Activation of sodium-proton exchange is a prerequisite for Ca2+ mobilization in human platelets

Stimulated platelets take up sodium ions and release hydrogen ions due to activation of Na+/H+ exchange resulting in cytoplasmic alkalinization. Suppression of Na+/H+ exchange either by removal of extracellular Na+ or by application of amiloride inhibits shape change, secretion of granule contents and aggregation. The data we present here indicate that inhibition of this transport by ethylisopropyl-amiloride or by lowering extracellular sodium reduces or even completely suppresses the rise in cytoplasmic free Ca2+ concentration that is essential for platelet aggregation in response to thrombin. We also demonstrate that cytoplasmic alkalinization produced by exposure to the ionophore monensin sensitizes the human platelet response to stimulation by thrombin resulting in enhanced Ca2+ mobilization and aggregability. We conclude that an increase in intracellular pH evoked by activation of Na+/H+ counter transport is an important signal in stimulus-response coupling and forms an essential step in the cascade of events required to increase cytoplasmic free Ca2+ in platelets.     

Arginine vasopressin enhances pHi regulation in the presence of HCO3- by stimulating three acid-base transport systems

Growth factors raise intracellular pH (pHi) by stimulating Na+/H+ exchange in the absence of HCO3-. In mutant cells that lack the Na+/H+ exchange activity, this alkalinization does not occur, and the cells do not proliferate without artificial elevation of pHi. It has therefore been widely suggested that an early pHi increase is a necessary signal for mitogenesis. In the presence of HCO3- however, growth factors fail to raise pHi in A431 cells, renal mesangial cells and 3T3 fibroblasts. In mesangial cells, arginine vasopressin (AVP) raises pHi in the absence of HCO3-, but lowers it when HCO3- is present; growth is stimulated under both conditions. We report here that, in the presence of HCO3-, AVP stimulates two potent HCO3- transporters, as well as the Na+/H+ exchanger. These are the Na+-dependent and Na+-independent Cl-/HCO3- exchangers. Our results indicate that AVP causes acidification in the presence of HCO3- because, at the resting pHi, it stimulates Na+-independent Cl-/HCO3- exchange (which lowers pHi) more than it stimulates the sum of Na+/H+ exchange and Na+-dependent Cl-/HCO3- exchange (both of which raise pHi). The stimulation of three acid-base transporters by the growth factor AVP greatly enhances the ability of the cell to regulate pHi.     

Charge movement during Na+ translocation by native and cloned cardiac Na+/Ca2+ exchanger

Na+/Ca2+ exchange is electrogenic and moves one net positive charge per cycle. Although the cardiac exchanger has a three-to-one Na+/Ca2+ stoichiometry, details of the reaction cycle are not well defined. Here we associate Na+ translocation by the cardiac exchanger with positive charge movement in giant membrane patches from cardiac myocytes and oocytes expressing the cloned cardiac Na+/Ca2+ exchanger. The charge movements are initiated by step increments of the cytoplasmic Na+ concentration in the absence of Ca2+. Giant patches from control oocytes lack both steady-state Na+/Ca2+ exchange current (INaCa) and Na(+)-induced charge movements. Charge movements indicate about 400 exchangers per micron 2 in guinea-pig sarcolemma. Fully activated INaCa densities (20-30 microA cm-2) indicate maximum turnover rates of 5,000 s-1. As has been predicted for consecutive exchange models, the apparent ion affinities of steady state INaCa increase as the counterion concentrations are decreased. Consistent with an electroneutral Ca2+ translocation, we find that voltage dependence of INaCa in both directions is lost as Ca2+ concentration is decreased. The principal electrogenic step seems to be at the extracellular end of the Na+ translocation pathway.     

pH-sensitive activation of the intracellular-pH regulation system in squid axons by ATP-gamma-S

