The calmodulin inhibitor R24571 induces a short-term Ca2+ entry and a pulse-like secretion of ATP in Ehrlich ascites tumor cells

The properties of the Ca2+ channel induced by a calmodulin inhibitor in Ehrlich ascites tumor cells were investigated using fluorescent indicators Indo-1 and chlortetracycline. The inhibitor of calmodulin calmidazolium (R24571) in concentrations of 1-2 microM induces a short-term Ca2+ entry and a pulse-like ATP secretion. Repeated addition of R24571 also causes a transient Ca2+ signal. Ca2+ channels induced by R24571 are permeable for Mn2+. Ca2+ entry does not depend on endoplasmic reticulum depletion by thapsigargin, ATP, or ionomycin and is suppressed by nordihydroguaretic acid (EC50 = 6.7 microM), quercetin (EC50 = 1.5 microM), dihydroquercetin (EC50 = 17 microM), arachidonic acid (AA) (EC50 = 8.6 microM), and suramin (EC50 = 0.25 +/- 0.05 MM), and weakly depends on temperature in the range of 18 - 37 degrees C. The apparent activation constant for R24571 and the Hill coefficient are 2.5 +/- 0.2 and 4 +/- 0.3 microM, respectively. The products of arachidonic acid oxidation are neither activators nor inhibitors of these channels. The inhibitory effect of nordihydroguaretic acid is indirect and is conceivably caused by the accumulation of arachidonic acid due to suppression of its lipoxygenase-catalyzed oxidation at phospholipase A2 activation. The maximal level of about 1.3 microM in the dependence of Ca2+ signal amplitude on R24571 concentration points to possible inhibition of the channel by increased Ca2+ concentration in the cytosol. The weak dependence on temperature implies that the channel is highly permeable, the chain of enzymic processes is not involved in Ca2+ entry activation, and the mutual compensation of processes with opposite contributions is possible. Using chlortetracycline fluorescence, we have shown in model experiments on calmodulin solution that Ca2+ induces cooperatively a conformational transition of calmodulin with the exposure of a hydrophobic chlortetracycline-Ca(2+)-binding site. The interaction of R24571 with the CaM-Ca2+ complex results in quenching of fluorescence to its level in water, which is interpreted as the elimination of the availability of calmodulin hydrophobic site for chlortetracycline-Ca+. Nordihydroguaretic acid, quercetin, and dihydroquercetin, but not suramin, also interact with calmodulin, but this does not result in the complete closing of its hydrophobic site. It is supposed that the activation of the Ca2+ channel occurs owing to the activation of calmodulin-dependent phospholipase A2 by R24571, which leads to the formation of a low-molecular short-lived secondary messenger, or because of the interaction of R24571 with calmodulin, which directly inhibits the channel. The termination of Ca2+ entry is probably due to the inhibition of phospholipase A2 and/or of the channel at increased concentrations of arachidonic acid and Ca2+.     

Hydrophobic regions function in calmodulin-enzyme(s) interactions

Certain naturally occurring lipids (phosphatidylinositol, phosphatidylserine, arachidonic acid) and sodium dodecyl sulfate activate at least two calmodulin-dependent enzymes, bovine brain 3':5'-cyclic nucleotide phosphodiesterase and chicken gizzard myosin light chain kinase in the absence of Ca2+. 2-p-Toluidinyl-naphthalene-6-sulfonate (TNS), which is often used as a probe for hydrophobic groups of proteins, inhibits these two calmodulin-dependent enzymes. Kinetic analysis of inhibition of chicken gizzard myosin kinase by TNS revealed a competitive fashion against calmodulin-induced activation. The interaction between TNS and purified bovine brain calmodulin as demonstrated in the appearance of TNS fluorescence in the presence of 3 microM or more of calcium ion was not observed in the presence of 2 mM EGTA. This suggests that TNS is able to bind to calmodulin in the presence of Ca2+. Moreover, a calmodulin-interacting agent N-(6-aminohexyl)-5-chloro-1-naphthalenesulfonamide suppressed the TNS fluorescence induced by complex formation with calmodulin in the presence of Ca2+. These results suggest that when Ca2+ binds to the high affinity sites of calmodulin, it induces a conformational change which exposes hydrophobic groups, and the calmodulin is then capable of activating calmodulin-dependent enzymes. We propose that hydrophobic properties of Ca2+-calmodulin are important for the activation of Ca2+-calmodulin-dependent enzymes.     

