Dual Ca2 Research Articles

Ucp2 Modulates Cellular Excitation Contraction Coupling via Mitochondrial Calcium Uptake

Introduction: Mitochondrial Ca2+ handling modulates the spatial and temporal profile of intracellular Ca2+ signaling. It is mainly mediated by the mitochondrial calcium uniporter (MCU). Uncoupling protein-2 (UCP2) a mitochondrial membrane protein has been proposed to be fundamental for MCU activity. Whether cellular excitation contraction (EC) coupling is modulated by UCP2 remains to be determined. Methods: To investigate this scenario, we isolated intact cardiomyocytes from adult wild-type (WT) and B6.129S4-Ucp2tm1Lowl/J (UCP2-/-) mice to analyze dual Ca2+ transients from the mitochondrial ((Ca2+)m) and intracellular compartment ((Ca2+)c) in the whole cell configuration using Rhod2-AM and Fluo4 pentapotassium salt. We also tested whether the previously described inhibitory effect of ATP on mitochondrial Ca2+ uptake could be mediated by UCP2. To detect possible regulatory effects on sarcolemmal Ca2+ uptake in UCP2-/- mice, trigger Ca2+ influx was measured using Ryanodine. Results: In cardiomyocytes of WT mice (Ca2+)m was selectively decreased by Ruthenium360 (Ru360) while (Ca2+)c was upregulated. The (Ca2+)m was decreased in UCP2-/- myocytes compared to WT while (Ca2+)c was unchanged suggesting a compensational modulation of EC coupling. Trigger Ca2+ influx was reduced in UCP2-/- vs. WT myocytes, presumably to prevent cytosolic Ca2+ overload. Additionally, we observed an inhibitory effect of ATP on mitochondrial Ca2+ uptake in myocytes of WT mice while no effect was observed in UCP2-/- mice. Conclusion: Our experiments suggest a possible role of MCU and UCP2 interaction in controlling mitochondrial Ca2+ uptake as well as EC coupling.

Vascular KCNQ Potassium Channels as Therapeutic Targets in Cerebral Vasospasm

Following subarachnoid hemorrhage, chronic narrowing of cerebral arteries, including basilar artery, leads to reduction of blood flow to the brain and results in high morbidity and mortality. During vasospasm, cerebrospinal fluid levels of putative spasmogens, endothelin‐1, serotonin, and vasopressin (AVP) are elevated. However the mechanisms by which they produce vasospasm are not clear. We recently found that AVP suppresses KCNQ (Kv7) potassium currents in mesenteric artery myocytes. This depolarizes the membrane leading to activation of voltage‐gated Ca2+ channels and arterial constriction. Here we propose that KCNQ channels are also central mediators of cerebral vasospasm. We used patch clamp electrophysiology in myocytes and pressure myography in isolated artery segments to characterize the role of KCNQ channels in rat basilar artery vasospasm. The spasmogens all suppress KCNQ currents in basilar artery myocytes. Flupirtine, a KCNQ channel opener, reversed the suppression of KCNQ currents and basilar artery constriction induced by the spasmogens. Celecoxib, a dual KCNQ channel opener and Ca2+ channel blocker was more effective than nimodipine in dilating basilar arteries. These findings provide the first evidence that KCNQ channels are expressed and functional in basilar artery and suggest that these channels are potential novel targets for therapeutic intervention in cerebral vasospasm. This work was supported by the NIH (R01‐HL089564 to KLB) and the AHA (09PRE2260209 to BKM)

Bcl-xL Regulation of InsP3 Receptor Gating Mediated by Dual Ca2+ Release Channel BH3 Domains

