Novel effects of calmodulin and calmodulin antagonists on the plasma membrane (Ca2+ + Mg2+)-ATPase from rabbit kidney proximal tubules.

In this work we report an unusual pattern of activation by calmodulin on the (Ca2+ + Mg2+)-ATPase from basolateral membranes of kidney proximal tubule cells. The activity of the ATPase depleted of calmodulin is characterized by a high Ca2+ affinity (Km = 2.2-3.4 microM) and a biphasic dependence on ATP concentration. The preparation responded to the addition of calmodulin by giving rise to a new Ca2+ site of very high affinity (Km less than 0.05 microM). Calmodulin antagonists had diverse effects on ATPase activity. Compound 48/80 inhibited calmodulin-stimulated activity by 70%, whereas calmidazolium did not modify this component. In the absence of calmodulin, 48/80 still acted as an antagonist, increasing the Km for Ca2+ to 5.7 microM and reducing enzyme turnover by competing with ATP at the low affinity regulatory site. Calmidazolium did not affect Ca2+ affinity, but it did displace ATP from the regulatory site. At fixed Ca2+ (30 microM) and ATP (5 mM) concentrations, Pi protected against 48/80 and potentiated inhibition by calmidazolium. At 25 microM ATP, Pi protected against calmidazolium inhibition. We propose that the effects of ATP and Pi arise because binding of the drugs to the ATPase occurs mainly on the E2 forms.     

Characterisation of a high affinity Ca2+-stimulated, Mg2+-dependent ATPase in the rat parotid plasma membrane

Two Ca2+-stimulated ATPase activities have been identified in the plasma membrane of rat parotid: (a) a (Ca2+ + Mg2+)-ATPase with high affinity for free Ca2+ (apparent Km = 208 nM, Vmax = 188 nmol/min per mg) and requiring micromolar concentration of Mg2+ and (b) a (Ca2+ or Mg2+)-ATPase with relatively low affinity for free Ca2+ (K0.5 = 23 microM) or free Mg2+ (K0.5 = 26 microM). The low-affinity (Ca2+ or Mg2+)-ATPase can be maximally stimulated by Ca2+ alone or Mg2+ alone. The high-affinity (Ca2+ + Mg2+)-ATPase exhibits sigmoidal kinetics with respect to ATP concentration with K0.5 = 0.4 mM and a Hill coefficient of 1.91. It displays low substrate specificity with respect to nucleotide triphosphates. Although trifluoperazine inhibits the activity of the high affinity (Ca2+ + Mg2+)-ATPase only slightly, it inhibits the activity of the low-affinity (Ca2+ or Mg2+)-ATPase quite potently with 22 microM trifluoperazine inhibiting the enzymic activity by 50%. Vanadate, inositol 1,4,5-trisphosphate, phosphatidylinositol 4,5-bisphosphate, Na+,K+ and ouabain had no effect on the activities of both ATPases. Calmodulin added to the plasma membranes does not stimulate the activities of both ATPases. The properties of the high-affinity (Ca2+ + Mg2+)-ATPase are distinctly different from those of the previously reported Ca2+-pump activity of the rat parotid plasma membrane.     

Role of magnesium in the (Ca2+ + Mg2+)-stimulated membrane ATPase of human red blood cells.

(Ca2+ + Mg2+)-stimulated ATPase of human red cell membranes as a function of ATP concentration was measured at fixed Ca2+ concentration and at two different but constant Mg2+ concentrations. Under the assumption that free ATP rather than Mg-ATP is the substrate, a value for Km (for ATP) of 1-2 micron is found which is in good agreement with the value obtained in the phosphorylation reaction by A.F. Rega and P.J. Garrahan (1975. J. Membrane Biol. 22:313). Mg2+ increases both the maximal rate and the affinity for ATP, whereas Ca2+ increases the maximal rate without affecting Km for ATP. As a by-product of these experiments, it was shown that after thorough removal of intracellular proteins the adenylate kinase reaction at approximately 1 mM substrate concentration is several times faster than maximal rate of (Ca2+ + Mg2+)ATPase in red cell membranes.     

