On the Mechanism of Activation of the Plasma Membrane Ca2+-ATPase by ATP and Acidic Phospholipids*

Claudia V. Filomatori {ddagger} and Alcides F. Rega §

From the Instituto de Química y Fisicoquímica Biológicas, Facultad de Farmacia y Bioquímica, Junín 956, 1113 Buenos Aires, Argentina

Received for publication, March 14, 2003 , and in revised form, March 24, 2003.


    ABSTRACT
 TOP
 ABSTRACT
 INTRODUCTION
 EXPERIMENTAL PROCEDURES
 RESULTS AND DISCUSSION
 REFERENCES
 
The activation of purified and phospholipid-depleted plasma membrane Ca2+-ATPase by phospholipids and ATP was studied. Enzyme activity increased with [ATP] along biphasic curves representing the sum of two Michaelis-Menten equations. Acidic phospholipids (phosphatidylinositol (PI) and phosphatidylserine (PS)) increased Vmax without affecting apparent affinities of the ATP sites. In the presence of 20 µM ATP, phosphorylation of the enzyme preincubated with Ca2+ (CaE1) was very fast (kapp {cong} 400 s1). vo of phosphorylation of CaE1 increased with [ATP] along a Michaelis-Menten curve (Km of 15 µM) and was phospholipid-independent. Without Ca2+ preincubation (E1 + E2), vo of phosphorylation was also phospholipid-independent, but was slower and increased with [ATP] along biphasic curves. The high affinity component reflected rapid phosphorylation of CaE1, the low affinity component the E2 -> E1 shift, which accelerated to a rate higher than that of the ATPase activity when ATP was bound to the regulatory site. Dephosphorylation of EP did not occur without ATP. Dephosphorylation increased along a biphasic curve with increasing [ATP], showing that ATP accelerated dephosphorylation independently of phospholipid. PI, but not phosphatidylethanolamine (PE), accelerated dephosphorylation even in the absence of ATP. kapp for dephosphorylation was 57 s1 at 0 µM ATP; that rate was further increased by ATP. Steady-state [EP] x kapp for dephosphorylation varied with [ATP], and matched the Ca2+-ATPase activity measured under the same conditions. Apparently, the catalytic cycle is rate-limited by dephosphorylation. Acidic phospholipids stimulate Ca2+-ATPase activity by accelerating dephosphorylation, while ATP accelerates both dephosphorylation and the conformational change from E2 to E1, further stimulating the ATPase activity.


    INTRODUCTION
 TOP
 ABSTRACT
 INTRODUCTION
 EXPERIMENTAL PROCEDURES
 RESULTS AND DISCUSSION
 REFERENCES
 
PMCA,1 which couples ATP hydrolysis to the extrusion of Ca2+ from the cytosol across the plasma membrane of most cells, is strongly modulated by natural PLs and ATP. Acidic PLs like PS and PI increase the enzyme's apparent affinity for Ca2+ and its turnover, whereas neutral PLs like PC and PE are without effect (1, 2). Acidic PLs may exert their effect by simultaneously interacting with the C-terminal regulatory region of PMCA and with a region between putative transmembrane domains 2 and 3 (3, 4). PS has also been reported to increase the phosphorylation, and therefore the activity, of Na/K-ATPase (5), but more recent reports suggest that the key determinant of Na/K-ATPase activity resides in the length of the fatty acyl chains rather than in the polar heads of the PLs (6, 7). Acidic PLs have no significant effect on the affinity of Ca2+ for SERCA, but do reduce the level of ATP binding, thereby inhibiting the enzyme activity (8). There are reports of activation of SERCA by PI, but that involves a complex mechanism involving phosphorylation of PI by ATP in the absence of Ca2+ (9, 10). It seems, therefore, that activation by acidic PLs is unique to PMCA. On the other hand, the binding of ATP at a regulatory site with lower affinity than the catalytic site increases the rate of ATP hydrolysis (11) and Ca2+ transport (12) by PMCA, as well as the activities of Na/K-ATPase (13, 14, 15) and SERCA (16, 17, 18).

We previously reported that PS lowers the apparent dissociation constant for ATP at the low affinity site on PMCA from 9700 to 640 µ,M in red cell membranes (19), an observation that others confirmed and extended to PI with PMCA purified from porcine erythrocytes (20). The fact that the concentration of ATP in the cytoplasm of most cells is near 1 mM suggests activation of PMCA by ATP is a physiologically significant event, and that it would only exert its effect in the presence of acidic PL. Likewise, PL would only have an effect on PMCA activity in the presence of ATP. Little specific information about the relationship between PL, ATP, and PMCA is currently available, however.

One way to approach this question is to measure the effects of PL and ATP on the partial reactions of the PMCA catalytic cycle in Scheme I (21). We recently measured the phosphorylation and dephosphorylation (Scheme I, Reactions 3 and 6) of purified PL-depleted PMCA under pre-steady-state conditions and found that asolectin, a mixture of acidic PLs, accelerated dephosphorylation of EP (21). This enzyme preparation should be suitable for studying the effects of ligands on partial reactions because: (i) it is virtually free of contaminant protein, (ii) the radioactivity incorporated from [{gamma}-32P]ATP is largely EP, (iii) it is free of CaM, which usually contaminates membrane preparations, and (iv) the nature of accompanying lipids can be controlled with pure PLs. In this work we present the results of rapid mixing experiments designed to test the effects of pure acidic and neutral PLs and ATP on the kinetics of the partial reactions that take place during hydrolysis of ATP by PMCA.



View larger version (11K):
[in this window]
[in a new window]
 
SCHEME I
 


    EXPERIMENTAL PROCEDURES
 TOP
 ABSTRACT
 INTRODUCTION
 EXPERIMENTAL PROCEDURES
 RESULTS AND DISCUSSION
 REFERENCES
 
Reagents—[{gamma}-32P]ATP was prepared by the method of Glynn and Chappell (22), except that no unlabelled orthophosphate was added to the incubation medium. Carrier-free [32P]H3PO4 was provided by the Comisión Nacional de Energía Atómica (Buenos Aires, Argentina). L-{alpha}-phosphatidylinositol, L-{alpha}-phosphatidyl-L-serine, L-{alpha}-phosphatidylethanolamine Type V, L-{alpha}-phosphatidylcholine, C12E10, CaM-agarose, and the enzymes and cofactors for the synthesis of [{gamma}-32P]ATP were all obtained from Sigma Chemical Co. Salts and reagents were of analytical reagent grade.

