Lipid peroxidation and active calcium transport in inside-out vesicles of red blood cells from preeclamptic women

We previously reported that in preeclampsia Ca-ATPase activity diminishes about 50% in red blood cells, myometrium and syncitiotrophoblast plasma membranes. In this work, we measured the active Ca++ uptake by inside-out vesicles of human red blood cells from preeclamptic and normotensive pregnant women. Active calcium uptake by the vesicles was diminished by 49+/-3% in the preeclamptic women as compared to the gestational controls ( 8.06 +/- 0.11 nmol Ca++/mg protein min, gestational controls; 4.08 +/- 0.1 nmol Ca++/mg protein min, preeclamptics). This lowered calcium uptake correlates well with the lowered Ca-ATPase activity found in the red blood cells ghosts of the preeclamptic women (17.05 +/- 0.96 nmol Pi/mg protein min, gestational controls; 8.85 +/- 0.45 nmol Pi/mg protein min, preeclamptics). The reduced calcium uptake and Ca-ATPase activity of the red cell membranes both appear to be associated with a high level of lipid peroxidation. Thus there is a diminution in the active transport of calcium in the red blood cells of preeclamptic women. If this also occurs in other cell types of the preclamptic women, it could result in an increase in their cytosolic calcium concentration which might be responsible, in part, for some of the symptoms of this disease.     

Ca-ATPase of human myometrium plasma membranes

We determined and characterized the Mg2+-dependent, Ca2+-stimulated ATPase (Ca-ATPase) activity in cell plasma membranes from the myometrium of pregnant women, and compared these characteristics to those of the active Ca2+-transport already demonstrated in this tissue. Similarly to the Ca2+-transport system, the Ca2+-ATPase is Mg2+-dependent, stimulated by calmodulin, and inhibited by vanadate. The Km for Ca2+ activation is 0.40 microM, very similar to that found for active calcium transport, i.e. 0.25 microM. Consequently, this Ca2+-ATPase can be responsible for the active calcium transport across the plasma membranes of smooth muscle cells.     

Activation of the Ca2+-ATPase of human erythrocyte membrane by an endogenous Ca2+-dependent neutral protease

Limited proteolysis of the plasma membrane calcium transport ATPase (Ca2+-ATPase) from human erythrocytes by trypsin produces a calmodulin-like activation of its ATP hydrolytic activity and abolishes its calmodulin sensitivity. We now demonstrate a similar kind of activation of the human erythrocyte membrane Ca2+-ATPase by calpain (calcium-dependent neutral protease) isolated from the human red cell cytosol. Upon incubation of red blood cell membranes with purified calpain in the presence of Ca2+ the membrane-bound Ca2+-ATPase activity was increased and its sensitivity to calmodulin was lost. In contrast to the action of other proteases tested, proteolysis by calpain favors activation over inactivation of the Ca2+-ATPase activity, except at calpain concentrations more than 2 orders of magnitude higher. Exogenous calmodulin protects the Ca2+-ATPase against calpain-mediated activation at concentrations which also activate the Ca2+-ATPase activity. Calcium-dependent proteolytic modification of the Ca2+-ATPase could provide a mechanism for the irreversible activation of the membrane-bound enzyme.     

ATPase and phosphatase activities from human red cell membranes: II. The effects of phospholipases on Ca2+-dependent enzymic activities.

Treatment of human red cell membranes with pure phospholipase A2 results in a progressive inactivation of both Ca2+-dependent and (Ca2+ + K+)-dependent ATPase and phosphatase activities. When phospholipase C replaces phospholipase A2, Ca2+-dependent ATPase activity and Ca2+-dependent phosphorylation of red cell membranes are lost, while Ca2+-dependent phosphatase activity is enhanced and its apparent affinity for Ca2+ is increased about 20-fold. Activation of Ca2+-dependent phosphatase following phospholipase C treatment was not observed in sarcoplasmic reticulum preparation. Phospholipase C increases the sensitivity of the phosphatase to N-ethylmaleimide but has little effect on the kinetic parameters relating the phosphatase activity to substrate and cofactors, suggesting that no extensive structural disarrangement of the Ca2+-ATPase system has occurred after incubation with phospholipase C.     