ATP inactivates hydrolysis of the K+-sensitive phosphoenzyme of kidney Na+,K+-transport ATPase and activates that of muscle sarcoplasmic reticulum Ca2+-transport ATPase

In order to characterize low affinity ATP-binding sites of renal (Na+,K+) ATPase and sarcoplasmic reticulum (Ca2+)ATPase, the effects of ATP on the splitting of the K+-sensitive phosphoenzymes were compared. ATP inactivated the dephosphorylation in the case of (Na+,K+)ATPase at relatively high concentrations, while activating it in the case of (Ca2+)ATPase. When various nucleotides were tested in place of ATP, inactivators of (Na+,K+)ATPase were found to be activators in (Ca2+)ATPase, with a few exceptions. In the absence of Mg2+, the half-maximum concentration of ATP for the inhibition or for the activation was about 0.35 mM or 0.25 mM, respectively. These values are comparable to the previously reported Km or the dissociation constant of the low affinity ATP site estimated from the steady-state kinetics of the stimulation of ATP hydrolysis or from binding measurements. By increasing the concentration of Mg2+, but not Na+, the effect of ATP on the phosphoenzyme of (Na+,K+)ATPase was reduced. On the other hand, Mg2+ did not modify the effect of ATP on the phosphoenzyme of (Ca2+)ATPase. During (Na+,K+)ATPase turnover, the low affinity ATP site appeared to be exposed in the phosphorylated form of the enzyme, but the magnesium-complexed ATP interacted poorly with the reactive K+-sensitive phosphoenzyme, which has a tightly bound magnesium, probably because of interaction between the divalent cations. In the presence of physiological levels of Mg2+ and K+, ATP appeared to bind to the (Na+,K+)ATPase only after the dephosphorylation, while it binds to the (Ca2+)-ATPase before the dephosphorylation to activate the turnover.     

Two classes of site for ATP in the Ca2+-ATPase from human red cell membranes.

(1) The response of the Ca2+-ATPase activity from human red cell membranes to ATP concentrations can be represented by the sum of two Michaelis-like curves: one with a Km of 2.5 micrometer and the other with a Km of 145 micrometer. (2) The maximum Ca2+-ATPase activity elicited by occupation of the site with lower Km represents about 10% of the activity attainable at non-limiting ATP concentrations. (3) 30--50% of the Ca2+-ATPase activity with lower Km remains in the absence of Mg2+ . Mg2+ increases V and the maximum effect of Ca2+, having no effect on the apparent affinities for ATP and Ca2+. (4) The large increase in Ca2+-ATPase activity which results from the occupation of the site with higher Km only takes place when Mg2+ is present. (5) Results are compatible with the idea that the Ca2+-ATPase from human red cell membranes has two classes of site for ATP binding, both of which are occupied when the enzyme catalyzes the hydrolysis of ATP at maximum rate. (6) The properties of the high affinity site suggest that this is the catalytic site of the Ca2+-ATPase. It is proposed that binding of ATP at the low affinity site regulates the turnover of the system.     

A high affinity calcium-stimulated magnesium-dependent ATPase in rat liver plasma membranes. Dependence of an endogenous protein activator distinct from calmodulin