Isolation of PMCA—Cell membranes depleted of CaM were prepared from pig red blood cells using the method of Gietzen et al. (23) with some modification. PL-depleted PMCA was isolated by affinity chromatography on a CaM-agarose column as described by Penniston et al. (24), with C12E10, K-MOPS and 20% (w/v) glycerol replacing Triton X-100, TES and PC, respectively. No PLs were added to the medium. The CaM-agarose column with the PMCA bound was washed with 30-column volumes of washing buffer, after which the enzyme was eluted with buffer containing 20 mM K-MOPS (pH 7.40 at 4 °C), 130 mM KCl, 1 mM MgCl2, 0.5 mg/ml C12E10, 2 mM dithiothreitol, 20% (w/v) glycerol, and 1 mM EGTA. No measurements were made of the amount of PL that may have remained with the enzyme. However, assuming that the activity of the soluble enzyme was fully dependent on PL, comparison of the ATPase activity in the absence and presence of added PI indicted the level of delipidation to be close to 90%. Protein concentrations were measured by the method of Lowry et al. (25) after the protein had been precipitated using deoxycholate and trichloroacetic acid to avoid interference (26). Bovine serum albumin was used as the standard.

Estimation of ATPase Activity—ATPase activity was estimated from the release of [32P]Pi from [{gamma}-32P]ATP at 25 °C. Samples (1–2 µg) of PMCA were preincubated for at least 10 min in 0.15 ml of buffer containing 0.5 mM EGTA, 100 mM KCl, 0.5 mM MgCl2, 50 mM Tris-HCl (pH 7.40 at 25 °C), and 150 µM free Ca2+, 140 µg/ml C12E10, 20% (w/v) glycerol, and 0 or 66 µg/ml PL. The reaction was started by addition of 0.15 ml of the same buffer containing the indicated concentrations of [{gamma}-32P]ATP plus an equimolar concentration of MgCl2.

Phosphorylation and Dephosphorylation of PMCA—Phosphorylation of PMCA using [{gamma}-32P]ATP was carried out at 25 °C in a rapid mixing apparatus adapted for chemical quenching (Intermekron AB, Uppsala, Sweden) based on the design of Mardh and Zetterqvist (27). In a typical experiment, one syringe contained 10–15 µg of purified PMCA, 140 µg of C12E10, 20% (w/v) glycerol, and 0 or 66 µg of pure PL in 1 ml of buffer containing 0.5 mM EGTA, 100 mM KCl, 0.5 mM MgCl2, 50 mM Tris-HCl (pH 7.40 at 25 °C), and 0 or 150 µM free Ca2+. A second syringe contained [{gamma}-32P]ATP, which had been passed through a Millipore filter (type HAWP, 0.45-µm pore size) before use, plus an equimolar concentration of MgCl2 in 1 ml of the same buffer. The enzyme in the buffer was preincubated with or without Ca2+ at 25 °C for at least 10 min before phosphorylation. The reaction was started by mixing the contents of the two syringes and was ended by collecting the mixture in 9 ml of denaturing solution containing 8.5% (w/v) trichloroacetic acid, 10 mM ATP, and 50 mM H3PO4 at 0 °C. The EP in the denaturing solution was collected by vacuum filtration by carefully adding the mixture, drop by drop, onto the center of a Millipore filter (type HAWP, 0.45-µm pore size). The residue on the filters was washed five times with 10 ml of 7% (w/v) trichloroacetic acid and 50 mM H3PO4, after which the filters were dried, and the radioactivity was measured by counting in 3 ml of Optiphase scintillation liquid (Fisher Chemical Co.). A blank was prepared by measuring the radioactivity incorporated by the enzyme in medium containing no CaCl2. The value of the blank was dependent on the amount of [{gamma}-32P]ATP added, but it did not vary with the reaction time and was subtracted from the EP measured in the presence of Ca2+.

Dephosphorylation was measured at 25 °C using three syringes and two mixing chambers, as described previously (21). EP was formed in the lines between the first and second mixing chambers and was chased in the second mixing chamber with buffer containing 5 mM EGTA and various concentrations of unlabeled ATP.


    RESULTS AND DISCUSSION
 TOP
 ABSTRACT
 INTRODUCTION
 EXPERIMENTAL PROCEDURES
 RESULTS AND DISCUSSION
 REFERENCES
 
Effect of PL and ATP on Ca2+-ATPase Activity—Fig. 1 shows the ATPase activity of the PL-depleted PMCA at 25 °C plotted as a function of the ATP concentration in medium containing either no PL or PE, PC, PS, or PI. In each case, the data were fitted by curves representing the sum of two Michaelis-Menten equations with the kinetic parameters shown in Table I. The range of values obtained for Km1 and Km2 fell within the range observed in our laboratory during successive measurements of Km under identical experimental conditions, and there was no significant correlation between Km1 or Km2 and the species of PL present. We therefore conclude that Km1 and Km2, and thus the interaction between ATP and the catalytic and regulatory sites of PMCA, are PL-independent, which is at variance with earlier reports suggesting that acidic PLs lower Km2 (19, 20). On the other hand, the observation that under any of the conditions tested activity curves were biphasic allowed to conclude that binding of ATP to the regulatory site activated the enzyme independently of PL.



View larger version (21K):
[in this window]
[in a new window]
 
FIG. 1.
Activation by ATP of PL-depleted PMCA in medium without added PL ({circ}) or with PE (), PC ({blacksquare}), PS ({triangleup}), or PI ({blacktriangleup}). The curves were fitted by the equation v = (V1 [ATP])/(Km1 + [ATP]) + (V2 [ATP])/(Km2 + [ATP]), where V1 and V2 are the maximum velocities, and Km1 and Km2 are the Michaelis-Menten constants of the high and the low affinity components, respectively. Kinetic parameters obtained by fitting the equation to the data using Sigma Plot for Windows are given in Table I. The symbols and bars depict means ± S.D. (n = 2).

