Deletions in the acidic lipid-binding region of the plasma membrane Ca2+ pump. A mutant with high affinity for Ca2+ resembling the acidic lipid-activated enzyme

The C-terminal segment of the loop between transmembrane helices 2 and 3 (A(L) region) of the plasma membrane Ca(2+) pump (PMCA) is not conserved in other P-ATPases. Part of this region, just upstream from the third transmembrane domain, has been associated with activation of the PMCA by acidic lipids. cDNAs coding for mutants of the Ca(2+) pump isoform h4xb with deletions in the A(L) region were constructed, and the proteins were successfully expressed in either COS or Chinese hamster ovary cells. Mutants with deletions in the segment 296-349 had full Ca(2+) transport activity, but deletions involving the segment of amino acids 350-356 were inactive suggesting that these residues are required for a functional PMCA. In the absence of calmodulin the V(max) of mutant d296-349 was similar to that of the recombinant wild type pump, but its K(0.5) for Ca(2+) was about 5-fold lower. The addition of calmodulin increased the V(max) and the apparent Ca(2+) affinity of both the wild type and d296-349 enzymes indicating that the activating effects of calmodulin were not affected by the deletion. At low concentrations of Ca(2+) and in the presence of saturating amounts of calmodulin, the addition of phosphatidic acid increased about 2-fold the activity of the recombinant wild type pump. In contrast, under these conditions phosphatidic acid did not significantly change the activity of mutant d296-349. Taken together these results suggest that (a) deletion of residues 296-349 recreates a form of PMCA similar to that resulting from the binding of acidic lipids at the A(L) region; (b) the A(L) region acts as an acidic lipid-binding inhibitory domain capable of adjusting the Ca(2+) affinity of the PMCA to the lipid composition of the membrane; and (c) the function of the A(L) region is independent of the autoinhibition by the C-terminal calmodulin-binding region.     

Loss of autoinhibition of the plasma membrane Ca(2+) pump by substitution of aspartic 170 by asparagin. A ctivation of plasma membrane calcium ATPase 4 without disruption of the interaction between the catalytic core and the C-terminal regulatory domain

The plasma membrane calcium ATPase (PMCA) actively transports Ca(2+) from the cytosol to the extra cellular space. The C-terminal segment of the PMCA functions as an inhibitory domain by interacting with the catalytic core. Ca(2+)-calmodulin binds to the C-terminal segment and stops inhibition. Here we showed that residue Asp(170), in the putative "A" domain of human PMCA isoform 4xb, plays a critical role in autoinhibition. In the absence of calmodulin a PMCA containing a site-specific mutation of D170N had 80% of the maximum activity of the calmodulin-activated PMCA and a similar high affinity for Ca(2+). The mutation did not change the activation of the PMCA by ATP. Deletion of the C-terminal segment further downstream of the calmodulin-binding site led to an additional increase in the maximal activity of the mutant, which suggests that the mutation did not affect the inhibition because of this portion of the C-terminal segment. The calmodulin-activated PMCA was more sensitive to vanadate inhibition than the autoinhibited enzyme. In contrast, inhibition of the D170N mutant required higher concentrations of vanadate and was not affected by calmodulin. Despite its higher basal activity, the mutant had an apparent affinity for calmodulin similar to that of the wild type enzyme, and its rate of proteolysis at the C-terminal segment was still calmodulin-dependent. Altogether these results suggest that activation by mutation D170N does not involve the displacement of the calmodulin-binding autoinhibitory domain from the catalytic core and may arise directly from changes in the accessibility to the calcium-binding residues of the pump.     

Plasma membrane Ca2+ATPase isoform 4b is cleaved and activated by caspase-3 during the early phase of apoptosis.