A Mg-dependent adenosine triphosphatase (ATPase) activated by submicromolar free Ca2+ was identified in detergent-dispersed rat liver plasma membranes after fractionation by concanavalin A-Ultrogel chromatography. Further resolution by DE-52 chromatography resulted in the separation of an activator from the enzyme. The activator, although sensitive to trypsin hydrolysis, was distinct from calmodulin for it was degraded by boiling for 2 min, and its action was not sensitive to trifluoperazine; in addition, calmodulin at concentrations ranging from 0.25 ng-25 micrograms/assay had no effect on enzyme activity. Ca2+ activation followed a cooperative mechanism (nH = 1.4), half-maximal activation occurring at 13 +/- 5 nM free Ca2+. ATP, ITP, GTP, CTP, UPT, and ADP displayed similar affinities for the enzyme; K0.5 for ATP was 21+/- 9 microM. However, the highest hydrolysis rate (20 mumol of Pi/mg of protein/10 min) was observed at 0.25 mM ATP. For all the substrates tested kinetic studies indicated that two interacting catalytic sites were involved. Half-maximal activity of the enzyme required less than 12 microM total Mg2+. This low requirement for Mg2+ of the high affinity (Ca2+-Mg2+)ATPase was probably the major kinetic difference between this activity and the nonspecific (Ca2+ or Mg2+)ATPase. In fact, definition of new assay conditions, i.e. a low ATP concentration (0.25 mM) and the absence of added Mg2+, allowed us to reveal the (Ca2+-Mg2+)ATPase activity in native rat liver plasma membranes. This enzyme belongs to the class of plasma membrane (Ca2+-Mg2+)ATPases dependent on submicromolar free Ca2+ probably responsible for extrusion of intracellular Ca2+.     

The high affinity (Ca2+-Mg2+)-ATPase in liver plasma membranes is a Ca2+ pump. Reconstitution of the purified enzyme into phospholipid vesicles

The purified (Ca2+-Mg2+)-ATPase from rat liver plasma membranes (Lotersztajn, S., Hanoune, J., and Pecker, F. (1981) J. Biol. Chem. 256, 11209-11215) was incorporated into soybean phospholipid vesicles, together with its activator. In the presence of millimolar concentrations of Mg2+, the reconstituted proteoliposomes displayed a rapid, saturable, ATP-dependent Ca2+ uptake. Half-maximal Ca2+ uptake activity was observed at 13 +/- 3 nM free Ca2+, and the apparent Km for ATP was 16 +/- 6 microM. Ca2+ accumulated into proteoliposomes (2.8 +/- 0.2 nmol of Ca2+/mg of protein/90 s) was totally released upon addition of the Ca2+ ionophore A-23187. Ca2+ uptake into vesicles reconstituted with enzyme alone was stimulated 2-2.5-fold by the (Ca2+-Mg2+)-ATPase activator, added exogenously. The (Ca2+-Mg2+)-ATPase activity of the reconstituted vesicles, measured using the same assay conditions as for ATP-dependent Ca2+ uptake activity (e.g. in the presence of millimolar concentrations of Mg2+), was maximally activated by 20 nM free Ca2+, half-maximal activation occurring at 13 nM free Ca2+. The stoichiometry of Ca2+ transport versus ATP hydrolysis approximated 0.3. These results provide a direct demonstration that the high affinity (Ca2+-Mg2+)-ATPase identified in liver plasma membranes is responsible for Ca2+ transport.     

The kinetics and divalent cation inhibition of plasma membrane ATPase in the yeast Candida albicans

The kinetics of ATP hydrolysis and cation effects on ATPase activity in plasma membrane from Candida albicans ATCC 10261 yeast cells were investigated. The ATPase showed classical Michaelis-Menten kinetics for the hydrolysis of Mg X ATP, with Km = 4.8 mM Mg X ATP. Na+ and K+ stimulated the ATPase slightly (9% at 20 mM). Divalent cations in combination with ATP gave lower ATPase activity than Mg X ATP (Mg greater than Mn greater than Co greater than Zn greater than Ni greater than Ca). Divalent cations inhibited the Mg X ATPase (Zn greater than Ni greater than Co greater than Ca greater than Mn). Free Mg2+ inhibited Mg X ATPase weakly (20% inhibition at 10 mM). Computed analyses of substrate concentrations showed that free Zn2+ inhibited Zn X ATPase, mixed (Zn2+ + Mg2+) X ATPase, and Mg X ATPase activities. Zn X ATP showed high affinity for ATPase (Km = 1.0 mM Zn X ATP) but lower turnover (52%) relative to Mg X ATP. Inhibition of Mg X ATPase by (free) Zn2+ was noncompetitive, Ki = 90 microM Zn2+. The existence of a divalent cation inhibitory site on the plasma membrane Mg X ATPase is proposed.     