 

View this table:
[in this window]
[in a new window]
 
TABLE I
Effect of PL on kinetic parameters of the ATPase activity of PMCA

The values ± S.D. correspond to the curves in Fig. 1.

 

Table I also shows that while PC increased Vm1 of the delipidated enzyme by nearly 45%, PS or PI increased Vm1 by 100% or more. Moreover, activation was much more clearly reflected by Vm2, which increased 10-fold in the presence of the acidic PLs. It appears, therefore, that in the presence of excess Ca2+, both PS and PI activate PMCA by increasing Vm rather than the apparent affinity for ATP.

It is noteworthy that at constant enzyme and detergent concentrations, omission of glycerol or Ca2+ from the incubation medium leads to irreversible loss of activity of detergent-purified PMCA (28). It is also known that such inactivation is diminished by PC, asolectin or erythrocyte membrane PLs (28, 29). With that in mind, one might ask whether the effects of PL summarized in Fig. 1 were due to protection of the enzyme rather than to its activation. To address this question, the enzyme in 20% (w/v) glycerol was incubated at 25 °C for varying lengths of time with and without PL, after which ATPase activity was measured in the same medium following addition of appropriate amounts of ATP and Ca2+. We found that incubation without Ca2+ and PL inactivated PMCA with a t1/2 = 30 min. The enzyme was fully protected by 33 µg/ml PI, while either 33 µg/ml PE or 100 µM Ca2+ reduced the amount of inactivation after 60 min incubation to only 20% of that seen in their absence. In the presence of 100 µM Ca2+, either PI, PE, or PC stabilized the activity of detergent-purified PMCA such that it remained unchanged even after 60 min of incubation. Given these observations, one would expect no more than 10% inactivation of the enzyme during the 10-min preincubation in medium containing glycerol, Ca2+, and no PL. Consequently, we are confident that the results shown in Fig. 1 do not reflect protection of the enzyme against inactivation. The information provided by the inactivation experiments was also useful for determining the conditions employed in the experiments described below.

Effect of PL on the Phosphorylation Kinetics—Fig. 2 shows the kinetics of EP formation when PMCA was preincubated in medium containing Ca2+ and Mg2+, with and without the indicated PLs, and then phosphorylated in the same medium containing 20 µM [{gamma}-32P]ATP at 25 °C. In the absence of added PL, the time course of phosphorylation was biphasic, with a rapid component (kapp = 367 s1) that reached a maximum of 843 pmol/mg of protein, followed by a slow component (kapp = 20 s1) that reached a maximum of 270 pmol/mg of protein. The steady-state concentration of EP was increased somewhat by PE and reduced somewhat by PC without changing the shape of the curve. By contrast, in the presence of the acidic PI or PS, the concentration of EP increased rapidly up to a maximum close to 600 pmol/mg of protein in 4 ms with kapp values of 325 s–1 and 427 s1 for PI and PS, respectively, and then declined more slowly to a steady-state level of near 470 pmol/mg of protein, a value about half that reached in the absence of acidic PL. These results confirm and extend to pure PC and PS our earlier findings on the effects of asolectin and pure PE and PI on the time course of phosphorylation of PL-depleted PMCA (21), and lend further support to the conclusion that the initial rate of phosphorylation (Scheme I, Reaction 3) is PL-independent.



View larger version (19K):
[in this window]
[in a new window]
 
FIG. 2.
Effect of PL on the time course of PMCA phosphorylation. PL-depleted PMCA was preincubated with 150 µM Ca2+ without PL ({circ}) or with PE (•), PC ({blacksquare}), PS ({triangleup}), or PI ({blacktriangleup}) and then phosphorylated by addition of 20 µM [{gamma}-32P]ATP. The curves obtained in the presence of PI and PS were drawn by eye. The curves obtained without PL and with PE or PC were fitted by the equation [EP] = [EPf](1 – exp(–kf·t) + [EPs](1 – exp(–ks·t), where t is time; kf and ks are the rate constants for the fast and the slow components, respectively (367 and 20 s1 without PLs, 506 and 33 s1 with PE, and 400 and 16 s1 with PC); [EPf] and [EPs] are the maximum concentrations of EP during the fast and the slow components, respectively (843 and 270 pmol/mg of protein without PLs, 980 and 103 pmol/mg of protein with PE and 828 and 63 pmol/mg of protein with PC). The symbols and bars depict means ± S.D. (n = 2).

 

Our earlier findings (21) suggest that the data shown in Fig. 2 might be the result of a transient fast phosphorylation of CaE1 occurring during preincubation and leading to a maximum EP concentration at about 4 ms, followed by a slower phosphorylation limited by the rate of CaE1 formation from CaE1P across Reactions 4, 5, 6, 7, and 1 in Scheme I. Moreover, under conditions that stimulate PMCA overall activity, acidic PLs reduced by 50% the steady-state concentration of EP. This suggests that acidic PLs accelerate at least one of the reactions following Reaction 3.

Effect of the Timing of the Addition of Ca2+ on the Kinetics of Phosphorylation—During the experiments summarized in Fig. 2, the enzyme was preincubated with Ca2+ and then phosphorylated by the addition of ATP. Fig. 3 shows the kinetics of the phosphorylation when Ca2+ and ATP were added simultaneously to PMCA preincubated with PI in the absence of Ca2+. The concentration of EP increased rapidly up to 4 ms and then at a slower rate to 500 pmol/mg of protein after 120 ms. The level of EP at 4 ms was 200 pmol/mg of protein, as compared with 600 pmol/mg of protein when Ca2+ was added before ATP (compare Figs. 2 and 3). This is in keeping with our earlier observation that preincubating PMCA in medium with limiting concentrations of Ca2+ lowered the rate of phosphorylation (21). Comparison of results in Figs. 2 and 3 also shows that: (i) the steady-state [EP] was the same regardless of the presence of Ca2+ during preincubation, and (ii) steady-state was reached at 20 ms in the presence while at 120 ms in the absence of Ca2+ during preincubation. This is consistent with the idea that activation of the PMCA by Ca2+ during phosphorylation depends on a slower reaction prior to phosphorylation, as will be shown below.