The regulation of intracellular pH (pHi) is essential for normal cell function, and controlled changes in pHi may play a central role in cell activation. Sodium-dependent Cl-HCO3 exchange is the dominant mechanism of pHi regulation in the invertebrate cells examined, and also occurs in mammalian cells. The transporter extrudes acid from the cell by exchanging extracellular Na+ and HCO3- (ref. 9) (or a related species) for intracellular Cl- (refs 3, 4). It is blocked by the stilbene derivatives DIDS (4,4'-diisothiocyano-stilbene-2,2'-disulphonate, ref. 10) and SITS (4-acetamido-4'-isothiocyano-stilbene-2,2'-disulphonate, ref. 3), and has a stoichiometry of two intracellular H+ neutralized for each Na+ taken up and each Cl- extruded by the axon. Because the inwardly-directed Na+ concentration gradient is sufficiently large to energize both the HCO3- influx and Cl- efflux, this electroneutral exchanger could be a classic secondary active transporter, thermodynamically independent of ATP hydrolysis. However, at least in the squid axon, the exchanger has an absolute requirement for ATP (ref. 3). Thus, a major unresolved issue is whether this Na-dependent Cl-HCO3 exchanger stoichiometrically hydrolyses ATP (the pump hypothesis), or whether ATP activates the transporter by a mechanism such as phosphorylation or simple binding (the activation hypothesis). We have now explored the role of ATP in pHi regulation by dialysing axons with the ATP analogue ATP-gamma-S. In many systems, ATP-gamma-S is an acceptable substrate for protein kinases, whereas the resulting thiophosphorylated proteins are not as readily hydrolysed by phosphatases as are phosphorylated proteins. Our results rule out the pump hypothesis, and show that the basis of the axon's ATP requirement is the pH-dependent activation (by, for instance, phosphorylation or ATP binding) of the exchanger itself, or of an essential activator.     

Effects of ATP and vanadate on calcium efflux from barnacle muscle fibres

Calcium ions carry the inward current during depolarization of barnacle muscle fibres and are involved in the contraction process. Intracellular ionized calcium ([Ca2+]i) in barnacle muscle, as in other cells, is kept at a very low concentration, against a large electrochemical gradient. This large gradient is maintained by Ca2+ extrusion mechanisms. When [Ca2+]i is below the contraction threshold, Ca2+ efflux from giant barnacle muscle fibres is, largely, both ATP dependent and external Na+ (Na+0) dependent (see also refs 5,6). When [Ca2+]i is raised to the level expected during muscle contraction (2-5 muM), most of the Ca2+ efflux from perfused fibres is Na0 dependent; as in squid axons, this Na+0-dependent Ca2+ efflux is ATP independent. Orthovanadate is an inhibitor of (Na+ + K+) ATPase and the red cell Ca2+-ATpase. We report here that vanadate inhibits ATP-promoted, Na+0-dependent Ca2+ efflux from barnacle muscle fibres perfused with low [Ca2+]i (0.2-0.5 microM), but has little effect on the Na+0-dependent, ATP-independent Ca2+ efflux from fibres with a high [Ca]i (2-5 microM). Nevertheless, ATP depletion or vanadate treatment of high [Ca2+]i fibres causes an approximately 50-fold increase of Ca2+ efflux into Ca2+-containing lithium seawater. These results demonstrate that both vanadate and ATP affect Ca2+ extrusion, including the Na+0-dependent Ca2+ efflux (Na-Ca exchange), in barnacle muscle.     

Role of intracellular Ca2+ sequestration in beta-adrenergic relaxation of a smooth muscle.