The locus of nucleotide specificity in the reaction mechanism of (Na+ + K+)-ATPase determined with ATP and GTP as substrates

ATP and GTP have been compared as substrates for (Na+ + K+)-ATPase in Na+-activated hydrolysis, Na+-activated phosphorylation, and the E2K----E1K transition. Without added K+ the optimal Na+-activated hydrolysis rates in imidazole-HCl (pH 7.2) are equal, but are reached at different Na+ concentrations: 80 mM Na+ for GTP, 300 mM Na+ for ATP. The affinities of the substrates for the enzyme are widely different: Km for ATP 0.6 microM, for GTP 147 microM. The Mg-complexed nucleotides antagonize activation as well as inhibition by Na+, depending on the affinity and concentration of the substrate. The optimal 3-s phosphorylation levels in imidazole-HCl (pH 7.0) are equally high for the two substrates (3.6 nmol/mg protein). The Km value for ATP is 0.1-0.2 microM and for GTP it ranges from 50 to 170 microM, depending on the Na+ concentration. The affinity of Na+ for the enzyme in phosphorylation is lower with the lower affinity substrate: Km (Na+) is 1.1 mM with ATP and 3.6 mM with GTP. The GTP-phosphorylated intermediate exists, like the ATP-phosphorylated intermediate, in the E2P conformation. Addition of K+ increases the optimal hydrolytic activity 30-fold for ATP (at 100 mM Na+ + 10 mM K+) and 2-fold for GTP (at 100 mM Na+ + 0.16 mM K+). K+ greatly increases the Km values for both substrates (to 430 microM for ATP and 320 microM for GTP). Above 0.16 mM K+ inhibits GTP hydrolysis. GTP does not reverse the quenching effect of K+ on the fluorescence of the 5-iodoacetamidofluorescein-labeled enzyme. ATP fully reverses this effect, which represents the transition from E1K to E2K. Hence GTP is unable to drive the E2K----E1K transition.     

The [Ca2+ + Mg2+]-dependent adenosine triphosphatase of SV40 transformed WI38 lung fibroblasts

The Ca2+-stimulated, Mg2+-dependent ATPase of SV40 transformed WI38 lung fibroblast homogenates exhibits a high affinity for Ca2+ (K0.5 = 0.20 microM) and moderately high affinity for ATP (Km = 28.6 microM) and Mg2+ (K0.5 = 138.5 microM). This activity was NaN3, KCN and oligomycin insensitive but very sensitive to vanadate (I50 = 0.5 microM) suggesting its being neither mitochondrial or microsomal but plasma membrane in origin. Under optimal conditions of protein, hydrogen ion and substrate concentration, 16-19 nmoles phosphate was released per min per mg protein. Hill plot analysis indicated no cooperativity to occur between Ca2+ binding sites. Nucleotides other than ATP and dATP were ineffective as substrates. The trivalent cation, lanthanum (La3+) completely inhibited hydrolysis of ATP at approximately 70 microM (I50 = 25 microM). Calmodulin antagonists trifluoperazine and calmidazolium inhibited ATP hydrolysis in a dose dependent fashion.     

ATP utilizing reactions of human erythrocyte membranes and the influence of modulator proteins