View larger version (14K):
[in this window]
[in a new window]
 
FIG. 3.
Time course of phosphorylation of PMCA preincubated without Ca2+ PMCA was preincubated with PI in absence of Ca2+ and phosphorylated under the conditions described in Fig. 2 by mixing 20 µM [{gamma}-32P]ATP with enough Ca2+ to give a final concentration of 150 µM. The curve was drawn by eye. The symbols and bars depict means ± S.D. (n = 3).

 

Effect of PI and ATP on the Steady-state Concentration of Phosphoenzyme—It has been shown previously that steady-state [EP] increases along a hyperbolic curve as a function of the ATP concentration up to 100 µM in human red cell membranes (Km, 6.5 µM at 0 °C) (30) as well as in preparations of purified enzyme (Km, 8.2 µM at 25 °C) (31). Furthermore, using a wider range of ATP concentrations, including some high enough for ATP to interact with the low affinity site, [EP] was shown to increase along a biphasic curve with a high affinity component (Km, 3.2–12.7 µM) and a low affinity component (Km, 515–665 µM) (32). As a result, the [EP] at 2 mM ATP is 3–5 times higher than at 0.1 mM ATP, which is indicative of the large effect exerted by the nucleotide binding to the low affinity site.

Because the results in Fig. 2 were obtained at a single ATP concentration, they do not provide information about the effects of ATP on steady-state [EP] or on the initial rate of phosphorylation. To measure those parameters simultaneously is troublesome, so we looked first at the effects of ATP (2–1000 µM) on steady-state [EP] in the presence and absence of PI. The results in Fig. 4 show that Km1 and Km2 were 2 and 155 µM, which is consistent with the values in Table I for the activity of the enzyme in the absence of PL. The low affinity component in Fig. 4, [EP]2, cannot be correlated with Vm2 in Table I, except with respect to its relative contribution to the total [EP], which is calculated as the ratio [EP]2/[EP]1 + [EP]2 and gave a value of 17%. Its equivalent for the ATPase activity calculated using the appropriate values in Table I (Vm2/Vm1 + Vm2) was 24%.



View larger version (15K):
[in this window]
[in a new window]
 
FIG. 4.
Effect of ATP on steady-state [EP] in absence ({circ}) and presence of PI ({blacktriangleup}). PMCA was phosphorylated using increasing concentrations of [{gamma}-32P]ATP for a period of 60 ms. The data were best fitted by the equation v = ([EP1] [ATP])/(Km1 + [ATP]) + ([EP2] [ATP])/(Km2 + [ATP]) in which [EP1] and [EP2] were respectively 1337 and 273 pmol/mg of protein in the absence of PI and 545 and 341 pmol/mg of protein in the presence of PI. Km1 and Km2 were, respectively, 2 and 155 µM in the absence of PI and 3 and 201 µM in the presence of PI. The symbols and bars depict means ± S.D. (n = 2).

 

Fig. 4 also shows the effects of ATP on [EP] in the presence of PI. As expected from the results in Fig. 2, PI reduced [EP]. Here again the values of Km1 and Km2 were consistent with the corresponding values in Table I. Under these conditions [EP]2/[EP]1 + [EP]2 = 38%, while Vm2/Vm1 + Vm2 = 58%. Thus, an increase in [EP] at high ATP concentrations in the presence of PI does not account for the increase in ATPase activity observed in Fig. 1 under similar conditions.

Effects of PL, ATP, and the Timing of the Addition of Ca2+ on the Initial Rate of Phosphorylation—The effect of ATP on vo of phosphorylation was tested on PMCA preincubated with or without Ca2+ and then phosphorylated using increasing concentrations of [{gamma}-32P]ATP for up to 3 ms. Fig. 5 shows that when preincubated with Ca2+ plus either the acidic PI or the neutral PE, the initial rate of PMCA phosphorylation increased with the ATP concentration along a Michaelis-Menten-like curve (Km, 15.0 µM) to a maximum of 570 pmol/mg of protein/ms at 200 µM ATP and then remained constant up to 800 µM ATP. Since the Km value was close to those in the literature (30, 31), it was concluded that, at any ATP concentration, phosphorylation of the enzyme preincubated with Ca2+ followed the binding of ATP to the high affinity catalytic site and was PL-independent.



View larger version (24K):
[in this window]
[in a new window]
 
FIG. 5.
Effect of ATP and PL on the initial rate of phosphorylation of PMCA preincubated with or without Ca2+ PMCA was preincubated for 10 min in medium containing either PE (open symbols) or PI (closed symbols), with ({circ}, •) and without ({square}, {blacksquare}) Ca2+, and then phosphorylated using increasing concentrations of [{gamma}-32P]ATP (5 to 800 µM). At each ATP concentration, vo of phosphorylation was estimated from the slope of the time course of phosphorylation up to 3 ms. The inset shows Lineweaver-Burk plots of the data. The curves best fitting the data obtained when PMCA was preincubated with Ca2+ were Michaelis-Menten-like: vo max = 570 pmol/mg of protein/ms and Km = 15 µM with either PE or PI. When the PMCA was preincubated without Ca2+, the data were best fitted by the equation vo = (vo max1 [ATP])/(Km1 + [ATP]) + (vo max2 [ATP])/(Km2 + [ATP]), where vo max1 and vo max2 are the maximum rates of phosphorylation after occupation of the high and low affinity sites, respectively. Their values were estimated by extrapolation of the double reciprocal plots and were respectively 97 and 150 pmol/mg of protein/ms with PE and 127 and 206 pmol/mg of protein/ms with PI. Km1 and Km2 are the Michaelis-Menten constants for the two sites and were respectively 17 and 142 µM with PE and 14 and 183 µM with PI. The symbols and bars depict means ± S.D. (n = 3).