The plasma membrane Ca(2+) pump (PMCA) is an essential element in the complex of mechanisms that maintain low intracellular Ca(2+) concentration in the living cell. This pump is tightly regulated by calmodulin through binding to a high affinity calmodulin-binding domain at the C terminus that also serves as an autoinhibitor of the enzyme. Inspection of the C terminus of hPMCA4b, the most widely distributed form of PMCA, revealed a caspase-3 consensus sequence ((1077)DEID(1080)) just a few residues upstream of the calmodulin-binding domain. We demonstrate here that, in the early phase of apoptosis, hPMCA4b is cleaved at aspartic acid Asp(1080) in hPMCA4b-transfected COS-7 cells or in HeLa cells that naturally express this protein. This cleavage of hPMCA4b produces a single 120-kDa fragment that is fully active in the absence of calmodulin, because the whole inhibitory region downstream of the (1077)DEID(1080) sequence is removed. Our experiments show that caspase-3 or a caspase-3-like protease is responsible for the formation of the constitutively active 120-kDa PMCA4b fragment: 1) Pretreatment of the cells with the caspase-3 inhibitor Z-DEVD-FMK (benzyloxycarbonyl-Asp(OMe)-Glu(OMe)-Val-Asp(OMe)-fluoromethyl ketone) was able to block the production of the 120-kDa fragment. 2) In vitro treatment of hPMCA4b with recombinant caspase-3 also generated a 120-kDa cleavage product, consistent with that seen in cells undergoing apoptosis. 3) Mutants in which the caspase-3 consensus sequence was altered ((1077)AEID(1080), (1077)DEIA(1080), and (1077)AEIA(1080) mutants) were resistant to proteolysis. Based on these data, we conclude that hPMCA4b is a newly identified, natural caspase-3 substrate. We suggest that a constitutively active form of this protein, responding much faster to an increase in Ca(2+) concentration than the autoinhibited form, may have an important role in regulating intracellular Ca(2+) concentration in the apoptotic cell.     

The N-terminal region of the plasma membrane Ca(2+) pump does not separate from the main catalytic fragments after proteolysis

The purified plasma membrane Ca(2+) pump (PMCA) was digested with trypsin, and the proteolytic products were identified by immunoblotting with monoclonal antibodies JA9 or 5F10 directed against the extreme N-terminal segment and the central portion of the molecule, respectively. After a short treatment with low concentrations of the protease, JA9 reacted predominantly with a peptide of 35 kDa whereas 5F10 detected a peptide of 90 kDa. The trypsin cut leading to the production of these fragments had no effect on the maximal activity of the enzyme. At higher concentrations of trypsin, JA9 detected a main fragment of 33 kDa and smaller fragments of 19 and 15 kDa. The persistence of fragments reacting with JA9 indicates that the N-terminal region containing its epitope (residues 51-75) was not easily accessible to the protease in the native PMCA. However, the reactivity with JA9 was rapidly lost during proteolysis of the denatured protein. The passage of the mixture of PMCA fragments through a calmodulin-Sepharose column resulted in the retention of the N-terminal 35 kDa fragment together with that of 90 kDa, despite the fact that only the latter binds calmodulin. The ethylenediaminetetraacetic acid (EDTA) eluate, which contained about equal amounts of both fragments, had a Ca(2+) ATPase activity similar to that of the intact enzyme. The tight association between the two peptides was evidenced by the fact that concentrations of polyoxyethylene 10 lauryl ether (C(12)E(10)), sodium dodecyl sulfate (SDS) high enough for inactivating the enzyme and dissociate the pump from calmodulin were unable of breaking the interaction between the 35 and 90 kDa fragments. Altogether, these results show that after digestion with trypsin, the N-terminal portion of the PMCA, including the extreme N-terminal segment, remains part of a fully functional catalytic complex.     