The ATP production of human erythrocytes in the steady state (approximately 2 mmoles . 1 cells-1 . h-1, 37 degrees C, pHi 7.2) is maintained by glycolysis and the ATP consumption is essentially limited to the cell membrane. About 25% of the ATP consumption is used for ion transport ATPases. The bulk of the ATP consuming processes in intact erythrocytes remains poorly understood. "Isotonic" erythrocyte membranes prepared under approximate intracellular conditions after freeze-thaw hemolysis have high (Ca2+, Mg2+)-ATPase activities (80% of the total membrane ATPase activity). There is a great discrepancy between the high capacity of the (Ca2+, Mg2+)-ATPase in isotonic membranes and the actual activity in the intact cell. The (Ca2+, Mg2+)-ATPase of isotonic membranes has a "high" Ca2+-affinity (Ka less than 0.5 microM) and a "low" Mg-ATP affinity (Km approximately 760 microM). This state of (Ca2+, Mg2+)-ATPase is caused by the association of calmodulin and 30000 Dalton polypeptides (ATP affinity modulator protein). Hypotonic washings of isotonic membranes result in a loss of the 30 kD polypeptides. EGTA (0.5 mM) extracts derived from isotonic membranes contain the 30 kD modulator protein and restore the properties of the (Ca2+, Mg2+)-ATPase of hypotonic membrane preparations to the isotonic characteristics. The Mg-ATP affinity modulator protein is assumed to form a complex with calmodulin and (Ca2+, Mg2+)-ATPase.     

The reaction of Mg2+ with the Ca2+-ATPase from human red cell membranes and its modification by Ca2+

Media prepared with CDTA and low concentrations of Ca2+, as judged by the lack of Na+-dependent phosphorylation and ATPase activity of (Na+ +K+)-ATPase preparations are free of contaminant Mg2+. In these media, the Ca2+-ATPase from human red cell membranes is phosphorylated by ATP, and a low Ca2+-ATPase activity is present. In the absence of Mg2+ the rate of phosphorylation in the presence of 1 microM Ca2+ is very low but it approaches the rate measured in Mg2+-containing media if the concentration of Ca2+ is increased to 5 mM. The KCa for phosphorylation is 2 microM in the presence and 60 microM in the absence of Mg2+. Results are consistent with the idea that for catalysis of phosphorylation the Ca2+-ATPase needs Ca2+ at the transport site and Mg2+ at an activating site and that Ca2+ replaces Mg2+ at this site. Under conditions in which it increases the rate of phosphorylation, Ca2+ is without effect on the Ca2+-ATPase activity in the absence of Mg2+ suggesting that to stimulate ATP hydrolysis Mg2+ accelerates a reaction other than phosphorylation. Activation of the E1P----E2P reaction by Mg2+ is prevented by Ca2+ after but not before the synthesis of E1P from E1 and ATP, suggesting that Mg2+ stabilizes E1 in a state from which Mg2+ cannot be removed by Ca2+ and that Ca2+ stabilizes E1P in a state insensitive to Mg2+. The response of the Ca2+-ATPase activity to Mg2+ concentration is biphasic, activation with a KMg = 88 microM is followed by inhibition with a Ki = 9.2 mM. Ca2+ at concentration up to 1 mM acts as a dead-end inhibitor of the activation by Mg2+, and Mg2+ at concentrations up to 0.5 mM acts as a dead-end inhibitor of the effects of Ca2+ at the transport site of the Ca2+-ATPase.     

High affinity Ca2+-stimulated Mg2+-dependent ATPase in rat brain synaptosomes, synaptic membranes, and microsomes

High affinity Ca2+-stimulated Mg2+-dependent ATPase activity of nerve ending particles (synaptosomes) from rat brain tissue appears to be associated primarily with isolated synaptic plasma membranes. The synaptic membrane (Ca2+ + Mg2+)-ATPase activity was found to exhibit strict dependence on Mg2+ for the presence of the activity, a high affinity for Ca2+ (K0.5 = 0.23 microM), and relatively high affinities for both Mg2+ and ATP (K0.5 = 6.0 microM for Mg2+ and KM = 18.9 microM for ATP). These kinetic constants were determined in incubation media that were buffered with the divalent cation chelator trans-cyclohexane-1,2-diamine-N,N,N',N'-tetraacetic acid. The enzyme activity was not inhibited by ouabain or oligomycin but was sensitive to low concentrations of vanadate. The microsomal membrane subfraction was the other brain subcellular fraction with a high affinity (Ca2+ + Mg2+)-ATPase activity which approximated that of the synaptic plasma membranes. The two membrane-related high affinity (Ca2+ + Mg2+)-ATPase activities could be distinguished on the basis of their differential sensitivity to vanadate at concentrations below 10 microM. Only the synaptic plasma membrane (Ca2+ + Mg2+)-ATPase was inhibited by 0.25-10 microM vanadate. The studies described here indicate the possible involvement of both the microsomal and the neuronal plasma membrane (Ca2+ + Mg2+)-ATPase in high affinity Ca2+ transport across membranes of brain neurons. In addition, they suggest a means by which the relative contributions of each transport system might be evaluated based on their differential sensitivity to inhibition by vanadate.     

