The plasma membrane calcium pump: a multiregulated transporter

Activation of many cells, especially nonexcitable cells, results in a Ca(2+) transient that is influenced in part by the kinetics of active extrusion of Ca(2+) across the plasma membrane. The molecular cloning of the plasma membrane Ca(2+)-pump has helped to clarify the relationship between its structure and function. The Ca(2+)-pump is controlled by multiple regulators, including calmodulin, phospholipids and various kinases. Longer term control is achieved through regulation of its gene expression, and the presence of a number of Ca(2+)-pump isoforms that differ in their regulatory domains provides potential functional diversity. In this review, we focus on the mechanisms that regulate the function of the Ca(2+)-pump, and their physiological significance.     

The targeting of the plasma membrane calcium pump in the cell

The information on the structural determinants that control the cellular distribution of P-type pumps is very scarce. However, recent experiments on the membrane targeting of the plasma membrane Ca²⁺ pump (PMCA) have provided interesting leads on the problem: they will be discussed in this succinct review. A general introduction on the biochemical properties of the PMCA pump will preface the discussion of the specific findings on the role of three distinct regions of the molecule in the targeting process.     

Irreversible effects of calcium ions on the plasma membrane calcium pump

The calcium pump of human red cells can be irreversibly activated by preincubation of the membranes in the presence of calcium ions, with a pattern reminiscent of that produced by controlled trypsin attack. With 1 mm Ca²⁺, the activity of the basal enzyme increases three to fourfold over 30 to 60 min, to levels about half those obtained in the presence of calmodulin. On the whole, the effect occurs slowly, with a very low Ca²⁺ affinity at 37°C and is unaffected by serine-protease inhibitors. The activation caused by 1 mm Ca²⁺ is little affected by leupeptin (a thiol-protease inhibitor) and that obtained at 10 m Ca²⁺ is not inhibited. Preincubations at 0°C also lead to activation, to a level up to half that seen at 37°C, and the effect is not affected by leupeptin or antipain. No activation is observed by preincubating soluble purified Ca,Mg-ATPase in Ca²⁺-containing solutions at 37°C. Instead, calcium ions protect the detergent-solubilized enzyme from thermal inactivation, the effect being half-maximal between 10 and 20 m Ca²⁺. We conclude that the activation of the membrane-bound Ca,Mg-ATPase by Ca²⁺ should result from an irreversible conformational change in the enzyme and not from attack by a membrane-bound protease, and that this change presumably arises from the release of inhibitory particles existing in the original membrane preparations.We thank The Wellcome Trust for a research grant, the Medical Research Council for an equipment grant and the Regional Transfusion Service (Sheffield) for bank blood supplies.     

The isoform- and location-dependence of the functioning of the plasma membrane calcium pump

The plasma membrane is a specialised multi-component structure with inter- and intracellular signalling functions. Ca2+ plays a crucial role in cellular physiology, and an ATP-driven plasma membrane calcium pump (PMCA) plays the greatest role in the maintenance of a low free Ca2+ concentration in the cytoplasm. The enzyme is coded by four separate genes (PMCA 1-4), and, due to alternative splicing, more than 20 variants can exist. PMCA 1 and 4 isoforms are present in almost all tissues, whereas PMCA 2 and 3 are found in more specialised cell types. The variants differ primarily in their regulatory regions, thus the modulation of calcium pump activity strongly depends on the isoform and the membrane composition. The unique function of PMCA isoforms was confirmed using the practical experimental models - a rat pheochromocytoma cell line, a human neuroblastoma cell line, or, more recently, knockout mice. In addition, based on the finding that PMCA could interact with several specific signaling proteins, it was concluded that its location in defined sites of the cell membrane could be a prerequisite for efficient intercellular communication.     

A calcium pump in plasma membrane vesicles from Leishmania braziliensis

A subcellular fraction highly enriched in plasma membrane vesicles was prepared from Leishmania promastigotes. This fraction showed (Ca2+ + Mg2+)-ATPase activity. This, however, represented a small fraction (about 25%) of the overall ATPase activity. The Ca2(+)-ATPase showed general characteristics common to plasma membrane ATPases involved in Ca2+ transport. Thus, the Ca2(+)-ATPase was activated by Ca2+ with a high affinity (Km about 0.7 microM), saturating at about 5 microM Ca2+. Furthermore, it was stimulated by calmodulin (about 70-80% with 5 micrograms/ml) and almost fully inhibited by trifluoperazine (100 microM). The above vesicles accumulated Ca2+ against a concentration gradient and released it after the addition of A23187, as shown independently by 45Ca2+ and Arsenazo III studies. The transport mechanism showed the same kinetics parameters as described for the enzyme, indicating a single molecular entity. In addition, Ca2(+)-ATPase activity and Ca2+ uptake were completely inhibited by vanadate (20 microM), indicating that an E1-E2 type mechanism is involved. The results clearly demonstrate the presence of a Ca2+ pump in the plasma membrane of Leishmania which is capable of maintaining a low cytoplasmic Ca2+ concentration.     