Deletions in the N-terminal segment of the plasma membrane Ca(2+) pump impair the expression of a correctly folded functional enzyme

Mutant cDNAs encoding h4 plasma membrane Ca(2+) pumps with deletions in the N-terminal segment have been constructed and expressed in COS cells. As judged by immunoblotting, each construct was expressed at a high level similar to that of the wild-type enzyme. The removal of the first six amino acids had no effect on the Ca(2+) transport activity, but deletions in the segment 15-75 reduced the activity to undetectable levels. The d(43-56)h4 mutant, lacking amino acids 43-56, was also efficiently expressed in stable form in CHO cells. The Ca(2+) transport activity of d(43-56)h4 in this system was about 40% of that of the wild type. The d(43-56)h4 enzyme exhibited a similar affinity for Ca(2+), a slightly increased apparent affinity for ATP, and a slightly lower sensitivity to inhibition by vanadate than the wild-type enzyme. Analysis of the phosphoenzyme intermediate formed in the presence of lanthanum showed that the phosphorylation reaction was not affected, but the maximum amount of phosphoenzyme was reduced to the same extent as the Ca(2+) transport activity. These results suggest that the expressed d(43-56)h4 was a mixture of fully active and inactive enzyme. The d(43-56)h4 enzyme was more easily degraded by proteases and had a higher sensitivity to heat inactivation than the wild type suggesting that the loss of function was due to the improper folding and instability of the mutant protein. On the basis of these findings, it appears that the N-terminal segment of the plasma membrane Ca(2+) pump is neither essential for synthesis nor for catalytic activity but is critical for the expression of a correctly folded functional enzyme.     

Expression,purification, and characterization of isoform 1 of the plasma membrane Ca2+ pump: focus on calpain sensitivity

The plasma membrane Ca2+ ATPase isoform 1(PMCA1) is ubiquitously distributed in tissues and cells, but only scarce information is available on its properties. The isoform was overexpressed in Sf9 cells, purified on calmodulin columns, and characterized functionally. The level of expression was very low, but sufficient amounts of the protein could be isolated for biochemical characterization. The affinity of PMCA1 for calmodulin was similar to that of PMCA4, the other ubiquitous PMCA isoform. The affinity of PMCA1 for ATP, evaluated by the formation of the phosphorylated intermediate, was higher than that of the PMCA4 pump. The recombinant PMCA1 pump was a much better substrate for the cAMP-dependent protein kinase than the PMCA2 and PMCA4 isoforms. Pulse and chase experiments on Sf9 cells overexpressing the PMCA pumps showed that PMCA1 was much less stable than the PMCA4 and PMCA2 isoforms, i.e. PMCA1 had a much higher sensitivity to degradation by calpain. The effect of calpain was not the result of a general higher susceptibility of the PMCA1 to proteolytic degradation, because the pattern of degradation by trypsin was the same in the three isoforms.     

Role of third extracellular domain of plasma membrane Ca2+-Mg2+-ATPase based on the novel inhibitor caloxin 3A1

The plasma membrane Ca2+ pump (PMCA) is a Ca2+-Mg2+-ATPase that expels Ca2+ from cells to help them maintain low concentrations of cytosolic Ca2+ ([Ca2+]i). It contains five putative extracellular domains (PEDs). Earlier we had reported that binding to PED2 leads to PMCA inhibition. Mutagenesis of residues in transmembrane domain 6 leads to loss of PMCA activity. PED3 connects transmembrane domains 5 and 6. PED3 is only five amino acid residues long. By screening a phage display library, we obtained a peptide sequence that binds this target. After examining a number of peptides related to this original sequence, we selected one that inhibits the PMCA pump (caloxin 3A1). Caloxin 3A1 inhibits PMCA but not the sarcoplasmic reticulum Ca2+-pump. Caloxin 3A1 did not inhibit formation of the 140 kDa acylphosphate intermediate from ATP or its degradation. Thus, PEDs play a role in the reaction cycle of PMCA even though sites for binding to the substrates Ca2+ and Mg-ATP2-, and the activator calmodulin are all in the cytosolic domains of PMCA. In endothelial cells exposed to low concentration of a Ca2+-ionophore, caloxin 3A1 caused a further increase in [Ca2+]i proving its ability to inhibit PMCA pump extracellularly. Thus, even though PED3 is the shortest PED, it plays key role in the PMCA function.     