 

Fig. 5 also shows the initial rate of phosphorylation of PMCA preincubated with either PI or PE in the absence of Ca2+ prior to simultaneous addition of [{gamma}-32P]ATP and Ca2+. Confirming the results in Fig. 3, phosphorylation was significantly slower than when PMCA was preincubated with Ca2+. It could be argued that this was a consequence of the conditions used in this particular experiment, which could have retarded the association of ATP with the enzyme, thereby reducing the number of reacting units. That possibility was dismissed, however, after a control experiment showed that addition of 0, 10, or 100 µM ATP to the Ca2+-free preincubation medium had no effect on the phosphorylation rate. In the absence of Ca2+, the rate of phosphorylation of preincubated PMCA increased along curves having two components whose parameters are given in the legend to Fig. 5. The rates obtained with PE were lower than with PI, a difference attributed to partial inactivation of the enzyme in the absence of Ca2+, as mentioned above. Regardless of the PL present, the values of Km1 were close to the Km of the enzyme preincubated with Ca2+, and were ascribed to the catalytic site; those of Km2 were comparable to the low affinity regulatory site.

Interpreting the results summarized in Fig. 5 on the basis of the consecutive catalytic cycle (Scheme I), we recognized that since the affinity of E1 for Ca2+ is more than 103 times higher than that of E2, after preincubation with excess Ca2+ most of the enzyme will be in the CaE1 form (33). Upon addition of ATP, Reactions 2 and 3 take place, leading to formation of phosphoenzyme, and according to our results these reactions are insensitive to high concentrations of ATP and to acidic PLs. The maximum rate was 570 pmol/mg of protein/ms, which is more than 3 times higher than the maximum ATPase activity (Fig. 1), again showing that phosphorylation is not rate-limiting during the PMCA catalytic cycle (34).

During preincubation in the absence of Ca2+, PMCA remains distributed between conformers E1 and E2, the latter of which is unfavorable for phosphorylation and must shift to E1. Consequently, following addition of Ca2+ plus [{gamma}-32P]ATP two events likely take place: (i) the existing E1 rapidly forms the CaE1ATP complex and is phosphorylated to CaE1P, and (ii) E2 shifts to E1 to form the CaE1ATP complex and phosphorylated to CaE1P. It seems reasonable to assume that the first event gives rise to most of the high affinity component of the biphasic curve in Fig. 5, since reaction 7 is slower than phosphorylation (33). vo increased even at ATP concentrations above those needed for occupation of the catalytic site, which is in keeping with the idea that ATP at the regulatory site increases the concentration of E1 by accelerating reaction 7. Based on our interpretation, vo should be directly related to the concentration of CaE1, so that the maximum rate of 570 pmol/mg of protein/ms reached by PMCA preincubated with Ca2+ can be ascribed to the condition in which 100% of the enzyme is in the CaE1 form. Similarly, in the presence of PI, the value of vo max1 (127 pmol/mg of protein/s) for the enzyme at rest without Ca2+ can be ascribed to E1 and represents 22% of the total enzyme, which is more than the 7% we reported previously for the PMCA in red cell membranes (33). Finally, vo max2 (206 pmol/mg of protein/s) represented 36% of the total and should reflect the extra E1 that accumulated due to occupation of the low affinity regulatory site during the phosphorylation period. If our interpretation that vo max2 corresponds to the vo of reaction 7 is correct, comparison of its value (12.4 µmol/mg of protein/min) with those of the Ca2+-ATPase activity (Fig. 1) should enable us to conclude that the conformational change E2 -> E1 is not rate-limiting during the PMCA catalytic cycle. Although ATP-induced acceleration of the E2 -> E1 shift is well documented for Na/K-ATPase (35) and SERCA (36), the present results represent the first experimental observation of such an effect in PMCA. Moreover, since the curves remained biphasic, regardless of the presence PI or PE, it can be concluded that acceleration of the conformational change by ATP is PL-independent.

Effect of PL on the Kinetics of Dephosphorylation—Fig. 6 shows the kinetics of the first 50 ms of the dephosphorylation of EP in the presence of various PLs. Without added PL, decomposition of EP followed simple exponential kinetics (kapp = 7 s–1) and except for the increase in kapp to 16 and 25 s1, respectively, PE and PC did not change the kinetics of the reaction. By contrast, EP prepared with acidic PL dephosphorylated with biphasic kinetics: kapp for the fast component was 100 and 124 s1 for PI and PS, respectively, while that for the slow component was 5 and 9 s1. This extends to pure PLs our earlier finding with asolectin (21). Although neutral PLs accelerated dephosphorylation, these results clearly demonstrate that the nearly 16-fold increase in kapp depended primarily on the presence of acidic PL. The fast component reflected at least 70% of [EP] at the start of the reaction with either PI or PS.



View larger version (22K):
[in this window]
[in a new window]
 
FIG. 6.
Effect of PL on the time course of dephosphorylation. PL-depleted PMCA was preincubated with 150 µM Ca2+ in medium without PL ({circ}) or with 33 µg/ml PE (•), PC ({blacksquare}), PS ({triangleup}), or PI ({blacktriangleup}) and then phosphorylated by addition of 20 µM [{gamma}-32P]ATP for a period of 60 ms. Dephosphorylation was started by addition of 5 mM EGTA. The data obtained in the absence of PL or in the presence of PE or PC were best fitted by the equation [EP] = [EPo](exp(–kapp·t)), where kapp = 7, 16, and 25 s1, respectively, and [EPo] = [EP] at 0 ms. The data obtained with PI or PS were best fitted by the equation [EP] = [EP1](exp(–kapp1·t)) + [EP2](exp(–kapp2·t)), where kapp1 = 100 and 124 s1 and kapp2 = 5 and 9 s1 with PI and PS, respectively. [EP1] and [EP2] were, respectively, 390 and 160 pmol/mg of protein with PI and 327 and 153 pmol/mg of protein with PS. The inset shows a semilog plot of the time course of dephosphorylation of EP with PI at the indicated concentrations (µg/ml). The lines were drawn by eye; those for the slow component are parallel to that obtained with 0 µg of PLs/ml. The data were obtained from two independent experiments.