The Homer-1 protein Ania-3 interacts with the plasma membrane calcium pump

The Homer family of scaffold proteins couples NMDA receptors to metabotropic glutamate receptors and links extracellular signals to calcium release from intracellular stores. Ania-3 is a member of the Homer family and is rapidly inducible in brain in response to diverse stimuli. Here, we report the identification of the plasma membrane Ca2+ ATPase (PMCA) as a novel Ania-3/Homer-associated protein. Ania-3/Homer interacts with the b-splice forms of all PMCAs (PMCA1b, 2b, 3b, and 4b) via their PDZ domain-binding COOH-terminal tail. Ectopically expressed Ania-3 colocalized with the PMCA at the plasma membrane of polarized MDCK epithelial cells, and endogenous Ania-3/Homer and PMCA2 are co-expressed in the soma and dendrites of primary rat hippocampal neurons. The interaction between Ania-3/Homer and PMCAs may represent a novel mechanism by which local calcium signaling and hence synaptic function can be modulated in neurons.     

Probing the extracellular release site of the plasma membrane calcium pump

Theplasma membrane Ca²⁺ pump is known to mediateCa²⁺/H⁺ exchange. Extracellular protonsactivated ⁴⁵Ca²⁺ efflux from human red bloodcells with a half-maximal inhibition constant of 2 nM when theintracellular pH was fixed. An increase in pH from 7.2 to 8.2 decreasedthe IC₅₀ for extracellular Ca²⁺ from ~33 to~6 mM. Changing the membrane potential by >54 mV had no effect onthe IC₅₀ for extracellular Ca²⁺. This arguesagainst Ca²⁺ release through a high-field access channel.Extracellular Ni²⁺ inhibited Ca²⁺ efflux withan IC₅₀ of 11 mM. Extracellular Cd²⁺ inhibitedwith an IC₅₀ of 1.5 mM, >10 times better thanCa²⁺. The Cd²⁺ IC₅₀ also decreasedwhen the pH was raised from 7.1 to 8.2, consistent withCa²⁺, Cd²⁺, and H⁺ competing forthe same site. The higher affinity for inhibition by Ni²⁺and Cd²⁺ is consistent with a histidine or cysteine as partof the release site. The cysteine reagent 2-(trimethylammonium)ethylmethanethiosulfonate did not inhibit Ca²⁺ efflux. Ourresults are consistent with the notion that the release site contains a histidine.

     

Functional importance of the synaptic plasma membrane calcium pump and sodium-calcium exchanger

Two major Ca2+ transport mechanisms co-function in a preparation of synaptosomal plasma membrane vesicles: an (ATP + Mg2+)-dependent Ca2+ pump, and a reversible Na+-Ca2+ exchanger (Gill, D. L., Grollman, E.F., and Kohn, L. D. (1981) J. Biol. Chem. 256, 184-192). An accurate comparative analysis of the kinetics of the two Ca2+ transporters under free Ca2+ conditions precisely buffered with EGTA, reveals that both mechanisms have high affinity for Ca2+. The ATP-dependent Ca2+ pump displays simple saturation kinetics with a Km for Ca2+ of 0.11 microM and a Vmax of 2.2 nmol/min/mg of protein. In contrast, the Na+-Ca2+ exchanger has a complex dependence on free Ca2+, the activity continuing to saturate over a wide range of free Ca2+ concentrations from 0.03 microM to 3 mM. The curvilinear Eadie-Hofstee analysis reveals a distinct high affinity component for the exchanger with a Km for Ca2+ of approximately 0.5 microM, and a lower affinity component not accurately resolvable into a discrete Km value. 2 mM amiloride blocks Na+-Ca2+ exchange-mediated Ca2+ uptake by 90% over a wide range of free Ca2+ (0.3-3000 microM), suggesting a similar noncompetitive inhibition of both low and high affinity Ca2+ sites. Ca2+ accumulated in vesicles via either the Ca2+ pump or Na+-Ca2+ exchanger is rapidly (in less than 1 min) released by 0.1% saponin (w/v), although a minor component (8-10%) of Ca2+ pump activity is resistant to saponin addition. The IC50 for the effect of saponin is the same (0.01%, w/v) for both Ca2+ transport mechanisms. The ATP-dependent Ca2+ pump is shown to be highly sensitive to vanadate inhibition (Ki = 0.5 microM). The high saponin sensitivity of both Ca2+ transporters and the potent effect of vanadate on Ca2+ pumping, together with previous Na+ channel and Na+ pump flux studies in the same membrane vesicles (Gill, D. L. (1982) J. Biol. Chem. 257, 10986-10990), all strongly suggest that both of the high affinity Ca2+ transporters function in the plasma membrane where they are of major functional importance to the regulation of intrasynaptic free Ca2+ levels.     

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.     