The plasma membrane Ca2+ pump isoform 4a differs from isoform 4b in the mechanism of calmodulin binding and activation kinetics: implications for Ca2+ signaling

The inhibition by the regulatory domain and the interaction with calmodulin (CaM) vary among plasma membrane calcium pump (PMCA) isoforms. To explore these differences, the kinetics of CaM effects on PMCA4a were investigated and compared with those of PMCA4b. The maximal apparent rate constant for CaM activation of PMCA4a was almost twice that for PMCA4b, whereas the rates of activation for both isoforms showed similar dependence on Ca2+. The inactivation of PMCA4a by CaM removal was also faster than for PMCA4b, and Ca2+ showed a much smaller effect (2- versus 30-fold modification). The rate constants of the individual steps that determine the overall rates were obtained from stopped-flow experiments in which binding of TA-CaM was observed by changes in its fluorescence. TA-CaM binds to two conformations of PMCA4a, an "open" conformation with high activity, and a "closed" one with lower activity. Compared with PMCA4b (Penheiter, A. R., Bajzer, Z., Filoteo, A. G., Thorogate, R., T?r?k, K., and Caride, A. J. (2003) Biochemistry 41, 12115-12124), the model for PMCA4a predicts less inhibition in the closed form and a much faster equilibrium between the open and closed forms. Based on the available kinetic parameters, we determined the constants to fit the shape of a Ca2+ signal in PMCA4b-overexpressing Chinese hamster ovary cells. Using the constants for PMCA4a, and allowing small variations in parameters of other systems contributing to a Ca2+ signal, we then simulated the effect of PMCA4a on the shape of a Ca2+ signal in Chinese hamster ovary cells. The results reproduce the published data (Brini, M., Coletto, L., Pierobon, N., Kraev, N., Guerini, D., and Carafoli, E. (2003) J. Biol. Chem. 278, 24500-24508), and thereby demonstrate the importance of altered regulatory kinetics for the different functional properties of PMCA isoforms.     

Tryptophan 1093 is largely responsible for the slow off rate of calmodulin from plasma membrane Ca2+ pump 4b

Tryptophan 1093 resides in the 28-residue calmodulin-binding/autoinhibitory domain of the plasma membrane Ca(2+) pump (PMCA). Previous studies with the isolated calmodulin-binding/autoinhibitory peptide from PMCA have shown that mutations of the tryptophan residue decrease the affinity of the peptide for calmodulin and its affinity as an inhibitor of proteolytically activated pump. In this study, the PMCA mutation in which tryptophan 1093 is converted to alanine (W1093A) was constructed in the full-length PMCA isoform 4b. The mutant pump was expressed in COS cells, and its steady state and pre-steady state kinetic properties were examined. The W1093A pump exhibited an increased basal activity in the absence of calmodulin, so the activation was approximately 2-fold (it is 10-fold in the wild type). The W1093A mutation also lowered the steady state affinity for calmodulin from K(0.5) of 9 nm for wild type to 144 nm (assayed at 700 nm free Ca(2+)). Pre-steady state measurements of the rate of activation by Ca(2+)-calmodulin revealed that the W1093A mutant responded 2.5-fold faster to calmodulin. In contrast to these relatively modest effects, the half-time of inactivation of the mutant was reduced by more than 2 orders of magnitude from 41 min to 7 s. We conclude that tryptophan 1093 does not play a substantial role in Ca(2+)-calmodulin recognition; rather it functions primarily to slow the inactivation of the calmodulin-activated pump.     

Deletions in the A(L) region of the h4xb plasma membrane Ca(2+) pump. High apparent affinity for Ca(2+) of a deletion mutant resembling the alternative spliced form h4zb

Mutants of the plasma membrane Ca(2+) pump (human isoform 4xb) with deletions in the linker between domain A and transmembrane segment M3 (A(L) region) were constructed and expressed in Chinese hamster ovary cells. The total or partial removal of the amino acid segment 300-349 did not change the maximal Ca(2+) transport activity, but mutants with deletions involving residues 300-338 exhibited a higher apparent affinity for Ca(2+) than the wild type h4xb enzyme. Deletion of the putative acidic lipid interacting sequence (residues 339-349) had no observable functional consequences. The removal of either residues 300-314 or 313-338 resulted in a similar increase in the apparent Ca(2+) affinity of the pump although the increase was somewhat lower than that obtained by the deletion 300-349 suggesting that both deletions affected the same structural determinant. The results show that alterations in the region of the alternative splicing site A change the sensitivity to Ca(2+) of the human isoform 4 of the PMCA.     