Mg2+ and ATP effects on K+ activation of the Ca2+-transport ATPase of cardiac sarcoplasmic reticulum.

ATP and the divalent cations Mg2+ and Ca2+ regulated K+ stimulation of the Ca2+-transport ATPase of cardiac sarcoplasmic reticulum vesicles. Millimolar concentrations of total ATP increased the K+-stimulated ATPase activity of the Ca2+ pump by two mechanisms. First, ATP chelated free Mg2+ and, at low ionized Mg2+ concentrations, K+ was shown to be a potent activator of ATP hydrolysis. In the absence of K+ ionized Mg2+ activated the enzyme half-maximally at approximately 1 mM, whereas in the presence of K+ the concentration of ionized Mg2+ required for half-maximal activation was reduced at least 20-fold. Second MgATP apparently interacted directly with the enzyme at a low affinity nucleotide site to facilitate K+-stimulation. With a saturating concentration of ionized Mg2+, stimulation by K+ was 2-fold, but only when the MgATP concentration was greater than 2 mM. Hill plots showed that K+ increased the concentration of MgATP required for half-maximal enzymic activation approx. 3-fold. Activation of K+-stimulated ATPase activity by Ca2+ was maximal at an ionized Ca2+ concentration of approx. 1 microM. At very high concentrations of either Ca2+ or Mg2+, basal Ca2+-dependent ATPase activity persisted, but the enzymic response to K+ was completely inhibited. The results provide further evidence that the Ca2+-transport ATPase of cardiac sarcoplasmic reticulum has distinct sites for monovalent cations, which in turn interact allosterically with other regulatory sites on the enzyme.     

Two Ca2+-requiring p-nitrophenylphosphatase activities of the highly purified Ca2+-pumping adenosinetriphosphatase of human erythrocyte membranes, one requiring calmodulin and the other ATP

The highly purified Ca2+-pumping ATPase from human erythrocyte membranes displays two p-nitrophenylphosphatase (NPPase) activities: one of these requires calmodulin and low concentrations of Ca2+, while the other requires ATP and higher Ca2+ concentrations. The free Ca2+ concentrations required for the expression of the two NPPase activities differed very substantially. Both activities required high free Mg2+ concentrations and displayed simple hyperbolic kinetics toward p-nitrophenyl phosphate (NPP) with a Km in the range of 5-20 mM. Study of the dependence of the calmodulin-stimulated NPPase on Mg2+ and NPP indicated that the Mg-NPP complex is not the substrate of the enzyme. Under conditions optimal for ATP-requiring NPPase (1 mM free Ca2+), the Ca2+-ATPase displayed simple hyperbolic kinetics with a low Km for ATP. NPP competitively inhibited this activity, and the apparent Ki for NPP was less than 1 mM, much lower than the Km for NPP as a substrate. If NPP were inhibiting the ATPase by binding at the same site at which NPP is hydrolyzed, the apparent Ki for NPP as inhibitor would be the same as the Km for NPP as substrate. (Under these circumstances, the apparent Ki and the Km can be directly compared, since NPP was being hydrolyzed under both circumstances.) Since Ki was much lower than Km, NPP must have been inhibiting at another site; thus, these data show the existence of two types of NPP sites on the enzyme, one at which NPP is hydrolyzed and the other at which it inhibits ATP hydrolysis.(ABSTRACT TRUNCATED AT 250 WORDS)     

Reconstruction of purified Ca2+,Mg2+-ATPase from the myometrium sarcolemma into liposomes and its catalytic properties