Effects of calcium and soluble cytoplasmic activator protein (calmodulin) on various states of (Ca2+ + Mg2+)-ATPase activity in isolated membranes of human red cells

(Ca2+ + Mg2+)-ATPase activity of red cells and their isolated membranes was investigated in the presence of various Ca2+ concentrations and cytoplasmic activator protein. Red cell ATPase activity was high at low Ca2+ concentrations, and low at moderate and high concentrations of Ca2+. In the case of isolated membranes, both low and moderate ca2+ concentrations produced higher (Ca2+ + Mg2+)-ATPase activity than high Ca2+ concentration. Membrane-free hemolysate containing soluble activator of (Ca2+ + Mg2+)-ATPase produced a significant increase in (Ca2+ + Mg2+)-ATPase activity only at low ca2+ concentration. Regardless of Ca2+ and activator concentrations, the enzyme activity in the membrane was lower than lysed red cells. The low level of (Ca2+ + Mg2+)-ATPase activity seen at high Ca2+ concentration can be augmented by lowering the Ca2+ concentration of EGTA in the assay medium. However, once the membrane was exposed to a high Ca2+ concentration, the activator could no longer exert it maximum stimulation at the low Ca2+ concentration brought about by addition of EGTA. This loss of activation was not attributable to the Ca2+-induced denaturation of activator protein but rather related to the alteration of (Ca2+ + Mg2+)-ATPase states in the membrane. On the basis of these data, it is suggested that only a small portion of (Ca2+ + Mg2+)-ATPase activity of isolated membranes can be stimulated by the soluble activator and that (ca2+ + Mg2+)ATPase most likely exists in various states depending upon ca2+ concentration and the presence of activator. The enzyme state exhibiting the high degree of stimulation by activator may undergo irreversible damage in the presence of high Ca2+ concentrations.     

Structural and functional properties of a Ca2+-ATPase from human platelets

An antibody prepared against highly purified rabbit muscle Ca2+-ATPase from sarcoplasmic reticulum has been observed to cross-react with proteins in human platelet membrane vesicles. The antibody specifically precipitated Ca2+-ATPase activity from solubilized human platelet membranes and recognized two platelet polypeptides denatured in sodium dodecyl sulfate with Mr = 107,000 and 101,000. Ca2+-ATPase activity from Brij 78-solubilized platelet membranes was purified up to 10-fold. The purified preparation consisted mainly of two polypeptides with Mr approximately 100,000, and 40,000. The lower molecular weight protein appeared unrelated to Ca2+-ATPase activity. The Ca2+-ATPase in human platelet membrane vesicles exhibited "negative cooperativity" with respect to the kinetics of ATP hydrolysis. The apparent Km for Ca2+ activation of ATPase activity was 0.1 microM. Ca2+-dependent phosphorylation of platelet vesicles by [gamma-32P]ATP at 0 degrees C yielded a maximum of 0.2-0.4 nmol of PO4/mg of protein that was labile at pH 7.0 and 20 degrees C. This result suggests that only about 2-4% of the total protein in platelet membrane vesicles is the Ca2+-ATPase, which agrees with an estimate based on the specific activity of the Ca2+-ATPase in platelet membranes (20-50 nmol of ATP hydrolyzed/min/mg of protein at 30 degrees C). Calmodulin resulted in only a 1.6-fold stimulation of Ca2+-ATPase activity even after extensive washing of membranes with a calcium chelator or chlorpromazine. It is concluded that human platelets contain a Ca2+-ATPase immunochemically related to the Ca2+ pump from rabbit sarcoplasmic reticulum and that the enzymatic characteristics and molecular weight of the platelet ATPase are quite similar to those of the muscle ATPase.     