A model for the activation of plasma membrane calcium pump isoform 4b by calmodulin

Overexpression of the plasma membrane calcium pump (PMCA) isoform 4b by means of the baculovirus system enabled us, for the first time, to study the kinetics of calmodulin binding to this pump. This was done by stopped-flow fluorescence measurements using 2-chloro-(amino-Lys(75))-[6-[4-(N,N-diethylamino)phenyl]-1,3,5-triazin-4-yl]calmodulin (TA-calmodulin). Upon mixing with PMCA, the fluorescence of TA-calmodulin changed along a biphasic curve: a rapid and small increase in fluorescence was followed by a slow and large decrease that lasted about 100 s. The experiment was done at several PMCA concentrations. Global fitting nonlinear regression analysis of these results led to a model in which PMCA is present in two forms: a closed conformation and an open conformation. Calmodulin reacts with both conformations but reacts faster and with higher affinity for the open conformation. Measurements of the ATPase activity of PMCA under similar conditions revealed that the open form has higher ATPase activity than the closed one. Contrasting with the reaction with the whole pump, TA-calmodulin reacted rapidly (in about 2 s) with a calmodulin-binding peptide made after the sequence of the calmodulin-binding domain of PMCA (C28). Results of TA-calmodulin binding to C28 are explained by a simpler model, in which only an open conformation exists.     

A comparative functional analysis of plasma membrane Ca2+ pump isoforms in intact cells

The four basic isoforms of the plasma membrane Ca2+ pump and the two C-terminally truncated spliced variants PMCA4CII(4a) and 3CII(3a) were transiently overexpressed in Chinese hamster ovary cells together with aequorin targeted to the cytosol, the endoplasmic reticulum, and the mitochondria. As PMCA3CII(3a) had not yet been cloned and studied, it was cloned for this study, partially purified, and characterized. At variance with the corresponding truncated variant of PMCA4, which had been studied previously, PMCA3CII(3a) had very high calmodulin affinity. All four basic pump variants influenced the homeostasis of Ca2+ in the native intracellular environment. The level of [Ca2+] in the endoplasmic reticulum and the height of the [Ca2+] transients generated in the cytosol and in the mitochondria by the emptying of the endoplasmic reticulum store by inositol 1,4,5-trisphosphate were all reduced by the overexpression of the pumps. The effects were much greater with the neuron-specific PMCA2 and PMCA3 than with the ubiquitously expressed isoforms 1 and 4. Unexpectedly, the truncated PMCA3 and PMCA4 were as effective as the full-length variants in influencing the homeostasis of Ca2+ in the cytosol and the organelles. In particular, PMCA4CII(4a) was as effective as PMCA4CI(4b), even if its affinity for calmodulin is much lower. The results indicate that the availability of calmodulin may not be critical for the modulation of PMCA pumps in vivo.     

Inhibitory interaction of the 14-3-3{epsilon} protein with isoform 4 of the plasma membrane Ca(2+)-ATPase pump

The isoform-specific interaction of plasma membrane Ca(2+)-ATPase (PMCA) pumps with partner proteins has been explored using a yeast two-hybrid technique. The 90 N-terminal residues of two pump isoforms (PMCA2 and PMCA4), which have a low degree of sequence homology, have been used as baits. Screening of 5 x 10(6) clones of a human brain cDNA library yielded approximately 100 LEU2- and galactoside-positive clones for both pumps. A clone obtained with the PMCA4 bait specified the epsilon-isoform of the 14-3-3 protein, whereas no 14-3-3epsilon clone was obtained with the PMCA2 bait. The 14-3-3epsilon protein immunoprecipitated with PMCA4 (not with PMCA2) when expressed in HeLa cells. Overexpression of 14-3-3epsilon in HeLa cells together with targeted aequorins showed that the ability of the cells to export Ca(2+) was impaired; stimulation with histamine, an inositol 1,4,5-trisphosphate-producing agonist, generated higher cytosolic [Ca(2+)] transients, higher post-transient plateaus of the cytosolic [Ca(2+)], and higher Ca(2+) levels in the endoplasmic reticulum lumen and in the subplasmalemmal domain. Thus, the interaction with 14-3-3epsilon inhibited PMCA4. Silencing of the 14-3-3epsilon gene by RNA interference significantly reduced the expression of 14-3-3epsilon, substantially decreasing the height of the histamine-induced cytosolic [Ca(2+)] transient and of the post-transient cytosolic [Ca(2+)] plateau.     

