with no effect in light vesicles. These functional differences between light and heavy vesicles suggest that calcium transport in terminal cisternae is regulated differently from that in longitudinal tubules.     

Vanadate binding to the gastric H,K-ATPase and inhibition of the enzyme's catalytic and transport activities

Vanadate inhibition of the catalytic and transport activities of the gastric magnesium-dependent, hydrogen ion transporting, and potassium-stimulated adenosinetriphosphatase (EC 3.6.1.3) (H,K-ATPase) has been studied. The principal experiment observations are the following: (1) Inhibition of adenosine 5'-triphosphate (ATP) hydrolysis is biphasic. Vanadate binding with a stoichiometry of 1.5 nmol mg-1 approximately halves K+-stimulated ATPase activity at physiological temperature. The remaining activity is inhibited by binding an additional 1.5 nmol mg-1 vanadate with lower apparent ions bind specifically to gastric vesicles with two affinities. Vanadate binding in the presence of nucleotide is compatible with competition for the kinetically defined high-affinity and low-affinity ATP sites. (3) Vanadate inhibits phosphoenzyme formation and the K+-stimulated p-nitrophenyl phosphatase activity of the enzyme monophasically. A maximum of 1.5 nmol mg-1 acid-stable phosphoenzyme is formed. The half-time for vanadate dissociation from the site that inhibits p-nitrophenyl phosphate hydrolysis is 5 min (4) At most, 3 nmol mg-1 vanadate is required to inhibit proton transport. The simplest interpretation of the data is that vanadate inhibits the H,K-ATPase by binding competitively with ATP at two catalytic sites. Different catalytic mechanisms at the high-affinity and low-affinity sites are suggested by the different stoichiometries found for vanadate binding and phosphoenzyme formation.     

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.     

Allosteric regulation of cardiac sarcoplasmic reticulum Ca ATPase: a comparative study

Summary The mechanisms of allosteric regulation of the Ca-ATPases of cardiac and skeletal sarcoplasmic reticulum by ATP have been compared. Although both enzymes showed stimulation of ATPase activity by ATP, the cardiac enzyme did not show the plateau in ATPase activity at 10–100M ATP seen with the skeletal enzyme. Likewise the phosphoenzyme (EP) levels did not plateau with the cardiac enzyme as they did with the skeletal enzyme. The apparent negative cooperatively which was seen in the kinetics of ATP hydrolysis at low ATP concentrations was not due to negative cooperatively in substrate binding to either enzyme. The cardiac enzyme did show, however, much higher affinity for the ATP analog, AMPPCP, which helps explain how AMPPCP blocks ATPase activity in the cardiac enzyme and stimulates ATPase activity in the skeletal enzyme. Fluorescein isothiocyanate was used to determine if allosteric regulation takes place through site-site interactions in oligomers. The 1 to 1 ratio between AMPPCP binding sites and FITC binding sites eliminated allosteric regulation by effector sites in both enzymes. The allosteric mechanism which remained was one in which the active-site becomes an effector-site by the early departure of ADP in the reaction mechanism. The step stimulated by the binding of ATP at the active-site turned effector-site was a nonphosphorylated form of the enzyme in cardiac sarcoplasmic reticulum and a phosphorylated form in skeletal sarcoplasmic reticulum.Abbreviations AMPPCP Adenylyl Methylenediphosphonate - EGTA Ethyleneglycol Bis(amino-ethyl ether)-N,N,N,N Tetraacetic Acid - Pi Inorganic Phosphate - EP Phosphorylated Enzyme - FITC Fluorescein Isothiocyanate - MOPS 3-(N-morpholino)-Propanesulfonic Acid - v/EP ratio of calcium dependent ATPase activity to phosphoenzyme level - V initial rate of phosphoenzyme formation - LSSR Light Sarcoplasmic Reticulum - CSR Cardiac Sarcoplasmic Reticulum.     

Infrared spectroscopic signals arising from ligand binding and conformational changes in the catalytic cycle of sarcoplasmic reticulum calcium ATPase.