The Ca2+, Mg2(+)-ATPase of the myometrium sarcolemma purified by the method of affinity chromatography on calmodulin sepharose is reconstituted into azolectin liposomes in the functionally active form by means of cholate dialysis. The ATPase-dependent accumulation of 45Ca is shown on the obtained model system. It makes up 95% of the total accumulation and may decrease to 43% under the effect of 0.8 microM A23187. Ca2+, Mg2(+)-ATPase reconstituted into azolectin liposomes is in the high affinity to Ca2+; Km for Ca2+ is equal to 0.88 +/- 0.22 microM, calmodulin practically does not change it. The highest activity of the reconstituted enzyme is observed at pH 7.0, temperature 50 degrees C, the Mg-ATP concentration 1-2 mM. The Km for substrate is 0.45 +/- 0.02 mM.     

Ca2+ activation of membrane-bound (Ca2++Mg2+)-dependent ATPase from human erythrocytes prepared in the presence or absence of Ca2+.

The kinetics of Ca2+ activation of membrane-bound (Ca2+ + Mg2+)-dependent ATPase (ATP phosphohydrolase EC 3.6.1.3) from human erythrocytes was studied. The ATPase from membrane prepared in the presence of 0.7-500muM Ca2+ showed positively cooperative behaviour and a Km for Ca2+ of between 1 and 4 muM. If the membranes were prepared in the absence of Ca2+ the Km increased, and an enzyme model with at least four calcium-binding sites accounted for the kinetic change assuming that one calcium-binding site decreased its affinity. Mg2+ or Mg-ATP could not replace Ca2+. Continuous-flow centrifugation involving a shear stress on membranes was necessary to obtain the high affinity ATPase activity. Using ordinary centrifugation the Ca2+-prepared membranes behaved as membranes prepared in the absence of Ca2+. The Ca2+-stimulated ATPase from membranes prepared without Ca2+ showed reduced maximum activity, but dialyzed, membrane-free hemolysates, whether prepared with Ca2+ present or not, recovered the activity when the hemolysate was present during the ATPase assay. It is suggested that the different Ca2+-affinities of the Ca2+-stimulated ATPase correspond to two different states of the calcium-pump.     

Characterization of a putative Ca2(+)-transporting Ca2(+)-ATPase in the pellicles of Paramecium tetraurelia

In Paramecium, no Ca2(+)-ATPases with the properties of Ca2+ pumps have been identified. Here we report a pellicle associated Ca2(+)-ATPase activity and a corresponding phosphoprotein intermediate characteristic of a pump. The Ca2(+)-ATPase activity requires 3 mM Mg for optimal Ca2+ stimulation (KCa = 90 nM) and is specific for ATP as substrate (Km = 75 microM). Vanadate and calmidazolium inhibit Ca2(+)-stimulated activity with an EC50 of about 2 microM and 0.5 microM, respectively. Likewise, 10 microM trifluoperazine inhibits 80% of Ca2(+)-ATPase activity, but bovine calmodulin fails to stimulate. The Ca2(+)-ATPase is not inhibited by sodium azide (10 mM), oligomycin (10 micrograms/ml) or ouabain (0.2 mM). Incubation of pellicles with [gamma-32P]ATP specifically labels a 133 kDa protein in a Ca2(+)-dependent, hydroxylamine-sensitive manner, and the level of phosphorylation is increased by 100 microM La3+. Phosphorylation of an endoplasmic reticulum-enriched fraction labels a Ca2(+)-dependent protein different from the pellicle protein, being lower in molecular mass and unaffected by La3+. Ca2+ uptake by the alveolar sacs, integral components of the pellicle membrane complex, is poorly coupled to Ca2(+)-stimulated ATP hydrolysis (Ca2+ transported/ATP hydrolysed less than 0.2) and is much less sensitive to vanadate inhibition (EC50 approx. 20 microM) compared to the total Ca2(+)-ATPase activity. Therefore, the majority of the Ca2(+)-ATPase activity is likely to be plasma membrane associated.     