Interchange of autoinhibitory domain conformations in plasma-membrane Ca2+-ATPase-calmodulin complexes

The Ca2+ signaling protein calmodulin (CaM) stimulates Ca2+ pumping in the plasma-membrane Ca2+-ATPase (PMCA) by binding to an autoinhibitory domain, which then dissociates from the catalytic domain of PMCA to allow full activation of the enzyme. We measured single-molecule fluorescence trajectories with polarization modulation to track the conformation of the autoinhibitory domain of PMCA pump bound to fluorescently labeled CaM. Interchange of the autoinhibitory domain between associated and dissociated conformations was detected at a physiological Ca2+ concentration of 0.15 microM, where the enzyme is only partially active, but not at 25 microM, where the enzyme is fully activated. In previous work we showed that the conformation of the autoinhibitory domain in PMCA-CaM complexes could be monitored by the extent of modulation of single-molecule fluorescence generated with rotating excitation polarization. In the present work, we determined the timescale of association and dissociation of the autoinhibitory domain with the catalytic regions of the PMCA. Association of the autoinhibitory domain was rare at a high Ca2+ concentration (25 microM). At a lower Ca2+ concentration (0.15 microM), conformations of the autoinhibitory domain interchanged with a dissociation rate of 0.042 +/- 0.011 sec(-1) and an association rate of 0.023 +/- 0.006 sec-1. The results indicate that the response time of PMCA upon a reduction in Ca2+ is limited to tens of seconds by autoinhibitory dynamics. This property may reduce the sensitivity of PMCA to transient reductions in intracellular Ca2+. We suggest that the dynamics of the autoinhibitory domain may play a novel role in regulating PMCA activity.     

Dynamic regulation of [Ca2+]i by plasma membrane Ca(2+)-ATPase and Na+/Ca2+ exchange during capacitative Ca2+ entry in bovine vascular endothelial cells.

The dynamic regulation of Ca2+ extrusion by the plasma membrane Ca(2+)-ATPase (PMCA) and Na+/Ca2+ exchange (NCX) was investigated in single cultured calf pulmonary artery endothelial (CPAE) cells using indo-1 microfluorimetry to measure cytoplasmic Ca2+ concentration ([Ca2+]i). The quantitative analysis of the recovery from an increase of [Ca2+]i elicited by activation of capacitative Ca2+ entry (CCE) served to characterize kinetic parameters of these Ca2+ extrusion systems in the intact cell. In CPAE cells the PMCA is activated in a Ca(2+)- and time-dependent manner. Full activation of the pump occurs only after [Ca2+]i has been elevated for at least 1 min which results in an increase of the affinity of the pump for Ca2+ and an increase in the apparent maximal extrusion rate (Vmax). Application of calmodulin antagonists W-7 and calmidazolium chloride (compound R 24571) revealed that calmodulin is a major regulator of PMCA activity in vivo. Sequential and simultaneous inhibition of PMCA and NCX suggested that both contribute to Ca2+ extrusion in a non-additive fashion. The activity of one system is dynamically adjusted to compensate for changes in the extrusion rate by the alternative transporter. It was concluded that in vascular endothelial cells, the PMCA functions as a calmodulin-regulated, high-affinity Ca2+ removal system. The contribution by the low-affinity NCX to Ca2+ clearance became apparent at [Ca2+]i > approximately 150 nM under conditions of submaximal activation of the PMCA.     