Fourier transform infrared spectroscopy was used to investigate ligand binding and conformational changes in the Ca2(+)-ATPase of sarcoplasmic reticulum during the catalytic cycle. The ATPase reaction was started in the infrared sample by release of ATP from the inactive, photolabile ATP derivative P3-1-(2-nitro)phenylethyladenosine 5'-triphosphate (caged ATP). Absorption spectroscopy in the visible spectral region using the Ca2(+)-sensitive dye Antipyrylazo III ensured that the infrared samples were able to transport Ca2+ in spite of their low water content, which is required for mid-infrared measurements (1800-950 cm-1). Small, but characteristic and highly reproducible infrared absorbance changes were observed upon ATP release. These infrared absorbance changes exhibit different kinetic properties. Comparison with model compound infrared spectra indicates that they are related to photolysis of caged ATP, hydrolysis of ATP in consequence of ATPase activity and to molecular changes in the active ATPase. The absorbance changes due to alterations in the ATPase were observed mainly in the region of Amide I and Amide II protein absorbance and presumably reflect the molecular processes upon phosphoenzyme formation. Since the absorbance changes were small compared to the overall ATPase absorbance, no major rearrangement of ATPase conformation as the result of catalysis could be detected.     

Ca2+-stimulated, Mg2+-dependent ATPase activity in neutrophil plasma membrane vesicles. Coupling to Ca2+ transport

Low concentrations of free Ca2+ stimulated the hydrolysis of ATP by plasma membrane vesicles purified from guinea pig neutrophils and incubated in 100 mM HEPES/triethanolamine, pH 7.25. In the absence of exogenous magnesium, apparent values obtained were 320 nM (EC50 for free Ca2+), 17.7 nmol of Pi/mg X min (Vmax), and 26 microM (Km for total ATP). Studies using trans- 1,2-diaminocyclohexane- N,N,N',N',-tetraacetic acid as a chelator showed this activity was dependent on 13 microM magnesium, endogenous to the medium plus membranes. Without added Mg2+, Ca2+ stimulated the hydrolysis of several other nucleotides: ATP congruent to GTP congruent to CTP congruent to ITP greater than UTP, but Ca2+-stimulated ATPase was not coupled to uptake of Ca2+, even in the presence of 5 mM oxalate. When 1 mM MgCl2 was added, the vesicles demonstrated oxalate and ATP-dependent calcium uptake at approximately 8 nmol of Ca2+/mg X min (based on total membrane protein). Ca2+ uptake increased to a maximum of approximately 17-20 nmol of Ca2+/mg X min when KCl replaced HEPES/triethanolamine in the buffer. In the presence of both KCl and MgCl2, Ca2+ stimulated the hydrolysis of ATP selectively over other nucleotides. Apparent values obtained for the Ca2+-stimulated ATPase were 440 nM (EC50 for free Ca2+), 17.5 nmol Pi/mg X min (Vmax) and 100 microM (Km for total ATP). Similar values were found for Ca2+ uptake which was coupled efficiently to Ca2+-stimulated ATPase with a molar ratio of 2.1 +/- 0.1. Exogenous calmodulin had no effect on the Vmax or EC50 for free Ca2+ of the Ca2+-stimulated ATPase, either in the presence or absence of added Mg2+, with or without an ethylene glycol bis(beta-aminoethyl ether)-N,N,N',N',-tetraacetic acid pretreatment of the vesicles. The data demonstrate that calcium stimulates ATP hydrolysis by neutrophil plasma membranes that is coupled optimally to transport of Ca2+ in the presence of concentrations of K+ and Mg2+ that appear to mimic intracellular levels.     

Stimulation of adenosine triphosphatase activity of sarcoplasmic reticulum by adenylyl methylene diphosphate.

The effects of adenylyl methylene diphosphate (AMD), a non-hydrolyzable ATP analogue, were examined in sarcoplasmic reticulum vesicles isolated from rabbit skeletal muscle. The Ca2+-dependent APTase activity measured at 5 degrees C and pH 7.0 in 5.2 micrometer [gamma-32P]ATP and in the absence of added alkali metal salts was stimulated by added AMD. The steady state level of phosphoenzyme, however, was not decreased greatly by added AMP under these conditions. The hydrolysis of the phosphoenzyme formed at the steady state in the absence of added alkali metal salts was accelerated by added AMD to an extent that can account for the stimulation of the ATPase activity. At 5 degrees C and pH 7.0 the maximum stimulation of phosphoenzyme hydrolysis by AMD and the Km value for this ATP analogue were 4.3-fold and 40 micrometer, respectively. These results provide further support for our previous conclusion (Shigekawa, M., Dougherty, J.P. and Katz, A.M. (1978) J.Biol. Chem. 253, 1442--1450) that 2 classes of ATP site exist in the calcium pump ATPase in the absence of added alkali metal salts, one being the catalytic site and the other being the regulation site which activates the activity of the catalytic site.     