Interaction of anti-apoptotic Bcl-xL with inositol trisphosphate receptor (InsP3R) Ca2+ release channels sensitize them to InsP3, enhancing low-level constitutive Ca2+ signaling that affords apoptosis resistance (White et al. Nat Cell Biol 7(2005); Li et al. PNAS 104(2007)). Here, we have identified two binding domains in the channel C-terminus that are both required for channel activation: the first is located at the bottom of TM6 immediately distal to the gate, and the second is near the extreme C-terminus. Each site binds to anti-apoptotic Bcl-2, Bcl-xL and Mcl-1 with similar affinities, but not to pro-apoptotic Bid or Bax. Bcl-xL binding to a construct containing both sites had apparent affinity several times higher than for either individual site or for Bax. Bcl-xL interaction with Bcl-2 proteins is mediated by pro-apoptotic protein BH3 domains. Several features suggest that each binding site in the InsP3R is similar to a BH3 domain. Sequence and secondary structural features are reminiscent of BH3 domains; mutations of key residues known to disrupt BH3 domain interactions disrupted Bcl-XL binding to either channel site; mutations in Bcl-xL that disrupt binding to BH3 domains inhibited binding to the channel sites; ABT-737 that binds in the Bcl-XL BH3 binding pocket inhibited binding to each channel site. In single-channel recordings, Bcl-xL activation of gating was abolished by mutations of either channel BH3-like domain or of the Bcl-xL BH3 binding pocket, or by ABT-737. These results suggest that dimeric Bcl-xL cross-links TM6 and the distal C-terminus through interactions involving channel BH3 domains. This interaction allosterically enhances the channel sensitivity to InsP3 by enabling the channel to open more easily.

Ca2+-stimulated Basal Adenylyl Cyclase Activity Localization in Membrane Lipid Microdomains of Cardiac Sinoatrial Nodal Pacemaker Cells

Spontaneous, rhythmic subsarcolemmal local Ca(2+) releases driven by cAMP-mediated, protein kinase A (PKA)-dependent phosphorylation are crucial for normal pacemaker function of sinoatrial nodal cells (SANC). Because local Ca(2+) releases occur beneath the cell surface membrane, near to where adenylyl cyclases (ACs) reside, we hypothesized that the dual Ca(2+) and cAMP/PKA regulatory components of automaticity are coupled via Ca(2+) activation of AC activity within membrane microdomains. Here we show by quantitative reverse transcriptase PCR that SANC express Ca(2+)-activated AC isoforms 1 and 8, in addition to AC type 2, 5, and 6 transcripts. Immunolabeling of cell fractions, isolated by sucrose gradient ultracentrifugation, confirmed that ACs localize to membrane lipid microdomains. AC activity within these lipid microdomains is activated by Ca(2+) over the entire physiological Ca(2+) range. In intact SANC, the high basal AC activity produces a high level of cAMP that is further elevated by phosphodiesterase inhibition. cAMP and cAMP-mediated PKA-dependent activation of ion channels and Ca(2+) cycling proteins drive sarcoplasmic reticulum Ca(2+) releases, which, in turn, activate ACs. This feed forward "fail safe" system, kept in check by a high basal phosphodiesterase activity, is central to the generation of normal rhythmic, spontaneous action potentials by pacemaker cells.

Synthesis, QSAR and Calcium Channel Modulator Activity of New Hexahydroquinoline Derivatives Containing Nitroimidazole

The discovery that 1,4-dihydropyridine class of calcium channel antagonists inhibit Ca2+ influx represented a major therapeutic advance in the treatment of cardiovascular disease. In contrast to the effects of known calcium channel blockers of the Nifedipine-type, the so-called calcium channel agonists, such as Bay K8644 and CGP 28392, increase calcium influx by binding at the same receptor regions. Our goal was to discover a dual cardioselective Ca2+-channel agonist/vascular selective smooth muscle Ca2+ channel antagonist third-generation 1,4-dihydropyridine drug which would have a suitable therapeutic profile for treating congestive heart failure (CHF) patients. A series of unsymmetrical alkyl, cycloalkyl and aryl ester analogues of 2-methyl-4-(1-methyl)-5-nitro-2-imidazolyl-5-oxo-1,4,5,6,7, 8-hexahydroquinolin-3-arboxylate were synthesized using modified Hantzsch reaction. All compounds show calcium antagonist activity on guinea-pig ileum longitudinal smooth muscle and some of them show agonist effect activity on guinea-pig auricle. Effect of structural parameters on the Ca2+ channel agonist/antagonist was evaluated by quantitative structure-activity relationship analysis. These compounds could be considered as a synthon for developing a suitable drug for treating CHF patients.