The H(+)-ATPase of the plasma membrane from yeast. Kinetics of ATP hydrolysis in native membranes, isolated and reconstituted enzymes

The H(+)-ATPase of the plasma membrane from Saccharomyces cerevisiae has been isolated, purified and reconstituted into asolectin liposomes. The kinetics of ATP hydrolysis have been compared for the H(+)-ATPase in the plasma membrane, in a protein/lipid/detergent micelle (isolated enzyme) and in asolectin proteoliposomes (reconstituted enzyme). In all three cases the kinetics of ATP hydrolysis can be described by Michaelis-Menten kinetics with Km = 0.2 mM MgATP (plasma membranes), Km = 2.4 mM MgATP (isolated enzyme) and Km = 0.2 mM MgATP (reconstituted enzyme). However, the maximal turnover decreases only by a factor of two during isolation of the enzyme and does not change during reconstitution; the activation of the H(+)-ATPase by free Mg2+ is also only slightly influenced by the detergent. The dissociation constant of the enzyme-Mg2+ complex Ka, does not alter during isolation and the dissociation constant of the enzyme-substrate complex, Ks, increases from Ks = 30 microM (plasma membranes) to Ks = 90 microM (isolated enzyme). ATP binding to the H(+)-ATPase ('single turnover' conditions) for the isolated and the reconstituted enzyme resulted in both cases in a second-order rate constant k1 = 2.6 x 10(4) M-1.s-1. From these observations it is concluded that the detergent used (Zwittergent TM 3-14) interacts reversibly with the H(+)-ATPase and that practically all H(+)-ATPase molecules are reconstituted into the liposomes with the ATP-binding site being directed to the outside of the vesicle.     

Studies on the bivalent-cation-activated ATPase activities of highly purified human platelet surface and intracellular membranes.

Membrane-bound Ca2+-ATPases are responsible for the energy-dependent transport of Ca2+ across membrane barriers against concentration gradients. Such enzymes have been identified in sarcoplasmic reticulum of muscle tissues and in non-muscle cells in both surface membranes and endoplasmic-reticulum-like intracellular membrane complexes. In a previous study using membrane fractionation by density-gradient and free-flow electrophoresis, we reported that the intracellular membranes of human blood platelets were a major storage site for Ca2+ and involved in maintaining low cytosol [Ca2+] in the unactivated cell. In the present report we demonstrated that the intracellular membranes also exhibit a high-affinity Ca2+-ATPase which appears to be kinetically associated with the Ca2+-sequestering process. We found that both the surface membrane and the intracellular membrane exhibited a basal Mg2+-ATPase activity, but Ca2+ activation of this enzyme was confined only to the intracellular membrane. Use of Ca2+-EGTA buffers to control the extravesicle [Ca2+] allowed a direct comparison of the Ca2+-ATPase and the Ca2+-uptake process over a Ca2+ range of 0.01 microM to 1.0 mM, and it was found that both properties were maximally expressed in the range of external [Ca2+] 1-50 microM, with concentrations greater than 100 microM showing substantial inhibition. Double-reciprocal plots for the Ca2+-ATPase activity and Ca2+ uptake gave apparent Km values for Ca2+ of 0.15 and 0.13 microM respectively. However, similar plots for ATP with the enzyme revealed a discontinuity (two affinity sites, with Km 20 and 145 microM), whereas plots for the Ca2+ uptake gave a single Km value for Ca2+, 1.1 microM. Phosphorylation studies during Ca2+ uptake using [gamma-32P]ATP revealed two components of 90 and 95 kDa phosphorylated at extravesicle [Ca2+] of 3 microM. The Ca2+-ATPase activity, Ca2+ uptake and phosphorylation were all almost completely inhibited in the presence of 500 microM-Ca2+. Similar studies using mixed membranes revealed four other phosphoproteins (50, 40, 20 and 18 kDa) formed in addition to the 90 and 95 kDa components. The findings are discussed in the context of platelet Ca2+ mobilization for function and the mechanisms whereby Ca2+ homoeostasis is controlled in the unactivated cell.