Ca2+-dependent potentiation of the nonselective cation channel TRPV4 is mediated by a C-terminal calmodulin binding site

Most Ca2+-permeable ion channels are inhibited by increases in the intracellular Ca2+ concentration ([Ca2+]i), thus preventing potentially deleterious rises in [Ca2+]i. In this study, we demonstrate that currents through the osmo-, heat- and phorbol ester-sensitive, Ca2+-permeable nonselective cation channel TRPV4 are potentiated by intracellular Ca2+. Spontaneous TRPV4 currents and currents stimulated by hypotonic solutions or phorbol esters were reduced strongly at all potentials in the absence of extracellular Ca2+. The other permeant divalent cations Ba2+ and Sr2+ were less effective than Ca2+ in supporting channel activity. An intracellular site of Ca2+ action was supported by the parallel decrease in spontaneous currents and [Ca2+]i on removal of extracellular Ca2+ and the ability of Ca2+ release from intracellular stores to restore TRPV4 activity in the absence of extracellular Ca2+. During TRPV4 activation by hypotonic solutions or phorbol esters, Ca2+ entry through the channel increased the rate and extent of channel activation. Currents were also potentiated by ionomycin in the presence of extracellular Ca2+. Ca2+-dependent potentiation of TRPV4 was often followed by inhibition. By mutagenesis, we localized the structural determinant of Ca2+-dependent potentiation to an intracellular, C-terminal calmodulin binding domain. This domain binds calmodulin in a Ca2+-dependent manner. TRPV4 mutants that did not bind calmodulin lacked Ca2+-dependent potentiation. We conclude that TRPV4 activity is tightly controlled by intracellular Ca2+. Ca2+ entry increases both the rate and extent of channel activation by a calmodulin-dependent mechanism. Excessive increases in [Ca2+]i via TRPV4 are prevented by a Ca2+-dependent negative feedback mechanism.     

A spectrin-dependent ATPase of the human erythrocyte membrane

Removal of spectrin from erythrocyte membranes results in the simultaneous loss of a calcium-stimulated, magnesium-dependent ATPase with an apparent KD for Ca2+ of 1 microM. This ATPase activity with high Ca2+ affinity is specifically reconstituted by addition of purified spectrin to spectrin-depleted membranes, and the reconstituted activity is directly proportional to the amount of spectrin that is reassociated with the membranes. Spectrin binding and activation of the high Ca2+ affinity Mg2+-ATPase are proportionally inhibited by thermal denaturation, trypsin digestion, or treatment of the membranes with thiol-reactive reagents. Binding of calmodulin to the Ca2+ pump ATPase requires that calmodulin contains bound ca2+. By contrast, spectrin binding to the erythrocyte membrane is Ca2+-independent. Direct assay of calmodulin is purified spectrin and absence of chlorpromazine inhibition of reconstitution demonstrate that activation of the high Ca2+ affinity ATPase resulting from spectrin binding is not a result of contamination of spectrin by calmodulin. Additional evidence that the spectrin-activated ATPase is an entity separate and distinct from the Ca2+ pump is provided by other characteristics of the activation phenomenon. It is suggested that spectrin constitutes part of an ATPase which may function as a component of the "cytoskeleton" controlling erythrocyte shape and membrane flexibility.     