 

The inset to Fig. 6 shows a semi-log plot of the time course of EP dephosphorylation up to 150 ms in the presence of increasing concentrations of PI. The portion of [EP] that decomposed rapidly at the start of the reaction increased from 66% with 15 µg of PI/ml, to 80% with 33 µg of PI/ml, and to 86% with 66 µg of PI/ml; the portion that decomposed slowly decreased in the same proportion. The rate of the slow decomposition of EP was independent of the PI concentration and equal to that of the delipidated PMCA. This suggests that 10–20% of the PMCA did not react with, or was insensitive to, PI, causing an apparently biphasic time course of the dephosphorylation of PMCA in the presence of acidic PL.

We have no definitive explanation for the biphasic kinetics of the dephosphorylation of EP. We previously suggested (21) that one way of interpreting it is to consider PMCA to be a molecular dimer, as has been proposed for SERCA (37) and Na/K-ATPase (38). In a dimeric enzyme, full dephosphorylation implies sequential liberation of Pi from the two enzyme subunits. Acceleration of one of the subunits by PL could explain the biphasic decomposition of EP, though it does not explain why part of the enzyme continued to behave as if it were delipidated.

The Effects of ATP on the kapp for Dephosphorylation—To determine whether phosphorylation at less than 20 µM ATP changed the behavior of PMCA during dephosphorylation, control experiments were run in which EP was prepared using 1.5, 3.0, 7.5, or 20 µM [{gamma}-32P]ATP and dephosphorylated in the presence of 13.3 µM ATP. No significant differences in the rates of dephosphorylation were observed (results not shown).

During the experiments summarized in Fig. 6, the dephosphorylation medium contained 13.3 µM ATP. Fig. 7 shows the effect of increasing the concentration of ATP in the dephosphorylation medium on the kapp for the reaction. By extrapolating the curves back to the ordinate, the dephosphorylation rate in medium without ATP could be estimated. The rate of decomposition of the delipidated EP in the absence of ATP was zero. In the presence of ATP, kapp increased as a function of the ATP concentration along a biphasic curve from 0 to 4 s1 at low ATP concentrations, and to 33 s1 at higher ATP concentrations; Km values for the two components were consistent with those for the catalytic and the regulatory sites. Addition of PE had little effect on the dephosphorylation response to ATP: kapp increased from 0 to 2 s1 and to 37 s1 within the low and high ATP concentration ranges, respectively. On the other hand, the effect of ATP on the kapp for dephosphorylation was strongly affected by the presence of PI. By extrapolating back to the ordinate, the kapp at 0 µM ATP was estimated to be 57 s1. This is the first demonstration that PI increased the rate of dephosphorylation via a mechanism independent of other PMCA ligands. Furthermore, comparison of the effects of PI with those of PE (Fig. 7) enabled us to conclude that activation of dephosphorylation in the absence of ATP was a specific effect of acidic PLs. In the presence of PI, increasing ATP caused kapp to increase along a biphasic curve up to 119 s1 at low ATP concentrations (Km1 of 13 µM) and then up to 192 s1 at higher ATP concentrations (Km2 of 132 µM). Clearly, ATP accelerated the dephosphorylation of PMCA. The same effect has been observed with SERCA (39), but not with Na/K-ATPase, where the rate of dephosphorylation was unaffected by ATP, either in the presence or absence of K+ (40).



View larger version (17K):
[in this window]
[in a new window]
 
FIG. 7.
Effect of ATP on the rate constant for dephosphorylation. PMCA dephosphorylation experiments were carried out as described in the legend to Fig. 6 without PL ({circ}) or with either 33 µg/ml PE (•) or PI ({blacktriangleup}), except that [{gamma}-32P]ATP in syringe II was 1.5–20 µM, and the solution in syringe III contained enough ATP to give the concentrations shown in the figure. Dephosphorylation was carried out for 5–8 ms, which was sufficient to obtain the initial rate. For dephosphorylation in the absence of PL or presence of PE, kapp was calculated as the ratio of vo and [EP] at the start of dephosphorylation; for dephosphorylation in the presence of PI, kapp was calculated as the ratio of vo and [EP] at the start of dephosphorylation x 0.7 to obtain the value for the fast component only on the basis of results from Fig. 6. The data were best fitted by the equation kapp = (kapp max1 [ATP])/(Km1 + [ATP]) + (kapp max2 [ATP])/(Km2 + [ATP]). In the case of PI, a constant term C = 57 s1, representing the rate constant at 0 µM ATP, was added. Km1 and Km2 were respectively 4 and 217 µM in the absence of PL, 2 and 135 µM with PE and 13 and 132 µM with PI. kapp max1 and kapp max2 were respectively 4 and 29 s1 in the absence of PL, 2 and 35 s1 with PE and 62 and 73 s1 with PI. The symbols and bars depict means ± S.D. (n = 2).

 

Activation of delipidated PMCA in the presence of PE was stimulated mainly via the low affinity regulatory site. In the presence of PI, by contrast, 46% of the maximum activation by ATP was apparent at concentrations too low to be mediated via the regulatory site. Without discarding alternative possibilities, occupation of the catalytic site by ATP would seem a simple way to account for this partial activation. Moreover, since Ca2+ was absent during dephosphorylation, the effect must be independent of phosphorylation. It is therefore notable that p-nitrophenylphosphatase activity, which is thought to reflect the dephosphorylation reaction catalyzed by the E2 conformer, is activated by either high affinity ATP binding (41) or CaM (42), and is further activated by ATP in the presence of CaM (43). The Km for ATP as an activator of p-nitrophenylphosphatase is equal to the Km of the Ca2+-ATPase (41). However, we have shown that the ATP-dependent activity of p-nitrophenylphosphatase from red cell membranes persists after most of the Ca2+-ATPase activity has stopped, and the phosphorylation reaction has been abolished by phospholipase C (44). It is tempting to suggest that the high affinity activation of dephosphorylation with PI and phosphatase activity by ATP could be related phenomena. The suggestion that in SERCA the high and low affinity sites are a single site that changes its affinity for ATP during the reaction cycle may support this view (18).