Various mechanisms have been proposed for beta-adrenergically mediated relaxation of smooth muscle. All theories suggest the involvement of cyclic AMP as a second messenger: beta-agonists stimulate adenylate cyclase which converts ATP to cyclic AMP and protein kinase, activated by cyclic AMP, is then thought to catalyse a protein phosphorylation that leads to a reduction in free Ca2+, thus effecting relaxation. How this last step is accomplished is much debated, but the following possibilities are currently considered as the mechanisms responsible for cyclic AMP-induced reduction of cytoplasmic Ca2+: activation of a Ca2+-ATPase in the plasma and/or sarcoplasmic reticulum membranes which lowers cytoplasmic [Ca2+] in a direct manner or stimulation of (Na+-K+)ATPase in the cell membrane which may indirectly effect Ca2+ extrusion. Among the hypotheses suggested, those of Ca2+ sequestration by the sarcoplasmic reticulum and of Ca2+ extrusion across the cell membrane are consistent with each other if it is assumed that both processes are effected by a cyclic AMP-sensitive Ca2+-ATPase. However, quite a different mechanism is implied by involving the Na+-K+ pump and Na+-Ca2+ exchange carrier. In this report, we present evidence that suggests intracellular Ca2+ sequestration is the mechanism involved.     

Diacylglycerol and phorbol ester stimulate secretion without raising cytoplasmic free calcium in human platelets

An increase in cytoplasmic free calcium, [Ca2+]i, is thought to be the trigger for secretory exocytosis in many cells. In blood platelets, large rises in [Ca2+]i can cause secretion and calcium has been regarded as the final common activator not only for secretion but also for shape-change and aggregation. We have shown that while thrombin and platelet-activating factor (PAF) normally elevate [Ca2+]i, they can also stimulate shape-change and secretion even when the [Ca2+]i rise is suppressed. The present results strongly implicate diacylglycerol, produced by stimulus-dependent breakdown of phosphoinositide, in this calcium-independent activation. Exogenous diacylglycerol activates a protein kinase (C-kinase) in platelets as do PAF, thrombin and collagen. 12-O-tetradecanoyl phorbol-13-acetate (TPA) also activates C-kinase and is a potent stimulus for secretion and aggregation. It is shown here that the exogenous diacylglycerol 1-oleoyl-2-acetyl-glycerol (OAG) and TPA evoke similar secretion and aggregation without elevating [Ca2+]i above the basal level of 0.1 microM. The pattern of secretion resembles that produced by collagen and thrombin when [Ca2+]i remains at basal levels. Modest increases in [Ca2+]i, insufficient to stimulate secretion, markedly accelerate the responses to TPA and OAG.     

A common sequence of calcium and pH signals in the mitogenic stimulation of eukaryotic cells

When normal quiescent (G0) cells are stimulated by mitogens to enter the cell cycle, the metabolic derepression which occurs is similar in a variety of cells. The mechanisms initiating these responses and their relationship to subsequent progression through G1 to DNA synthesis in S phase, however, are generally undefined. The clearest evidence has been obtained in sea urchin eggs, where fertilization by sperm causes a rapid, transient increase in the concentration of free cytoplasmic Ca2+ [(Ca]i), followed by a sustained increase in cytoplasmic pH (pHi). It has been demonstrated clearly that these ionic responses are obligatory for progression to DNA synthesis by the normal pathway after fertilization, although the Ca2+ signal can be bypassed by parthenogenetic agents which elevate directly pHi (for example, NH+4 ions). These observations raise the questions of whether other eukaryotic cells show the same sequence of ionic responses when stimulated by mitogens and whether such signals are an obligatory component of their mitogenic pathways. We show here that a common sequence of [Ca]i and pHi responses occurs in both quiescent mouse thymocytes and Swiss 3T3 fibroblasts stimulated by appropriate mitogens. Furthermore, 'opportunistic' mitogens (those that do not act on the cells in vivo, such as concanavalin A (Con A), the Ca2+ ionophore A23187 and 12-o-tetradecanoyl phorbol 13-acetate CTPA] that are mitogenic for both mouse thymocytes and 3T3 fibroblast, each produce characteristic ionic responses that are the same in both types of cell.     