A Gain-of-Function Mutation in Synaptotagmin-1 Reveals a Critical Role of Ca2+-Dependent SolubleN-Ethylmaleimide-Sensitive Factor Attachment Protein Receptor Complex Binding in Synaptic Exocytosis

Synaptotagmin-1, the Ca2+ sensor for fast neurotransmitter release, was proposed to function by Ca2+-dependent phospholipid binding and/or by Ca2+-dependent soluble N-ethylmaleimide-sensitive factor attachment protein receptor (SNARE) complex binding. Extensive in vivo data support the first hypothesis, but testing the second hypothesis has been difficult because no synaptotagmin-1 mutation is known that selectively interferes with SNARE complex binding. Using knock-in mice that carry aspartate-to-asparagine substitutions in a Ca2+-binding site of synaptotagmin-1 (the D232N or D238N substitutions), we now show that the D232N mutation dramatically increases Ca2+-dependent SNARE complex binding by native synaptotagmin-1, but leaves phospholipid binding unchanged. In contrast, the adjacent D238N mutation does not significantly affect SNARE complex binding, but decreases phospholipid binding. Electrophysiological recordings revealed that the D232N mutation increased Ca2+-triggered release, whereas the D238N mutation decreased release. These data establish that fast vesicle exocytosis is driven by a dual Ca2+-dependent activity of synaptotagmin-1, namely Ca2+-dependent binding both to SNARE complexes and to phospholipids.

Dual Ca2+ modulation of glycinergic synaptic currents in rodent hypoglossal motoneurones

Glycinergic synapses are implicated in the coordination of reflex responses, sensory signal processing and pain sensation. Their activity is pre- and postsynaptically regulated, although mechanisms are poorly understood. Using patch-clamp recording and Ca2+ imaging in hypoglossal motoneurones from rat and mouse brainstem slices, we address here the role of cytoplasmic Ca2+ (Ca(i)) in glycinergic synapse modulation. Ca2+ influx through voltage-gated or NMDA receptor channels caused powerful transient inhibition of glycinergic IPSCs. This effect was accompanied by an increase in both the failure rate and paired-pulse ratio, as well as a decrease in the frequency of mIPSCs, suggesting a presynaptic mechanism of depression. Inhibition was reduced by the cannabinoid receptor antagonist SR141716A and occluded by the agonist WIN55,212-2, indicating involvement of endocannabinoid retrograde signalling. Conversely, in the presence of SR141716A, glycinergic IPSCs were potentiated postsynaptically by glutamate or NMDA, displaying a Ca2(+)-dependent increase in amplitude and decay prolongation. Both presynaptic inhibition and postsynaptic potentiation were completely prevented by strong Ca(i) buffering (20 mm BAPTA). Our findings demonstrate two independent mechanisms by which Ca2+ modulates glycinergic synaptic transmission: (i) presynaptic inhibition of glycine release and (ii) postsynaptic potentiation of GlyR-mediated responses. This dual Ca2(+)-induced regulation might be important for feedback control of neurotransmission in a variety of glycinergic networks in mammalian nervous systems.

A Developmental Switch in the Excitability and Function of the Starburst Network in the Mammalian Retina

Dual patch-clamp recording and Ca2+ uncaging revealed Ca2+-dependent corelease of ACh and GABA from, and the presence of reciprocal nicotinic and GABAergic synapses between, starburst cells in the perinatal rabbit retina. With maturation, the nicotinic synapses between starburst cells dramatically diminished, whereas the GABAergic synapses remained and changed from excitatory to inhibitory, indicating a coordinated conversion of the starburst network excitability from an early hyperexcitatory to a mature nonepileptic state. We show that this transition allows the starburst cells to use their neurotransmitters for two completely different functions. During early development, the starburst network mediates recurrent excitation and spontaneous retinal waves, which are important for visual system development. After vision begins, starburst cells release GABA in a prolonged and Ca2+-dependent manner and inhibit each other laterally via direct GABAergic synapses, which may be important for visual integration, such as the detection of motion direction.

Isradipine prevents the development of spontaneously occurring cardiac necrosis in cardiomyopathic hamster.