Alternative splicing of the first intracellular loop of plasma membrane Ca2+-ATPase isoform 2 alters its membrane targeting

Plasma membrane Ca(2+)-ATPases (PMCAs) are involved in local Ca(2+) signaling and in the spatial control of Ca(2+) extrusion, but how different PMCA isoforms are targeted to specific membrane domains is unknown. In polarized MDCK epithelial cells, a green fluorescent protein-tagged PMCA4b construct was targeted to the basolateral membrane, whereas a green fluorescent protein-tagged PMCA2b construct was localized to both the apical and basolateral domain. The PDZ protein-binding COOH-terminal tail of PMCA2b was not responsible for its apical membrane localization, as a chimeric pump made of an NH(2)-terminal portion from PMCA4 and a COOH-terminal tail from PMCA2b was targeted to the basolateral domain. Deletion of the last six residues of the COOH terminus of either PMCA2b or PMCA4b did not alter their membrane targeting, suggesting that PDZ protein interactions are not essential for proper membrane localization of the pumps. Instead, we found that alternative splicing affecting the first cytosolic loop determined apical membrane targeting of PMCA2. Only the "w" form, which contains a 45-amino acid residue insertion, showed prominent apical membrane localization. By contrast, the x and z splice variants containing insertions of 14 and 0 residues, respectively, localized to the basolateral membrane. The w splice insert was the crucial determinant of apical PMCA2 localization, and this was independent of the splice configuration at the COOH-terminal end of the pump; both PMCA2w/b and PMCA2w/a showed prominent apical targeting, whereas PMCA2x/b, PMCA2z/b, and PMCA2z/a were confined to the basolateral membrane. These data report the first differential effect of alternative splicing within the first cytosolic loop of PMCA2 and help explain the selective enrichment of specific PMCA2 isoforms in specialized membrane compartments such as stereocilia of auditory hair cells.     

The role of the Ca2+ binding ligand Asn879 in the function of the plasma membrane Ca2+ pump

Asn879 in the transmembrane segment M6 of the plasma membrane Ca²⁺ pump (PMCA human isoform 4xb) has been proposed to coordinate Ca²⁺ at the transport site through its carboxylate. This idea agrees with the fact that this Asn is conserved in other Ca²⁺-ATPases but is replaced by Asp, Glu, and other residues in closely related 2P-type ATPases of different ionic specificity. Previous mutagenesis studies have shown that the substitution of Ala for Asn abolishes the activity of the enzyme (Adebayo et al., 1995; Guerini et al., 1996). We have constructed a mutant PMCA in which the Asn879 was substituted by Asp. The mutant protein was expressed in Saccharomyces cerevisiae, solubilized and purified by calmodulin affinity chromatography. The Asn879Asp PMCA mutant exhibited about 30% of the wild type Ca²⁺-dependent ATPase activity and only a minor reduction of the apparent affinity for Ca²⁺. The decrease in the Ca²⁺-ATPase of the mutant enzyme was in parallel with the reduction in the amount of phosphoenzyme formed from Ca²⁺ plus ATP. Noteworthy, the mutation nearly eliminated the ability of the enzyme to hydrolyze pNPP which is maximal in the absence of Ca²⁺ revealing a major effect of the mutation on the Ca²⁺-independent reactions of the transport cycle. At a pH low enough to protonate the Asp carboxylate the pNPPase activity of Asn879Asp increased, suggesting that the binding of protons to Asn879 is essential for the activities catalyzed by E₂-like forms of the enzyme.     

