Kinetic evidence for cytoplasmic calcium as an inhibitory messenger in parathyroid hormone release

A sudden change of extracellular Ca2+ from 0.5 to 3.0 mM resulted in a transient rise of the cytoplasmic Ca2+ concentration (Ca2+i) followed by a sustained increase in parathyroid cells loaded with the Ca2+-indicator fura-2. The initial transient could be eliminated by increasing the Ca2+ buffering capacity of the cytoplasm. Under such conditions the rise of Ca2+i exhibited kinetics reminiscent of those for 45Ca uptake and cell depolarization. Addition of 0.5 mM Mn2+ mimicked the effect of raising the extracellular Ca2+ concentration, since there was an initial Ca2+i transient followed by a slower entry of Mn2+ into the cells. This reaction pattern was different from that of pancreatic alpha 2-cells in which there was no substantial influx of Mn2+ before depolarization with arginine. When measuring the kinetics of parathyroid hormone (PTH) release it was apparent that Ca2+ inhibition of secretion followed Ca2+i and thus became substantially delayed after eliminating the initial transient. The results support the concept of a depolarizing Ca2+ permeability in the parathyroid cell membrane which can be activated by external Ca2+, and indicate that Ca2+i is an inhibitory messenger of importance for the physiological regulation of PTH release.     

Identification and characterization of a Ca2+ -sensitive interaction of the vanilloid receptor TRPV1 with tubulin

The vanilloid receptor TRPV1 plays a well-established functional role in the detection of a range of chemical and thermal noxious stimuli, such as those associated with tissue inflammation and the resulting pain. TRPV1 activation results in membrane depolarization, but may also trigger intracellular Ca2+ -signalling events. In a proteomic screen for proteins associated with the C-terminal sequence of TRPV1, we identified beta-tubulin as a specific TRPV1-interacting protein. We demonstrate that the TRPV1 C-terminal tail is capable of binding tubulin dimers, as well as of binding polymerized microtubules. The interaction is Ca2+ -sensitive, and affects microtubule properties, such as microtubule sensitivity towards low temperatures and nocodazole. Our data thus provide compelling evidence for the interaction of TRPV1 with the cytoskeleton. The Ca2+ -sensitivity of this interaction suggests that the microtubule cytoskeleton at the cell membrane may be a downstream effector of TRPV1 activation.     

The effect of oxidizing agents on cell division and shape

Certain oxidizing agents such as vitaminK(VK) and lipid peroxides were found to suppress an increase in cytoplasmic Ca2+ concentration by growth factors, and inhibit on cell proliferation. These oxidizing agents induced a marked change in cell shape. In a detailed analysis of each phase in the cell cycle, the inhibition of an increase in cytoplasmic Ca2+ and cell division occurred only when the agents were added at G0/G1 phase. The addition to S or M phase cells did not influence in cytoplasmic Ca2+ and cell division. These experimental results suggest that these oxidizing agents may inhibit the transfer of stimulation signals from growth factors by acting on cell membrane sites and suppress subsequent DNA replication and mitotic division.     

Regulation of phosphatidylserine transbilayer redistribution by store-operated Ca2+ entry: role of actin cytoskeleton

The phosphatidylserine transmembrane redistribution at the cell surface is one of the early characteristics of cells undergoing apoptosis and also occurs in cells fulfilling a more specialized function, such as the phosphatidylserine-dependent procoagulant response of platelets after appropriate activation. Although an increase in cytoplasmic Ca2+ is essential to trigger the remodeling of the plasma membrane, little is known about intracellular signals leading to phosphatidylserine externalization. Here, the role of store-operated Ca2+ entry on phosphatidylserine exposure was investigated in human erythroleukemia HEL cells, a pluripotent lineage with megakaryoblastic properties. Ca2+ entry inhibitors (SKF-96365, LaCl(3), and miconazole) inhibited store-operated Ca2+ entry in A23187- or thapsigargin-stimulated cells and reduced the degree of phosphatidylserine externalization concomitantly, providing evidence for a close link between the two processes. In cells pretreated with cytochalasin D, an agent that disrupts the microfilament network of the cytoskeleton, store-operated Ca2+ entry and phosphatidylserine externalization at the cell surface were inhibited. In a context where most of the key actors remain to be identified, these results provide evidence for the implication of both store-operated Ca2+ entry and cytoskeleton architectural organization in the regulation of phosphatidylserine transbilayer migration.     