Recent studies on the heart necrotizing process at the early stages of hamster polymyopathy have led us to believe that this hereditary disease derives from an anomalous transmembrane ion flux due to the presence of slow Na+ channels that contribute to intracellular Na+ accumulation which promote intracellular Ca2+ overload via the Ca2+ influx through the Na+-Ca2+ exchanger. In the present study, we investigated the potential beneficial effect of chronic treatment with a dual L-type Ca2+ and slow Na+ channel blockers isradipine, on the development of necrosis in myopathic hamster hearts. Young cardiomyopathic (CM) hamsters (CMH) were treated with isradipine (0.1 mg x kg(-1) x day(-1)) and nifedipine (1 mg x kg(-1) x day(-1)) for 4 consecutive weeks. Microscopic assessments were carried out in staged serial paraffin sections of heart ventricles from tissues freshly dissected at autopsy. In comparison with control nontreated hearts, which exhibited numerous necrotic calcific foci, myolytic lesions, and dilated right ventricle, isradipine treatment prevented, in a significant manner, all the above spontaneous pathological changes, while nifedipine had no effect. Our present observations provide evidence for the first time that in vivo treatment with a DHP Ca2+ channel blocker, isradipine, is cardioprotective against the development of necrosis in hereditary cardiomyopathy in the hamster. It is possible that the protective effect of isradipine in CMH could be largely due to the indirect blockade of Ca2+ influx through the Na+-Ca2+ exchanger as well as to possible direct blockade of Ca2+ influx through the T-type Ca2+ channel.

Intrinsic Bursting Alone Does Not Beget Seizures.

Long-Lasting Modification of Intrinsic Discharge Properties in Subicular Neurons Following Status Epilepticus Wellmer J, Su H, Beck H, Yaari Y Eur J Neurosci 2002;16:259–266 A single episode of status epilepticus (SE) induces neuropathologic changes in the brain that may lead to the development of a permanent epileptic condition. Most studies of this plasticity have focused on the hippocampus, where both synaptic function and intrinsic neuronal excitability have been shown to be persistently modified by SE. However, many other brain structures are activated during SE and also may be involved in the subsequent epileptogenic process. Here we investigated whether SE, induced in rats with pilocarpine and terminated after 40 minutes with diazepam (DZP), persistently modifies the intrinsic excitability of pyramidal neurons in the subiculum. Subicular slices were prepared from control and SE-experienced rats (2 to 5 weeks after SE). In the control group, only 4% of the neurons fired bursts in response to intrasomatic, threshold-straddling depolarizing current pulses (low-threshold bursters). The remaining neurons either fired bursts in response to strong (3 times threshold) depolarizations (35%; high-threshold bursters) or fired in a completely regular mode (61%; nonbursters). In the SE-experienced group, the fractions of low- and high-threshold bursters markedly increased to 29% and 53%, respectively. This change in firing behavior was associated with a marked increase in the size of the spike afterdepolarization, particularly in low-threshold bursters. Experimental suppression of Ca2+ currents selectively blocked low-threshold bursting but did not affect high-threshold bursting, suggesting that a dual Ca2+-dependent and Ca2+-independent mechanism controls bursting in these neurons. The persistent upregulation of intrinsic bursting in the subiculum, in concert with similar changes in the hippocampus, undoubtedly contributes to epileptogenesis after pilocarpine-induced SE.

Long-lasting modification of intrinsic discharge properties in subicular neurons following status epilepticus.