Plasma membrane calcium pump (PMCA) isoform 4 is targeted to the apical membrane by the w-splice insert from PMCA2

Local Ca(2+) signaling requires proper targeting of the Ca(2+) signaling toolkit to specific cellular locales. Different isoforms of the plasma membrane Ca(2+) pump (PMCA) are responsible for Ca(2+) extrusion at the apical and basolateral membrane of polarized epithelial cells, but the mechanisms and signals for differential targeting of the PMCAs are not well understood. Recent work demonstrated that the alternatively spliced w-insert in PMCA2 directs this pump to the apical membrane. We now show that inserting the w-insert into the corresponding location of the PMCA4 isoform confers apical targeting to this normally basolateral pump. Mutation of a di-leucine motif in the C-tail thought to be important for basolateral targeting did not enhance apical localization of the chimeric PMCA4(2w)/b. In contrast, replacing the C-terminal Val residue by Leu to optimize the PDZ ligand site for interaction with the scaffolding protein NHERF2 enhanced the apical localization of PMCA4(2w)/b, but not of PMCA4x/b. Functional studies showed that both apical PMCA4(2w)/b and basolateral PMCA4x/b handled ATP-induced Ca(2+) signals with similar kinetics, suggesting that isoform-specific functional characteristics are retained irrespective of membrane targeting. Our results demonstrate that the alternatively spliced w-insert provides autonomous apical targeting information in the PMCA without altering its functional characteristics.     

Hyperactivation of the Human Plasma Membrane Ca2+ Pump PMCA h4xb by Mutation of Glu99 to Lys

The transport of calcium to the extracellular space carried out by plasma membrane Ca²⁺ pumps (PMCAs) is essential for maintaining low Ca²⁺ concentrations in the cytosol of eukaryotic cells. The activity of PMCAs is controlled by autoinhibition. Autoinhibition is relieved by the binding of Ca²⁺-calmodulin to the calmodulin-binding autoinhibitory sequence, which in the human PMCA is located in the C-terminal segment and results in a PMCA of high maximal velocity of transport and high affinity for Ca²⁺. Autoinhibition involves the intramolecular interaction between the autoinhibitory domain and a not well defined region of the molecule near the catalytic site. Here we show that the fusion of GFP to the C terminus of the h4xb PMCA causes partial loss of autoinhibition by specifically increasing the V_max. Mutation of residue Glu⁹⁹ to Lys in the cytosolic portion of the M1 transmembrane helix at the other end of the molecule brought the V_max of the h4xb PMCA to near that of the calmodulin-activated enzyme without increasing the apparent affinity for Ca²⁺. Altogether, the results suggest that the autoinhibitory interaction of the extreme C-terminal segment of the h4 PMCA is disturbed by changes of negatively charged residues of the N-terminal region. This would be consistent with a recently proposed model of an autoinhibited form of the plant ACA8 pump, although some differences are noted.     

Intramolecular interactions of the regulatory region with the catalytic core in the plasma membrane calcium pump

The access of three proteases to their sites of cleavage was used as a measure of regulatory interactions in the plasma membrane Ca2+ pump isoform 4b (PMCA4b). When the proteases could not cut at their sites in the C-terminal regulatory region, the interaction was judged to be tight. This was the case in the absence of Ca2+, when chymotrypsin and caspase cut PMCA only very slowly. Ca2+ accelerated the fragmentation, but the digestion remained incomplete. In the presence of Ca2+ plus calmodulin, the digestion became nearly complete in all cases, indicating a more flexible conformation of the carboxyl terminus in the fully activated state. The acceleration of proteolysis by Ca2+ or Ca2+ plus calmodulin occurred equally at the caspase site upstream of the calmodulin-binding domain and the chymotrypsin and calpain sites downstream of that domain. Replacing Trp1093 (a key residue within the calmodulin-binding domain) with alanine had a much more specific effect, because it exposed only proteolytic sites within the calmodulin-binding domain that had previously been shielded in the native protein. At these sites, both calpain and chymotrypsin cut the Trp1093 --> Ala mutant in the absence of calmodulin. These data indicate that, in the auto-inhibited conformation, the calmodulin-binding/auto-inhibitory sequence and the regions both upstream and downstream are in close contact with the catalytic core. Trp1093 plays an essential role not only in stabilizing the Ca2+-calmodulin/calmodulin-binding domain complex but also in the formation or stability of the inhibitory conformation of that domain when it interacts with the catalytic core of PMCA4b.