Effects of La3+ on calcium binding to erythrocyte cytoskeleton]

When the whole erythrocytes were exposed to LaCl3, A--23187, ionomycin, orthovanadate and saponin, there was Ca2+ binding only following La3+ treatment of the cells. The binding was evident at a wide range (0.1 microM--1.OmM) of La3+ concentrations. Iodoacetamide-induced (incubation for 3 hours, 37 degrees C) decrease in erythrocyte ATP levels was found to result in a 3-fold reduction in Ca2+ binding to the cytoskeleton. La(3+)-induced Ca2+ binding enhanced the incorporation of 14C-glucose and/or its metabolites into the red cell skeleton. Thus, the detected new type of Ca2+ binding to the cytoskeleton of human and rat erythrocytes is likely to be due to the cumulative process: direct binding of La3+ to the outer surface of a membrane and the metal-induced trigger of nucleotide--dependent intracellular process.     

Simultaneous measurement of stimulus-induced changes in cytoplasmic Ca2+ and in membrane potential of human neutrophils

The activation of human neutrophils by chemotactic peptides evokes a rapid change in membrane potential and an increase in cytoplasmic Ca2+ levels. These events are followed up to a minute later by detectable levels of microbicidal agents formed by the oxidative burst. Except for the latter, the sequence of events has remained unclear. We report here that a new fluorescent Ca2+ indicator developed by R. Tsien, Indo-1, has allowed us to resolve the temporal relationship between the rapid and transient cytoplasmic Ca2+ rise and the membrane potential change and to do so on very small samples by using a fluorescence-activated cell sorter. We have adapted a FACS 440 for simultaneous single cell membrane depolarization and cytoplasmic [Ca2+] detection in human neutrophils upon stimulation with formyl-methionyl-leucyl-phenylalanine (fMLP). A membrane potential probe, dipentyloxacarbocyanine, allows us to determine that the membrane potential change is fMLP dose-dependent and apparently biphasic. The depolarization is maximal 40 s after stimulation. In contrast, cytosolic [Ca2+], while fMLP-dose dependent, is maximal at 10 s and already decreasing rapidly when the cell has reached its lowest potential. It can be measured with Indo-1 which has a fluorescence emission (lambda ex = 357 nm) maximum at 485 nm when Ca2+-free and 405 nm when Ca2+-liganded. The ratio of these fluorescences may then be calibrated in terms of cytoplasmic Ca2+ levels. Thus, Ca2+ release into the cytoplasm becomes the earliest evidence of neutrophil stimulation by fMLP and occurs in close association with an apparent membrane hyperpolarization.     

Annexin V relocates to the platelet cytoskeleton upon activation and binds to a specific isoform of actin.

We have previously reported that stimulation of platelets causes a relocation of annexin V to the cytoplasmic side of the plasma membrane where it associates with actin. This study examined the association of annexin V with the platelet cytoskeleton and its binding to actin, following both physiological activation with thrombin and Ca2+ -ionophore activation. The time-dependence of annexin V incorporation into the detergent-extracted cytoskeleton following activation with thrombin was also measured. Although calcium from the intracellular stores was enough to relocate intracellular annexin V to the cytoskeleton, this relocation was further enhanced by influx of extracellular calcium. The association of annexin V with the cytoskeleton was found to be unaffected by the action of cytochalasin E, however, annexin V was solubilized when DNase I was used to depolymerize the membrane cytoskeleton, and spontaneously re-associated with the actin filaments when re-polymerization was induced in vitro. Using a bifunctional crosslinking reagent we have identified an 85-kDa complex in both membrane and cytoskeleton fractions containing annexin V and actin. Direct binding to actin filaments was only observed in high [Ca2+], however, inclusion of an extract from thrombin-stimulated platelets lowered the [Ca2+] requirement for the binding of annexin V to F-actin to physiological levels. We also show that GST-annexin V mimics the physiological binding of annexin V to membranes, and that this GST-annexin V binds directly to a specific isoform of actin. Immunoprecipitation using antibodies against annexin V copurify annexin V and gamma- but not beta-actin from activated platelets. This is the first report of a possible preferential binding of annexin V to a specific isoform of actin, namely gamma-actin. The results of this study suggest a model in which annexin V that relocates to the plasma membrane and binds to gamma-actin in an activation-dependent manner forms a strong association with the platelet cytoskeleton.     

Cell binding function of E-cadherin is regulated by the cytoplasmic domain.