We have shown (45) that in the presence of a non-limiting concentration of Mg2+, the transition CaE1P -> CaE2P during phosphorylation is rapid, suggesting that in the experiments summarized in Figs. 6 and 7 most of the phosphoenzyme was in the CaE2P form at zero time. This means the effect of acidic PL or ATP should be exerted on a reaction downstream of that transition. However, our results do not provide enough information about whether activation of dephosphorylation by acidic PLs and ATP was the result of accelerated EP hydrolysis (Scheme I, Reaction 6) or the release of Ca from CaE2P (Reaction 5) to enable us to draw a conclusion.

Comparison of the ATPase activity with the Estimated Rate of Pi Production in Presence of PI—Multiplication of the steady-state [EP] x the kapp for dephosphorylation gives the rate of production of Pi from EP. If the dephosphorylation that we measured represents a reaction that participates in the PMCA catalytic cycle, the rate of Pi production should be close to the rate of ATP hydrolysis. Such comparison requires that [EP], kapp and ATPase activity are measured under identical experimental conditions. This was the case when these quantities were measured as a function of the ATP concentration in the presence of PI (Figs. 1, 4, and 7). The results in Fig. 8 show good agreement between the experimental findings and the calculated activity, giving strong support to the idea that the properties of dephosphorylation shown here belong to a reaction that participates in the PMCA catalytic cycle, that activation by ATP and PI are key determinants of the activity, and that dephosphorylation of CaE2P is the rate-limiting step in the catalytic cycle. Furthermore, since the concentration of ATP in the cytoplasm of most animal cells is close to 1 mM, results in this study assign to acidic phospholipids a key role in the physiological regulation of PMCA.



View larger version (17K):
[in this window]
[in a new window]
 
FIG. 8.
Comparison of the Ca2+-ATPase activity with the estimated rate of Pi production in presence of PI. The data depicting Ca2+-ATPase activity ({blacktriangleup}) are those from Fig. 1 obtained in the presence of PI. The data depicting the calculated Ca2+-ATPase activity ({triangleup}) are the product of the [EP] from Fig. 4 x kapp from Fig. 7 at the corresponding ATP concentrations. Ca2+-ATPase activity, [EP], and kapp were measured at 25 °C in media of identical composition.

 


    FOOTNOTES
 
* This work was supported by grants from the Consejo Nacional de Invetigaciones Científicas y Técnicas, Argentina, the Universidad de Buenos Aires, and the Ministerio de Salud, Argentina. The costs of publication of this article were defrayed in part by the payment of page charges. This article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact. Back

{ddagger} Recipient of a fellowship from the Universidad de Buenos Aires. Back

§ To whom correspondence should be addressed. Tel.: 5411-49648289 (ext. 123); Fax: 5411-49625457; E-mail: rega{at}qb.ffyb.uba.ar.

1 The abbreviations used are: PMCA, plasma membrane Ca2+-ATPase; SERCA, sarcoplasmic/endoplasmic reticulum Ca2+-ATPase; PL, phospholipid; PE, phosphatidylethanolamine; PC, phosphatidylcholine; PS, phosphatidylserine; PI, phosphatidylinositol; EP, phosphoenzyme; E1 and E2, conformers of the Ca2+-ATPase; C12E10, polyoxyethylene 10-laurylether; MOPS, 3-[N-morpholino]propanesulfonic acid; TES, N-tris(hydroxymethyl)methyl-2-aminoethanesulfonic acid; CaM, calmodulin. Back