Inhibition of a Low Km GTPase Activity in Rat Striatum by Calmodulin

In rat striatum, the activation of adenylate cyclase by the endogenous Ca2+-binding protein, calmodulin, is additive with that of GTP but is not additive with that of the nonhydrolyzable GTP analog, guanosine-5'-(beta, gamma-imido)triphosphate (GppNHp). One possible mechanism for this difference could be an effect of calmodulin on GTPase activity which has been demonstrated to "turn-off" adenylate cyclase activity. We examined the effects of Ca2+ and calmodulin on GTPase activity in EGTA-washed rat striatal particulate fractions depleted of Ca2+ and calmodulin. Calmodulin inhibited GTP hydrolysis at concentrations of 10(-9)-10(-6) M but had no effect on the hydrolysis of 10(-5) and 10(-6) M GTP, suggesting that calmodulin inhibited a low Km GTPase activity. The inhibition of GTPase activity by calmodulin was Ca2+-dependent and was maximal at 0.12 microM free Ca2+. Maximal inhibition by calmodulin was 40% in the presence of 10(-7) M GTP. The IC50 for calmodulin was 100 nM. In five tissues tested, calmodulin inhibited GTP hydrolysis only in those tissues where it could also activate adenylate cyclase. Calmodulin could affect the activation of adenylate cyclase by GTP in the presence of 3,4-dihydroxyphenylethylamine (DA, dopamine). Calmodulin decreased by nearly 10-fold the concentration of GTP required to provide maximal stimulation of adenylate cyclase activity by DA in the striatal membranes. The characteristics of the effect of calmodulin on GTPase activity with respect to Ca2+ and calmodulin dependence and tissue specificity parallel those of the activation of adenylate cyclase by calmodulin, suggesting that the two activities are closely related.(ABSTRACT TRUNCATED AT 250 WORDS)     

Calmodulin plays a dominant role in determining neurotransmitter regulation of neuronal adenylate cyclase

Ca2+, through the mediation of calmodulin, stimulates the activity of brain adenylate cyclase. The growing awareness that fluctuating Ca2+ concentrations play a major role in intracellular signalling prompted the present study, which aimed to investigate the implications for neurotransmitter (receptor) regulation of enzymatic activity of this calmodulin regulation. The role of Ca2+/calmodulin in regulating neurotransmitter-mediated inhibition and stimulation was assessed in a number of rat brain areas. Ca2+/calmodulin stimulated adenylate cyclase activity in EGTA-washed plasma preparations from each region studied--from 1.3-fold (in striatum) to 3.4-fold (in cerebral cortex). The fold-stimulation produced by Ca2+/calmodulin was decreased in the presence of GTP, forskolin, or Mn2+. In EGTA-washed membranes, receptor-mediated inhibition of adenylate cyclase was strictly dependent upon Ca2+/calmodulin stimulation in all regions, except striatum. A requirement for Mg2+ in combination with Ca2+/calmodulin to observe neurotransmitter-mediated inhibition was also observed. In contrast, receptor-mediated stimulation of activity was much greater in the absence of Ca2+/calmodulin. The findings demonstrate that ambient Ca2+ concentrations, in concert with endogenous calmodulin, may play a central role in dictating whether inhibition or stimulation of adenylate cyclase by neurotransmitters may proceed.     

Insulin release and protein phosphorylation: possible role of calmodulin

Both Ca2+ and cyclic AMP (cAMP) are implicated in the regulation of insulin release in the pancreatic beta cell. In hamster insulinoma cells used in our laboratory to study the mechanism of insulin release, Ca2+ and cAMP trigger secretion independently. Concomitant with stimulation of the secretory apparatus both cAMP and Ca2+ promote phosphorylation of distinct insulinoma cell proteins. Calmodulin may be involved in the stimulation of insulin release and protein phosphorylation induced by Ca2+ influx. The Ca2+-dependent protein kinase of the insulinoma cell is activated by exogenous calmodulin and blocked by trifluoperazine, and inhibitor of calmodulin action. This drug also inhibits glucose-induced insulin release in pancreatic islets. In insulinoma cells trifluoperazine blocks Ca2+ influx-mediated insulin release and protein phosphorylation with no effect on basal or cAMP-mediated insulin release and protein phosphorylation with no effect on basal or cAMP-mediated secretion. Inhibition of Ca2+ influx-mediated insulin release and protein phosphorylation occurs with nearly identical dose dependence. Inasmuch as trifluoperazine affects voltage-dependent Ca2+ uptake in insulinoma cells, an involvement of calmodulin cannot be directly inferred. The evidence suggests that protein phosphorylation may be involved in the activation of the secretory apparatus by both cAMP and Ca2+. It is proposed that stimulation of insulin release by cAMP and Ca2+ is mediated by cAMP-dependent protein kinase and calmodulin-dependent protein kinase, respectively.     