Cadherins are a family of transmembrane glycoproteins responsible for Ca2+-dependent cell-cell adhesion. Their amino acid sequences are highly conserved in the cytoplasmic domain. To study the role of the cytoplasmic domain in the function of cadherins, we constructed expression vectors with cDNAs encoding the deletion mutants of E-cadherin polypeptides, in which the carboxy terminus was truncated at various lengths. These vectors were introduced into L cells by transfection, and cell lines expressing the mutant E-cadherin molecules were isolated. In all transfectants obtained, the extracellular domain of the mutant E-cadherins was exposed on the cell surface, and had normal Ca2+-sensitivity and molecular size. However, these cells did not show any Ca2+-dependent aggregation, indicating that the mutant molecules cannot mediate cell-cell binding. The mutant E-cadherin molecules could be released from cells by nonionic detergents, whereas a fraction of normal E-cadherin molecules could not be extracted with the detergent and appeared to be anchored to the cytoskeleton at cell-cell junctions. These results suggest that the cytoplasmic domain regulates the cell-cell binding function of the extracellular domain of E-cadherin, possibly through interaction with some cytoskeletal components.     

The cytoplasmic concentration of free calcium in platelets is controlled by stimulators of cyclic AMP production (PGD2, PGE1, forskolin)

Maximal stimulation of platelets with thrombin results in a rapid increase in cytoplasmic Ca2+ (from 0.1 microM to 1-3 microM), as measured with the fluorescent intracellular Ca2+ indicator Quin-2. Prior addition of the adenylate cyclase stimulators PGD2, PGE1 or forskolin inhibited the rise in cytoplasmic Ca2+. When added after the maximal response to thrombin was attained adenylate cyclase stimulators caused a rapid fall of cytoplasmic Ca2+ back to the original "resting" level. This effect coincides with the reversal of thrombin-induced, Ca2+-dependent protein phosphorylation, and cytoskeleton assembly. It is suggested that cAMP-dependent reactions maintain low levels of cytoplasmic Ca2+ by promoting transport and/or binding of Ca2+.     

Macrophage activation by synthetic peptides. III. Changes in the membrane potential, Ca2+ content and the regulatory decrease of macrophage volume under the action of tuftsin and its antagonist

With the use of oxonol voltage-sensitive fluorescent dye it has been shown that the stimulation of macrophages (MP) with tuftsin results in a two-phase change in membrane potential: depolarization followed by hyperpolarization of plasma membrane. The pattern of changes in membrane potential depends on Na+ concentration in the medium and is disturbed with binding of cytoplasmic Ca2+. Fluorescent signal obtained from MP loaded with Ca(2+)-activated photoprotein obelin points to a significant increase in the concentration of cytoplasmic Ca2+ under the influence of tuftsin on cells: the source for Ca2+ being the medium. The rate of regulatory voltage decrease in MP increases under the influence of tuftsin: the effect of this peptide being similar to that of calcium ionophore. All these findings taken together enable us to suggest a phenomenological scheme of transmembrane ion signals arising during stimulation of MP with tuftsin: the receptor-mediated calcium channel provides a rise in cytoplasmic Ca2+ which opens non-selective cation channels for Na+ ions to activate eventually Ca(2+)-dependent K(+)-transport.     

Cellular distribution of three mammalian Ca2+-binding proteins related to Torpedo calelectrin.

Addition of Ca2+ to post-microsomal fractions of bovine adrenal or liver produced a sedimentable complex of membrane vesicles and cytoplasmic proteins. Proteins with apparent mol. wts. 70 000, 36 000 and 32 500 were solubilized from this complex by Ca2+ chelation. The 36 000 mol. wt. protein (p36) was immunoprecipitated by an antiserum specific for pp36, a major substrate for Rous sarcoma virus src-gene tyrosine kinase. This protein was present in many mesenchymal cells and associated with membrane cytoskeleton of bovine fibroblasts in a Ca2+-dependent manner. The 70 000 and 32 500 mol. wt. proteins were widely distributed in established cell lines, but were not clearly associated with cell organelles in tissue sections, nor retained in cytoskeleton preparations. On immunoblots p36 reacted strongly with antibodies produced against the electric fish protein Torpedo calelectrin and the similar Ca2+-binding properties and subunit mol. wts. of these proteins suggests that they might be functionally related. Since Torpedo calelectrin, p70, p36 and p32.5 were bound by lipid vesicles or microsomal membranes at micromolar free Ca2+ concentrations, regulated association with intrinsic membrane components may be involved in the functions of these widespread proteins.     