A single episode of status epilepticus (SE) induces neuropathological changes in the brain that may lead to the development of a permanent epileptic condition. Most studies of this plasticity have focused on the hippocampus, where both synaptic function and intrinsic neuronal excitability have been shown to be persistently modified by SE. However, many other brain structures are activated during SE and may also be involved in the subsequent epileptogenic process. Here we have investigated whether SE, induced in rats with pilocarpine and terminated after 40 min with diazepam, persistently modifies the intrinsic excitability of pyramidal neurons in the subiculum. Subicular slices were prepared from control and SE-experienced rats (2-5 weeks after SE). In the control group, only 4% of the neurons fired bursts in response to intrasomatic, threshold-straddling depolarizing current pulses (low-threshold bursters). The remaining neurons either fired bursts in response to strong (3x threshold) depolarizations (35%; high-threshold bursters) or fired in a completely regular mode (61%; nonbursters). In the SE-experienced group, the fractions of low- and high-threshold bursters markedly increased to 29% and 53%, respectively. This change in firing behaviour was associated with a marked increase in the size of the spike after depolarization, particularly in low-threshold bursters. Experimental suppression of Ca2+ currents selectively blocked low-threshold bursting but did not affect high-threshold bursting, suggesting that a dual Ca2+- dependent and Ca2+- independent mechanism controls bursting in these neurons. The persistent up-regulation of intrinsic bursting in the subiculum, in concert with similar changes in the hippocampus, undoubtedly contributes to epileptogenesis following pilocarpine-induced SE.

Nicotinic receptors mediate the release of amino acid neurotransmitters in cultured cortical neurons.

Nicotine stimulation of cortical neurons obtained from gestation day 19 rats provoked a dose-dependent release of aspartate, glutamate, glycine and GABA, indicating a functional role for the nicotinic receptor in this model. This release was exclusively Ca2+-dependent (vesicular release) in the case of aspartate and dual Ca2+-dependent and Ca2+-independent) for glutamate, glycine and GABA. Nicotine also raised the membrane potential and the intracellular calcium concentration. These effects were specific, since they were reversed by hexamethonium, an antagonist of the nicotinic receptor. It was shown that L, N, and P/Q type Ca2+ channels are involved in nicotine-mediated Ca2+ entry into cortical neurons. Evaluation of the effects of nicotine on Ca2+ entry in isolated cells showed that 100% of the cells responded to nicotine, although the intensity of the response was variable: 63% of the neurons showed an increase in intracellular Ca(2+) of 152 +/- 5 grey levels, 25% of 88 +/- 12 grey levels and 12% of 48 +/- 1 grey levels. Tetrodotoxin, which blocks voltage-dependent Na(+) channels, completely reversed nicotine-induced Ca2+ entry into single cells. This suggests that the Ca2+ increment is mediated by opening of Ca2+ channels and not by the nicotinic receptor.

Role of simian virus 40 Vp1 cysteines in virion infectivity.

We have developed a new nonoverlapping infectious viral genome (NO-SV40) in order to facilitate structure-based analysis of the simian virus 40 (SV40) life cycle. We first tested the role of cysteine residues in the formation of infectious virions by individually mutating the seven cysteines in the major capsid protein, Vp1. All seven cysteine mutants-C9A, C49A, C87A, C104A, C207S, C254A, and C267L-retained viability. In the crystal structure of SV40, disulfide bridges are formed between certain Cys104 residues on neighboring pentamers. However, our results show that none of these disulfide bonds are required for virion infectivity in culture. We also introduced five different mutations into Cys254, the most strictly conserved cysteine across the polyomavirus family. We found that C254L, C254S, C254G, C254Q, and C254R mutants all showed greatly reduced (around 100,000-fold) plaque-forming ability. These mutants had no apparent defect in viral DNA replication. Mutant Vp1's, as well as wild-type Vp2/3, were mostly localized in the nucleus. Further analysis of the C254L mutant revealed that the mutant Vp1 was able to form pentamers in vitro. DNase I-resistant virion-like particles were present in NO-SV40-C254L-transfected cell lysate, but at about 1/18 the amount in wild-type-transfected lysate. An examination of the three-dimensional structure reveals that Cys254 is buried near the surface of Vp1, so that it cannot form disulfide bonds, and is not involved in intrapentamer interactions, consistent with the normal pentamer formation by the C254L mutant. It is, however, located at a critical junction between three pentamers, on a conserved loop (G2H) that packs against the dual interpentamer Ca(2+)-binding sites and the invading C-terminal helix of an adjacent pentamer. The substitution by the larger side chains is predicted to cause a localized shift in the G2H loop, which may disrupt Ca(2+) ion coordination and the packing of the invading helix, consistent with the defect in virion assembly. Our experimental system thus allows dissection of structure-function relationships during the distinct steps of the SV40 life cycle.

Hypotonic stress-induced dual Ca(2+) responses in bovine aortic endothelial cells.