Multiple transport modes of the cardiac Na+/Ca2+ exchanger

The cardiac Na+/Ca2+ exchanger (NCX1; ref. 2) is a bi-directional Ca2+ transporter that contributes to the electrical activity of the heart. When, and if, Ca2+ is exported or imported depends on the Na+/Ca2+ exchange ratio. Whereas a ratio of 3:1 (Na+:Ca2+) has been indicated by Ca2+ flux equilibrium studies, a ratio closer to 4:1 has been indicated by exchange current reversal potentials. Here we show, using an ion-selective electrode technique to quantify ion fluxes in giant patches, that ion flux ratios are approximately 3.2 for maximal transport in either direction. With Na+ and Ca2+ on both sides of the membrane, net current and Ca2+ flux can reverse at different membrane potentials, and inward current can be generated in the absence of cytoplasmic Ca2+, but not Na+. We propose that NCX1 can transport not only 1 Ca2+ or 3 Na+ ions, but also 1 Ca2+ with 1 Na+ ion at a low rate. Therefore, in addition to the major 3:1 transport mode, import of 1 Na+ with 1 Ca2+ defines a Na+-conducting mode that exports 1 Ca2+, and an electroneutral Ca2+ influx mode that exports 3 Na+. The two minor transport modes can potentially determine resting free Ca2+ and background inward current in heart.     

Extrusion of calcium from rod outer segments is driven by both sodium and potassium gradients

Calcium is transported across the surface membrane of both nerve and muscle by a Na+-dependent mechanism, usually termed the Na:Ca exchange. It is well established from experiments on rod outer segments that one net positive charge enters the cell for every Ca2+ ion extruded by the exchange, which is generally interpreted to imply an exchange stoichiometry of 3 Na+:1 Ca2+. We have measured the currents associated with the operation of the exchange in both forward and reversed modes in isolated rod outer segments and we find that the reversed mode, in which Ca2+ enters the cell in exchange for Na+, depends strongly on the presence of external K+. The ability of changes in external K+ concentration ([K+]o) to perturb the equilibrium level of [Ca2+]i indicates that K+ is co-transported with calcium. From an examination of the relative changes of [Ca2+]o, [Na+]o, [K+]o and membrane potential required to maintain the exchange at equilibrium, we conclude that the exchange stoichiometry is 4 Na+:1 Ca2+, 1 K+ and we propose that the exchange should be renamed the Na:Ca, K exchange. Harnessing the outward K+ gradient should allow the exchange to maintain a Ca2+ efflux down to levels of internal [Ca2+] that are considerably lower than would be possible with a 3 Na+:1 Ca2+ exchange.     

Cyclic nucleotides control a system which regulates Ca2+ sensitivity of platelet secretion

Cellular responses to extracellular signals are mediated by changes in the intracellular concentrations of one or more second messengers. In platelets, inhibitory agonists increase intracellular cyclic-3',5'-AMP [( cyclic AMP]i (refs 2, 3] whereas excitatory agonists increase [Ca2+]i and/or [1,2-diacylglycerol]i (refs 4-9), and in some cases decrease [cyclic AMP]i (refs 10, 11). Both activation and inhibition of platelet responses have been attributed to an increase in [cyclic-3',5'-GMP]i (refs 8, 12). The activity of protein kinase C, which is associated with the platelet secretory response, is increased by both 1,2-diacylglycerol and Ca2+ (refs 4, 7, 8). The role of cyclic AMP may involve either inhibition of Ca2+ mobilization to the cytosol or stimulation of intracellular Ca2+ uptake, and in addition inhibition of 1,2-diacylglycerol formation. The relationship between cyclic-3',5'-GMP (cyclic GMP) and other second messengers in platelet activation has not been defined. Using platelets made permeable by exposure to an intense electric field, we demonstrate here modulation of the Ca2+ sensitivity of platelet secretion by thrombin, and by 12-O-tetradecanoylphorbol-13-acetate (TPA) and 1-oleyl-2- acetylglycerol ( OAG ), both potent activators of protein kinase C. The effect of thrombin is selectively modified by cyclic GMP and cyclic AMP. The response to OAG and TPA is also modulated by cyclic AMP but to a much lesser extent.     