Membrane crystals of Ca2+-ATPase in sarcoplasmic reticulum of fast and slow skeletal and cardiac muscles

Crystalline arrays of Ca2+ transport ATPase develop in sarcoplasmic reticulum membranes after treatment with Na3VO4 in a calcium-free medium [ Dux , L. and Martonosi , A. (1983) J. Biol. Chem. 258, 2599-2603]. The proportion of vesicles containing Ca2+-ATPase crystals in microsome preparations isolated from rat muscle of different fiber types (semimembranosus, levator ani, extensor digitorum longus, diaphragm, soleus, and heart) correlates well with the Ca2+-ATPase content and Ca2+-modulated ATPase activity. This implies that the concentration of Ca2+-ATPase in sarcoplasmic reticulum membranes of fast and slow skeletal or cardiac muscles differs only slightly, and the low Ca2+ transport activity of 'sarcoplasmic reticulum' preparations isolated from slow-twitch skeletal and cardiac muscles is due to the presence of large amount of non-sarcoplasmic-reticulum membrane elements. This is in accord with the relatively small differences in the density of 8.5-nm intramembranous particles seen by freeze-etch electron microscopy in sarcoplasmic reticulum of red and white muscles. The dimensions of the Ca2+-ATPase crystal lattice are similar in sarcoplasmic reticulum membranes of different fiber types; therefore if structural differences exist between 'isoenzymes' of Ca2+-ATPase, these are not reflected in the crystal-lattice.     

Trifluoperazine inhibition of calmodulin-sensitive Ca2+ -ATPase and calmodulin insensitive (Na+ +K+)- and Mg2+ -ATPase activities of human and rat red blood cells

Trifluoperazine dihydrochloride-induced inhibition of calmodulin-activated Ca2+ -ATPase and calmodulin-insensitive (Na+ +K+)- and Mg2+ -ATPase activities of rat and human red cell lysates and their isolated membranes was studied. Trifluoperazine inhibited both calmodulin-sensitive and calmodulin-insensitive ATPase activities in these systems. The concentration of trifluoperazine required to produce 50% inhibition of calmodulin-sensitive Ca2+ -ATPase was found to be slightly lower than that required to produce the same level of inhibition of other ATPase activities. Drug concentrations which inhibited calmodulin-sensitive ATPase completely, produced significant reduction in calmodulin-insensitive ATPases as well. The data presented in this report suggest that trifluoperazine is slightly selective towards calmodulin-sensitive Ca2+ -ATPase but that it is also capable of inhibiting calmodulin-insensitive (Na+ +K+)-ATPase and Mg2+ -ATPase activities of red cells at relatively low concentrations. Thus the action of the drug is not due entirely to its interaction with calmodulin-mediated processes, and trifluoperazine cannot be assumed to be a selective inhibitor of calmodulin interactions under all circumstances.     

Fe2+ and other divalent metal ions uncouple Ca2+ transport from (Ca2+-Mg2+)-ATPase in rat liver plasma membranes

The addition of nanomolar concentrations of free Fe2+, Mn2+, or Co2+ to rat liver plasma membranes resulted in an activation of ATP hydrolysis by these membranes which was not additive with the Ca2+-stimulated ATPase activity coupled to the Ca2+ pump. Detailed analysis showed that, if fact, (i) as for the stimulation of (Ca2+-Mg2+)-ATPase by Ca2+, activation of ATP hydrolysis by Fe2+, Mn3+, or Co2+ followed a cooperative mechanism involving two ions; (ii) two interacting sites for ATP were involved in the activation of both Fe2+- and Ca2+-stimulated ATPase activities; (iii) micromolar concentrations of magnesium caused the same dramatic inhibition of both activities; and (iv) the subcellular distribution of Fe2+-activated ATP hydrolysis activity corresponded to that of plasma membrane markers. This suggests that the (Ca2+-Mg2+)-ATPase might be stimulated not only by Ca2+, but also by Fe2+, Mn2+, or Co2+. However, interaction of (Ca2+-Mg2+)-ATPase with Fe2+, Mn2+, or Co2+ inhibited the Ca2+ pump activity. Furthermore, neither the formation of the phosphorylated intermediate of (Ca2+-Mg2+)-ATPase, nor ATP-dependent (59Fe) uptake could be detected in the presence of Fe2+ concentrations which stimulated ATP hydrolysis. We conclude that: (i) under the influence of certain metal ions, the Ca2+ pump in the liver plasma membrane may be switched to an uncoupled state which displays ATP hydrolysis activity, but does not insure ion transport; (ii) therefore the Ca2+ pump in liver plasma membranes specifically insures Ca2+ transport.     