We have investigated the effects of hypotonic stress on intracellular calcium concentration ([Ca(2+)](i)) in bovine aortic endothelial cells. Reducing extracellular osmolarity by 5% to 40% elicited a steep Ca(2+) transient both in normal Krebs and Ca(2+)-free solutions. The hypotonic stress-induced Ca(2+) transient was inhibited by phospholipase C inhibitors (neomycin and U-73122), a P(2)-receptor antagonist (suramin), and an ATP-hydrolyzing enzyme (apyrase), suggesting that the hypotonic stress-induced Ca(2+) transient is mediated by ATP. A luciferin-luciferase assay confirmed that 40% hypotonic stress released 91.0 amol/cell of ATP in 10 min. When the hypotonic stress-induced fast Ca(2+) transient was inhibited by neomycin, suramin, or apyrase, a gradual [Ca(2+)](i) increase was observed instead. This hypotonic stress-induced gradual [Ca(2+)](i) increase was inhibited by a phospholipase A(2) inhibitor, 4-bromophenacyl bromide. Furthermore, exogenously applied arachidonic acid induced a gradual [Ca(2+)](i) increase with an ED(50) of 13.3 microM. These observations indicate that hypotonic stress induces a dual Ca(2+) response in bovine aortic endothelial cells, i.e., an ATP-mediated fast Ca(2+) transient and an arachidonic acid-mediated gradual Ca(2+) increase, the former being the predominant response in normal conditions.

Ca2+ versus Zn2+ transport in the gills of freshwater rainbow trout and the cost of adaptation to waterborne Zn2+

Previous work suggested that Ca2+ and Zn2+ share a common uptake pathway in rainbow trout gills. We here report on relationships between the kinetic variables for unidirectional Ca2+ influx and unidirectional Zn2+ influx during a 1 month exposure of freshwater rainbow trout to Zn2+ (150 &micro;g l-1=2.3 &micro;mol l-1 as total zinc, Zn). Initial exposure to Zn2+ caused a large competitive inhibition of Ca2+ influx, as indicated by a threefold increase in apparent Km for Ca2+ (measured in the presence of Zn2+). There was also a smaller non-competitive inhibition (50 % decrease in Jmax) of the Ca2+ transport system, which was abolished after 1&shy;2 weeks of exposure. The Km, measured in the absence of Zn2+, decreased dramatically (i.e. elevated affinity) on days 1&shy;4 but increased thereafter; both true and apparent Km finally stabilized significantly above control levels. However, the Km values for Ca2+ (<200 &micro;mol l-1) were low relative to the Ca2+ level in the water (1000 &micro;mol l-1), and therefore the changes did not influence the actual Ca2+ influx of the fish, which tracked Jmax. In contrast, water [Zn2+] (2.3 &micro;mol l-1 as total Zn) was close to the reported apparent Km (3.7 &micro;mol l-1) for Zn2+ influx in the presence of 1000 &micro;mol l-1 Ca2+. Unidirectional Zn2+ influx increased during the first week of exposure to waterborne Zn2+, followed by a persistent reduction to about 50 % of control levels, effects that may be largely explained by the observed changes in true Km for Ca2+. We speculate that the initial response of the fish to elevated [Zn2+] is to compensate for a reduced availability of Ca2+ by markedly increasing the affinity of a dual Ca2+/Zn2+ transporter. Once the Ca2+ influx is 'corrected' by restoration of functional transport sites (Jmax), the system is tuned to limit the influx of Zn2+ by a persistent reduction in the affinities for both ions. The changes in influx characteristics for Ca2+ and Zn2+ were correlated with internal physiological alterations indicative of adaptation to Zn2+ and increased metabolic cost. Depressed plasma [Ca] was corrected within 1 week, and there were no effects on whole-body [Ca] or [Zn]. A slight accumulation of Zn in the gills was associated with increased branchial metallothionein levels. Rates of protein synthesis and degradation in the gills were initially increased and whole-body growth was transiently impaired, effects which were reversed after 18 days of exposure. Sublethal challenge with Zn2+ (at 450 &micro;g l-1=6.9 &micro;mol l-1 as total Zn) always depressed plasma [Ca] in control fish, but by 1 month of exposure to Zn2+ at 150 &micro;g l-1 (as total Zn), experimental fish were resistant to challenge. However, the fish did not acquire increased survival tolerance (LT50) to a lethal concentration of Zn2+ (4 mg l-1=61 &micro;mol l-1 as total Zn).