A model for intracellular translocation of protein kinase C involving synergism between Ca2+ and phorbol esters

The activation of protein kinase C by diacylglycerol and by tumour promoters has implicated this enzyme in transmembrane signalling and in the regulation of the cell cycle. In vitro studies revealed that catalytic activity requires the presence of calcium and phospholipids with a preference for phosphatidylserine. Diacylglycerol and tumour promoters such as phorbol esters bind to the enzyme, leading to its activation while sharply increasing its affinity for Ca2+ and phospholipid. Addition of diacylglycerol analogues or phorbol esters to intact cells results in the phosphorylation of specific polypeptides. Several cellular processes, including hormone and neurotransmitter release and receptor down-regulation, are modulated by the activation of protein kinase C, while phorbol ester-induced stimulation of the enzyme in whole cells has been associated with its translocation from the cytoplasm to the plasma membrane. Moreover, the use of Ca2+ ionophores has revealed an apparent synergism between Ca2+ mobilization and protein kinase C activation. This synergism has recently also been found to apply to receptor down-regulation (ref. 23 and accompanying paper). Here we describe a reconstitution system in which intracellular translocation of protein kinase C and the synergism between Ca2+ and enzyme activators can be studied. The results suggest a rationale for concomitant Ca2+ mobilization and diacylglycerol formation in response to some hormones, neurotransmitters and growth factors.     

Regulation and deregulation of cardiac Na(+)-Ca2+ exchange in giant excised sarcolemmal membrane patches

A plasmalemmal Na(+)-Ca2+ exchange mechanism is an important electrogenic determinant of contractility in cardiac cells. As in other cell types, calcium influx by Na(+)-Ca2+ exchange is secondarily activated by cytoplasmic calcium and probably ATP, but these modulatory mechanisms are either absent or altered in isolated cardiac sarcolemmal vesicles. Involvement of a calcium-dependent protein kinase in exchange regulation has been suggested but not verified. Here I describe measurements of outward Na(+)-Ca2+ exchange current, corresponding to calcium influx, in giant excised sarcolemmal patches from guinea pig myocytes. The exchange current is stimulated by both calcium and Mg-ATP from the cytoplasmic face, evidently through separate mechanisms. Activation by cytoplasmic calcium takes place within seconds, is reversible, and does not require ATP. Stimulation by Mg-ATP reverses only slowly over greater than 10 min, or not at all. Unexpectedly, a substantial decrease in exchange current occurs during activation by cytoplasmic sodium, which seems to reflect an inactivation process rather than ion concentration changes or a 'first pass' exchange cycle. This apparent inactivation, and the modulations by cytoplasmic calcium and Mg-ATP, are all abolished by brief treatment of the cytoplasmic surface with chymotrypsin, leaving the exchanger in a maintained state of high activity. Therefore, limited proteolysis deregulates Na(+)-Ca2+ exchange and could contribute to the loss of secondary regulation of the exchange in isolated sarcolemmal vesicles.     

Antigen-dependent increase in cytosolic free calcium in specific human T-lymphocyte clones

Calcium has been implicated as an intracellular messenger in the cellular response to various external stimuli. Exposure of lymphocytes to various mitogens and lectins results in rapid transmembrane calcium fluxes and increased cytoplasmic calcium concentrations ([Ca2+]i). It is not clear, however, whether the mechanisms by which these non-physiological stimuli activate cells are related to those involved in antigen-specific activation. We have now used antigen-specific T-cell clones to study changes in [Ca2+]i associated with specific activation and show here that these cells respond specifically in the presence of antigen and antigen-presenting cells (APC) with increased [Ca2+]i and that this increased [Ca2+]i shows the same genetic restrictions as are seen in the proliferation assay. The kinetics of the [Ca2+]i response to antigen indicate that antigen undergoes a time-dependent processing step as a prerequisite for recognition by T cells, as has been shown for T-cell proliferative responses, but that the [Ca2+]i response to processed antigen is extremely rapid. The close correlation between changes in [Ca2+]i and cell activation resulting in proliferation suggests that Ca2+ may act as an intracellular messenger in antigen-specific responses.     