Dysfunction of calcium handling by smooth muscle in hypertension

Dysfunction of ion handling, including binding and fluxes (passive and active transport) of physiologically important ions such as potassium, sodium, calcium, and magnesium, by vascular smooth muscle cell membranes has repeatedly been reported to be associated with the pathophysiology of hypertension. The specific purpose of this review is to summarize and evaluate the evidence for alterations of calcium ion (Ca2+) handling by vascular smooth muscle in various forms of hypertension in the animal model on the basis that regulation of cytoplasmic Ca2+ concentration is a complex and yet vitally important process for a normal function of vascular smooth muscle and that derangement of such a regulation may result in excessive retention of cytoplasmic Ca2+, contribute toward increase of total peripheral resistance, and ultimately lead to elevation of blood pressure. Emphasis is placed upon the consideration of the usefulness of the subcellular membrane fractionation technique in studies of binding and transport of Ca2+ by vascular and nonvascular smooth muscle membranes from genetic as well as experimental hypertensive rats. The limitations of the interpretation of data using such an approach are also considered. Decreased active transport of Ca2+ across isolated plasma membrane vesicles from large and small arteries occurs in several but not all forms of hypertension. This membrane abnormality also occurs in nonvascular smooth muscles and other tissues or cells not confined to the cardiovascular system in genetic hypertension, but not in experimental hypertension. A hypothesis of general membrane defects in spontaneous hypertension is proposed.(ABSTRACT TRUNCATED AT 250 WORDS)     

Adaptative Responses of Leaf Cells of Rice Seedling to Horizontal Clinostatic Conditions

The authors have studied enzyme cytochemistry, electron probe and ultrastructures in leaf cells of rice seedlings treated under horizontal clinostatic conditions simulating microgravity for 14 days. After treatment, the activity of Ca2+-ATPase in the leaf cell membrane disappeared; the density of total Ca2+ in plasm increased as that density of the cytoskeleton in the leaf cells became sparse; the cell wall was irregular being either or convex in appearance; the structure of chloroplast granas and mitochondria cristae were changed. The authors have proposed the following sequence of events: firstly, the activity of Ca2+-ATPase in leaf cell membrane disappeared; then the calcium-influx in the membrane ceased functioning thereby abolished the cross-membrane Ca2+ gradient; this weakened the assembly of the microtubule and microfilaments, loosened the cytoskeleton, disoriented the movement of the secretory vacuoles, and lead to cell wall thinning and irregularity.     

Localization and characterization of the inhibitory Ca2+-binding site of Physarum polycephalum myosin II

A myosin II is thought to be the driving force of the fast cytoplasmic streaming in the plasmodium of Physarum polycephalum. This regulated myosin, unique among conventional myosins, is inhibited by direct Ca2+ binding. Here we report that Ca2+ binds to the first EF-hand of the essential light chain (ELC) subunit of Physarum myosin. Flow dialysis experiments of wild-type and mutant light chains and the regulatory domain revealed a single binding site that shows moderate specificity for Ca2+. The regulatory light chain, in contrast to regulatory light chains of higher eukaryotes, is unable to bind divalent cations. Although the Ca2+-binding loop of ELC has a canonical sequence, replacement of glutamic acid to alanine in the -z coordinating position only slightly decreased the Ca2+ affinity of the site, suggesting that the Ca2+ coordination is different from classical EF-hands; namely, the specific "closed-to-open" conformational transition does not occur in the ELC in response to Ca2+. Ca2+- and Mg2+-dependent conformational changes in the microenvironment of the binding site were detected by fluorescence experiments. Transient kinetic experiments showed that the displacement of Mg2+ by Ca2+ is faster than the change in direction of cytoplasmic streaming; therefore, we conclude that Ca2+ inhibition could operate in physiological conditions. By comparing the Physarum Ca2+ site with the well studied Ca2+ switch of scallop myosin, we surmise that despite the opposite effect of Ca2+ binding on the motor activity, the two conventional myosins could have a common structural basis for Ca2+ regulation.     