Regulation of p68 RNA helicase by calmodulin and protein kinase C.

Human p68 RNA helicase is a nuclear RNA-dependent ATPase that belongs to a family of putative helicases known as the DEAD box proteins. These proteins have been implicated in aspects of RNA function including translation initiation, splicing, and ribosome assembly in a variety of organisms ranging from Escherichia coli to humans. While members of this family are believed to function in the manipulation of RNA secondary structure, little is known about the regulation of these enzymes. By immunological methods and sequence comparison, we have found that p68 possesses a region of sequence similarity to the conserved protein kinase C phosphorylation site and calmodulin binding domain (also known as the IQ domain) of the neural-specific proteins neuromodulin (GAP-43) and neurogranin (RC3). We report that p68 is phosphorylated by protein kinase C in vitro and binds calmodulin in a Ca(2+)-dependent manner. Both phosphorylation and calmodulin binding inhibited p68 ATPase activity, suggesting that the RNA unwinding activity of p68 may be regulated by dual Ca2+ signal transduction pathways through its IQ domain.

Dual Ca2+ requirement for optimal lipid peroxidation of low density lipoprotein by activated human monocytes.

The oxidative modification of LDL seems a key event in atherogenesis and may participate in inflammatory tissue injury. Our previous studies suggested that the process of LDL oxidation by activated human monocytes/macrophages required O2- and activity of intracellular lipoxygenase. Herein, we studied the mechanisms involved in this oxidative modification of LDL. In this study, we used the human monocytoid cell line U937 to examine the role of Ca2+ in U937 cell-mediated lipid peroxidation of LDL. U937 cells were activated by opsonized zymosan. Removal of Ca2+ from cell culture medium by EGTA inhibited U937 cell-mediated peroxidation of LDL lipids. Therefore, Ca2+ influx and mobilization were examined for their influence on U937 cell-mediated LDL lipid peroxidation. Ca2+ channel blockers nifedipine and verapamil blocked both Ca2+ influx and LDL lipid peroxidation by activated U937 cells. The inhibitory effects of nifedipine and verapamil were dose dependent. TMB-8 and ryanodine, agents known to prevent Ca2+ release from intracellular stores, also caused a dose-dependent inhibition of LDL lipid peroxidation by activated U937 cells while exhibiting no effect on Ca2+ influx. Thus, both Ca2+ influx through functional calcium channels and Ca2+ mobilization from intracellular stores participate in the oxidative modification of LDL by activated U937 cells. 45Ca2+ uptake experiments revealed profound Ca2+ influx during the early stages of U937 cell activation, however, the Ca2+ ionophore 4-bromo A23187 was unable to induce activation of U937 cells and peroxidation of LDL lipids. Release of intracellular Ca2+ by thapsigargin only caused a suboptimal peroxidation of LDL lipids. Our results indicate that although increases in intracellular Ca2+ levels provided by both influx and intracellular Ca2+ mobilization are required, other intracellular signals may be involved for optimal peroxidation of LDL lipids by activated human monocytes.

Effects of trifluoperazine on synaptically evoked potentials and membrane properties of CA1 pyramidal neurons of rat hippocampus in situ and in vitro.