Identification of Na-Ca exchange current in single cardiac myocytes

In cardiac muscle the exchange of intracellular Ca2+ for extracellular Na+ is an important transport mechanism for regulation of the intracellular free Ca2+ concentration [( Ca]i) and hence the contractile strength of the heart. Due to its stoichiometry of greater than or equal to 3:1 Na+/Ca2+ (refs 3,5), Na-Ca exchange is supposed to generate a current across the cell membrane. It is thought that such a current may contribute to cardiac action potential and physiological or pathological pacemaker activity. Although the occurrence of Na-Ca exchange is well documented, a membrane current generated by this transport has not been identified unequivocally. Previous attempts to detect such a current in multicellular preparations, for example, by measuring small current differences after varying the extracellular ionic composition, although providing evidence, did not rule out other possible interpretations. Here we demonstrate that a transient rise in [Ca]i caused by release of Ca from sarcoplasmic reticulum (SR) generates a membrane current in cardiac myocytes. The dependence of this current on the transmembrane gradients for Na+ and Ca2+ and on membrane potential meets the criteria for a current produced by electrogenic Na-Ca exchange. Cyclic activation of this current by release of Ca from the SR can cause maintained spontaneous activity, suggesting that Na-Ca exchange contributes to certain forms of cardiac pacemaking.     

Control of Ca2+ in rod outer segment disks by light and cyclic GMP

Photons absorbed in vertebrate rods and cones probably cause electrochemical changes at the photoreceptor plasma membrane by changing the cytoplasmic concentration of a diffusible transmitter substance, reducing the Na+ current flowing into the outer segment of the cell in the dark, to produce the observed membrane hyperpolarization that is the initial excitatory response. Cyclic GMP has been proposed as the transmitter because a light-activated cyclic GMP phosphodiesterase (PDE) has been found in rod disk membranes and because intracellularly injected cyclic GMP reduces rod membrane potentials. Free Ca2+ has also been proposed because increasing external [Ca2+] quickly and reversibly reduces the dark current and divalent cationophores increase the Ca2+ sensitivity. Ca2+ efflux from rod outer segments (ROS) of intact retinas occurs simultaneously with light responses. Vesicles prepared from ROS disk membranes become more permeable on illumination, releasing trapped ions or molecules, but intact outer segment disks have not previously been found to store sufficient Ca2+ in darkness and to release enough in light to meet the theoretical requirements for control of the dark current by varying cytoplasmic Ca2+ (refs 14-18). We now report experiments that show the required Ca2+ storage and release from rod disk membranes suspended in media containing high-energy phosphate esters and electrolytes approximating the cytoplasmic composition of live rod cells. Cyclic GMP stimulates Ca2+ uptake by ROS disks in such media.     

Stimulation of the Na/H exchanger of sea urchin eggs by phorbol ester

On fertilization of a sea urchin egg, marked changes occur in the cytoplasmic concentration of calcium and hydrogen ions. These ionic signals represent the necessary and sufficient stimuli for the increased metabolism, protein synthesis and DNA synthesis that constitute egg activation. Cytoplasmic alkalinization, the major immediate cause of the increased rate of protein synthesis which occurs at fertilization, arises because the sperm-induced intracellular calcium transient activates a coupled flux of sodium ions and hydrogen ions across the oolemma. The experiments reported here suggest that the second messenger which links the activation of the Na/H exchange to the calcium transient may be a substance which stimulates protein kinase C8, as 12-O-tetradecanoyl phorbol acetate (TPA), a known activator of protein kinase C9, appears to stimulate protein synthesis by turning on the Na/H exchanger and causing a cytoplasmic alkalinization. Our data indicate that one consequence of treating other tissues with TPA, a tumour promoter, may be an increase in intracellular pH.     