Calcium transport in human erythrocytes. Separation and reconstitution of high and low Ca affinity (Mg mca)-AT Pase activities in membranes prepared at low ionic strength.

Human erythrocyte membranes obtained by freeze-thawing of ghosts prepared in the absence or presence of EDTA, by washing with a 12 mosm medium at pH 7.7 or a 2 mosm medium at pH 6.5 contain both high and low Ca affinity (Mg + Ca)-ATPase activities. Incubation of ghosts in a less than 2 mosm medium at pH 7.5 or in 0.1 mm EDTA + 1 Him Tris-maleate (pH 8.0) results in removal of the high affinity (Mg + Ca)-ATPase activity from the membrane in a time dependent manner. Under similar conditions up to 25% of membrane proteins are removed. The soluble protein fraction extracted, although devoid of ATPase activity, reconstitutes with the remaining membrane residue with restoration of original (Mg + Ca)-ATPase activity. Addition of the soluble protein fraction to heat-treated membranes devoid of low affinity (Mg + Ca)-ATPase activity allows reconstitution of more than 33% of the original high affinity (Mg + Ca)-ATPase activity which has a Ca dissociation constant of approximately 1.6μm. Temperature and phospholipase A₂ studies indicate that low affinity (Mg + Ca)-ATPase activity is phospholipid dependent in contrast to high affinity (Mg + Ca)-ATPase activity. Ruthenium red and LaCl₃ inhibit both high and low affinity (Mg + Ca)-ATPase activities with similar potencies. The ease of removal of high affinity (Mg + Ca)-ATPase activity from the membrane by relatively mild conditions suggests that an activator protein or the high affinity (Mg + Ca)-ATPase itself is only loosely attached to the membrane. These studies show that low affinity (Mg + Ca)-ATPase activity is not an artifact and is distinct from high affinity (Mg + Ca)-ATPase activity. The low affinity (Mg + Ca)-ATPase activity is sensitive to Ca²⁺ in the concentration range from below 0.3 μm to 300 μm compatible with an association of this enzyme with Ca transport.     

The plasma membrane calcium pump: regulation by a soluble Ca2+ binding protein

The Ca2+ pump of the plasma membrane of human red blood cells is associated with the activity of a (Ca2+ + Mg2+)-ATPase. Both the ATPase and the pump are stimulated above basal activities by calmodulin, an ubiquitous Ca2+-binding protein. Calmodulin isolated from human red blood cells was shown to be equipotent and equieffective with that isolated from beef brain. Half-maximal activation of ATPase (isolated red blood cell membranes, 37 C) and transport (inside-out red blood cell membrane vesicles, 25 C) were obtained with 2.5 and 4.4 nM calmodulin, respectively. Ca2+ dependence of Ca2+ transport was measured in the absence and in the presence of 50 nM calmodulin. At all Ca2+ concentrations above 2 X 10(-7) M Ca2+, the rate of transport was greater in the presence of calmodulin. The results implicate calmodulin in the regulation of the plasma membrane Ca2+ pump, but the mechanism(s) remain to be elucidated.     

Calcium-Activated ATPases in Presynaptic Nerve Endings

We studied the properties of calcium-activated ATPases present in preparations of isolated presynaptic nerve ending (synaptosome) and its subfractions from mouse brain. ATPase activity in the preparation was stimulated by Ca2+ and by Mg2+, but not by Na+ and K+, when each was added alone. The substrate specificities were found to be similar. The ATPases hydrolyzed only the high-energy phosphate bond and similar activity was exhibited for all nucleoside triphosphates tested (ATP, CTP, GTP, UTP). Moreover, the enzymes were insensitive to mitochondrial markers and to ouabain, but were inhibited by La3+. La3+ produced uncompetitive inhibition of Ca2+-ATPase in intact synaptosomes. Inhibition by La3+ was greatly increased after lysis of the synaptosomes, suggesting that the active sites of the enzymes may be on the cytosolic face of the membranes. The Ca2+-ATPase activity in synaptosomes was increased by increasing concentrations of external K+, suggesting that Ca2+ influx may be involved The Ca2+-ATPase in synaptosomal plasma membranes and synaptic vesicles had higher specific activities than those of intact synaptosomes and were activated, both in the presence and the absence of Mg2+, by Ca2+ concentrations approximating the intracellular level (10(-7) M). It is concluded that the nonmitochondrial synaptosomal Ca2+-ATPase may play an important role in the regulation of intracellular Ca2+.     