Mechanism of Ca(2+)-dependent desensitization in TRP channels

The 30+ members of the family of TRP channels are diverse in their physiological roles, yet the mechanisms that regulate their gating may be conserved. In particular, all TRP channels show an activity-dependent inhibition which is mediated by Ca(2+). The mechanism by which Ca(2+) inhibits TRP channels is currently a matter of intense debate, with Ca(2+)-regulated kinases, phosphatases, phospholipases and calmodulin all proposed to be involved. In this review, we will discuss different mechanisms for Ca(2+)-dependent desensitization in TRP channels. We will conclude with a model that focuses on Ca(2+)-dependent activation of phospholipase C and Ca(2+) binding to calmodulin and propose that the phospholipase C and calmodulin pathways are structurally and functionally coupled.     

Interaction of tertiapin, a neurotoxin from bee venom, with calmodulin

Tertiapin, a neurotoxin from the honey bee venom, interacts specifically with calmodulin in the presence of Ca2+. The nature of this interaction was studied using calmodulin-cAMP phosphodiesterase system. Tertiapin does not affect the unstimulated basal activity of phosphodiesterase. However, it totally inhibits the enzyme-activating capacity of calmodulin. Analysis of the dose-dependent activation of phosphodiesterase by calmodulin in the presence of tertiapin indicated that inhibition is caused by the interaction of two tertiapin molecules with calmodulin (Kd 2 microM). The data obtained suggest that the toxic effect of tertiapin in nervous tissue is mediated by blockade of calmodulin function.     

Ca2+ stimulates the Mg2(+)-ATPase activity of brush border myosin I with three or four calmodulin light chains but inhibits with less than two bound.

Brush border myosin I from chicken intestinal microvilli is a membrane-associated, single-headed myosin composed of a 119-kDa heavy chain and several calmodulin light chains. We first describe in detail a new procedure for the rapid purification of brush border myosin I in greater than 99% purity with a yield of 40%, significantly higher than for previous methods. The subunit stoichiometry was determined to be 4 calmodulin light chains/myosin I heavy chain by amino acid compositional analysis of the separated subunits. We have studied the effects of Ca2+ and temperature on dissociation of calmodulin from myosin I and on myosin I Mg2(+)-ATPase and contractile activities. At 30 degrees C the actin-activable ATPase activity is stimulated 2-fold at 10-700 microM Ca2+. Dissociation of 1 calmodulin occurs at 25-50 microM Ca2+, but this has no effect on actin activation. The contractile activity of myosin I, expressed as superprecipitation, is greatly enhanced by Ca2+ under conditions in which 1 calmodulin is dissociated. This calmodulin is thus not essential for actin activation or superprecipitation. Myosin I was found to be highly temperature-sensitive, with an increase to 37 degrees C resulting in dissociation of 1 calmodulin at below 10(-7) M Ca2+ and an additional 1.5 calmodulins at 1-10 microM Ca2+. A complete loss of actin activation accompanies the Ca2(+)-induced calmodulin dissociation at 37 degrees C. Our conclusion is that physiological levels of Ca2+ can either stimulate or inhibit the mechanoenzyme activities of brush border myosin I in vitro, with the mode of regulation determined by the number of associated calmodulin light chains.     

Activation by calmodulin of inositol-1,4,5-trisphosphate 3-kinase in guinea pig peritoneal macrophages

The activity of inositol-1,4,5-trisphosphate 3-kinase in the cytosol fraction of guinea pig macrophages was assayed with special reference to the dependence on the free Ca2+ concentration. The enzyme activity, as assessed by the production of inositol 1,3,4,5-tetrakisphosphate was reversibly activated by free Ca2+ concentrations ranging from 10(-7) to 10(-6)M. The calmodulin antagonists, W-7 and chlorpromazine, inhibited the Ca2+-activated enzyme activity in a dose-dependent fashion, thereby indicating that calmodulin may be involved in the activation by Ca2+. The content of calmodulin in the cytosol fraction (about 2.8 micrograms/mg of cytosol protein) was markedly reduced to less than 0.03 microgram/mg of proteins by subfractionation by ammonium sulfate, followed by an anion-exchange chromatography. The subfraction obtained by the chromatography showed no Ca2+ dependence in the enzyme activity, while an exogenous addition of calmodulin with 10(-6)M Ca2+ increased the enzyme activity. The enzyme activity was retained on a calmodulin-affinity column in the presence of Ca2+, and was eluted from the column by lowering the free Ca2+ concentration by adding ethylene glycol bis(beta-aminoethyl ether)-N,N'-tetraacetic acid. These results clearly indicate that calmodulin activates the inositol-1,4,5-trisphosphate 3-kinase activity.     