An inositol tetrakisphosphate-containing phospholipid in activated neutrophils

Inositol (1,4,5)triphosphate (InsP3) and tetrakisphosphate (InsP4) have been observed in a variety of cell types and have been proposed to play roles in the receptor-mediated rise in intracellular Ca2+ (refs 2, 3). Recently, they have been shown to act synergistically in the activation of a Ca2+-dependent K+ channel in lacrimal acinar cells. InsP3 is the product of phospholipase C (PLC) action on phosphatidylinositol 4,5-bisphosphate (PtdInsP2) whereas InsP4 is believed to arise from phosphorylation of InsP3 by a cytosolic kinase. Although sought as a source for InsP4, PtdInsP3 has not been identified in any specific cell type. There were early reports of InsP4-containing phospholipids in crude extract from bovine brain, but this finding was later withdrawn. Recently, however, a membrane-bound enzyme (Type 1 PI kinase) which adds phosphate onto the 3 position of inositol phospholipids has been identified and the phosphatidylinositol-3-phosphate (PtdIns(3)P) product characterized. This suggests that several forms of phosphoinositides may exist and could be precursors for some of the variety of soluble inositol phosphate products which have been reported in recent years. Here we report the appearance of another novel phosphoinositide containing four phosphates, phosphatidylinositol trisphosphate (PtdInsP3) which we find only in activated but not in unstimulated neutrophils from human donors.     

Activation of chloride channels in normal and cystic fibrosis airway epithelial cells by multifunctional calcium/calmodulin-dependent protein kinase.

Cystic fibrosis is associated with defective regulation of apical membrane chloride channels in airway epithelial cells. These channels in normal cells are activated by cyclic AMP-dependent protein kinase and protein kinase C. In cystic fibrosis these kinases fail to activate otherwise normal Cl- channels. But Cl- flux in cystic fibrosis cells, as in normal cells, can be activated by raising intracellular Ca2+ (refs 5-10). We report here whole-cell patch clamp studies of normal and cystic fibrosis-derived airway epithelial cells showing that Cl- channel activation by Ca2+ is mediated by multifunctional Ca2+/calmodulin-dependent protein kinase. We find that intracellular application of activated kinase and ATP activates a Cl- current similar to that activated by a Ca2+ ionophore, that peptide inhibitors of either the kinase or calmodulin block Ca2(+)-dependent activation of Cl- channels, and that a peptide inhibitor of protein kinase C does not block Ca2(+)-dependent activation. Ca2+/calmodulin activation of Cl- channels presents a pathway with therapeutic potential for circumventing defective regulation of Cl- channels in cystic fibrosis.     

Vanadate inhibits uncoupled Ca efflux but not Na--Ca exchange in squid axons.

Nerve cells can maintain a very low intracellular calcium concentration ([Ca2+]i) against large Ca2+ electrochemical gradients (see ref. 1 for review). The properties of the calcium efflux from these cells depend on [Ca2+]i (ref. 2), and within the physiological range, most Ca efflux depends on ATP (which stimulates with high affinity) and is insensitive to Na1, Na0 and Ca0 (uncoupled Ca efflux). When the [Ca2+]i is well above the physiological range, Ca efflux becomes only partially dependent on ATP (acting now with low affinity), is inhibited by Nai and is stimulated by Na0 and Ca0 (Na--Ca exchange). Orthovanadate, a powerful inhibitor of the (Na+ + K+)ATPase and the Na pump, also inhibits the Ca-stimulated ATPase activity, which is the enzymatic basis for the uncoupled Ca pump, in human red cells. The experiments reported here show that in squid axons the ATP-dependent uncoupled Ca efflux can be fully and reversibly inhibited by vanadate, whereas concentrations of vanadate 10 times higher have no effect on the Na--Ca exchange. This is another indication that the uncoupled Ca efflux represents an ATP-driven Ca pump, and supports the suggestion that the uncoupled Ca efflux and Na--Ca exchange are mediated by different mechanisms.