Inhibition of red cell Ca2+-ATPase by vanadate

1. The Mg2+- plus Ca2+-dependent ATPase (Ca2+-ATPase) in human red cell membranes is susceptible to inhibition by low concentrations of vanadate. 2. Several natural activators of Ca2+-ATPase (Mg2+, K+, Na+ and calmodulin) modify inhibition by increasing the apparent affinity of the enzyme for vanadate. 3. Among the ligands tests, K+, in combination with Mg2+, had the most pronounced effect on inhibition by vanadate. 4. Under conditions optimal for inhibition of Ca2+-ATPase, the K 1/2 for vanadate was 1.5 microM and inhibition was nearly complete at saturating vanadate concentrations. 5. There are similarities between the kinetics of inhibition of red cell Ca2+-ATPase and (Na+ + K+)-ATPase prepared from a variety of sources; however, (Na+ + K+)-ATPase is approx. 3 times more sensitive to inhibition by vanadate.     

Effect of ovarian steroids on membrane ATPase activities in microsomes (microsomal fractions) from rat myometrium. Inhibition of a component of the Mg2+-activated ATPase by Ca2+-calmodulin and by oxytocin.

The activities of Mg2+-ATPase (Mg2+-activated ATPase), (Ca2+ + Mg2+)-activated ATPase and (Na+ + K+)-activated ATPase have been determined in microsomes (microsomal fractions) obtained from rat myometrium under different hormonal conditions. Animals were either ovariectomized and treated for a prolonged period of time with 17 beta-oestradiol or progesterone, or myometria were obtained at day 21 of pregnancy. In each case the endometrium was carefully removed. The Mg2+-ATPase consists of two components: an inactivating labile component and a second constant component. The rate of ATP hydrolysis by the labile component of the Mg2+-ATPase declines exponentially as a function of time after adding the membranes to the assay medium; this inactivation is caused by the presence of ATP in the medium. This ATPase activity inhibited by ATP is catalysed by a labile enzyme and hence it gradually diminishes within a few hours, even when the microsomes are kept on ice. This labile component has the highest activity in microsomes from pregnant rats, a lower activity in progesterone-treated rats, and the lowest in 17 beta-oestradiol-treated rats. This component of the Mg2+-ATPase is not affected by 90 nM-oxytocin. The constant component of the Mg2+-ATPase must be ascribed to a different enzyme, which, in contrast with the labile component, is very stable and not affected by the hormonal status of the animal. This constant component of the Mg2+-ATPase is inhibited both by Ca2+-calmodulin, and by oxytocin in microsomes from pregnant and from progesterone-treated animals, whereas such inhibition does not occur in microsomes from 17 beta-oestradiol-treated animals. The activity of the (Na+ + K+)-activated ATPase is not dependent on the hormonal status of the animal. Myometrial microsomes present an ATP-dependent Ca2+ transport, irrespective of the hormonal condition, but only in microsomes obtained from rats treated with 17 beta-oestradiol, can a (Ca2+ + Mg2+)-activated ATPase activity be demonstrated. This activity can be stimulated by calmodulin.     

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.     

The role of a (Ca2+ + Mg2+)-ATPase of the rough endoplasmic reticulum in regulating intracellular Ca2+ during cholinergic stimulation of rat pancreatic acini