Phosphorylation from inorganic phosphate and ATP synthesis of sarcoplasmic membranes

The incorporation of inorganic phosphate in the fragmented sarcoplasmic membranes induced by the removal of calcium ions bound to high affinity binding sites at the cytoplasmic surface of the membranes gives rise to the formation of two species of phosphoenzyme. The properties of the phosphoproteins formed depend on the absence or the presence of a gradient of calcium ions across the membranes. The phosphoenzymes differ by the affinity of the protein for phosphate, the enthalpy of formation, the kinetics of phosphate incorporation, and by the sensitivity to ionophores and ADP. In the absence of a calcium gradient less than 0.5 nmol phosphoenzyme per mg protein are formed in media containing less than 5 mM phosphate at pH7 and 10 degrees C. Under the same conditions approximately 2 nmol of phosphoenzyme per mg protein are formed with an initial rate of 0.5 nmol mg-1-s-1 when a calcium gradient exists. When the gradient is abolished by the addition of the ionophore X537A, the level of phosphoprotein drops to the same value as observed in the absence of a gradient. On addition of ADP at concentrations increasing from 0.3 to 10 muM continuous ATP formation is activated to its maximum rate, and simultaneously, the level of phosphoprotein declines. These concentrations of ADP scarcely affect phosphoprotein formed in the absence of a gradient, the phosphoryl residue of which is displaced when the concentration of ADP exceeds 10 micrometer without the formation of an equivalent amount of ATP. Minimum mechanisms for the formation of gradient-independent and gradient-dependent phosphoprotein are discussed.     

The partial reactions in the catalytic cycle of the calcium-dependent adenosine triphosphatase purified from erythrocyte membranes

A preparation of purified erythrocyte membrane ATPase whose activation by Ca2+ is or is not dependent on calmodulin depending on the enzyme dilution was used in the low dilution state for these studies. In appropriate conditions, the purified ATPase in the absence of calmodulin exhibited a Ca2+ concentration dependence identical to that of the native enzyme in the erythrocyte membrane ghost in the presence of calmodulin. Accordingly, an apparent Kd approximately equal to 1 X 10(-7) M was derived for cooperative calcium binding to the activating and transport sites of the nonphosphorylated enzyme. The kinetics of enzyme phosphorylation in the transient state following addition of ATP to enzyme activated with calcium were then resolved by rapid kinetic methods, demonstrating directly that phosphoenzyme formation precedes Pi production, consistent with the phosphoenzyme role as an intermediate in the catalytic cycle. Titration of a low affinity site (Kd approximately equal to 2 X 10(-3) M) with calcium produced inhibition of phosphoenzyme cleavage and favored reversal of the catalytic cycle, indicating that calcium dissociation from the transport sites precedes hydrolytic cleavage of the phosphoenzyme. The two different calcium dissociation constants of the nonphosphorylated and phosphorylated enzyme demonstrate that a phosphorylation-induced reduction of calcium affinity is the basic coupling mechanism of catalysis and active transport, with an energy expenditure of approximately 6 kcal/mol of calcium in standard conditions. From the kinetic point of view, a rate-limiting step is identified with the slow dissociation of calcium from the phosphoenzyme; another relatively slow step following hydrolytic cleavage and preceding recycling of the enzyme is suggested by the occurrence of a presteady state phosphoenzyme overshoot.     

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.     

Interaction of magnesium and inorganic phosphate with calcium-deprived sarcoplasmic reticulum adenosinetriphosphatase as reflected by organic solvent induced perturbation