Quantitation of plasma membrane calcium pump phosphorylated intermediates by electrophoresis

P-ATPases are characterized by the formation of acid-stable phosphorylated intermediates (EP) during their reaction cycle. We have developed a microscale method to determine EP that involves the phosphorylation of the enzyme using [gamma-(32)P]ATP and precipitation with TCA; separation of the sample by SDS-PAGE, and measurement of the enzyme protein and (32)P-labeled EP by digital analysis of both the stained gel and its autoradiogram, respectively. The principal advantages of this method over typical procedures (filtration and centrifugation) are the low amount of enzyme required and the substantial decrease in the blank values and data scattering produced by unspecific phosphorylation and nonquantitative recovering of the enzyme. Application of this new method to a purified preparation of the plasma membrane calcium ATPase (PMCA) results in overcoming the difficulties of measuring EP at high ATP concentrations. A biphasic behavior of the substrate curve for EP was observed when the study was extended to ATP levels within the physiological range. Since, in principle, the method does not require the use of highly purified preparations, it could be helpful for the study of phosphorylated intermediates especially under conditions in which small amounts of protein are available, e.g., mutated variants of P-ATPases.     

Vacuolar-type proton pump ATPases: roles of subunit isoforms in physiology and pathology

The vacuolar-type H(+)-ATPases (V-ATPases) are a family of multi-subunit ATP-dependent proton pumps involved in diverse cellular processes, including acid/base homeostasis, receptor-mediated endocytosis, processing of proteins and signaling molecules, targeting of lysosomal enzymes, and activation of various degradation enzymes. These fundamental cellular activities are naturally related to higher order physiological functions in multicellular organisms. V-ATPases are involved in several physiological processes, including renal acidification, bone resorption, and neurotransmitter accumulation. Both forward- and reverse-genetic approaches have revealed that V-ATPase malfunction causes diseases and/or pathophysiological states, demonstrating its diverse roles in normal physiology. Here, we focus on the recent insights into the function of mammalian V-ATPase in highly differentiated cells and tissues.     

Primary structure of the cAMP-dependent phosphorylation site of the plasma membrane calcium pump

The primary structure of a region of the erythrocyte plasma membrane calcium pump which is phosphorylated by the cAMP-dependent protein kinase has been determined. The sequence is A-P-T-K-R-N-S-S(P)-P-P-P-S-P-D. The site is located between the calmodulin binding domain and the C-terminus of the ATPase. The ATPase is phosphorylated only at this site by the cAMP-dependent protein kinase, and the phosphorylation is inhibited by calmodulin. The effect of the phosphorylation is to decrease the Km for Ca2+ of the purified ATPase from about 10 microM to about 1.4 microM and to increase the Vmax of ATP hydrolysis about 2-fold.     

Binding of calcium by calmodulin: influence of the calmodulin binding domain of the plasma membrane calcium pump.

The interaction between calmodulin and synthetic peptides corresponding to the calmodulin binding domain of the plasma membrane Ca2+ pump has been studied by measuring Ca2+ binding to calmodulin. The largest peptide (C28W) corresponding to the complete 28 amino acid calmodulin binding domain enhanced the Ca2+ affinity of calmodulin by more than 100 times, implying that the binding of Ca2+ increased the affinity of calmodulin for the peptide by more than 10(8) times. Deletion of the 8 C-terminal residues from peptide C28W did not decrease the affinity of Ca2+ for the high-affinity sites of calmodulin, but it decreased that for the low-affinity sites. A larger deletion (13 residues) decreased the affinity of Ca2+ for the high-affinity sites as well. The data suggest that the middle portion of peptide C28W interacts with the C-terminal half of calmodulin. Addition of the peptides to a mixture of tryptic fragments corresponding to the N- and C-terminal halves of calmodulin produced a biphasic Ca2+ binding curve, and the effect of peptides was different from that on calmodulin. The result shows that one molecule of peptide C28W binds both calmodulin fragments. Interaction of the two domains of calmodulin through the central helix is necessary for the high-affinity binding of four Ca2+ molecules.     

Hormone-induced phosphorylation of the plasma membrane calcium pump in cultured aortic endothelial cells.

The regulation of the plasma membrane Ca2+ pump by hormones via phosphorylation in intact cells has not been clearly established. We now present evidence that the Ca2+ pump is phosphorylated on both serine and threonine residues in unstimulated and stimulated cultured rat aortic endothelial cells. Among the stimuli tested, the protein kinase C activator phorbol 12-myristate 13-acetate (PMA) was most potent and increased the level of phosphorylation threefold, while the cAMP-dependent protein kinase activator 8-(4-chlorophenylthio)-cAMP (CPT-cAMP) stimulated the phosphorylation 1.6-fold. Two-dimensional tryptic phosphopeptide maps of the Ca2+ pump from unstimulated and CPT-cAMP-stimulated cells have identical patterns (five phosphopeptides) while PMA-stimulated cells have three additional phosphopeptides. Isoproterenol-, ATP-, angiotensin II-, and bradykinin-stimulated cells also have increased levels of Ca2+ pump phosphorylation. Stimuli-induced phosphorylation of the Ca2+ pump was rapid (5-10 min) and was concomitant with stimulated calcium efflux from the same cells. This is the first direct evidence that the plasma membrane Ca2+ pump in intact cells is regulated by various hormones or agonists via cAMP-dependent protein kinase or protein kinase C phosphorylation.