Increases in intracellular Ca2+ regulate the binding of [3H]phorbol 12,13-dibutyrate to intact 1321N1 astrocytoma cells

The redistribution of protein kinase C (Ca2+/phospholipid-dependent protein kinase) from a cytosolic or a loosely associated membrane compartment to a more integral membrane compartment is stimulated by Ca2+ in vitro. This event is thought to be necessary for activation of the enzyme. To determine whether such a redistribution of protein kinase C occurs following hormonally stimulated increases in cytoplasmic Ca2+, we measured [3H]phorbol 12,13-dibutyrate ([3H]PDB) binding to protein kinase C in intact 1321N1 astrocytoma cells. The muscarinic agonist carbachol causes a 2-fold increase in [3H]PDB binding. This increase is transient, peaking at 1 min and returning toward control levels by 5 min. Scatchard analysis of [3H]PDB binding in the presence of carbachol reveals a 2-fold increase in the Bmax and no change in the KD compared to control values. This increase in Bmax likely represents a redistribution of protein kinase C to the membrane because [3H]PDB binding in intact cells is predominantly to membrane-associated enzyme. The Ca2+ ionophore ionomycin, and two other Ca2+-mobilizing hormones, bradykinin and histamine, mimic the effects of carbachol. Furthermore, when hormone-sensitive Ca2+ stores are depleted by prior agonist treatment, the carbachol-induced increases in intracellular [Ca2+] and [3H]PDB binding are completely blocked. Under these conditions, phosphoinositide hydrolysis and diacylglycerol (DAG) formation are not inhibited. We also examined the time course of DAG accumulation in response to carbachol. DAG is not yet significantly elevated when the increase in [3H]PDB binding is maximal. Furthermore, [3H]PDB binding has returned to control levels when DAG concentrations are maximally elevated. These data suggest that hormone-stimulated increases in cytoplasmic Ca2+ cause a marked and rapid redistribution of protein kinase C which precedes any significant increase in DAG. Our findings also demonstrate that [3H]PDB binding to intact cells may be a useful measure of the ability of Ca2+-mobilizing hormones to affect protein kinase C.     

Ca2(+)-dependent regulation of the spectrin/actin interaction by calmodulin and protein 4.1

The Ca2(+)-dependent regulation of the erythroid membrane cytoskeleton was investigated. The low-salt extract of erythroid membranes, which is mainly composed of spectrin, protein 4.1, and actin, confers a Ca2+ sensitivity on its interaction with F-actin. This Ca2+ sensitivity is fortified by calmodulin and antagonized by trifluoperazine, a potent calmodulin inhibitor. Additionally, calmodulin is detected in the low-salt extract. These results suggest that calmodulin is the sole Ca2(+)-sensitive factor in the low-salt extract. The main target of calmodulin in the erythroid membrane cytoskeleton was further examined. Under native conditions, calmodulin forms a stable and equivalent complex with protein 4.1 as determined by calmodulin affinity chromatography, cross-linking experiments, and fluorescence binding assays with an apparent Kd of 5.5 x 10(-7) M irrespective of the free Ca2+ concentration. Domain mapping with chymotryptic digestion reveals that the calmodulin-binding site resides within the N-terminal 30-kDa fragment of protein 4.1. In contrast, the interaction of calmodulin with spectrin is unexpectedly weak (Kd = 1.2 x 10(-4) M). Given the content of calmodulin in erythrocytes (2-5 microM), these results imply that the major target for calmodulin in the erythroid membrane cytoskeleton is protein 4.1. Low- and high-shear viscometry and binding assays reveal that an equivalent complex of calmodulin with protein 4.1 regulates the spectrin/actin interaction in a Ca2(+)-dependent manner. At a low Ca2+ concentration, protein 4.1 potentiates the actin cross-linking and the actin binding activities of spectrin. At a high Ca2+ concentration, the protein 4.1-potentiated actin cross-linking activity but not the actin binding activity of spectrin is suppressed by Ca2+/calmodulin. The Ca2(+)-dependent regulation of the spectrin/protein 4.1/calmodulin/actin interaction is discussed.     

Store‐operated Ca2+ entry: Vesicle fusion or reversible trafficking and de novo conformational coupling?