Rough endoplasmic reticulum membranes, purified from isolated rat pancreatic acini stimulated by carbachol, had a decreased Ca2+ content and increased (Ca2+ + Mg2+)-ATPase activity. Ca2+ was regained and ATPase activity reduced to control levels only after blockade by atropine. The (Ca2+ + Mg2+)-ATPase was activated by free Ca2+ (half-maximal at 0.17 microM; maximal at 0.7 microM) over the concentration range which occurs in the cell cytoplasm. Pretreatment with EGTA, at a high concentration (5 mM), inhibited ATPase activity which, our results suggest, was due to removal of a bound activator such as calmodulin. The rate of (Ca2+ + Mg2+)-ATPase actively declined during the 10-min period over which maximal active accumulation of Ca2+ by membrane vesicles occurs. In the presence of ionophore A23187, which released actively accumulated Ca2+ and stimulated the (Ca2+ + Mg2+)-ATPase, this time-dependent decline in activity was not observed. Our data provide evidence that the activity of the Ca2+-transporting ATPase of the rough endoplasmic reticulum is regulated by both extra and intravesicular Ca2+ and is consistent with a direct role of this enzyme in the release and uptake of Ca2+ during cholinergic stimulation of pancreatic acinar cells.     

Abnormal Ca2(+)-ATPase activity in erythrocytes of non-insulin-dependent diabetic rats

Non-insulin-dependent diabetic (NIDD) rats have an increased Ca2(+)-ATPase activity in their kidney basolateral membranes. We find that a similar increased activity occurs in erythrocytes of the NIDD animals. This alteration in membrane ATPase activity appears to be specific for the Ca2(+)-ATPase as (Na(+) + K+) and Mg2(+)-ATPase and Na, K and Mg concentrations in the erythrocyte were not affected by the diabetic condition in these animals. Thus, abnormalities in membrane Ca2(+)-ATPase activity in the NIDD rats are not restricted to one tissue and appear to be a generalized pathology in the NIDD animals.     

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.     

Target sizes of human erythrocyte membrane Ca2+-ATPase and Mg2+-ATPase activities in the presence and absence of calmodulin

We have investigated the subunit structure of Ca2+-transport ATPase in human erythrocyte membranes using radiation inactivation analysis. All inactivation data were linear on a semilog plot down to at least 20% of the control activity. We found a target size for the calmodulin-dependent Ca2+-ATPase activity of 331 kDa, consistent with the presence of this enzyme as a dimer in calmodulin-depleted ghosts. Membranes which had been saturated with calmodulin before irradiation yield a a similar size of 317 kDa, implying that activation of Ca2+-transport ATPase by calmodulin does not involve significant change in oligomeric structure. Basal (calmodulin-independent) Ca2+-ATPase activity corresponded to a size of 290 kDa, suggesting that this activity resides in the same, or similar-sized, complex as the calmodulin-dependent activity. Mg2+-ATPase activity, however, was found to reside in a smaller complex of 224 kDa, which proved to be statistically distinct from the target size of Ca2+-ATPase activity. It would appear that Mg2+-ATPase is a distinct entity whose function is likely unrelated to the Ca2+-transport ATPase.     

ATPase and phosphatase activities from human red cell membranes: I. The effects of N-ethylmaleimide.

In human red cell membranes the sensitivity to N-ethylmaleimide of Ca2+-dependent ATPase and phosphatase activities is at least ten times larger than the sensitivity to N-ethylmaleimide of (Na+ + K+)-ATPase and K+-activated phosphatase activities. All activities are partially protected against N-ethylmaleimide by ATP but not by inorganic phosphate or by p-nitrophenylphosphate. (ii) Protection by ATP of (Na+ + K+)-ATPase is impeded by either Na+ or K+ whereas only K+ impedes protection by ATP of K+-activated phosphatase. On the other hand, Na+ or K+ slightly protects Ca2+-dependent activities against N-ethylmaleimide, this effect being independent of ATP. (iii) The sensitivity to N-ethylmaleimide of Ca2+-dependent ATPase and phosphatase activities is markedly enhanced by low concentrations of Ca2+. This effect is half-maximal at less than 1 micron Ca2+ and does not require ATP, which suggests that sites with high affinity for Ca2+ exist in the Ca2+-ATPase in the absence of ATP. (IV) Under all conditions tested the response to N-ethylmaleimide of the ATPase and phosphatase activities stimulated by K+ or Na+ in the presence of Ca2+ parallels that of the Ca2+-dependent activities, suggesting that the Ca2+-ATPase system possesses sites at which monovalent cations bind to increase its activity.