Calmodulin Stimulation of Ca2+-Dependent ATP Hydrolysis and ATP-Dependent Ca2+ Transport in Synaptic Membranes

We report here characterization of calmodulin-stimulated Ca2+ transport activities in synaptic plasma membranes (SPM). The calcium transport activity consists of a Ca2+-stimulated, Mg2+-dependent ATP hydrolysis coupled with ATP-dependent Ca2+ uptake into membraneous sacs on the cytosolic face of the synaptosomal membrane. These transport activities have been found in synaptosomal subfractions to be located primarily in SPM-1 and SPM-2. Both Ca2+-ATPase and ATP-dependent Ca2+ uptake require calmodulin for maximal activity (KCm for ATPase = 60 nM; KCm for uptake = 50 nM). In the reconstituted membrane system, KCa was found to be 0.8 microM for Ca2+-ATPase and 0.4 microM for Ca2+ uptake. These results demonstrate for the first time the calmodulin requirements for the Ca2+ pump in SPM when Ca2+ ATPase and Ca2+ uptake are assayed under functionally coupled conditions. They suggest that calmodulin association with the membrane calcium pump is regulated by the level of free Ca2+ in the cytoplasm. The activation by calmodulin, in turn, regulates the cytosolic Ca2+ levels in a feedback process. These studies expand the calmodulin hypothesis of synaptic transmission to include activation of a high-affinity Ca2+ + Mg2+ ATPase as a regulator for cytosolic Ca2+.     

Activation of skeletal muscle myosin light chain kinase by calcium(2+) and calmodulin

Many biological processes are now known to be regulated by Ca2+ via calmodulin (CM). Although a general mechanistic model by which Ca2+ and calmodulin modulate many of these activities has been proposed, an accurate quantitative model is not available. A detailed analysis of skeletal muscle myosin light chain kinase activation was undertaken in order to determine the stoichiometries and equilibrium constants of Ca2+, calmodulin, and enzyme catalytic subunit in the activation process. The analysis indicates that activation is a sequential, fully reversible process requiring both Ca2+ and calmodulin. The first step of the activation process appears to require binding of Ca2+ to all four divalent metal binding sites on calmodulin for form the complex, Ca42+-calmodulin. This complex then interacts with the inactive catalytic subunit of the enzyme to form the active holoenzyme complex, Ca42+-calmodulin-enzyme. Formation of the holoenzyme follows simply hyperbolic kinetics, indicating 1:1 stoichiometry of Ca42+-calmodulin to catalytic subunit. The rate equation derived from the mechanistic model was used to determine the values of KCa2+ and KCM, the intrinsic activation constants for each step of the activation process. KCa2+ and KCM were found to have values of 10 microM and 0.86 nM, respectively, at 10 mM Mg2+. The rate equation using these equilibrium constants accurately predicts the extent of enzyme activation over a wide range of Ca2+ and calmodulin concentrations. The kinetic model and analytical techniques employed herein may be generally applicable to other enzymes with similar regulatory schemes.     

Characterization of a calmodulin-stimulated adenylate cyclase from abalone spermatozoa