Store-operated Ca2+ entry (SOCE), a mechanism regulated by the filling state of the intracellular Ca2+ stores, is a major pathway for Ca2+ influx. Hypotheses to explain the communication between the Ca2+ stores and plasma membrane (PM) have considered both the existence of small messenger molecules, such as a Ca2+-influx factor (CIF), and both stable and de novo conformational coupling between proteins in the Ca2+ store and PM. Alternatively, a secretion-like coupling model based on vesicle fusion and channel insertion in the PM has been proposed, which shares some properties with the de novo conformational coupling model, such as the role of the actin cytoskeleton and soluble N-ethylmaleimide (NEM)-sensitive-factor attachment proteins receptor (SNARE) proteins. Here we review recent progress made in the characterization of the de novo conformational coupling and the secretion-like coupling models for SOCE. We pay particular attention into the involvement of SNARE proteins and the actin cytoskeleton in both SOCE models. SNAREs are recognized as proteins involved in exocytosis, participating in vesicle transport, membrane docking, and fusion. As with secretion, a role for the cortical actin network in Ca2+ entry has been demonstrated in a number of cell types. In resting cells, the cytoskeleton may prevent the interaction between the Ca2+ stores and the PM, or preventing fusion of vesicles containing Ca2+ channels with the PM. These are processes in which SNARE proteins might play a crucial role upon cell activation by directing a precise interaction between the membrane of the transported organelle and the PM.     

Effect of active oxygen on cytoplasmic Ca2+ sequestration mechanism

Effects of the active oxygen on the extrusion mechanism of once-increased cytoplasmic Ca2+, which causes various physiological phenomena, were investigated using different kinds of culture cells. First we found that, in response to stimulation with vitamin K (VK), various culture cells showed a decrease in cytoplasmic Ca2+ concentration. On the presumption that this phenomenon might be related to the oxidizing action of VK, we performed the same experiments using oxidizing agents such as H2O2 or KO2. They also showed a decrease in cytoplasmic Ca2+ concentration. Furthermore, they suppressed the increase of cytoplasmic Ca2+ by vasopressin. It would be inferred from these results that the active oxygen may act upon some site of the cellular signal transduction system of cell membrane to lower the cytoplasmic Ca2+ level.     

Membrane binding and subcellular targeting of C2 domains

C2 domains are a ubiquitous structural module and many of them function in Ca2+ -dependent membrane binding and thereby serve as Ca2+ effectors for divergent Ca2+ -mediated cellular processes. Extensive structural, biochemical, biophysical, and cellular studies of C2 domains and host proteins in the past decade have shown that due to their structural diversity C2 domains have disparate Ca2+ sensitivity, lipid selectivity and membrane binding mechanisms. This review summarizes the basic structural and functional properties of C2 domains as well as recent findings on Ca2+ and membrane binding, lipid selectivity, and subcellular localization of C2 domains and their host proteins.     

Platelet-derived growth factor stimulates non-mitochondrial Ca2+ uptake and inhibits mitogen-induced Ca2+ signaling in Swiss 3T3 fibroblasts

Changes in intracellular free Ca2+ concentration [( Ca2+]i) were used to study the interaction between mitogens in Swiss 3T3 fibroblasts. Platelet-derived growth factor (PDGF) produced an increase in [Ca2+]i and markedly decreased the increases in [Ca2+]i caused by subsequent addition of bradykinin and vasopressin. If the order of the additions was reversed the [Ca2+]i response to PDGF was not inhibited by bradykinin or vasopressin. Inhibition of protein kinase C by staurosporine or chronic treatment of the cells with phorbol 12-myristate 13-acetate prevented the inhibitory effect of PDGF on the [Ca2+]i response to vasopressin but not bradykinin. PDGF did not decrease the receptor binding of bradykinin and produced only a small decrease in the receptor binding of vasopressin. PDGF decreased the rise in [Ca2+]i caused by the Ca2+ ionophores 4-bromo-A23187 and ionomycin and by a membrane perturbing ether lipid, 1-octadecyl-2-methyl-rac-glycero-3-phosphocholine, both in the presence and absence of external Ca2+. There was no change in cell 45Ca2+ influx caused by PDGF, vasopressin, or bradykinin. 45Ca2+ efflux from cells exposed to PDGF and vasopressin mirrored the changes in [Ca2+]i caused by the agents, that is, PDGF added after vasopressin produced a further increase in 45Ca2+ efflux but vasopressin did not increase 45Ca2+ efflux after PDGF. PDGF but not vasopressin caused an increase in the uptake of 45Ca2+ into an inositol 1,4,5-trisphosphate-insensitive non-mitochondrial store in permeabilized cells. The results suggest that the decreased [Ca2+]i response to mitogens after PDGF represents an action of PDGF at a point beyond the release of intracellular Ca2+ and the influx of external Ca2+, caused by an increase in the rate of removal of cytoplasmic free Ca2+. This increased removal of cytoplasmic Ca2+ by PDGF is not due to the increased export of Ca2+ from the cell but results from increased Ca2+ uptake into non-mitochondrial stores.