The mechanism of sarcoplasmic reticulum (SR) ATPase Mg2+-dependent phosphorylation from Pi was investigated in the presence of 15% v/v dimethyl sulfoxide at pH 6, 20 degrees C, and in the absence of potassium. Measurements of intrinsic fluorescence changes and of 32P-labeled phosphoprotein (*E-P) were in agreement, both at equilibrium and in transient situations. We found that the amount of phosphoenzyme present and its rate of formation depended solely on the concentration of the (Mg X Pi) complex. Up to 6 nmol of phosphate/mg of protein was covalently bound to the enzyme, implying almost complete phosphorylation. Oxygen exchange experiments were also performed in order to allow calculation of the absolute rate constant of *E-P hydrolysis to the noncovalent complex (0.8-1.0 s-1), which differs from the observed rate of enzyme dephosphorylation (0.3-0.5 s-1); in addition, they allowed calculation of the bimolecular rate constant of substrate binding (2-2.4 M-1 s-1). The results demonstrate that in the presence of dimethyl sulfoxide, phosphorylation occurs by the following simple mechanism: relatively slow binding of the neutral substrate (Mg X Pi), with poor affinity, followed by a thermodynamically favorable formation of the covalent bond between phosphate and the possibly hydrophobic active site. The interaction between magnesium and calcium-deprived SR vesicles was studied in the presence of 0-20% v/v dimethyl sulfoxide (or 0-30% v/v glycerol) at pH 7 and 20 degrees C. The presence of either solvent led to the disappearance of the two typical pH-dependent effects we previously characterized for magnesium: loss of the Mg2+-induced spectral shift of tryptophan fluorescence emission and loss of the biphasic pattern displayed by the intrinsic fluorescence rise after addition of calcium to Ca2+-deprived Mg2+-preincubated vesicles. In the absence of solvent, the interaction of magnesium with the calcium-deprived ATPase was also characterized from the point of view of phosphoenzyme formation from ATP or Pi at pH 7 in the absence of potassium: we found that calcium-independent phosphorylation was slower when phosphate was added to SR vesicles preincubated with magnesium that when magnesium was added to vesicles preincubated with phosphate, suggesting that preincubation with magnesium had depleted the phosphate-reactive conformation of the ATPase. A simple reaction scheme for phosphoenzyme formation is described: it implies that the (Mg X Pi) complex is a substrate for this reaction, whereas the Mg2+ itself acts as a pH-dependent, dimethyl sulfoxide sensitive inhibitor of full enzyme phosphorylation.(ABSTRACT TRUNCATED AT 400 WORDS)     

Functional consequences of alterations to Gly310, Gly770, and Gly801 located in the transmembrane domain of the Ca(2+)-ATPase of sarcoplasmic reticulum.

Site-specific mutagenesis was used to replace Gly310, Gly770, and Gly801, located in the transmembrane domain of the sarcoplasmic reticulum Ca(2+)-ATPase, with either alanine or valine. In addition, Gly310 was substituted with proline. In the Gly310----Ala mutant, the Vmax for Ca2+ transport and ATPase activity was reduced to about 40% of the wild type activity, but the apparent Ca2+ affinity was close to normal. The Gly310----Val and Gly310----Pro mutants were devoid of Ca2+ transport or ATPase activity and displayed more than a 20-fold reduction in the apparent Ca2+ affinities measured in the phosphorylation assays with either ATP or Pi. In these mutants, the rate of phosphoenzyme hydrolysis was reduced, and the ADP-insensitive phosphoenzyme intermediate accumulated. The apparent affinity for Pi was increased in the absence, but not in the presence, of dimethyl sulfoxide. The properties of this new class of Ca(2+)-ATPase mutants ("E2/E2P" type) are consistent with a conformational state in which the protein-phosphate interaction is stabilized and the Ca(2+)-protein interaction is destabilized. The Gly770----Ala mutant transported Ca2+ with a Vmax close to that of the wild type, but displayed more than a 20-fold reduction of apparent Ca2+ affinity. The Gly770----Val mutant was not phosphorylated from either ATP or Pi. The Gly801----Ala mutant transported Ca2+ with a Vmax of 126% that of the wild type, hydrolyzed ATP at the same Vmax as the wild type in the presence of calcium ionophore, and displayed a 3-fold reduction in apparent Ca2+ affinity. The Gly801----Val mutant was unable to transport Ca2+ and to be phosphorylated from ATP, even at a Ca2+ concentration of 1 mM, but Ca2+ in the micromolar range inhibited phosphorylation from Pi. The ability to bind ATP with normal affinity was retained. The properties of this mutant are consistent with a disruption of one of the two Ca2+ binding sites required for phosphorylation with ATP.     