The effects of trifluoperazine (TFP), a phenothiazine antipsychotic, on hippocampal activity were studied in the CA1 subfield, both in situ and in slices. In the extracellular studies in situ and in vitro, both somatic population spikes and dendritic excitatory postsynaptic potentials (EPSP) fields were depressed reversibly by TFP, applied by microiontophoresis or in the bath (50-100 microM). Similar effects were also seen during iontophoretic applications of sphingosine in situ. Like TFP (at micromolar concentrations) sphingosine is a dual Ca2+/calmodulin-dependent kinase and protein kinase C (PKC) inhibitor. In intracellular recordings from slices, 50-100 microM TFP induced a slow depolarization and a decrease in input resistance (RN), probably through a gamma-aminobutyric acid (GABA)-mediated increase in Cl- conductance (GCl). TFP also reduced the slow afterhyperpolarization (AHP) as well as electrically evoked inhibitory postsynaptic potentials (IPSPs), but EPSPs were augmented in both amplitude and duration. When CA1 neurons were voltage clamped, TFP elicited a corresponding inward current (consistent with depolarization), increased the leak conductance, and enhanced excitatory synaptic currents; whereas inhibitory synaptic currents and high-threshold Ca2+ currents were reduced. In conclusion, these effects of TFP--which cannot be readily explained by its potent antidopamine action--are in keeping with other evidence that both Ca2+/calmodulin-dependent kinase and PKC can modulate GCl-conductance and high-threshold Ca(2+)-conductance, as well as inhibitory and excitatory postsynaptic currents.

ATP-dependent and ATP-independent pathways of exocytosis revealed by interchanging glutamate and chloride as the major anion in permeabilized mast cells.

Most investigations of the mechanism of regulated exocytosis have involved the use of secretory cells permeabilized in glutamate-based electrolyte solutions. In our previous work we have used NaCl-based electrolyte solutions. For secretion to occur from rat mast cells under these latter conditions, a dual effector system comprising Ca2+ and a guanine nucleotide are required; together they are sufficient. Here we compare the secretion from mast cells permeabilized in solutions of different electrolytes. Replacement of Na+ by K+ had little effect. Replacement of Cl- by Br-, SO4-, gluconate, isethionate, acetate, tartrate, succinate, etc. affected the maximal extent of secretion elicited by the dual effectors Ca2+ and guanosine-5'-O-(3-thiotriphosphate) (Ca2(+)-plus-GTP-gamma-S) but had little influence on the effective affinity for Ca2+. The dicarboxylic amino acids (L- and D-glutamate, and L-aspartate) permitted exocytosis to be elicited by Ca2+ or GTP-gamma-S alone. Secretion stimulated by GTP-gamma-S is strongly inhibited by Cl- (50% inhibition by 20 mM Cl-), whereas the extent of Ca2(+)-induced secretion is proportional to the concentration of glutamate in mixed electrolyte buffers. Unlike dual-effector stimulation, secretion due to the single effectors requires adenosine triphosphate (ATP) and is prevented by inhibitors of protein kinase C. These results point to the existence of two parallel pathways for control of exocytosis in permeabilized cells, one ATP dependent, the other ATP independent.

Chelation of intracellular calcium blocks insulin action in the adipocyte.

The hypothesis that intracellular Ca2+ is an essential component of the intracellular mechanism of insulin action in the adipocyte was evaluated. Cells were loaded with the Ca2+ chelator quin-2, by preincubating them with quin-2 AM, the tetrakis(acetoxymethyl) ester of quin-2. Quin-2 loading inhibited insulin-stimulated glucose transport (IC50, 26 microM quin-2 AM) without affecting basal activity. The ability of insulin to stimulate glucose uptake in quin-2-loaded cells could be partially restored by preincubating cells with buffer supplemented with 1.2 mM CaCl2 and the Ca2+ ionophore A23187. These conditions had no effect on basal activity and omission of CaCl2 from the buffer prevented the restoration of insulin-stimulated glucose uptake by A23187. Quin-2 loading also inhibited insulin-stimulated glucose oxidation (IC50, 11 microM quin-2 AM) and the ability of insulin to inhibit cAMP-stimulated lipolysis (IC50, 78 microM quin-2 AM), without affecting their basal activities. Incubation of cells with 100 microM quin-2 or quin-2 AM had no effect on intracellular ATP concentration or the specific binding of 125I-labeled insulin to adipocytes. These findings suggest that intracellular Ca2+ is an essential component in the coupling of the insulin-activated receptor complex to cellular physiological/metabolic machinery. Furthermore, differing quin-2 AM dose-response profiles suggest the presence of dual Ca2+-dependent pathways in the adipocyte. One involves insulin stimulation of glucose transport and oxidation, whereas the other involves the antilipolytic action of insulin.