Abalone sperm adenylate cyclase activity is particulate in nature and displays a high Mg2+-supported activity (Mg2+/Mn2+ = 0.8) as compared to other sperm adenylate cyclases. Approximately 90% of the enzyme activity in crude homogenates is inhibited by EGTA in a concentration-dependent manner which is overcome by added micromolar free Ca2+. The EGTA-inhibited Ca2+-stimulated enzyme activity is also inhibited by phenothiazines. Added calmodulin, however, has no effect on enzyme activity prepared from crude homogenates. Preparation of a twice EGTA-extracted 48,000 X g pellet fraction yields a particulate enzyme activity that can be stimulated 10-65% by added calmodulin in the presence of micromolar free Ca2+. Detergent extraction (1% Lubrol PX) of the EGTA-washed 48,000 X g pellet solubilizes 2-5% of the total particulate adenylate cyclase activity, and this solubilized enzyme is activated up to 125% by calmodulin. The ability of the different enzyme preparations to be stimulated by calmodulin is inversely proportional to the endogenous calmodulin concentration. Calmodulin stimulation of the Lubrol PX-solubilized enzyme is specific to this Ca2+-binding protein and is mediated as an effect on the velocity of the enzyme. This stimulation is completely Ca2+ dependent and is fully reversible. These data suggest that the control of sperm cAMP synthesis by changes in Ca2+ conductance may be mediated via this Ca2+-binding protein.     

Calmodulin, synchronous and asynchronous release of neurotransmitter

Evidence collected from studies on a wide range of secretory cells suggests that calmodulin may play an important role in stimulus-secretion coupling. Work on synaptosomes, central synaptic preparations and chromaffin cell preparations indicates that calmodulin probably also acts as the intracellular Ca2+-receptor for secretion in neuronal cells, Ca2+-binding resulting in activation of protein kinases and phosphorylation of certain secretory vesicle proteins. Studies on the effects of calmodulin-binding drugs at peripheral synapses have given surprising results, particularly the finding that evoked (synchronous) transmitter release is not suppressed by calmodulin inhibition, though asynchronous release can be markedly inhibited. It is suggested that the insensitivity of synchronous release to drug treatment is due to the fact that only vesicle-bound calmodulin is involved in this form of transmitter secretion. Asynchronous release, however, involves recruitment of cytosolic calmodulin and can therefore be inhibited by calmodulin-binding drugs.     

Calmodulin activation and inhibition of skeletal muscle Ca2+ release channel (ryanodine receptor).

The calmodulin-binding properties of the rabbit skeletal muscle Ca2+ release channel (ryanodine receptor) and the channel's regulation by calmodulin were determined at < or = 0.1 microM and micromolar to millimolar Ca2+ concentrations. [125I]Calmodulin and [3H]ryanodine binding to sarcoplasmic reticulum (SR) vesicles and purified Ca2+ release channel preparations indicated that the large (2200 kDa) Ca2+ release channel complex binds with high affinity (KD = 5-25 nM) 16 calmodulins at < or = 0.1 microM Ca2+ and 4 calmodulins at 100 microM Ca2+. Calmodulin-binding affinity to the channel showed a broad maximum at pH 6.8 and was highest at 0.15 M KCl at both < or = 0.1 MicroM and 100 microM Ca2+. Under condition closely related to those during muscle contraction and relaxation, the half-times of calmodulin dissociation and binding were 50 +/- 20 s and 30 +/- 10 min, respectively. SR vesicle-45Ca2+ flux, single-channel, and [3H]ryanodine bind measurements showed that, at < or = 0.2 microM Ca2+, calmodulin activated the Ca2+ release channel severalfold. Ar micromolar to millimolar Ca2+ concentrations, calmodulin inhibited the Ca(2+)-activated channel severalfold. Hill coefficients of approximately 1.3 suggested no or only weak cooperative activation and inhibition of Ca2+ release channel activity by calmodulin. These results suggest a role for calmodulin in modulating SR Ca2+ release in skeletal muscle at both resting and elevated Ca2+ concentrations.     

Preparation of an enzymatically active cross-linked complex between brain cyclic nucleotide phosphodiesterase and 3-(2-pyridyldithio)propionyl-substituted calmodulin