Structures of the Ca2+-ATPase complexes with ATP, AMPPCP and AMPPNP. An FTIR study

We studied binding of ATP and of the ATP analogs adenosine 5'-(beta,gamma-methylene)triphosphate (AMPCP) and beta,gamma-imidoadenosine 5'-triphosphate (AMPPNP) to the Ca(2+)-ATPase of the sarcoplasmic reticulum membrane (SERCA1a) with time-resolved infrared spectroscopy. In our experiments, ATP reacted with ATPase which had AMPPCP or AMPPNP bound. These experiments monitored exchange of ATP analog by ATP and phosphorylation to the first phosphoenzyme intermediate Ca(2)E1P. These reactions were triggered by the release of ATP from caged ATP. Only small differences in infrared absorption were observed between the ATP complex and the complexes with AMPPCP and AMPPNP indicating that overall the interactions between nucleotide and ATPase are similar and that all complexes adopt a closed conformation. The spectral differences between ATP and AMPPCP complex were more pronounced at high Ca(2+) concentration (10 mM). They are likely due to a different position of the gamma-phosphate which affects the beta-sheet in the P domain.     

Calcium and magnesium regulation of phosphorylation by ATP and ITP in sarcoplasmic reticulum vesicles.

Membrane phosphorylation and nucleoside triphosphatase activity of sarcoplasmic reticulum vesicles isolated from rabbit skeletal muscle were studied using ATP and ITP as substrates. The Ca2+ concentration was varied over a range large enough to saturate either the high affinity Ca2+-binding site or both high and low affinity binding sites. In intact vesicles, which are able to accumulate Ca2+, the steady state level of enzyme phosphorylated by either ATP or ITP is already high in 0.02 mM Ca2+ and does not vary as the Ca2+ concentration is increased to 10 mM. Essentially the same pattern of membrane phosphorylation by ATP is observed when leaky vesicles, which are unable to accumulate Ca2+, are used. However, for leaky vesicles, when ITP is used as substrate, the phosphoenzyme level increases 3- to 4-fold when the Ca2+ concentration is raised from 0.02 to 20 mM. When Mg2+ is omitted from the assay medum, the degree of membrane phosphorylation by ATP varies with Ca2+ in the same way as when ITP is used in the presence of Mg2+. Membrane phosphorylation of leaky vesicles by either ATP or ITP is observed in the absence of added Mg2+. When these vesicles are incubated in media containing ITP and 0.1 mM Ca2+, addition of Mg2+ up to 10 mM simultaneously decreases the steady state level of phosphoenzyme and increases the rate of ITP hydrolysis. When ATP is used, the addition of 10 mM Mg2+ increases both the steady state level of phosphoenzyme and the rate of ATP hydrolysis. When the Ca2+ concentration is raised to 10 or 20 mM, the degree of membrane phosphorylation by either ATP or ITP is maximal even in the absence of added Mg2+ and does not vary with the addition of 10 mM Mg2+. In these conditions the ATPase and ITPase activities are activated by Mg2+, although not to the level observed in 0.1 mM Ca2+. An excess of Mg2+ inhibits both the rate of hydrolysis and membrane phosphorylation by either ATP or ITP.     

Calcium fluxes across the membrane of sarcoplasmic reticulum vesicles

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

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.     

Steady state kinetics of ATP synthesis and hydrolysis coupled calcium transport catalyzed by the reconstituted sarcoplasmic reticulum ATPase

The steady state kinetics of calcium transport driven by ATP hydrolysis and ATP synthesis catalyzed by purified, reconstituted calcium ATPase has been investigated as a function of the transmembrane calcium gradient. Purified calcium ATPase was reconstituted into phospholipid vesicles enabling control of the transmembrane calcium gradient. Calcium transport was monitored spectrophotometrically by the calcium indicator, Arsenazo III. Thus, only the enzymatic activity of coupled transport was measured. It was shown under conditions of low external calcium that ATP hydrolysis and synthesis follow simple Michaelis-Menten kinetics and that Michaelis constants obtained for both processes appear independent of the calcium gradient. The maximum velocities for both hydrolysis and synthesis strongly depend on the transmembrane calcium gradient. Based on these results, a mechanism is proposed in which a random addition of substrates for ATP synthesis is followed by random release of ATP and calcium. By measuring the ATP hydrolysis and synthesis under identical conditions, determination of the equilibrium constant for ATP hydrolysis as a function of the transmembrane calcium gradient was possible. Our results indicate that the thermodynamics of the catalytic cycle can be totally accounted for by the energetics of transport of 2.2 +/- 0.3 calciums and the hydrolysis of 1 ATP. An equilibrium constant for ATP hydrolysis in the absence of a calcium gradient was determined to be 4.0 X 10(4).