    REFERENCES
 TOP
 ABSTRACT
 INTRODUCTION
 EXPERIMENTAL PROCEDURES
 RESULTS AND DISCUSSION
 REFERENCES
 

  1. Ronner, P., Gazzotti, P., and Carafoli, E. (1977) Arch. Biochem. Biophys. 179, 578–583[Medline] [Order article via Infotrieve]
  2. Niggli, V., Adunyah, E., and Carafoli, E. (1981) J. Biol. Chem. 256, 8588–8592[Abstract/Free Full Text]
  3. Filoteo, A. G., Enyedi, A., and Penniston, J. T. (1992) J. Biol. Chem. 267, 11800–11805[Abstract/Free Full Text]
  4. Brodin, P., Falchetto, R., Vorherr, T., and Carafoli, E. (1992) Eur. J. Biochem. 204, 939–946[Abstract]
  5. Wheeler, K. P. (1975) Biochem. J. 146, 729–738[Medline] [Order article via Infotrieve]
  6. Johannsson, A., Smith, G. A., and Metcalfe, J. C. (1981) Biochim. Biophys. Acta 641, 416–421[Medline] [Order article via Infotrieve]
  7. Cornelius, F, Mahmmoud, Y. A., and Christensen H. R. (2001) J. Bioenerg. Biomembr. 33, 415–423[CrossRef][Medline] [Order article via Infotrieve]
  8. Dalton, K. A., East, J. M., Oliver, S., Starling, A. P., and Lee, A. G. (1998) Biochem. J. 329, 637–646[Medline] [Order article via Infotrieve]
  9. Starling, A. P., East, J. M., and Lee, A. G. (1995) J. Biol. Chem. 270, 14467–14470[Abstract/Free Full Text]
  10. Varsanyi, M., Tolle, H. J., Heilmeyer, L. M. G., Dawson, R. M. G., and Irvine, R. F. (1983) EMBO J. 2, 1543–1548[Medline] [Order article via Infotrieve]
  11. Richards, D. E., Rega, A. F., Garrahan, P. J. (1978) Biochim. Biophys. Acta 511, 194–201[Medline] [Order article via Infotrieve]
  12. Muallem, S., and Karlish, S. J. D. (1979) Nature 277, 238–240[Medline] [Order article via Infotrieve]
  13. Glynn, I. M., and Karlish, S. J. D. (1976) J. Physiol. 256, 465–496
  14. Robinson, J. (1976) Biochim. Biophys. Acta 429, 1006–1019[Medline] [Order article via Infotrieve]
  15. Froehlich, J. P., Albers, R. W., Koval, G. J., Goebel, R., and Berman, M. (1976) J. Biol. Chem. 251, 2186–2188[Abstract]
  16. Neet, K. E., and Green, N. M. (1977) Arch. Biochem. Biophys. 178, 588–597[Medline] [Order article via Infotrieve]
  17. Scofano, H. M., Vieyra, A., and de Meis, L. (1979) J. Biol. Chem. 254, 10227–10231[Abstract]
  18. Hua, S., Ma, H., Lewis, D., Inesi, G., and Toyoshima, C. (2002) Biochem. 41, 2264–2272[CrossRef][Medline] [Order article via Infotrieve]
  19. Rossi, J. P. F. C., and Rega, A. F. (1989) Biochim. Biophys. Acta. 996, 153–159[Medline] [Order article via Infotrieve]
  20. Lehotsky, J., Raeymaekers, L., Missiaen, L., Wuytack, F., De Smedt, H., and Casteels, R. (1991) Biochim. Byophys. Acta. 1105, 118–124
  21. Bredeston, L. M., and Rega, A. F. (2002) Biochem. J. 361, 355–361[CrossRef][Medline] [Order article via Infotrieve]
  22. Glynn, I. M., and Chappell, J. B. (1964) Biochem. J. 90, 147–149[Medline] [Order article via Infotrieve]
  23. Gietzen, K., Tejcka, M., and Wolf, H. U. (1980) Biochem. J. 189, 81–88[Medline] [Order article via Infotrieve]
  24. Penniston, J. T., Filoteo, A. G., McDonough, C. S., and Carafoli, E. (1988) Methods Enzymol. 157, 340–351[Medline] [Order article via Infotrieve]
  25. Lowry, O. H., Rosebrough, N. J., Farr, A. L., and Randall, R. J. (1951) J. Biol. Chem. 193, 265–275[Free Full Text]
  26. Peterson, J. L. (1977) Anal. Biochem. 83, 346–356[Medline] [Order article via Infotrieve]
  27. Mardh, H. S., and Zetterqvist, O. (1974) Biochim. Biophys. Acta 350, 473–483[Medline] [Order article via Infotrieve]
  28. Pikula, S., Wrzosek, A., and Famulski, K. (1991) Biochim. Biophys. Acta 1061, 206–214[Medline] [Order article via Infotrieve]
  29. Levi, V., Rossi, J. P., Echarte, M. M., Castello, P. R., and Gonzalez Flecha, F. L. (2000) J. Membr. Biol. 173, 215–225[CrossRef][Medline] [Order article via Infotrieve]
  30. Rega, A. F., and Garrahan, P. J. (1975) J. Membr. Biol. 22, 313–327[Medline] [Order article via Infotrieve]
  31. Kosk-Kosicka, D., Scaillet, S., and Inesi, G. (1986) J. Biol. Chem. 261, 3333–3338[Abstract/Free Full Text]
  32. Echarte, M. M., Levi, V., Villamil, A. M., Rossi, R. C., and Rossi, J. P. (2001) Anal. Biochem. 289, 267–273[CrossRef][Medline] [Order article via Infotrieve]
  33. Adamo, H. P., Rega, A. F., and Garrahan, P. J. (1990) J. Biol. Chem. 265, 3789–3792[Abstract/Free Full Text]
  34. Adamo, H. P., Rega, A. F., and Garrahan, P. J. (1988) J. Biol. Chem. 263, 17548–17554[Abstract/Free Full Text]
  35. Steinberg, M., and Karlish, S. J. (1989) J. Biol. Chem. 264, 27726–27734
  36. Inesi, G., Kurzmack, M., Coan, C., and Lewis, D. E. (1980) J. Biol. Chem. 255, 3025–3031[Free Full Text]
  37. Ikemoto, N., and Nelson, R. W. (1984) J. Biol. Chem. 259, 11790–11797[Abstract/Free Full Text]
  38. Frohelich, J. P., Taniguchi, K., Fendler, K., Mahaney, J. E., Thomas, D. D., and Albers, R. W. (1997) Ann. N. Y. Acad. Sci. 834, 280–296[Medline] [Order article via Infotrieve]
  39. Champeil, P., Riollet, S., Orlowiski, S., Guillain, F., Seebregts, C. J., and McIntosh, D. B. (1988) J. Biol. Chem. 263, 12288–12294[Abstract/Free Full Text]
  40. Schwarzbaum, P. J., Kaufman, S. B., Rossi, R. C., and Garrahan, P. J. (1995) Biochim. Biophys. Acta 1233, 33–40[Medline] [Order article via Infotrieve]
  41. Caride, A. J., Rega, A. F., and Garrahan, P. J. (1982) Biochim. Biophys. Acta 689, 421–428[Medline] [Order article via Infotrieve]
  42. Verma, A. K., and Penniston, J. (1984) Biochem. 23, 5010–5015[Medline] [Order article via Infotrieve]
  43. Rossi, J. P., Garrahan, P. J., and Rega, A. F. (1986) Biochim. Biophys. Acta 858, 21–30[Medline] [Order article via Infotrieve]
  44. Richards, D. E., Vidal, P. J., Garrahan, P. J., and Rega, A. F. (1977) J. Membr. Biol. 35, 125–136[Medline] [Order article via Infotrieve]
  45. Herscher, C. J., Rega, A. F., and Garrahan, P. J. (1994) J. Biol. Chem. 269, 10400–10406[Abstract/Free Full Text]




This Article
Abstract
Full Text (PDF)
All Versions of this Article:
278/25/22265    most recent
M302657200v1
Purchase Article
View Shopping Cart
Alert me when this article is cited
Alert me if a correction is posted
Citation Map
Services
Email this article to a friend
Similar articles in this journal
Similar articles in PubMed
Alert me to new issues of the journal
Download to citation manager
Copyright Permissions
Google Scholar
Articles by Filomatori, C. V.
Articles by Rega, A. F.
Articles citing this Article
PubMed
PubMed Citation
Articles by Filomatori, C. V.
Articles by Rega, A. F.


HOME HELP FEEDBACK SUBSCRIPTIONS ARCHIVE SEARCH TABLE OF CONTENTS
 All ASBMB Journals   Molecular and Cellular Proteomics 
 Journal of Lipid Research   Biochemistry and Molecular Biology Education 
Copyright © 2003 by the American Society for Biochemistry and Molecular Biology.