Cyclic nucleotide phosphodiesterase (0.07 nM) was activated by near stoichiometric concentrations of [3-(2-pyridyldithio)propionyl]calmodulin (PDP-CaM) after initial incubation of these proteins at 200-fold higher concentrations; activity in assays with EGTA was 80% of that in the presence of Ca2+. The enzyme incubated with native calmodulin under identical conditions required approximately 1 nM for half-maximal activation, and no activation was observed in the absence of calcium. These data suggested formation of a covalent complex between phosphodiesterase and PDP-CaM. On high-performance gel-permeation chromatography in the presence of metal chelators, the complex appeared considerably larger than the native enzyme. Incubation of phosphodiesterase with the thiolated (inactivated) form of PDP-CaM did not change its chromatographic behavior, indicating that reactive sulfhydryl groups were involved in complex formation. Although the total activities recovered from chromatography were not significantly different, maximal activation of PDP-CaM-phosphodiesterase complex was only approximately 20%, whereas the control enzyme was activated 6-8-fold by Ca2+ plus calmodulin. Kinetics of cGMP hydrolysis in the presence of EGTA by the isolated complex differed from those of control enzyme but were indistinguishable from those of control enzyme assayed with saturating Ca2+ and CaM. The calmodulin antagonists W-7 and trifluoperazine had relatively little effect on activity of the PDP-CaM-phosphodiesterase complex. Incubation of the complex with dithiothreitol dramatically increased its Ca2+ and calmodulin responsiveness, suggesting that reduction of the disulfide cross-link released phosphodiesterase from the complex.(ABSTRACT TRUNCATED AT 250 WORDS)     

Protein phosphorylation in permeabilized pancreatic islet cells.

A system of digitonin-permeabilized islet cells was developed to characterize Ca2+- and calmodulin-dependent protein phosphorylation further and to determine whether activation of this membrane-bound process was sufficient for initiation of Ca2+-stimulated insulin secretion. The efficacy of digitonin in permeabilizing the plasma membrane was assessed by Trypan Blue exclusion, by extracellular leakage of lactate dehydrogenase, and by permeability to [gamma-32P]ATP. This treatment did not detectably alter the ultrastructure of the permeabilized cells. Digitonin was equally effective when presented to islet cells that had been previously dispersed or directly to intact isolated islets. The Ca2+- and calmodulin-dependent phosphorylation of endogenous membrane-bound substrates could be demonstrated in the permeabilized cells incubated with [gamma-32P]ATP. This activity displayed characteristics that were similar to those described for the protein kinase measured in subcellular fractions and was dependent on addition of exogenous calmodulin, indicating that calmodulin had been removed from the kinase by permeabilization of the cells. Ca2+-dependent insulin release by the digitonin-permeabilized islet was demonstrated, with half-maximal release occurring at 0.1 microM-free Ca2+ and maximal secretion at 0.2 microM-free Ca2+. Under these conditions, calmodulin did not further enhance insulin release, although a stimulatory effect of calmodulin was observed in the absence of free Ca2+. These studies indicate that the permeabilized-islet model will be useful in dissecting out the factors involved in Ca2+-activated insulin secretion.     

Biochemical characterization of the inhibitory effect of CsA on cytolytic T lymphocyte effector functions

We have examined the effects of cyclosporine A (CsA) on a number of CTL effector functions. CsA partially inhibited the CTL-mediated lysis of Ag-bearing target cells. Both target cell- and anti-TCR mAb-induced granule exocytosis were markedly inhibited by CsA. In addition, marked inhibition of PMA and calcium ionophore (A23187) induced granule exocytosis was produced by CsA suggesting that the inhibitory effects of CsA on granule exocytosis involve biochemical events after protein kinase C activation and increases in intracellular free Ca2+. CsA had no inhibitory effects on TCR-mediated phosphatidylinositol metabolism. The inhibitory effects of CsA were not mediated by the cAMP-dependent protein kinase inhibitory pathway and no effect of CsA on the Ca2+-induced binding of calmodulin to calmodulin-binding proteins could be demonstrated. CsA was also a potent inhibitor of IgE receptor-mediated exocytosis in rat basophil leukemia cells. CsA had no effect on receptor-mediated phosphatidylinositol hydrolysis; 400 ng/ml CsA resulted in a 90% inhibition of serotonin release but had no effect on phosphatidylinositol hydrolysis. These results indicate that CsA may inhibit some common event in Ca2+-dependent secretory cells. Taken together, these results suggest that CsA does not inhibit signal transduction but rather interferes with the biochemical events in the later stages of Ca2+-dependent reactions that follow the binding of calmodulin to cytoskeletal or cytoplasmic calmodulin binding proteins.